Durston and Craig on an infinite temporal past . . .

KF,

DS, we patently cannot traverse an endless span of steps of warrant in either direction step by step, pivoting on our finitude and fallibility given that a chunk of time, effort, energy will be taken up by each successive step in building a worldviws case. Pointing across the ellipsis of endlessness and imposing a conclusion is a finitely remote final step, even in Mathematics. And this ‘ent Maths, it is warranting worldviews. Why the persistent sidetrack on a tangential matter when you have already in effect acknowledged tangentiality? KF

Well, when you state "the infinite regress is absurd, we cannot even get to A step by step from infinity”, you are are certainly making a mathematical statement. This "warranted worldviews" argument makes a much weaker claim than the above, however. You are not showing that infinite regresses are absurd, or even that they raise any logical problems. Rather you are arguing that finite humans cannot comprehend them. The upshot is that we cannot dismiss the possibility that infinite regresses exist, which then leaves a gap in your argument. daveS

KF, Interesting proof published earlier this year: Mathematicians Bridge Finite-Infinite Divide

With a surprising new proof, two young mathematicians have found a bridge across the finite-infinite divide, helping at the same time to map this strange boundary. The boundary does not pass between some huge finite number and the next, infinitely large one. Rather, it separates two kinds of mathematical statements: “finitistic” ones, which can be proved without invoking the concept of infinity, and “infinitistic” ones, which rest on the assumption — not evident in nature — that infinite objects exist. Mapping and understanding this division is “at the heart of mathematical logic,” said Theodore Slaman, a professor of mathematics at the University of California, Berkeley. This endeavor leads directly to questions of mathematical objectivity, the meaning of infinity and the relationship between mathematics and physical reality.

The actual paper. daveS

KF,

The claim is, one is coming from the transfinitely remote, thus across a zone of endlessness.

Well, no, the ladder has infinitely many rungs, each finitely many steps from the ground. I've made no claims about coming from the "transfinitely remote".

Now, if our man was descending without beginning but at no time was he ever endlessly remote in stages, he was always only finitely removed.

Yes, that's true. I think we're making progress.

That is, his past becomes a problem: finite remove and finite stages will not span endlessness.

The fact that he was always finitely many steps from the ground is completely consistent with the fact that he has descended every one of the infinite number of steps on the ladder. n seconds ago he was on rung number n, for all natural numbers n. No rungs were missed.

What I think you are saying is in effect we have had a potentially infinite past. But that is just what we cannot have had. The real past, whatever it was, HAS to have been actualised. It is how we got here.

I am saying the past comprises an actual infinity (in this thought experiment).

The future is different, we may successively and open-endedly add, pointing onward.

Yes, just as ω and ω* are different.

We can specify a set with endlessness in it and may conceptually deliver it in an all at once grand step (which typically points across an ellipsis of endlessness) but what we never do is actually traverse the span in successive, cumulative finite stage steps.

What was actually traversed in successive finite stages was accumulatively finite. Must be. Finite past is implied.

Let's review:

1. The ladder has infinitely many rungs (in 1-1 correspondence with the natural numbers). 2. The man was on rung n, n seconds ago, for every natural number n. 3. The man has just reached rung 0.

What we have is a man descending an infinite ladder throughout an infinite past, just now completing his traversal of every rung. daveS

DS, You will see that I pointed to the case of a start-point then the case of beginningless descent on stipulation of an endlessly remote zone. (This points to the tree of surreal numbers, cf Ehrlich in OP as augmented.) The claim is, one is coming from the transfinitely remote, thus across a zone of endlessness. In particular, it is claimed or implied that our cosmos -- in relevant causally successive stages -- has come from an endlessly remote past to the present. Descending a ladder that is endlessly high to reach its foot is a drawing out of the essence of that. Now, if our man was descending without beginning but at no time was he ever endlessly remote in stages, he was always only finitely removed. That is, his past becomes a problem: finite remove and finite stages will not span endlessness. What I think you are saying is in effect we have had a potentially infinite past. But that is just what we cannot have had. The real past, whatever it was, HAS to have been actualised. It is how we got here. The future is different, we may successively and open-endedly add, pointing onward. In both cases, what we never actually traverse in finite stage steps is an endless span, such as is represented by an ellipsis of endlessness. The pink.blue tape example shows us why. It is in the endlessness that the transfinite property lies. We can specify a set with endlessness in it and may conceptually deliver it in an all at once grand step (which typically points across an ellipsis of endlessness) but what we never do is actually traverse the span in successive, cumulative finite stage steps. That seems firmly shown. And that is why the requirement of actual traversal in causally successive stages of the real past . . . whatever it was . . . to achieve the present (comparable to the successive accumulation of stepping up or down a ladder) implies finitude. What was actually traversed in successive finite stages was accumulatively finite. Must be. Finite past is implied. There was a distinct beginning to our causally successive world. This is also a clue to root of our world. There is now necessitated an a-causal, non successive finite stage accumulated root for our world. As I have said, non-being has no causal powers, and were there ever utter nothing, there thus would have been no succession -- nothingness would forever obtain. A real cosmos from true nothing is impossible. A cosmos now is and is of successive causal stage character, pointing to a beginning. The root of that beginning is necessary being that is of diverse character, no temporally successive causally dependent accumulation . . . or else we are just regressing the problem. We are looking into the strange conceptual world of eternal, necessary being as root of any temporal, causally successive world. The image that comes to mind is of lines of longitude converging at a north pole that is simultaneously due north of them all. And if this is beginning to sound like a scrunching of the spacetime domain into a point at infinity in effect that swallows them all, or as pointing to a higher order hyper space world or even like "in him we live and move and have our being" that is what it looks like we are peering into. The world of eternal forms is taking its revenge. Eternally contemplated in eternal mind. Mind with power to spin out a causally successive world: fiat lux . . . ! KF kairosfocus

KF,

In various ways, this has been discussed many times.

That's definitely an understatement! :-)

By the nature of this situation if one has been descending and reaches down to 0, his start point was finitely not endlessly remote.

Of course in the ladder example, it is assumed there was no start point.

And if he never started but was always descending in finite stage finite time steps, so long as he was actually endlessly remote he cannot traverse the endless span to reach a finite near neighbourhood of the 0 point.

He never started, but he also was never "endlessly remote" from the bottom rung. Do we have that squared away now?

1) There is/was no starting point. 2) At no time was he infinitely far from the bottom rung.

daveS

DS, the issue is the nature of endlessness. Once there is an endless span, as the pink vs blue tape example shows, on reaching any large but finite k, the k, k+1, k+2 etc can be placed in 1:1 correspondence with 0,1, 2 etc. This is a part of defining the counting numbers as infinite and two sets in 1:1 match will be of the same cardinality. That is, endlessness dominates and both are infinitely large, cardinality aleph null. So, going up stepwise to the far zone one cannot complete traversal of the endless. Coming down, the same endless span confronts the one who would come down from the endlessly remote to the point where the ladder stands on the ground, its level 0. By the nature of this situation if one has been descending and reaches down to 0, his start point was finitely not endlessly remote. And if he never started but was always descending in finite stage finite time steps, so long as he was actually endlessly remote he cannot traverse the endless span to reach a finite near neighbourhood of the 0 point. In various ways, this has been discussed many times. The pivotal issue is traversal of the endless span. KF kairosfocus

KF,

And it should be clear that if endlessness cannot be spanned going up, it cannot be spanned in steps down too.

That's exactly the question; and no, it isn't clear to me and to a number of authors who have published on this subject. What exactly is the justification? I would think that if this is true, you should be able to demonstrate it with no mention whatsoever of climbing up the ladder. daveS

DS Yes we are quite relieved at relative good news. The logic is direct, once distinct identity applies all three do. A sandbox where LEM may not, is a case where distinct identity is needed to get there. The problem with counting up to/down from the span of the endless ladder lies in the endlessness. Once that is there ahead, at any finite k, k, k+1 etc can go in 1:1 match endlessly with 0,1,2 etc. So you never get beyond a finite span in steps, endlessness remains before you. And it should be clear that if endlessness cannot be spanned going up, it cannot be spanned in steps down too. KF kairosfocus

KF,

(And a diagnosis on a close person has been dialled back, thank God.)

I'm glad to hear that. If you do run across a published argument showing that LEM and LNC are corollaries of LOI, then I would appreciate you posting it. Now regarding the ladder scenario:

Ponder such a ladder and imagine one of those inking counters. Have someone stamp a bottom plate 0, then rungs 1,2, 3 . . . but, you cannot complete stamping going up. Now imagine said ladder is being stamped by someone else counting down. He steps off rung 1, bends over on his knees (which pop alarmingly) then brushes away a very long beard and stamps 0 on the plate, gets up and says, finished. This cannot be done counting down, no more than it can be done going up. For the same reason of attempted completing of endlessness in steps.

Under the assumptions I am making about time, I agree that the person climbing up the ladder cannot complete the job in time. That's because I am assuming that every moment in the future is finitely many seconds from the present (or from the time he began climbing). But why is it impossible for the person climbing down to finish inking all the rungs? I don't see anything other than an assertion here. daveS

PS: While I am now here, the past week or so has seen an all quiet for the moment including a cluster of bad dogs that suddenly stopped barking after a major public meeting fizzled, with a sitting following being distinctly tame. (And a diagnosis on a close person has been dialled back, thank God.) I think my mind can give enough focus here for the moment, to comment a little bit on infinite successions in steps. My suggestion is that the relevant order type in a ladder of endless succession of rungs is w, omega. Ponder such a ladder and imagine one of those inking counters. Have someone stamp a bottom plate 0, then rungs 1,2, 3 . . . but, you cannot complete stamping going up. Now imagine said ladder is being stamped by someone else counting down. He steps off rung 1, bends over on his knees (which pop alarmingly) then brushes away a very long beard and stamps 0 on the plate, gets up and says, finished. This cannot be done counting down, no more than it can be done going up. For the same reason of attempted completing of endlessness in steps. kairosfocus

DS, My concern is not logics but the world in which such logics can be conceived. The sandbox logic should be understood to be just that -- a sandbox in a world. This is similar to the presence of Observer in Quantum work. Yes, we can set up a sandbox algebra as you describe but to do so we have to use distinct symbols or concepts which means we are relying on the triple laws. KF kairosfocus

KF,

DS, to get to fuzzy logic, you have to use things that have distinct identity starting with alphanumeric characters. The same obtains for quantum theory. Refining a partial set member concept requires thought using distinct identity and its immediately present co-laws. Try to conceptualise and communicate or reason without marking distinctions — impossible. So, the way we think about fuzzy logic has to reckon with that or fall into incoherence. KF

But I'm not saying anything contrary to distinct identity. In fact, I _believe_ there are fuzzy logics with two-valued identity relations but many-valued predicates. Therefore LOI is true but LEM (could be) false in such logics. daveS

KF,

I remain however quite busy here with developments so I cannot give much attention.

That's fine, no rush. With some bolding added:

I do note that if a stepwise finite stage traversal of the endless is impossible then it follows that this cannot be accomplished — completed, thus ending the endless (language here is trying to warn us) — in stages from the past to the present as much as from the present to the future.

Again, this hasn't been shown. That we cannot traverse a set of order type ω in time does not imply that we cannot traverse a set of order type ω* in time. You have not addressed the asymmetry between the two order types. If you believe that traversing sets of order type ω* in time is impossible, then you should be able to prove such without ever referring to any sets of order type ω. daveS

F/N: Putting background for the renewal of this long lived thread: https://uncommondescent.com/darwinism/pastafarians-not-giving-up-their-claim-to-be-a-religion/#comment-603347 >>37 daveSApril 19, 2016 at 6:22 am KF, Infinite regress being unattainable as endlessness cannot be traversed in finite stage steps, *Proof pending? 39 kairosfocusApril 19, 2016 at 6:34 am DS, proof given over and over, as the case of the thought exercise of pink and blue punched tapes shows. start both at 0, advance blue to arbitrarily large but finite k, then k+1 etc. Put blue from k in complete, endless 1:1 match with pink from 0. This shows pink is infinite and blue from k on is the same. Moreover as endlessness onward is always there from any finite k, no process of repeated finite stage steps can traverse that endlessness. I suggest this side issue goes back to its proper thread. KF 40 daveSApril 19, 2016 at 6:36 am KF, Thanks, I’ll respond in the other thread.>> I remain however quite busy here with developments so I cannot give much attention. I do note that if a stepwise finite stage traversal of the endless is impossible then it follows that this cannot be accomplished -- completed, thus ending the endless (language here is trying to warn us) -- in stages from the past to the present as much as from the present to the future. Infinite sets are delivered all at once, often by giving a general case and pointing to endlessness and across it. From potential to actual. But at no point is there ever an actual completion of endlessness in steps. with the tapes, for any k in our k-register, there will be always endlessness onwards from k+1 etc an infinite set is always there in front, untraversed from any finite k. KF kairosfocus

KF,

DS, proof given over and over, as the case of the thought exercise of pink and blue punched tapes shows. start both at 0, advance blue to arbitrarily large but finite k, then k+1 etc. Put blue from k in complete, endless 1:1 match with pink from 0. This shows pink is infinite and blue from k on is the same. Moreover as endlessness onward is always there from any finite k, no process of repeated finite stage steps can traverse that endlessness. I suggest this side issue goes back to its proper thread. KF

Modulo some issues with vocabulary, I don't disagree with this. Here's what I was referring to, with emphasis added:

Infinite regress being unattainable as endlessness cannot be traversed in finite stage steps,

I take this to mean that (paraphrasing) "because we cannot construct N starting with 0 and the successor operation, an infinite regress (for example, an infinite past) is impossible" . That is what I'm objecting to. The tapes example simply shows that two sets are infinite. It doesn't show that an infinite past (or an infinite regress) is impossible. daveS

KF,

I pointed to Godel’s theorems regarding complex systems in Maths.

Well, the real numbers are reasonably complex. Furthermore, I think much of our discussion could be conducted in the theory of Presburger arithmetic, which is also known to be complete and consistent. I'm concerned that we don't use Gödel's theorems to cast doubt on all forms of axiomatic reasoning, even when they don't apply.

Potential vs actually completed infinity is a relevant concept.

Maybe, but I'm not aware of it appearing in mathematics.

I suggest pondering HeKS’ ladder (recall Russell’s village barber illustration) to see the challenge of completed infinite descent. KF

I haven't seen any straightforward contradiction derived from the ladder illustration, as there is with the barber paradox. I still stand by my claim that none of the arguments presented so far against an infinite past succeed. daveS

DS, again, my focus has to be local. I pointed to Godel's theorems regarding complex systems in Maths. Potential vs actually completed infinity is a relevant concept. I suggest pondering HeKS' ladder (recall Russell's village barber illustration) to see the challenge of completed infinite descent. KF kairosfocus

KF,

Including that post Godel, axiomatic systems are incomplete or incoherent, and there is no constructive process that guarantees coherence of axiom systems.

To the contrary, there are many axiomatic systems that are known to be complete and consistent. For example, the theory of real numbers is both complete and consistent.

This means succession to traverse the set from 0 cannot be completed and that ordinary mathematical induction addresses the potential not the completed infinite.

I think we are all in agreement that constructing N starting from 0 in "+ 1" steps as you say, is not possible. I'm not clear why you are repeating this once more. Furthermore, I'm not aware of the distinction between "potential" and "complete" infinities being made in the mathematical systems we have been discussing. Sets are either infinite or not. If you want to explore further, I suggest considering the traversal of sets of order type ω* in order as a model of an infinite past. That's what I've been talking about all along, but I believe you have primarily focused on sets of order type ω, which are different. daveS

PS: Alternative frames for set theory: http://plato.stanford.edu/entries/settheory-alternative/ also a note on the number tree: https://uncommondescent.com/mathematics/fyi-ftr-on-ehrlichs-unified-overview-of-numbers-great-and-small-ht-ds/ as well as, the surreals (HT DS): http://www.ohio.edu/people/ehrlich/Unification.pdf kairosfocus

Folks, I think that -- absent some good fresh Mathematics and/or phil of Math put on the table, this thread will make little further progress. Where also, local events are necessarily drawing my focus in a way that means I cannot do justice to discussions here for a while at least. In that light, I am thinking the best I can do just now is suggest that endlessness is a key to understanding infinity and the surreals seem to have a lot of promise on that. I am led to conclude that the oxymoronic phrase, trying to end the endless by traversing it in finite stage steps, is not only a matter of a form of words. It speaks to core realitues and constraints involving coherence, logic and the logical analysis of structure and quantity, aka mathematics. This includes causally connected stages comparable to descending an infinite ladder to reaching just now arriving on the ground. Such can be extended to cosmological unfolding and makes claims of an infinite past quasi-physical causal stage succession cosmos dubious. BTW, that is where I think Mathematics gains its relevance and causal influence, the coherence of distinct identity and the need that all things present in our world be sufficiently mutually compatible that they can exist together in a common actualised domain or possible world. Mathematics is not magic off by itself. However, that means it becomes foundational to understanding reality, and that we must bear in mind its strengths and limitations. Including that post Godel, axiomatic systems are incomplete or incoherent, and there is no constructive process that guarantees coherence of axiom systems. Mathematics is not a stand-in for absolute unquestionable truth established by circles of adepts. This too becomes an open ended, hopefully progressive research programme. I remain of the view that the ellipsis of endlessness is key to understanding the successive counting numbers. Any given k has k+1 etc in succession that can be 1:1 matched to the full set from 0,1,2 on. That is the original set and the set that is bijective with it are both infinite. This is an illustration of how endlessness and infinity are connected. This means succession to traverse the set from 0 cannot be completed and that ordinary mathematical induction addresses the potential not the completed infinite. Transfinite induction goes beyond that but requires a more stringent process, outlined fairly recently above. Also, this leads me to the view that all counting sets we can reach to specifically in +1 steps, or represent as numerals based on such (place value, sci notation etc) or symbolise specifically will be finite but we must reckon with onward endlessness lest we draw conclusions that can get us into trouble. I for now hold to the view that the conclusion on ordinary math induction that all counting numbers constitute an infinite sequence of only finite values is a step too far, failing to adequately reckon with onward endlessness. I would rather say, what we can reach is finite but the endlessness onward implies we cannot fully define its members. Instead we recognise endlessness as a new quantitative phenomenon and assign the numeral omega, w for convenience above. On to the surreals for exploring the jungle of numbers great and small. Yes, a minority view, but I cannot honestly go beyond what I see in the logic at any time; even if I have to say simply, I do not follow this could you show me the steps I may have missed. I of course remain open to further understanding. As a closing word, thanks for a civil, generally serious discussion. KF kairosfocus

KF,

Ds, passing by. I say the opposite, we CANNOT complete an actual infinity in finite stage steps.

I'm agreeing with that above, at least in a mathematical context. ω cannot be "completed" in finite stage steps, that is, by starting with {} and applying the successor operation repeatedly.

And the infinite past issue has to do with exactly that succession of finite stages. KF

Well, the connection is unclear to me. First of all, an infinite past is not a deduction or construction in first-order logic. Second, an infinite past would have no beginning, whereas a deduction or construction in first-order logic would. daveS

at 1392, ellazimm quotes Wikipedia as saying

The set of finite ordinals is infinite, the smallest infinite ordinal is omega (spelled out because WordPress didn’t take the Greek letter)..

This seems correct to me. Then kf says,

Wiki should take a pause but likely won’t. The value w is not as a succession to definite finite steps say k –> k+1 –> w, but instead it is a recognition of their endlessness as a distinct quantitative phenomenon worth recognising with a symbol.

This second part seems correct to me: "w is a recognition of their endlessness it is a recognition of their endlessness as a distinct quantitative phenomenon worth recognising with a symbol.with a symbol" but I don't think that the Wikepedia quote said that "the value w is a succession to definite finite steps". The Wikipedia quote recognizes that the set of finite ordinals is infinite, and the kf says what I have said a few times: that a new number and symbol were created by Cantor as a name for this "distinct quantitative phenomenon." Aleta

Ds, passing by. I say the opposite, we CANNOT complete an actual infinity in finite stage steps. Cf what happens onward when one reaches ant k. And the infinite past issue has to do with exactly that succession of finite stages. KF PS: EZ, Wiki should take a pause but likely won't. The value w is not as a succession to definite finite steps say k --> k+1 --> w, but instead it is a recognition of their endlessness as a distinct quantitative phenomenon worth recognising with a symbol. kairosfocus

KF,

KF:

Namely, we are dealing with the capital case divergent sequence, it is HOW we count up without limit. And by definition as we go it expands in value endlessly. So, on the copy the set so far principle to get to the next value, if endlessness WERE completed, it would entail endless members of the set of counting sets. That is, the claim, an infinite succession of finite incrementing values is not valid as were it completed not all values would be finite.

Me:

Can you prove this? I have interpreted this as saying that ω has elements (sets) of infinite cardinality. If that’s what you mean, then this statement is false. You are of course invited to prove this statement if you disagree.

PS to this exchange: Another interpretation of your statement is that you are speaking of starting with {} and applying the successor operation infinitely many times. But as I have stated, this construction is simply undefined in first-order logic so it doesn't tell us anything about ω, the set of counting sets. daveS

KF #1390 From the Wikipedia page on ordinal numbers:

The set of finite ordinals is infinite, the smallest infinite ordinal is omega (spelled out because WordPress didn't take the Greek letter)..

Apparently Wikipedia doesn't have a problem with an infinite set of finite values either. ellazimm

KF,

This brings back a main point I have made all along, we cannot complete endlessness in finite stage steps such as +1 counting steps. (And yes that goes to the thread’s main point on claimed infinite past causal stage succession to get to our now world.)

I would express your first sentence as: you cannot construct N starting with {} and the successor operation in first-order logic. That certainly doesn't prove that an infinite past is impossible.

Namely, we are dealing with the capital case divergent sequence, it is HOW we count up without limit. And by definition as we go it expands in value endlessly. So, on the copy the set so far principle to get to the next value, if endlessness WERE completed, it would entail endless members of the set of counting sets. That is, the claim, an infinite succession of finite incrementing values is not valid as were it completed not all values would be finite.

Can you prove this? I have interpreted this as saying that ω has elements (sets) of infinite cardinality. If that's what you mean, then this statement is false. You are of course invited to prove this statement if you disagree.

We may proceed to recognise a new quantity, w, for order type of the endless succession.

That's where the Axiom of Infinity comes in. We (most of us, anyway) postulate that we have a set ω that has {} as an element and which is closed under the successor operation. So again, ω is not "completed" through a series of + 1 steps.

That is very different from ending the endless in finite stage steps.

Yes, exactly. We do not "end the endless" through finite stage steps, since we can't do that in first-order logic. The existence of the completed set ω is assumed.

Also, ordinary mathematical induction on ase 0 then case k => case k+1 implies a chained succession, whether we want to look at the chain as a whole or at its linking successive property or generalise on that. The very k, k+1 chaining points to the same onward endlessness issue. So, in a case like this, due caution is needed when endlessness has material force.

Hmm. If you're not saying that these inductive proofs have infinitely many steps, I have no argument here. If you are saying this, I would again point out such proofs are impossible.

Yes, we can set up axioms etc, but we must not forget their potential for error or incoherence, as Godel highlighted. Nor should we forget that when an imposed premise p is directly responsible for the force of a conclusion C, the locus shifts to, why that P?

Well, there's always the possibility of error or inconsistency. How else can we do mathematics other than by setting up axioms and logical systems? If we don't have a "rule book", so to speak, then how do we determine what is allowed? daveS

EZ, I pass by briefly. I am using w for OMEGA (an ordinal) not aleph-null, which is in effect the cardinality of the first range of transfinite ordinals w, w+1 etc. The cardinality of the reals is an irrelevance to that. I have no problem with diagonalisation. And I suggest that you may find it helpful to look at the clips on surreals added to the OP long since [HT DS], which show a tree of numbers great and small. This seems to give a good framework for addressing the overall structure of quantity, complete with many ellipses of endlessness. KF kairosfocus

KF #1388 Since I don't think you've said anything new here and I don't have anything new to say either it seems pointless to pick my way through your statement. I did read it all. You are using a small omega to stand for what is normally called aleph-null, the smallest infinite cardinal number, the cardinality of the integers (and the rational numbers). Any set with that cardinality is said to be countably infinite. Cantor proved that the cardinality of the real numbers is greater than that of the rationals. Do you agree with his proof? Are there more real numbers than rational numbers? Just curious. You seem to just want to lump all infinite sets into 'endlessness'. ellazimm

Folks, As noted, local issues are peaking. That said, a couple of quick notes. First, mathematics is far more than axiomatised systems, though those are important in pulling together fields of thought. Next, it is clear the successive counting sets from 0 are just that as von Neumann's construction shows. This requires that a coherent view brings that to bear and answers to it. In that context, patently once we have arbitrarily large but finite value/set of counting sets so far k, k+1 etc beckon onwards. Indeed that is how we know k is finite, it is bounded on the upper side. But as k, k+1 etc can be matched endlessly with 0,1,2 etc, this means BOTH are infinite [0,1,2 etc by way of matching with a proper subset, k on as it matches with a set just shown infinite . . . a bit of a subtle difference from mere circularity], though to a certain extent that is repeating, endlessness is the essence of being infinite. This brings back a main point I have made all along, we cannot complete endlessness in finite stage steps such as +1 counting steps. (And yes that goes to the thread's main point on claimed infinite past causal stage succession to get to our now world.) It is also the pivot of a point that does not depend for its force on whether there is abundant or even sparse discussion of it in the literature. Though, the finitists of today have a few pungent observations to make. Namely, we are dealing with the capital case divergent sequence, it is HOW we count up without limit. And by definition as we go it expands in value endlessly. So, on the copy the set so far principle to get to the next value, if endlessness WERE completed, it would entail endless members of the set of counting sets. That is, the claim, an infinite succession of finite incrementing values is not valid as were it completed not all values would be finite. But as was reminded of, endlessness cannot be completed in such +1 steps or the like. That is we have a potential infinity on this line, and it is relevant to highlight the ellipsis of endlessness onward. We may proceed to recognise a new quantity, w, for order type of the endless succession. That is very different from ending the endless in finite stage steps. A safer conclusion, then, seems to be that every particular value we can succeed to or represent, k, will be finite but endlessness continues onward and cannot be captured by using specific values. Hence the ellipsis of endlessness. Also, ordinary mathematical induction on ase 0 then case k => case k+1 implies a chained succession, whether we want to look at the chain as a whole or at its linking successive property or generalise on that. The very k, k+1 chaining points to the same onward endlessness issue. So, in a case like this, due caution is needed when endlessness has material force. In such cases we may be well advised to look at transfinite induction (including, I just point to, how it handles limit ordinals such as w). Yes, we can set up axioms etc, but we must not forget their potential for error or incoherence, as Godel highlighted. Nor should we forget that when an imposed premise p is directly responsible for the force of a conclusion C, the locus shifts to, why that P? We could go on, but that is enough for now on balance. Again, sorry, local pressures. KF kairosfocus

Pardon, local issues are peaking again. kairosfocus

Kf has found other battles to fight based on the comment list so don't expect him to come back here anytime soon. I rather suspect we're at an end anyway. He's insistent that Cantor's mathematics is troubling and we don't agree. What else is there to say really? ellazimm

KF, replying to Aleta:

More broadly, we should always be very cautious about imposed axiomatic criteria that pretty directly force results, as that may run close to begging questions.

But mathematicians have no choice other than to impose axiomatic criteria that force results. That's how mathematics works. For example, the abc conjecture which I mentioned above. If Mochizuki has proved it, then that's because ZFC + first-order logic force this conjecture to be true (I assume that's the system Mochizuki works in). daveS

Thanks, kf. I appreciate the specific comments to some of my questions. 1. We seem to be in agreement that "logically internally consistent systems" should be "anchored to reality." However, I am still puzzled that you are not more specific about what is worse than paradox when you write,

paradox by definition skirts incoherence ... or goes across its border. The latter ends in shipwreck, so it is important to resolve.

Given that "across the border" and "shipwreck" are not exactly mathematical terms, do you mean "contradiction"? 2. When I asked,

Can God comprehend the infinite in its entirety, or can he also, as we do, just see endless step-by-step traversal of, for instance, the natural numbers?

you answered

God knows fully, we know in part. What we know is, endlessness as ellipsis can itself be a finite stand in for completion. Where something is logically incoherent, ending the endless in finite stage steps, no being can know or actualise the logically impossible in thought or physically. God cannot create a square circle, this is an impossible being.

Interesting and good, clear answer. I'll think about this. 2. When I asked,

Can/has God created time as an independent dimension which passes in some sense even if no physical events are happening, or does time pass only if causally connected events are occuring? That is, is time independent from or dependent on a succession of material events?

you answered,

Time is temporary and rooted in the visible, material realm. The very succession of moments is causally connected and successive. This includes say molecular agitation and intra atomic or intra nuclear forces which are inherently dynamic so a material world in which time passes but nothing happens is not feasible.

This also is a good clear answer. "Before" God created the universe, then, there was no time: time manifests itself in the succession of causally connected moments. I agree with that. Question: As a thought exercise, could God then create another universe, different than ours, with its own timeline? If so, would it be impossible to say which universe came "first", as there would be no set of material events to establish the timeline by which the existence of the two universe could be compared? 3. You also write,

Perhaps you mean can we have a snapshot, frozen moment contemplated by Deity? That seems possible but it has nothing to do with whether time proceeds once a material world is actual.

I wasn't thinking of that, but the idea of a "moment of time" brings up an interesting point. The whole idea of the continuity of the reals brings up a different set of issues concerning infinity other than the ones we've been discussing, and "a moment in time" was at the heart of Zeno's paradox about the arrow that can't move. So if God could see a moment in time would he not be, in a sense, "ending the endlessness" in respect to the infinitely small, as opposed to the endlessly large? Is that also a paradox? I'm going to think about this also. 4. You also write,

And I have no problem with accepting abstractions as real in their own way. Existence and physical existence are not the same. I think it was Augustine who pointed to eternal contemplation in the mind of God (a necessary, root being undergirding reality) as a sufficient realisation of abstractions.

For the sake of this discussion, I am assuming what you say is true: that all mathematics exists as pure abstractions in the mind of God, as Plato originally assumed when he spoke of the perfect circle. However, I've been pondering this. Human beings have devised some pretty strange mathematics. For instance, dave or ellazimm pointed me to Cantor's function (or cantor's ladder - google it if you're not familiar with it), and it seems like a pretty bizarre thing for Cantor to have even thought of. Question: So, did Cantor's ladder already exists as an abstraction in the mind of God, or did it only become an abstraction in the mind of God when Cantor invented it? Either way seems to be puzzling. For instance, I could make up a function like Cantor's ladder, but use base 17 and some other set of rules. Does this function also already exist as an abstraction in the mind of God. Or how about every possible fractal Julia set? Does every possible logical construction we could ever think of already exist in the mind of God? Or do they become part of the mind of God after we invent them? Aleta

KF #1380 Nice articles. I notice that no one seems to think any of the examples discussed are paradoxical or concerning. ellazimm

KF #1380

pardon, but I must ask: why did you keep bringing up convergent series with terms heading for the infinitesimal, in a context where the relevant issue is divergent sequences that count up towards the infinite?

It's come up several times in the thread (you're always talking about y = 1/x, etc, et. I won't bring it up again.

I find it strange that you seem to find it hard to see that an endless succession — thus (potentially?) INFINITE — of values that increment at +1 and yet are all deemed FINITE is at minimum paradoxical.

I can live with the fact that you find it paradoxical but I don't. And since we've been running over the same old ground, finding your same old fear it's probably time to stop talking about it. Aleta and daveS and I are not going to change our minds and you aren't either. Let it go.

There is an onward issue opened up by how non standard analysis uses 1/x to catapult from near 0 in [0,1] to the transfinite hyper-reals. That opens up possibilities for contemplating how multiplicative inverses are mutually connected in the reals and it raises issues on the continuity of reals in [0,1] as infinitesimals are sometimes said to be non real near neighbours of 0.

See, you brought it up again. No, the infinitesimals are not non-real. All the numbers on the number line are 'real' numbers. And, as I pointed out, there is nothing special about zero if that kind of thing bothers you. There are 'infinitesimals' everywhere. Like I said, between any two numbers on the number line there are infinitely many rational (and even more real) numbers between them. 1, 2, 3, 4, 5 . . . . and 1, 1/2, 1/3, 1/4, 1/5 . . . (or 1 + 1/2, 1 + 1/3, 1 + 1/4, 1 + 1/5, 1 + 1/6 . . . ) are all finitely valued infinite sequences. None are paradoxical. It's the way mathematics works. Two sequences converge (to zero and one respectively), one sequence diverges. ellazimm

Some thoughts: https://aeon.co/opinions/how-thinking-about-infinity-changes-kids-brains-on-math with: http://learning.blogs.nytimes.com/2013/01/30/teaching-the-mathematics-of-infinity/?_r=1 kairosfocus

Pardon a string of notes: Aleta: Yes, logically internally consistent systems may in some cases fail to correspond to facets of reality. That is part of why we need to anchor key parts of mathematics to reality by bringing to bear key cases, thought exercises and problems anchored to reality. That brings to bear a wider coherence that controls for factual adequacy. In the case of varied geometries, we see different aspects of reality being tied to various possible geometries. More broadly, we should always be very cautious about imposed axiomatic criteria that pretty directly force results, as that may run close to begging questions. I also emphasise that mathematics is not an isolated force on its own. It is the study of the logic of structure and quantity. Where one bridge between logic and reality is that in a cosmos, entities have to have mutually consistent core characteristics to be feasible (no square circles) and that the things populating the world must then also be mutually coherent, forming an ordered unified whole. Just, mathematics slices off that facet where quantitative and structural aspects are involved. I am actually surprised that this seems to be viewed as controversial. I add, paradox by definition skirts incoherence -- where it gets its spiciness from -- or goes across its border. The latter ends in shipwreck, so it is important to resolve. On some Q's raised: >>1. Can God comprehend the infinite in its entirety, or can he also, as we do, just see endless step-by-step traversal of, for instance, the natural numbers?>> God knows fully, we know in part. What we know is, endlessness as ellipsis can itself be a finite stand in for completion. Where something is logically incoherent, ending the endless in finite stage steps, no being can know or actualise the logically impossible in thought or physically. God cannot create a square circle, this is an impossible being. >>2. Can/has God created time as an independent dimension which passes in some sense even if no physical events are happening, or does time pass only if causally connected events are occuring? That is, is time independent from or dependent on a succession of material events?>> Time is temporary and rooted in the visible, material realm. The very succession of moments is causally connected and successive. This includes say molecular agitation and intra atomic or intra nuclear forces which are inherently dynamic so a material world in which time passes but nothing happens is not feasible. Perhaps you man can we have a snapshot, frozen moment contemplated by Deity? That seems possible but it has nothing to do with whether time proceeds once a material world is actual. EZ, pardon, but I must ask: why did you keep bringing up convergent series with terms heading for the infinitesimal, in a context where the relevant issue is divergent sequences that count up towards the infinite? I find it strange that you seem to find it hard to see that an endless succession -- thus (potentially?) INFINITE -- of values that increment at +1 and yet are all deemed FINITE is at minimum paradoxical. In reply, I have pointed out how

a: such finite stage divergent succession is inherently built into the system of counting numbers [that is what they do], b: that at any k we reach or represent there is onward endlessness k+1 etc (that can be 1:1 matched with 0,1,2 etc . . . implying BOTH sets are endless thus infinite) and c: that the k = copy of set from 0 to k-1 copy of set so far principle means that were the succession to ACTUALLY go to endlessness, some members would be just that . . . endless. But in fact, d: point b shows we cannot actually complete, we have potential but not actual infinite succession, we are pointing across an ellipsis of onward endlessness. Thus, e: while any value k we can get to in succession or represent k will be finite, endlessness is an inextricable part of the concept and we can not actually attain to such endlessness or infinity in finite stage steps. That is, f: it -- the infinite -- is a concept not a number, and g: we recognise that by defining a transfinite order type to the incomplete succession that goes on endlessly, omega [w for convenience]. h: We then proceed with onward mathematics that for the moment seems to be pulled together in the tree framework provided by the surreals, cf OP

Going on, infinitesimal stages are not relevant to finite stage divergence. There is an onward issue opened up by how non standard analysis uses 1/x to catapult from near 0 in [0,1] to the transfinite hyper-reals. That opens up possibilities for contemplating how multiplicative inverses are mutually connected in the reals and it raises issues on the continuity of reals in [0,1] as infinitesimals are sometimes said to be non real near neighbours of 0. MT: Infinity and space are distinct categories. Abstract, non space based things can go to endlessness, and in principle, abstract space can do the same, cf the arrows of continuation on axes of graphs. And I have no problem with accepting abstractions as real in their own way. Existence and physical existence are not the same. I think it was Augustine who pointed to eternal contemplation in the mind of God (a necessary, root being undergirding reality) as a sufficient realisation of abstractions. Perhaps, your question is whether observed physical space such as what we live in is infinite in actuality. This goes beyond geometry of space-time, which seems near flat. It is beyond observation, so is phil not sci. The answer lies in the issue of actualising infinite extension physically, which as Hilbert's Hotel shows, is highly dubious. The infinite tapes are a thought exercise in extension of physical phenomena, much like Turing's machine. Gotta go again, KF kairosfocus

KF, Does infinity transcend spacial dimensions ? IOW, every dimension is limited but as dimensions are infinite,may be the infinite tape goes on and on from one dimension to next. Me_Think

At 1366 kf writes,

I have said something that is almost a commonplace, that reality is coherent, which is a logical constraint tied to distinct and mutually compatible identities of particular things in a world that despite such diversity shows harmony. Cosmos, not chaos.

I responded to this in 1377. I agree that we expect reality to be amenable to logical descriptions, but as you yourself mention in respect to the parallel postulate, we can have logical systems that do accurately describe the world and we can have logical systems that don't. We can't just assume that a logical system is accurate until we test it against the evidence. That is why I think it is misleading to say "logic and mathematics constrain reality", because that phrase ambiguously conflates logic and math causing reality to be a certain way (which is false) with logic and math describing the reality that we find before us. Aleta

Thanks for the thoughts at 1364, HeKS. Perhaps contradiction is what kf sees as worse than a paradox, but that would be a pretty simple thing to say directly rather than hint at, so I still wonder if he has something else in mind. Your second point brings up one of the key issues, I think. You write,

Regarding the notion that math constrains reality, I tend to think that KF would be more likely to say logic constrains reality, but this might be better phrased as simply saying that reality really is consistent with logic, so if a proposition relating to the real world entails a logical contradiction, we are warranted in concluding that the proposition is false.

This is what kf said the second time, but this is significantly different than his first statements that logic constrains reality. Here's why. Logic and math by themselves say nothing about the real world until a mathematical model is proposed that maps particular aspects of the math to the world, and is then tested to see if it is consistent with reality. A proposition like "that is a square circle" can be rejected immediately because it is contradictory within math itself, but a statement like "a particle can take two different simultaneous paths from point A to B" may seem like a contradiction but is actually supported by evidence. In this case the problem is not the math itself but the model that needs to be adjusted. So the statement that "reality really is consistent with logic", while true in theory, is only true in practice if we assess our models with reality itself, rejecting some and accepting others. The classical example of this, which I wrote a lot about many months ago in a discussion on this topic, is that of the three different plane geometries which arise from different parallel postulates. All three geometries (for flat, positively curved, and negatively curved surfaces) are mathematically consistent, but obviously only one can apply to a particular surface. So the issue is not whether reality can be described logically and mathematically, but which mathematical model best describes reality. So if kf really thinks reality is constrained by logic, then he may very well think that somehow our discussions about the logic of infinity actually tell us something about the reality of time. However, my position is that we can use our understanding of infinity to propose models about time (and those models must be logically consistent), but that we can only check to see if our model is correct by testing it. If our tests show problems with our model, we don't conclude the universe is illogical or unmathematical. We conclude that we need to change our model to include new features: new definitions, new mathematical formulations, etc. P.S. Thanks for your note to kf, where you said,

Just to be clear, do you realize that neither [ellazimm or me] has argued that an infinite past-time is possible? It seems that the only thing they’ve been arguing is that infinity is well defined as an abstract mathematical concept and so can be used without issue within that specific abstract realm of pure mathematics. But neither has said that this in any way lends support to the coherence of an infinite past-time. Do you acknowledge this?

And I see that kf answered this question, so I'm glad that is clear. Aleta

KF #1373

we are simply not seeing the same thing. No, what I speak of is an issue of the logic involved, an endless succession of +1 stage increments that is thus a divergent and infinite trending sequence . . . it is what we count with . . . that is infinitely extended but always finite is at minimum paradoxical.

Not if you consider Cantor's work. You clearly think it is a problem but I don't and neither do thousands upon thousands of mathematicians. And there is now work built upon the very thing you find troubling. And it hasn't come tumbling down in over a century. What about sqrt(-1)? Is that not paradoxical? And yet it's part of an equation I now you find compelling. Why don't you find that paradoxical?

We are talking divergence, coarse grained finite steps that are not heading to infinitesimal size and more. Please do not conflate the cases.

Well, you keep mentioning infinitesimals so I thought I'd throw those in as well. If you didn't want to talk about them, why did you bring them up? Anyway, you are troubled but I don't know of anyone else who is. So I guess it's just a concern you'll have to bear. But it doesn't give you cause to call the mathematics into question. Again, I'm not saying anything about an infinite past or future. Nor am I addressing any particular point of physics or philosophy. Just the math. And since your concern is not one shared by the mathematics community or research then I guess there's an end to it. ellazimm

Hi kf.

that is infinitely extended but always finite is at minimum paradoxical

I've asked you a number of times to tell us specifically what you see that might be more than paradoxical, and you haven't answered. HeKs says he thinks you might mean contradictory. So do you mean this: "... that is infinitely extended but always finite is at minimum paradoxical but might be worse - might be a contradiction?" Is contradiction what you are seeing as worse than paradoxical? Aleta

KF,

DS, appeals to authority do not go beyond the force of fact and logic.

Well, I'm actually appealing not to authority but to standard definitions that you can find in any book on first-order logic. Just as if we were playing a game of Go, we might have to consult the/a rule book to decide whether a particular move is legal.

The issue is ending the endless in finite stage steps.

I suggest we stick to the specific issue of whether ω has any infinite elements.

As discussed again k k+1 on shows why that fails. Sorry, more later, real world calls as the sun rises. KF

Let me respond more fully to this and the following quote from a previous post:

g –> on the contrary, you have not met the required criterion of endlessness and have actually admitted the point that the set cannot be completed in succession.

I have never said that ω can be "completed" by starting with {} and applying the successor operation. That's why I brought up the Axiom of Infinity many hundreds of posts ago (perhaps in one of the earlier threads). The set ω is "completed" by the Axiom of Infinity in a single step. daveS

EZ, we are simply not seeing the same thing. No, what I speak of is an issue of the logic involved, an endless succession of +1 stage increments that is thus a divergent and infinite trending sequence . . . it is what we count with . . . that is infinitely extended but always finite is at minimum paradoxical. It is not a ho hum done over with. And a convergent sequence or series [as in via partial sums as a sequence and neighbourhoods etc] is not even relevant to the matter. We are talking divergence, coarse grained finite steps that are not heading to infinitesimal size and more. Please do not conflate the cases. KF kairosfocus

KF #1371

Think about an infinite succession of numbers that increases by 1 each step and is always for every case finite at the far endless zone, bearing in mind that infinite means continued endlessly and finite just the opposite, having an end.

So? Cantor figured out how to handle that 100+ years ago. And his method works.

I note, ordinary induction speaks to a first value and a chaining of successive specific values, hence the inherent finitude and potential infinity as opposed to completed.

Again, if I can prove a statement is true for 1, 2, 3 AND I can show that if the statement is true for any n > 1 and is therefore true for n+1 there is no problem. I'm always dealing with finite values.

Next, do you notice that I am constantly pointing out the place of finite scale stages at each step? (As in, do not put into my place a strawman target.) Sequences that reduce to infinitesimal values can converge and can do so in finite time, as in the Zeno paradoxes. Not relevant.

Take 1, 1/2, 13, 1/4, 1/5 . . . . it converges to zero but it never gets to zero. It will beat any value you pick in (0, 1] in a finite period of time (part of the definition of a limit but leaving out the deltas and epsilons) but it will never, ever get to zero.

Continuity of reals in [0,1] is particularly relevant to the issue of speaking of numbers not real near 0. As has appeared above.

What numbers are you talking about? Infinitesimals are 'real' even if you can't measure them. 'Real' has a particular mathematical meaning. Check this out if you really want to give your head a twist: https://en.wikipedia.org/wiki/Infinitesimal AND between any two given real numbers there is always another. In fact, between any two give real numbers there are an infinite number of real numbers. Not only is the cardinality of all the real numbers in [0, 1] greater than the cardinality of the positive integers but that is also true for any interval [a, b]. The real number line is ever where infinite. And this is not controversial or a paradox. This is the bedrock upon which limits and therefore calculus rests. Note: there is nothing special about 0. Consider . . . 2, 1 + 1/2, 1 + 1/3, 1 + 1/4, 1 + 1/5 . . . . That sequence converges on 1 although it never gets there. I can construct an infinite sequence of numbers that converges to any finite value you specify. From above or below. ellazimm

EZ, Think about an infinite succession of numbers that increases by 1 each step and is always for every case finite at the far endless zone, bearing in mind that infinite means continued endlessly and finite just the opposite, having an end. Which is the specific case in question, so your name one challenge is needless. I note, ordinary induction speaks to a first value and a chaining of successive specific values, hence the inherent finitude and potential infinity as opposed to completed. Next, do you notice that I am constantly pointing out the place of finite scale stages at each step? (As in, do not put into my place a strawman target.) Sequences that reduce to infinitesimal values can converge and can do so in finite time, as in the Zeno paradoxes. Not relevant. Continuity of reals in [0,1] is particularly relevant to the issue of speaking of numbers not real near 0. As has appeared above. And more, again, gotta go. KF kairosfocus

KF #1366

Namely, the assertion and claimed proof on ordinary mathematical induction that there are INFINITELY many +1 step from 0 successive and FINITE whole counting numbers or counting sets. At minimum this is a strange paradox, or it may be much worse than mere paradox.

It's not a paradox though. Why can't there be an infinite number of finite numbers? How can you get something infinite by counting up by 1 from anything finite?

After the weeks of back forth and rethinking on concepts as recently as during the night, I find myself at the point where I think the core matter is that when we succeed to or write down or symbolise any specific counting sequence number, k, there is an unlimited, end-less onward succession that consistently escapes attempts to capture it beyond an ellipsis of endlessness.

An infinite sequence of finite values. Correct.

Every counting value k we can reach, represent, write down or symbolise, k, is finite, but beyond the end-less-ness lurks, as an integral part of defining the set of counting numbers {0,1,2 . . . }. Beyond k will always lie k+1, k+2 etc without upper limit in a far zone of endlessness. We can represent or actualise the potential infinite but we cannot exhaust or traverse endlessness in finite stage steps or things based on such, e.g. Place value or sci notation.

I don't know what 'potential infinite' means but you seem mostly on track here.

This also constrains what ordinary mathematical induction — and recall, such preceded axiomatisations [and yes, there is a plural there] — shows. This too only reaches the potentially infinite.

If I want to prove a statement is true for all positive integers and I show it's true for the first few and I can also show that if it's true for n it's also true for n+1 I'm just working with finite values!

We may then put in a “forcing” axiom [generic sense here] as a further premise, but we must beware of cases where endlessness affects the result.

Name one. Any result for whole numbers is not meant for infinite cardinal numbers. That's why Cantor had to come up with something new.

I have other points of discomfort such as the continuousness of the closed interval [0,1] which is connected through y = 1/x to the domain of transfinites beyond the ellipsis of endlessness in the number tree in the OP.

What is the problem here? Clearly you can show many examples of, again, endless series of finite values all of which lie in the interval [0, 1] 1/2, 1/3, 1/4, 1/5, 1/6 . . . . That one is monotonically decreasing with a greatest lower bound of 0. 1/2, 2/3, 3/4, 4/5, 5/6, 6/7 . . . That one is monotonically increasing with a least upper bound of 1. If you consider the interval [-1, 1] you can get things like 1/2, -1/3, 1/4, -1/5, 1/6, -1/7 . . . which converges on 0. This is all important because some very useful tools in physics depend on infinite series converging to finite values. Fourier analysis is one example. Taylor series is another. If you have a problem with these things then you clearly never progressed past third semester Calculus. Which I took as a sophomore in college. There's a lot of math after that. Taylor discussed his series in 1715. That makes the topic 300 years old at least. I don't know about you but I don't really want to go back to the math (and therefore the physics) of 300 years ago. ellazimm

KF @ 1367

The point is not that light and balls calculate but that they reflect constraints that are expressible in terms of least action etc.

That's of course true, yet is it logically understood that light follows the fastest path or that ball follows a path that minimizes the Action? It is understood if you know the physics, not by logic or intuition.

Likewise, popular notions that quantum physics undermines the logic of distinct identity fail.

The most popular QM experiment is the double slit experiment. Is the result logical? Me_Think

DS, appeals to authority do not go beyond the force of fact and logic. The issue is ending the endless in finite stage steps. As discussed again k k+1 on shows why that fails. Sorry, more later, real world calls as the sun rises. KF kairosfocus

MT, The point is not that light and balls calculate but that they reflect constraints that are expressible in terms of least action etc. Likewise, popular notions that quantum physics undermines the logic of distinct identity fail. Starting with, to do quantum mechanics one must rely on distinct identity. Superposition does not destroy identity. Likewise, your statement:

if a proposition relating to the real world entails a logical contradiction, we are not always correct in concluding that the proposition is false

. . . necessarily relies on the principles of distinct identity it tries to set aside. Start with I vs not I and F vs not F, then proceed. Inherently self falsifying by self referential incoherence. KF kairosfocus

HeKS (Attn Aleta & EZ): I have said something that is almost a commonplace, that reality is coherent, which is a logical -- prime sense prior to axiomatisations, which are in this context secondary -- constraint tied to distinct and mutually compatible identities of particular things in a world that despite such diversity shows harmony. Cosmos, not chaos. There cannot be a square circle or the like in any possible world, as core characteristics of squarishness and roundness stand in contradiction. And the like. In that context, I have repeatedly pointed to an understanding of Mathematics: the logic of structure and quantity which we of course may study. So, it is in that context appropriate to indicate that such coherence has causal impact. Put three pennies, a three-pence coin and a sixpence in a drawer and necessarily one has a shilling's worth absent interference. As C S Lewis pointed out. So, there is no contradiction between logic and mathematics constraining reality, both express the prior point, coherence of reality. Just, when well done, mathematics works it out in exacting and often surprising details. I am aware A & EZ have not suggested an infinite past causal succession completed in the present. DS, in some moods has come close to trying to justify that, usually by reworking in terms of unlimited past regress of finite stages and finite values. As the OP shows, there are significant people out there who have tried to argue for an infinite past quasi-physical succession of stages arriving at our now world. This is highly questionable, not least on logic of structure and quantity grounds. Now, during the course of the thread an incidental issue and linked cluster of concerns popped up. Namely, the assertion and claimed proof on ordinary mathematical induction that there are INFINITELY many +1 step from 0 successive and FINITE whole counting numbers or counting sets. At minimum this is a strange paradox, or it may be much worse than mere paradox. After the weeks of back forth and rethinking on concepts as recently as during the night, I find myself at the point where I think the core matter is that when we succeed to or write down or symbolise any specific counting sequence number, k, there is an unlimited, end-less onward succession that consistently escapes attempts to capture it beyond an ellipsis of endlessness. Which is what the pink vs blue tape example illustrates. Every counting value k we can reach, represent, write down or symbolise, k, is finite, but beyond the end-less-ness lurks, as an integral part of defining the set of counting numbers {0,1,2 . . . }. Beyond k will always lie k+1, k+2 etc without upper limit in a far zone of endlessness. We can represent or actualise the potential infinite but we cannot exhaust or traverse endlessness in finite stage steps or things based on such, e.g. Place value or sci notation. This also constrains what ordinary mathematical induction -- and recall, such preceded axiomatisations [and yes, there is a plural there] -- shows. This too only reaches the potentially infinite.We may then put in a "forcing" axiom [generic sense here] as a further premise, but we must beware of cases where endlessness affects the result. And the conclusion traced to the forcing, not the inherent pattern of the logic. Much as happens with Euclid's 5th postulate on parallel lines etc and how we discovered after 2000 years that there were other possible and consistent geometries that obeyed other patterns. Some of which turned out to be physically relevant. I have other points of discomfort such as the continuousness of the closed interval [0,1] which is connected through y = 1/x to the domain of transfinites beyond the ellipsis of endlessness in the number tree in the OP. But that can go to another day. What is clear for the main purpose of the thread is that a suggested infinite past causal succession attaining by finite stages to the present is quite questionable. I do not doubt the reality of the transfinite, and have freely used omega etc [w is a stand-in]. The issue at focus for me was as described, and I have suggested that ending or traversing the endless in finite stage steps is incoherent and dubious to the point of fallacy. I did take the non standard approach as an example and suggested broader use of 1/x as a catapult between infinitesimals near 0 and transfinites. I further suggested that as there are onward ellipses of endlessness, we can distinguish hard infinitesimals that catapult us into such far-far zone transfinites yielding hyper-integers and linked hyper reals without defined first values. A suggested mild infinitesimal m would catapult to the first band, beyond w so that 1/m --> A, A = w +g, g a finite value. Those are suggestions. The surreals seem to have promise to bring things out. And DS has repeatedly brought to the table useful new things. Discussion can go on without limit but I have to pause for now. KF kairosfocus

HeKS @ 1364

so if a proposition relating to the real world entails a logical contradiction, we are warranted in concluding that the proposition is false.

That is not true in many cases. Quantum mechanics comes to mind immediately, but the way you describe ordinary processes too determines whether something is logical or not. For E.g., Light bends when going from less dense to denser medium. However, if you describe the process as light finds the fastest path to traverse (Fermet's principle) it will be illogical because it makes no sense that light can calculate the path that takes least time and traverse the path, yet it is true. Similarly, when you throw a ball, the trajectory of the ball is a hyperbola, but the path which the balls follows is the path which minimises the difference between Kinetic and Potential energy (Principle of Least action). It makes no sense logically, yet the ball does exactly that. Of course there are more 'illogical' phenomenon - Ball lightening, Hessdalen light, crop circles etc, so if a proposition relating to the real world entails a logical contradiction, we are not always correct in concluding that the proposition is false. Me_Think

To Aleta: I just want to offer a couple brief thoughts on KF's position. Regarding his comments about being 'a paradox, and maybe far worse', I believe the 'far worse' bit refers to an actual contradiction and therefore actually unresolvable, unlike a paradox, which may only seem like a contradiction. Regarding the notion that math constrains reality, I tend to think that KF would be more likely to say logic constrains reality, but this might be better phrased as simply saying that reality really is consistent with logic, so if a proposition relating to the real world entails a logical contradiction, we are warranted in concluding that the proposition is false. If it merely presents a paradox, then there is room at least for further investigation or consideration, but if it entails a bona fide contradiction or logical impossibility then it is false. To KF: I'm a little unclear here as to what your disagreement is with Aleta and ellazimm at this point. Just to be clear, do you realize that neither has argued that an infinite past-time is possible? It seems that the only thing they've been arguing is that infinity is well defined as an abstract mathematical concept and so can be used without issue within that specific abstract realm of pure mathematics. But neither has said that this in any way lends support to the coherence of an infinite past-time. Do you acknowledge this? If so, what is it that you disagree with them about (if the answer is the math itself, you might as well just say "it's the math", cause any further commentary about that math will likely go over my head) HeKS

Hi kf. Some questions for you to comment on, if you wish. Pick one or more. re 1329 1. Can God comprehend the infinite in its entirety, or can he also, as we do, just see endless step-by-step traversal of, for instance, the natural numbers? 2. Can/has God created time as an independent dimension which passes in some sense even if no physical events are happening, or does time pass only if causally connected events are occuring? That is, is time independent from or dependent on a succession of material events? Another way of asking this: Does our universe exist within a dimension of time, or does time only exist within our universe? 3. You often talk about the consequences of our ideas about infinity being a paradox, or "far worse". In 1356, I asked,

Could you explain more specifically what could be “far worse” than paradoxical. I don’t think we have any idea what you’re talking about, and you won’t tell us.

It may be obvious to you what these dire consequences are, but not me. Could you give a specific example? 4, In 1357 I point out that you have been inconsistent as to whether you think that math constrains reality, or is more a tool that describes a world that is amenable to mathematical description. Could you comment on what your position is on this? Thanks Aleta

Another example, from notes entitled "Deduction in First-Order Logic:

Deductions: A deduction in FOL_C from a set Γ of sentences is a finite sequence D of formulas such that whenever a formula A occurs in the sequence D then at least one of the following holds. (1) A ∈ Γ (2) A is an axiom. (3) A follows by modus ponens from two formulas occurring earlier in the sequence D or follows by the Quantifier Rule from a formula occurring earlier in D.

Regarding the construction of terms in first-order logic, from wikipedia:

The set of terms is inductively defined by the following rules: 1. Variables. Any variable is a term. 2. Functions. Any expression f(t1, ... ,tn) of n arguments (where each argument ti is a term and f is a function symbol of valence n) is a term. In particular, symbols denoting individual constants are 0-ary function symbols, and are thus terms. Only expressions which can be obtained by finitely many applications of rules 1 and 2 are terms. For example, no expression involving a predicate symbol is a term.

The bolded part explains why we can only apply the successor operation finitely many times in FOL. daveS

PS to 1360: To elaborate on:

KF: e –> Where n will be an endlessly large value, i.e., one without a finite successor. Me: Well, no, there aren’t any of those. As I stated, n is a natural number, so n + 1 exists and is finite.

Every natural number n ∈ ω can be reached through a finite number of applications of the successor operation to 0. We cannot apply the successor operation infinitely many times ("endlessly", I think you would say). That is forbidden. These proofs and constructions have only finitely many steps. That's why if {0, 1, 2, ..., n} ∈ ω, then n is finite. daveS

KF,

DS, has your union continued to endlessness? (Where, for any k in the succession, k, k+1 etc can be endlessly put in 1:1 correspondence with 0,1,2 . . . ) If so, kindly show us, and show us how such a union will be also not endless.

I am going to use standard mathematical vocabulary here. The union I spoke of is of a countably infinite sequence of sets, and that union is by definition ω. It is not in any process of "continuing", it just exists by the Axiom of Union. The correspondence you are requesting is : {} -> {0, 1, 2, ..., k - 1} {0} -> {0, 1, 2, ..., k} {0, 1} -> {0, 1, 2, ..., k + 1} and so on, for any k. More compactly, n -> n + k, for all n ∈ N.

a –> Actually I spoke of a were the succession to endlessness completed. Where, there is a copy of the set so far pattern that can be shown and was shown. b –> But also I showed where for any k the onward succession k, k+1 etc continues tot he same endlessness as 0,1,2 etc. So, directly, the completion cannot occur.

Well, again it appears you are still talking about applying the successor operation infinitely many times. We (neither you nor I) are not allowed to do this, so ω cannot be formed in this manner.

c –> Where the imposition of “for all n in the succession” does little more than loop the matter, and ignores the chaining inherent in posing a claim case k => case k+1, hung on a first case.

No infinite loops allowed, as I stated above. ω is the union of all finite ordinals; it's not constructed by "endlessly" applying the successor operation.

Me: Let’s call this set α . But by definition of the union of sets, this means that α ∈ {1, 2, 3, …, n} for some natural number n. KF: e –> Where n will be an endlessly large value, i.e., one without a finite successor.

Well, no, there aren't any of those. As I stated, n is a natural number, so n + 1 exists and is finite.

f –> tantamount to saying that you cannot actually continue to endlessness, so the whole argument collapses via imposition of the conclusion you want in the course of the argument.

No, it is tantamount to saying that proofs consist of finitely many steps. That is, unless you want to work in some exotic infinitary logic, which I doubt.

g –> on the contrary, you have not met the required criterion of endlessness and have actually admitted the point that the set cannot be completed in succession.

As I said, this sort of "endlessness" doesn't occur in proofs except in some exotic forms of logic. The following quotation explains why

The main idea of mathematical induction is that if a statement can be proved true for the number 1, and if we can also show that by assuming it true for 1, 2, 3, 4, ..., n, we can prove it true for n + 1, then our statement will therefore true for all natural numbers n ≥ 1. The power of this method is that a statement can be proved true for all natural numbers in finitely many steps, rather than having to prove it true for each n ∈ {1, 2, 3, 4, ..} individually.

If you google "proofs have finitely many steps", you will find other examples. daveS

KF

the issue is not mathematics constraining reality so much as that reality is coherent, a logical criterion. Bring to bear structural and quantitative aspects and then we see that such coherence can have mathematical forms.

Where is the mathematical problem? Where is the fault in a proof or a theorem? You keep objecting but you can't point to a specific fault except that you think there's some issue with reality vs math but you can't say exactly what is it.

As for mind changing, the issue I have has been openly stated from early on, the concept of infinitely many finite counting sets incrementing from {} –> 0 by the copy set so far principle, becomes at minimum paradoxical, and may well be far worse.

What can be worse? You've been asked over and over and over again and you won't say. SPELL IT OUT.

has your union continued to endlessness? (Where, for any k in the succession, k, k+1 etc can be endlessly put in 1:1 correspondence with 0,1,2 . . . ) If so, kindly show us, and show us how such a union will be also not endless.

What? We've been saying over and over and over again that there is no controversy or problem or issue with the mathematics. All these questions have been dealt with a long time ago. But, for some reason, you keep repeating the same thing over and over and over again when you can't even explain your problem in standard mathematical parlance.

If not, has it then captured all the elements of the set of successive counting numbers, which is to continue without upper limit?

Yes, it has. You are just talking on and on without really addressing all the work that has been done already. Seriously, you seemingly completely ignore all the posts we've written in good faith trying to explain and elucidate our views and the well established mathematics. You continue to talk in vague and non-mathematical terms which we have repeated asked you to clarify. And you have singularly failed to get specific about what exactly you are having a problem with mathematically. Again, 'endlessness' is NOT a mathematical problem. It's a problem with you. What is your problem? PLEASE be specific so we are not all just wasting our time. I'm beginning to think you are just trying to provoke us into behaving badly because you ignore our questions and queries and just keep repeating yourself over and over and over and over and over and over and over again. If you want to have a dialogue then you need to respond and not just repeat. ellazimm

DS, has your union continued to endlessness? (Where, for any k in the succession, k, k+1 etc can be endlessly put in 1:1 correspondence with 0,1,2 . . . ) If so, kindly show us, and show us how such a union will be also not endless. If not, has it then captured all the elements of the set of successive counting numbers, which is to continue without upper limit? KF PS: Let me clip you at 1344: >>if I understand you correctly, you are saying that the union of the countably infinite sequence of sets 0, {0}, {0, 1}, {0, 1, 2}, … must include an element (itself a set) of infinite cardinality. >> a --> Actually I spoke of a were the succession to endlessness completed. Where, there is a copy of the set so far pattern that can be shown and was shown. b --> But also I showed where for any k the onward succession k, k+1 etc continues tot he same endlessness as 0,1,2 etc. So, directly, the completion cannot occur. c --> Where the imposition of "for all n in the succession" does little more than loop the matter, and ignores the chaining inherent in posing a claim case k => case k+1, hung on a first case. d --> Making the chaining implicit does not make it go away. >>Let’s call this set ?. But by definition of the union of sets, this means that ? ? {1, 2, 3, …, n} for some natural number n. >> e --> Where n will be an endlessly large value, i.e., one without a finite successor. >>But again, the sets {0, 1, 2, …, n} that occur in that union all have finite endpoints n (since I am not allowed to repeat the successor operation more than finitely many times).>> f --> tantamount to saying that you cannot actually continue to endlessness, so the whole argument collapses via imposition of the conclusion you want in the course of the argument. >> So we have a contradiction: our infinite subset ? is an element of a finite set (of finite sets) {0, 1, 2, …, n}.>> g --> on the contrary, you have not met the required criterion of endlessness and have actually admitted the point that the set cannot be completed in succession. kairosfocus

kf, here are three places where you has have said that math and logic constrain reality: Back in 1009, for instance, you wrote,

PS: That we are relying on proof by contradiction to carry enormous weights is a deep and pervasive commitment to coherence of truth and the constraining power on reality posed by logic ...

and at 1080,

Logical-mathematical realities can and do causally constrain the real world. ... And this seems there as a limit to observable reality imposed by logic, never mind that we cannot observe the remote past, or even the much nearer past.

and the most telling quote,

the logic of structure and quantity — a matter of pure abstract logic — constrains physical reality ... Logic of abstract entities has causal constraining force in the physical world

But now you say differently:

the issue is not mathematics constraining reality so much as that reality is coherent, a logical criterion. Bring to bear structural and quantitative aspects and then we see that such coherence can have mathematical forms.

Can you clarify your beliefs on this topic. You've said inconsistent things. Aleta

may well be far worse.

Could you explain more specifically what could be "far worse" than paradoxical. I don't think we have any idea what you're talking about, and you won't tell us. Aleta

KF,

the concept of infinitely many finite counting sets incrementing from {} –> 0 by the copy set so far principle, becomes at minimum paradoxical, and may well be far worse. KF

Have you found any published sources indicating there is an actual logical problem here? I would think such a problem would have been identified long ago. daveS

Aleta, the issue is not mathematics constraining reality so much as that reality is coherent, a logical criterion. Bring to bear structural and quantitative aspects and then we see that such coherence can have mathematical forms. As for mind changing, the issue I have has been openly stated from early on, the concept of infinitely many finite counting sets incrementing from {} --> 0 by the copy set so far principle, becomes at minimum paradoxical, and may well be far worse. KF kairosfocus

KF, I am not going to bring up God again because we just go down the rabbit hole. Me_Think

I don't think changing kf's mind about anything is a reasonable goal. My goals are 1. to learn to really understand the positions of others, in part by pushing them to articulate and further their views, 2. to improve my understanding and ability to articulate my own views, 3. to learn more, both from others and by researching topics that are brought up (I've re-learned lots of stuff I've haven't thought about in years and learned a bunch of new stuff in this discussion) 4. to have some intellectual recreation Aleta

Aleta #1250

Exactly what ellazimm said – very good post!

Thanks! I don't think it will change much but it was fun trying to remember examples. What did I miss . . . ellazimm

Exactly what ellazimm said - very good post! Aleta

KF #1345

was it Wheeler who wrote on the unreasonable effectiveness of Mathematics in the physical sciences?] The divorcing of the two is ill advised. That has been one of my points of concern all along.

Why is it ill-advised? When imaginary numbers were first proposed they had zero applications in the real world. When Euler came up with his famous equation he used i = sqrt(-1) without worrying about whether or not he was 'divorced' from the real world. I know you admire that equation but what does it model? What about the Goldbach conjecture (every even integer greater than 2 can be expressed as the sum of two primes)? Does the truth or falseness of that say anything about the physical world? Or Fermat's Last Theorem which occupied mathematicians for 300 years! What about the Four Color Theorem? It's easy enough to verify it for any 'real' map but that doesn't make it true in mathematics. What about Zeno's paradox? Do we actually see Achilles NOT catching up with the tortoise? What about the Axiom of Choice? Is it true? How would its truth or falseness change anything we can experience? Differential equations are terribly useful in many fields of science. Have you looked at the theorems determining when a differential equation has a continuous, differential solution? Do we, in the real world, have anything that is actually an everywhere continuous function? If I measure the coastline of England using a yard stick and you measure it with a 12-inch ruler we will get different results (after a conversion). Mandelbrot considered that kind of problem and came up with fractals (he was working on other things as well) which stay 'jagged' no matter how far you zoom in. I took a class where we studied fractional dimensions and integrals. I still can't quite get my head around that stuff. But the math works. We use values like sqrt(2) or Pi without being able to write them down or measure them beyond a rather small level of accuracy. But in mathematics they are exact values. Reality and mathematics are frequently separate. A lot of mathematics has turned out to be useful in modelling real world phenomena . . . to a level of accuracy. But if you take a real world circle and find the ratio between the measured circumference and the diameter you will not get the mathematically exact value of Pi. It's true that some mathematics was motivated by a real-life problem. But there's quite a lot that was 'discovered' just because some (mostly) guys were just trying to out-do each other. For some reason you have taken a particular topic of pure mathematics and decided you can't go there because of some perceived real world implications. You've not been able to tell us why that is so important to you on this particular point and you keep using non-standard and undefined terms to discuss the issue. Unless you can clearly and concisely explain what it is that is causing you cognitive conflicts (because the mathematics is very clear and has been for over a century) then I think it's time to agree to disagree and leave it. And PLEASE try hard to not just repeat all the things you've already said over and over again. If they didn't make sense to us the first and second and third time you said them they're not going to make sense now. Just get to the real 'problem' you see because I don't get it. 'Endlessness' is NOT a mathematical issue or problem. Why is it a problem for you? ellazimm

in 1345, I believe kf is affirming what I said at 1342: he believes that math constrains reality rather than that math is a tool for describing reality. Aleta

KF,

DS, The von Neumann sequencing shows how stage by stage the next ordinal is a copy of the set so far. That copy is by way of union of the successive counting sets to that stage, giving the +1 succession as illustrated.

Yes, certainly.

This continues without end, end-less-ly.

If you mean we can take the successor of any ordinal, true. We cannot carry out an infinite sequence of these steps, however. That's illegal in standard logic/mathematics.

Were there an infinity of such successive sets, at the far region, zone or whatever there would be members that are endless, per that infinity or endlessness.

No, this remains to be shown. I claim the set ω includes only finite elements, and showed how assuming otherwise leads to a contradiction, so I don't believe you can show this.

All the values we can reach are finite but we cannot exhaust the set.

We cannot "exhaust the set" meaning construct ω starting with {} and the successor operation? Yes, we cannot do that in a mathematical proof.

PS: Do you see why I take a serious pause in the face of a claim like there are INFINITELY many successive FINITE natural numbers starting from 0,1,2 etc?

Yes, in that any suggestion of a contradiction should be taken seriously. I take it seriously, but it's not difficult to show that there actually is no contradiction. To sum up, I believe that I have shown that the union of the sets {}, {0}, {0, 1}, ... contains no infinite elements. My challenge to you is to prove otherwise, in standard mathematical language. daveS

DS, The von Neumann sequencing shows how stage by stage the next ordinal is a copy of the set so far. That copy is by way of union of the successive counting sets to that stage, giving the +1 succession as illustrated. This continues without end, end-less-ly. Were there an infinity of such successive sets, at the far region, zone or whatever there would be members that are endless, per that infinity or endlessness. The point is, we cannot attain that zone that way as at any k, endlessness lies still ahead; hence the pink vs blue tapes example. We point across the potential infinite and the ellipsis of endlessness and say the successor to the lot is w. But we cannot define a predecessor to w as a specific, finite value or member. My point is we CANNOT complete the succession and that is part of the nature of the set of successive counting sets. All the values we can reach are finite but we cannot exhaust the set. So, w has no specific finite predecessor, it is a limit ordinal. So also, we can only speak to the finitude of what we can reach to or represent, we have to accept that we cannot traverse to completion in +1 steps or things based on that. This includes ordinary mathematical induction. KF PS: Do you see why I take a serious pause in the face of a claim like there are INFINITELY many successive FINITE natural numbers starting from 0,1,2 etc? kairosfocus

EZ (& Aleta), forgive an early morning type-up. I adjust: >>the difference would be to

[a] first, analysis of the logic of structure and quantity [aka mathematics],

then also, necessarily, to

[b] domains in which structures (abstract or physical) and quantities are relevant.

[ --> was it Wheeler who wrote on the unreasonable effectiveness of Mathematics in the physical sciences?] The divorcing of the two is ill advised. That has been one of my points of concern all along.>> Both and, in short. But with a first and foremost. KF kairosfocus

KF,

DS (attn VS), the tree structure in the OP shows that in the W-zone, w – 1 to w/2 is a branch from w and would be beyond the marked ellipsis of endlessness. The far zone from the zero neighbourhood would include such. And far zone is observationally descriptive, treating quantities as a phenomenon.

Thanks, I see now. The primary issue I have at this point is your contention regarding this countably infinite sequence:

0 = {} 1 = {0} 2 = {0, 1} 3 = {0, 1, 2} etc.

namely, that if we *repeat this successor operation a countably infinite number of times*, then the resulting set will necessarily include an element of infinite cardinality. I believe at some point above you replaced the phrase enclosed with asterisks with something like "take the union of all 0, {0}, {0, 1}, ...", which I think is more correct. For example, ω is the union of all finite ordinals. ("Applying the successor operation infinitely many times" is not allowed in standard mathematical proofs, but forming the union of an arbitrary family of sets is). So, if I understand you correctly, you are saying that the union of the countably infinite sequence of sets 0, {0}, {0, 1}, {0, 1, 2}, ... must include an element (itself a set) of infinite cardinality. Let's call this set α. But by definition of the union of sets, this means that α ∈ {1, 2, 3, ..., n} for some natural number n. But again, the sets {0, 1, 2, ..., n} that occur in that union all have finite endpoints n (since I am not allowed to repeat the successor operation more than finitely many times). So we have a contradiction: our infinite subset α is an element of a finite set (of finite sets) {0, 1, 2, ..., n}. daveS

MT, the first question is whence the cosmos, a cosmos in which we find ourselves as responsibly free and rational beings. To which the best answer is a necessary and inherently good being who is also the is grounding ought. The God of ethical theism as worldview, which is not an issue of various religious traditions but of philosophy at foundational level. Such an inherently good Creator and God is worthy of our reasonable, responsible loyalty and service in light of our evident nature and equality of nature as people. This is a serious, responsible view in and of itself and not one to be brushed aside with dismissive talking points such as oh, men made up the notion of god out of whole cloth. As to the oh then why are there different views and traditions about God, look no further than that we are finite, fallible, morally struggling and too often ill-willed. That 876,985 + 234,761 = 1,111,746 is not answered by but different people who did the sum came up with different answers. Of course, that is what we expect in a world where error is a commonplace. The issue is, what is right, on what grounds and how can we move towards what is right. I suggest that here on, do not skip the vid, may well be of help. But, this is an aside from the main focus of this thread -- I took it up because in some ways it is even more important than the main point as the weight of one soul outweighs the wealth of a planet. KF kairosfocus

to Dave re:1340. I also find it hard to follow kf's meaning, and am not sure why a straightforward answer wouldn't suffice, but I think was kf is saying is that you can't separate math and reality. In some earlier posts, several times kf said that the math "constrains reality." I really think he believes that what we determine about math also tells us something certain about reality. That is the opposite of my belief, which is that we have to model reality using math, and then test the model to see if it fits. I think this difference is perhaps fundamentally driving his resistance to accepting orthodox interpretations of infinity. He thinks that in talking about infinity mathematically we are also truly discussing how time and the past have to be. Aleta

to me_think and kf, re: 1329. I assumed for the sake of discussion that a "root of reality" outside of time exists, but that that being was not the Christian God, and not a God with a particular interest in human beings. Part of my purpose was to separate the big philosophical ideas about time and events from the further beliefs about God of any particular human religion. Aleta

KF #1338

Aleta, the difference would be to first analysis of the logic of structure and quantity [aka mathematics], then also necessarily to domains in which structures (abstract or physical) and quantities are relevant. The divorcing of the two is ill advised. That has been one of my points of concern all along. KF

I find it hard to parse this sentence but it does seem that you are not necessarily objecting to the mathematical work done by Cantor and others which established methods and structures for handling infinite cardinal numbers. If that is true then Aleta, daveS and I have no argument with you. As I've said before, how you or anyone else chooses to see the mathematics reflected in the real world has nothing to do with the mathematics. I think it would be helpful if you'd clear up whether your 'concerns' have to do with the actual mathematics or its use. ellazimm

KF @ 1337

F/N: for those who imagine it a clever dismissive clip to suggest man invented God, I suggest a ponder here on with a look to the question of necessary being root of reality i/l/o modal considerations on being/non being. KF

Sorry KF, that link does not explain why different religion have different God with their own stories. If you have read Robert Spitzer's book (Chapter III), you know that the 'unconditional reality (God) has to be the simplest possible reality and should be unique Me_Think

Aleta, the difference would be to first analysis of the logic of structure and quantity [aka mathematics], then also necessarily to domains in which structures (abstract or physical) and quantities are relevant. The divorcing of the two is ill advised. That has been one of my points of concern all along. KF PS: It is in that context of logic in primary sense as a prior and defining aspect of mathematics that I have seen it as at minimum paradoxical and perhaps far worse, to suggest an INFINITE sequence of FINITE, successive +1 step counting steps from 0 on through 1,2,3 etc. Especially where a --> at each succession the counting set that leads to the next value is a copy of the set so far. As I pointed out yesterday. b --> Were such to go to endlessness as infinite suggests, there would be individual, endless members. c --> Which would not be finite. d --> That is why I suggest instead the view that while the sequencing -- and no it cannot be brushed aside, e.g. in von Neumann's construction it is there for all to see -- can go on endless-LY in principle, it also cannot be completed in finite stage steps. e --> It is potential, not exhausted or ended. f --> So there is ever an onward endlessness at any stage k we reach, k+1 etc on. This, the pink/blue tapes and do forever algorithm of 217 underscore. g --> The ellipsis of endlessness is a material part of the definition of the natural counting numbers. h --> It is then in recognition of an emergent type of quantity that we define w etc. And yes, i --> I am seeing this as putting a caution on how we understand what an ordinary mathematical induction . . . which preceded the axiomatisation since C19 . . . proves, that j --> a result depending on an initial case and a chaining implication case k => case k+1 will show a result that goes on endless-LY but that's not the same as giving an ending of the process that actually traverses a transfinite span that in effect reaches to the zone of w. So, k --> all PARTICULAR counting sets we can specifically reach, instantiate and/or denote by succession or representations on notations depending on such (place value, scientific etc) will be finite but such cannot exhaust endlessness. l --> We are not warranted to infer that all counting sets in the onward endless succession are finite (or even that some are infinite), which breaks the possibility of outright contradiction.* m --> We may point across an ellipsis of endlessness to draw a general conclusion, but we must circumscribe such with due limits.* ________________ * F/N: Thus, the question of materiality of endlessness. ______________ n --> Transfinite induction allows us to address ALL ordinals, but that is because it takes some very powerful and potentially constraining steps. kairosfocus

F/N: for those who imagine it a clever dismissive clip to suggest man invented God, I suggest a ponder here on with a look to the question of necessary being root of reality i/l/o modal considerations on being/non being. KF kairosfocus

Ez, BTW, w is a stand in for omega, the first transfinite ordinal i/l/o say the von Neumann type construction from {} --> 0 on, which has cardinality aleph null. Kindly refer to the tree of numbers in the OP as a context for usages and remarks. KF kairosfocus

DS (attn VS), the tree structure in the OP shows that in the W-zone, w - 1 to w/2 is a branch from w and would be beyond the marked ellipsis of endlessness. The far zone from the zero neighbourhood would include such. And far zone is observationally descriptive, treating quantities as a phenomenon. On eternity and infinite past time suggestions, Enyart or whoever may freely make up what he wants to, that is different from such being serious historic views. Above, I gave a model that would help some, of time-space's north pole point as God's throne room view. Thus, echoing Paul's citation of poets at Mars Hill in AD 50, in him we live and move and have our being. As a sampler, Augustine:

What times existed which were not brought into being by you? Or how could they pass if they never had existence? Since, therefore, you are the cause of all times, if any time existed before you made heaven and earth, how can anyone say that you abstained from working? (Augustine, Confessions, XI. xiii (15)). It is not in time that you precede times. Otherwise you would not precede all times. In the sublimity of an eternity which is always in the present, you are before all things past and transcend all things future, because they are still to come. (Augustine Confessions XI. xiii (16)). In you it is not one thing to be and another to live: the supreme degree of being and the supreme degree of life are one and the same thing. You are being in a supreme degree and are immutable. In you the present day has no ending, and yet in you it has its end: ‘all these things have their being in you’ (Rom.11.36). They would have no way of passing away unless you set a limit to them. Because ‘your years do not fail’ (Ps.101.28), your years are one Today. (Augustine Confessions, I. vi (10))

Time and eternity, actuality of a world. possible vs impossible beings, and of possible contingent vs necessary are all bound up in this. I simply note that true nothing, non being has no causal power. Were there utter nothing, such would forever obtain. If a world now is, a root of reality always was, a necessary being foundational to a world existing. Such points beyond the space time zone we inhabit to a zone of eternity that undergirds it. Something qualitatively different from time. Hence the north pole of space time model as a suggestion to help us ponder i/l/o how all lines of longitude converge at a single point. Just, to spark thought. The point is, we must beware our conceptual limitations and perhaps want of relevant background when we traipse into such matters. KF kairosfocus

#1333 error correction: In the first sentence, the word 'chance' should read 'change' instead. Sorry for this misspelling, which shows I wasn't as careful as I should. Dionisio

Whatever y'all argue in this discussion, it aint't gonna chance a bit of the ultimate reality, which is written:

In the beginning was Logos

In the beginning was the Word, and the Word was with God, and the Word was God. He was in the beginning with God. [John 1:1-2 (ESV)]

The creation of the world

In the beginning, God created the heavens and the earth. [Genesis 1:1 (ESV)]

All things were made through Logos

All things were made through Him, and without Him was not any thing made that was made. [John 1:3 (ESV)]

Alright, you may continue with your arguments... or whatever, until the end of this age of grace. Paká! :) Dionisio

My thoughts: Humans created God. Every religion has their own God and their own story. If God was one infinite being, this wouldn't be the case. Me_Think

As far as I can tell, this thread isn't going away very soon, so no hurry! :-) And I also have had this line of thought in the back of my mind for a long time, but in the interest of a focused discussion (such as it has been), I didn't want to mix these metaphysical speculations with the pure math concerning infinity. Aleta

Aleta, You've opened the door to a very interesting discussion here. I have some thoughts to offer on these points, and had actually been thinking of addressing some of them earlier today, though I didn't get around to it. I don't really have the time to write anything right now, but hopefully I'll have a chance tomorrow, because there are some really interesting issues here. Take care, HeKS HeKS

Since we (at least I) have pretty much exhausted the discussion about mathematical infinity, I think I'll take off my mathematician hat and venture into speculative metaphysics. Specifically, I'm going to take the perspective of a theist of the following sort: I'll assume an eternal, omniscient, omnipotent, omnipresent immaterial being capable of creating a universe or universes. However, I'm not assuming the Christian God, and specifically not a special focus on our little planet nor any of the special theological beliefs that are attached beyond the properties I listed above, I'll also agree with Origenes and kf that God is eternal and thus outside of both time and space. A disclaimer: I am going to talk of God creating multiple universes in my speculations below. In doing so, I am not referring to the multiple universe hypotheses ralted to quantum possibilities being discussed elsewhere - those don't interest me. Rather, I am assuming the a God capable of creating this universe is capable of creating other similar universes, and given his eternal nature, might not create many universes. So here are some thoughts and questions. Comments welcome. 1. Assuming God has omniscient knowledge of all possible mathematics, does God experience the infinite, be it the integers or the real number line or the digits of pi, in their entirety, as a completed whole? We are limited to just pointing to the lack of a limit, but my opinion is that God does not have that limitation. Even though we can't begin to grasp what it means to comprehend the whole of the infinite, I assume God can do so. 2. Since time doesn't apply to God, what is going on in God before he has created a universe? I assume he doesn't think linearly like we do, but rather has complete and instantaneous comprehension of all concepts. So during his eternal existence, does it make any sense to talk about what he is/does when there is no material universe? You can't ask what is he even doing "before" he created the universe, because he doesn't exist in time: no number line runs concurrently with God, so to speak. 3. So where does time come in? What does it mean to say that God created time. I see two possibilities, which I'll offer as a question: Does God create time as an independent creation and then create a universe in time, or is there no time until a universe is created? I ask this question to try to possibly separate the two issues of the possible infinitude of time from the question of the creation of a first causal event in time. 4. On the one hand, it may be that time cannot exist without events happening: that is, time is a by-product of events happening in causal sequence, so if nothing exists to happen, time does not exist. On the other hand, God might create time as a dimension which exists irrespective of whether any physical universe exists in which events happen in causal sequence. It is perhaps interesting to consider these two possibilities. 5. If God did create time independently of a universe, and then created a universe at a moment in time, could God have created time so it was infinite, so that an infinite number line truly represented this metaphysical time within which universes and physical time might exist, even though no causal events and no physical time, existed until the moment of creation. In this case, God could create multiple universes at different times (and even concurrently), and he could create/have created an infinite number of universes stretching back infinitely into the past and infinitely far in the future. 6. On the hand, if it really makes no sense, even to God, to consider time as being able to exist independently of events, then consider this situation: God creates universe A. It runs for 30 billion years or so, comes to a complete dead end, and then God utterly destroys it. Some time "later", which really doesn't make sense if God is outside time, God makes universe B and time starts up fresh in that universe. In this case we have two periods of time, one for each universe, with nothing "in between" except the God himself, and since he is eternal and atemporal, we couldn't say there is any time between the two universes. But surely, it seems to me, God would know the temporal sequence of the two universe, which might imply that God has an internal time line as one of his omniscient conceptions, not a timeline that pre-existed him, but an infinite internal timeline by which he knows of time even when there is nothing happening. Or perhaps God knows time when it is happening in a universe, but is so all-of-a-piece, such a Oneness, that his knowledge of different instances of time in different universe are themselves not temporally related. Thoughts? Questions? Aleta

KF: The beginningless past would refer to eternity which is different from time. How can you have a past without time? velikovskys

Bump 1314 kairosfocus April 4, 2016 at 8:08 am Material in context means what makes a difference to decisions or analysis etc. 1315 Aleta April 4, 2016 at 8:15 am Do you mean " makes a difference to decisions or analysis" in the world of abstract mathematics, or do you mean " makes a difference to decisions or analysis" in respect to the material, physical, actual world? Your response in 1314 doesn’t make clear which you mean. Aleta

DaveS #1322

(...) many Scriptural teachings at kgov.com/time showing that God exists in time, therefore we teach that God has not existed atemporally outside of time and then entered time, but rather, that His goings forth are from of old, from everlasting, from ancient times, (...)

God eternally existing in time would mean that time is more fundamental than God, which is incoherent. It would pose the question: "where did time (and space) come from?" and God would not be candidate as a cause. God cannot be the foundation of all reality and (eternally) be enclosed by time.

Because of the impossibility of time itself being created (...)

Big bang? Origenes

KF,

DS, please look at the numbers tree in the OP. 0 and neighbourhood is the near zone, you then face endlessness and successors starting at w on. KF

If we're working in the surreal numbers, are ω - 1, ω - 2, and so on also in the far zone?

The beginningless past would refer to eternity which is different from time.

Hmm. I don't know that Enyart would agree; he apparently believes God exists in time and has existed for an actual infinity of time. To be honest, I didn't find the Morriston paper that persuasive, however. This does at least show there is some diversity of opinion even among Christians regarding an infinite past. daveS

The beginningless past would refer to eternity which is different from time. kairosfocus

DS, please look at the numbers tree in the OP. 0 and neighbourhood is the near zone, you then face endlessness and successors starting at w on. KF KF kairosfocus

Interestingly, Bob Enyart, who posts here occasionally, has done a show on this topic. The title of the webpage: "God crossed an actual infinity of time through the beginningless past".

Age Old Philosophical Question Answered: Bob Enyart answers the age old philosophical objection to countless Bible passages that present God as having existed throughout eternity past. Because of the impossibility of time itself being created, and by the many, many Scriptural teachings at kgov.com/time showing that God exists in time, therefore we teach that God has not existed atemporally outside of time and then entered time, but rather, that His goings forth are from of old, from everlasting, from ancient times, the everlasting God who continues forever, from before the ages of the ages, He who is and who was and who is to come, who remains forever, the everlasting Father, whose years never end, from everlasting to everlasting, and of His kingdom there will be no end.

Further down the page:

God has existed through the "beginningless past" (Morriston, 2010, Faith and Philosophy, pp. 439-450). Christian theologians who object to this typically do so by being inconsistent, and thus, their objection is easily neutralized, and then answered.

Here's a paper by Morriston on the subject (I haven't read it yet) entitled "Beginningless Past, Endless Future, Actual Finite". The abstract:

One of the principal lines of argument deployed by the friends of the kalam cosmological argument against the possibility of a beginningless series of events is a quite general argument against the possibility of an actual infinite. The principal thesis of the present paper is that if this argument worked as advertised, parallel considerations would force us to conclude, not merely that a series of discrete, successive events must have a first member, but also that such a series must have a final member. Anyone who thinks that an endless series of events is possible must therefore reject this popular line of argument against the possibility of an actual infinite.

daveS

KF, Is it accurate to say your "far zone" consists of all ordinals ω and larger? daveS

Aleta, there is an ellipsis of endlessness that commonly crops up, I add e.g. {0,1,2 . . . }. There is such a thing as beyond that ellipsis starting with w as can be seen in the tree of surreals appended to the OP. The far zone from counting numbers near zero is what happens in and beyond that ellipsis of endlessness. Which the surreals do highlight in a reasonable framework. The onward points then are, the spanning or traversal of such endlessness, which it is evident cannot be executed in finite stage steps as would be required for an infinite past of causally connected stages but mainly as a consequence of the involved logic of structure and quantity. In that wider context, there was a proposal that implies that there are infinitely many +1 step successive finite natural numbers ranging up from 0, which I find to be at best paradoxical, for cause. There is more but there is no need to go on repeating much the same as has already been said. KF kairosfocus

I don’t think that is true. The concern about an infinite past is always in the back of his mind, I’m sure, but a great deal of what he has said has been about some unorthodox notions about the pure mathematics of the natural numbers, such as that “beyond the ellipsis” there is a “far zone”, etc. I don’t believe that he thinks “infinity works just fine as a purely mathematical construct.”

Ok, well I'll leave KF to address whether or not that is the case. Some of the math stuff that has been discussed lies clearly outside my knowledge and understanding and I find it best to be up-front when that is the case. But from what I've understood of what he's written, the concern about an infinite past has been closer to the front of his mind than the back, and the math related stuff he has been discussing has seemed to be offered in the larger context of how impossible it would be to have an infinity in the real world, which is what an infinite past would be.

In respect to the point about starting from infinity, you write, “I disagree with you that I’m confused.” My apologies for misunderstanding you. We are in agreement that “starting from infinity” is meaningless.

Not a problem. It was an understandable misunderstanding. It would obviously become burdensome on my part if I had to specify every time I make a statement of a certain sort that it is made for the purpose of drawing out the absurdity of some situation, or that some scenario would need to be described with the words I'm using even though the words amount to a nonsensical statement, so I've just used a shorthand hoping that my ultimate meaning is clear from prior posts, but clearly that's not always the case. HeKS

Thanks, HeKS.

as far as I can tell, KF has all along been discussing this issue of infinity as it relates to the coherence of a real-world instantiation in the form of an infinite past-time. He wrote the OP and that’s pretty clearly the issue he has been trying to discuss, so I’m not sure what the argument is about for you and ellazimm if your point is merely that infinity works just fine as a purely mathematical construct, as I don’t think KF has argued otherwise.

I don't think that is true. The concern about an infinite past is always in the back of his mind, I'm sure, but a great deal of what he has said has been about some unorthodox notions about the pure mathematics of the natural numbers, such as that "beyond the ellipsis" there is a "far zone", etc. I don't believe that he thinks "infinity works just fine as a purely mathematical construct." In respect to the point about starting from infinity, you write, "I disagree with you that I’m confused." My apologies for misunderstanding you. We are in agreement that "starting from infinity" is meaningless. Aleta

Aleta, Thanks for your response. You said:

So the language you propose is a bit more accurate because it fleshes out a bit more what the definition of infinite is. (An aside, though: even the phrase you use “towards infinity as a limit” is informal and not truly accurate, as infinity is not really a place that can be a limit. It would be more accurate to just say “without limit.”)

I agree. I wasn't actually intending to suggest that it was infinity itself that was the limit, but that the limit of our counted set can continually increase towards infinity. Having said that, I realize upon rereading that my wording suggested it was infinity that was the actual limit, so I should have been even more careful about the way I worded that. You said:

In any discussion, different people may have different ideas about what the thread is about.

Fair enough. However, I was speaking with reference to the OP. Of course, you are free to add to the discussion on any aspect of the relevant issue you choose, but what I was ultimately trying to get at is that, as far as I can tell, KF has all along been discussing this issue of infinity as it relates to the coherence of a real-world instantiation in the form of an infinite past-time. He wrote the OP and that's pretty clearly the issue he has been trying to discuss, so I'm not sure what the argument is about for you and ellazimm if your point is merely that infinity works just fine as a purely mathematical construct, as I don't think KF has argued otherwise.

The relevant question here is not whether every specific integer is a finite number, but whether every integer is reachable through a succession of finite steps. … It would take a finite number of steps to reach a particular finite integer from zero or from any other specific finite integer, but it would take an infinite number of steps to reach any finite integer from infinity. And that is the point at issue in this thread. Getting from infinity to some finite number may or may not present a problem in the abstract realm of pure mathematics.

I’m afraid this quote contains one of the key confusions in the discussion. The phrase “from infinity” makes no sense. Infinity is not a place you can start from. You are falling prey here to the same thing you cautioned me against above when you suggested we be more precise about what infinite means on the number line, confusing an informal way of talking with the more accurate mathematical idea.

I disagree with you that I'm confused. I completely agree with you that "[t]he phrase 'from infinity' makes no sense. Infinity is not a place you can start from." Please don't take my use of that phrase or the statement that "it would take an infinite number of steps to reach any finite integer from infinity" to suggest this was a coherent concept or a thing that could happen. My point all along in this thread has specifically been that such a notion makes absolutely no sense and ultimately amounts to word salad. In fact, I specifically said this in my comment to you:

The man’s statement [about descending from infinity], and the entire scenario it relates to, is utterly nonsensical. It is absurd.

My reason for using the phrases is to draw out that claims of having arrived at the present from the infinite reaches of a beginningless past amount to making statements of the sort that you are saying (with my full agreement) make no sense. Statements about the feasibility of doing it are basically meaningless, because the entire notion is nonsensical. You said:

You write, “Getting from infinity to some finite number may or may not present a problem in the abstract realm of pure mathematics.” No, “Getting from infinity to some finite number” is, as they say, not even wrong. The statement makes no mathematical sense.

Thanks for the info. As I said, at least as the issue relates to the real world I have been saying all along that the idea doesn't make any sense at all, but I was uncertain as to whether there might be some mathematical formality that could in some way represent such a thing, however absurd it is in reality. HeKS

Hi HeKS. Thanks for your thoughtful reply. In respect to the question, "1. True or False: there are an infinite number of integers," you write,

but as it is worded I find it has the potential to confuse the real issues, which are decidedly not purely mathematical. The illustrations, like that of the ladder, were intended to serve a few different purposes, but the ultimate purpose I had in mind in my comments was to stress the importance of maintaining mental distinctions between abstract concepts and concrete realities.

I'm sorry the question seems confusing, but I think I made it clear that this question is about pure math when I wrote "Note: this is a purely mathematical question. It is not about time, or ladders, or tapes – just math." I know you are unlikely to have followed all my posts on this, but I am a strong advocate for doing exactly as you say, "maintaining mental distinctions between abstract concepts and concrete realities." You write,

After all, there is not an actually existing infinite set of integers just sitting around out there somewhere, and so we must question what is meant by the word “are” in your claim, since it would normally be a reference to existence. I think a more accurate way of stating matters would be to say that there is no arbitrarily large integer that would be the largest possible integer, and so the integers can continuously increase from the zero point towards infinity as a limit in both the positive and negative directions.

The question of in what sense mathematical concepts exist is of interest, but not the topic of this thread. Mathematicians of all philosophical and religious perspectives work with perfect circles and pi and infinite sets as they are defined within the symbolic world of math: they all agree that those concepts exist as part of those mathematically systems and as part of our ability to apprehend those concepts. That is what I mean by "exist" and "are". I'm making no claims about their metaphysical nature nor about any physical representation. Also, I agree with you that there are more accurate ways to state what we mean by "infinite", but, as with many concepts, we informally use a word or phrase that we all know has a more precise meaning. For instance, in calculus we start by stressing the idea of limit: for instance, in discussing the series 1/2 + 1/4 + 1/8 + ..., we stress that the limit of this series as n goes to infinity is 1, but that any partial sum (where we stop at some finite n) is not 1: informally, we say we "get infinitely close to 1". However, later in the year we may say that the sum of that series is 1, because, since we understand the more precise meaning, we can shortcut the language. So the language you propose is a bit more accurate because it fleshes out a bit more what the definition of infinite is. (An aside, though: even the phrase you use "towards infinity as a limit" is informal and not truly accurate, as infinity is not really a place that can be a limit. It would be more accurate to just say "without limit.") However, there is more than that. Cantor formalized the notion of infinity, and set in motion a whole branch of mathematics that goes beyond just trying to accurately describe numbers on a number line. He created a new kind of number, the transfinites, and named the particular order of infinite possessed by the integers as aleph null, and then discovered that there are other infinite numbers: some infinite numbers are bigger than others. So the integers are infinite with cardinality aleph null would be a more accurate statement for those familiar withe mathematics of infinite sets. You write,

The abstract concept of infinity can be used without problem by mathematicians, but that doesn’t mean that an infinity can be translated into a concrete and coherent reality in the world. And that is what this thread is about.

In any discussion, different people may have different ideas about what the thread is about. For kf, the connection of the topic to arguments about an infinite past are paramount. However, that topic has not been my interest. I've written a few posts about why I feel that way, but the vast majority of my interest is about the pure math. So when I say that the integers are infinite I am in no way discussing any possible connection of that statement with anything physically real. Translating "an infinity ... into a concrete and coherent reality in the world" is not what my involvement in the discussion is about. You write,

The relevant question here is not whether every specific integer is a finite number, but whether every integer is reachable through a succession of finite steps. ... It would take a finite number of steps to reach a particular finite integer from zero or from any other specific finite integer, but it would take an infinite number of steps to reach any finite integer from infinity. And that is the point at issue in this thread. Getting from infinity to some finite number may or may not present a problem in the abstract realm of pure mathematics.

I'm afraid this quote contains one of the key confusions in the discussion. The phrase "from infinity" makes no sense. Infinity is not a place you can start from. You are falling prey here to the same thing you cautioned me against above when you suggested we be more precise about what infinite means on the number line, confusing an informal way of talking with the more accurate mathematical idea. You write, "Getting from infinity to some finite number may or may not present a problem in the abstract realm of pure mathematics." No, "Getting from infinity to some finite number" is, as they say, not even wrong. The statement makes no mathematical sense. Returning to the topic of what is the discussion about, you write,

Aleta and ellazimm, you seem to keep saying that your interest is purely in the mathematical issues here and not in the issues that arise when translating the abstract concept of infinity into a real world case like an infinite past-time, and you seem to expect that people are engaging you on those terms. But looking to the OP, this thread is and always has been about the latter, not the former, so it kinda seems like we’re all sort of talking past each other here.

Your first sentence is accurate. My disagreement with the second sentence is that I think in a discussion people often limit their interest, and in fact it often useful to narrow the focus. I think it's reasonable to expect people who respond to me to accept that it is only the math I'm interested in. However, it should be clear that if one intends to apply math to the real world, one better have the math right, so discussing the pure math can be a necessary first step. For instance, as above, it one realizes that mathematically "getting from infinity to some finite number" is nonsensical, then one won't mistakenly try to apply that sentence to an application of the concept to a discussion about reality of whatever kind. Aleta

Do you just mean significant in the world of abstract mathematics, or do you mean have consequences for the material, physical, actual world? Your response in 1314 doesn't make clear which you mean. Aleta

Material in context means what makes a difference to decisions or analysis etc. kairosfocus

kf, when you write,

"In that context, I again state, I find it at minimum paradoxical, and I fear it much worse than that, ...

what exactly do you fear? What would be "worse than paradoxical"? And, as asked before, when you write,

Hence, my suggestion that it may be wiser, sounder to highlight onward endlessness and circumscribe our conclusions by such, where that is material.

, what do you mean by material? Do you just mean significant, or do you mean have consequences for the material, physical, actual world? Aleta

KF,

DS, I have answered with a context that makes the reason for my answer plain.

But you have not stated whether the steps I referred to in #1310 are a necessary part of the proof. Kindly tell us whether they are or are not. daveS

DS, I have answered with a context that makes the reason for my answer plain. Chaining is implied in any induction process that uses case k to imply case k+1 and hangs the chain of implications on an initial case as a peg. k and k+1 are not just abstractions that operate above the realities of the initial case peg and that which depends on it. Where also -- per weakest link -- in a chain, the support is effectively instantly, necessarily present all along the line or the chain breaks. But there is a clear priority of dependence. KF kairosfocus

KF, Please answer this specific question: Do you believe the steps P(1) → P(2), P(2) → P(3), and so forth are a necessary part of the proof I gave in #1303? daveS

DS 1303, the chaining is generalised but hangs on the peg of the initial case. I do not know about domino metaphors but I can see a succession, chaining rule and an initial value, with a running index integer number generalised as k or n or whatever. A chain incorporates both succession and simultaneity, as the weakest link principle shows. KF kairosfocus

F/N: I find it useful to cite Merriam Webster's summary, as well as AmHD and Collins, to draw out the sense of the term finite:

MW finite 1 a : having definite or definable limits a finite number of possibilities> b : having a limited nature or existence finite beings> 2 : completely determinable in theory or in fact by counting, measurement, or thought the finite velocity of light> 3 a : less than an arbitrary [--> but specific] positive integer [= counting set or natural number] and greater than the negative of that integer b : having a finite number of elements a finite set> Am HD: fi·nite (f??n?t?) adj. 1. a. Having bounds; limited [--> as in within or progressing to an end point that gives bounds] : a finite list of choices; our finite fossil fuel reserves. b. Existing, persisting, or enduring for a limited time only; impermanent. 2. Mathematics a. Being neither infinite nor infinitesimal. b. Having a positive or negative numerical value; not zero. c. Possible to reach or exceed by counting. Used of a number. d. Having a limited number of elements. Used of a set. Collins: finite (?fa?na?t) adj 1. (Mathematics) bounded in magnitude or spatial or temporal extent: a finite difference. 2. (Mathematics) maths logic having a number of elements that is a natural number; able to be counted using the natural numbers less than some natural number. Compare denumerable, infinite4 3. a. limited or restricted in nature: human existence is finite. b. (as noun): the finite.

High quality dictionaries of course set out to summarise relevant usage. The issue here is that the finite will be within bounds set by some given specific natural, counting set based number. I add, the finite will be limited or bounded, often in a quantitative way such that a bounding number or structure, an end, can be given. One is 5 ft, 9 inches tall, or the radius of the observable cosmos is 45 bn Ly or something like that. Even vectors gave magnitudes comparable to a bounding sphere with a radius. Such values may then be assigned a next biggest whole counting number that bounds. Which makes it crucial to observe that this set of counting numbers itself continues endlessly so it has a far zone that is open-ended, unbounded, ever able to go on. But particular values k -- however large -- will always be exceeded by k+1 etc. Which brings to bear the issue of onward end-less-ness, as k, k+1 etc can be put in 1:1 match with 0,1,2 etc. The defined "first" transfinite ordinal w reflects that emergent quantitative phenomenon, first degree endlessness. It has no definable specific finite immediate predecessor z such that z + 1 = w. Instead any particular z will be exceeded by z+1 z+2 etc, i.e. the pattern continues. It is in this context that I have spoken, above, to the material significance of endlessness in understanding the set of natural counting numbers, and the distinction to be made between any particular value in the set k and the set as a whole. Where, in building the set, it is readily seen that per von Neumann et al, a counting set k +1 collects the counting sets 0 to k, and so shows the copy of the list so far principle. For simple illustration: {0,1,2,3,4} --> 5 Where {} --> 0 {0}--> 1 {0,1} --> 2 {0,1,2} --> 3 {0,1,2,3} --> 4 and so forth, without limit to stepwise +1 stage progression of these ordinals; usually shown by the ellipsis of endlessness, . . . This takes significance in speaking to an imagined completion -- note, imagined as opposed to actualised -- to endless extent, as on this, we would have to copy that endlessness into some element. But in fact, once we arrive at any given k, the onward endlessness prevails and we cannot successively actually complete the set, we may only point to the pattern and point on across the ellipsis of endlessness. All specific values, k, we can reach or state in notations giving explicit values (or -- as just shown -- even symbolically represent, e.g. k) will be finite and bounded by k+1 etc. But that then implies onward endlessness. (Which points to the first degree endlessness of the set and its cardinality aleph null.) As a result any chaining . . . cf here https://www.math.ntnu.no/~hanche/notes/transfinite/transfinite-a4.pdf . . . successive stepwise process that proceeds in finite stages whether +1 increments or something else, will never exhaust endlessness. We attain thus to a potential but not actualised infinite through such processes. To assert the infinite, we abstract from such and define the overall set by in effect pointing across the ellipsis of endlessness. This is evident in the way w is stated as order type of the set: {0,1,2 . . . } --> w However, this then affects how we handle ordinary mathematical induction when the induced conclusion is materially affected by endlessness. Let me highlight by setting off in a block:

Induction INHERENTLY chains using the chaining principle -- and chaining is acknowledged in the literature -- that case k implies case k+1, thus to k+2 etc. The chaining is right there in that succession, however we may generalise from 0,1,2 etc to for all cases n; but also as it proceeds in +1 steps, we see the same issue that at any stage k we can go onwards endlessly in match with 0,1,2 etc. That is why I find discomfort with assertions such as that per an induction, all natural counting set numbers are finite, and there is an infinity of such finite values. I would find that an infinite set of successive +1 separated values or sets from 0 will proceed to endlessness and by the copy list so far principle would then enfold at least one endless member. Instead, I suggest we cannot complete to endlessness and the conclusion is restricted by the reach-ability issue. That is, any particular natural counting number k that we may attain by k applications of a +1 successive increment starting from 0 [notice the number of edits distance metric implied] will be such that onward from k there are k+1, k+2 etc that allow us to put such in 1:1 correspondence with 0,1,2 etc without limit. That is, end-less-ness cannot be traversed in steps like that. Or, in things that build on such.

We can use stepwise chaining to say things about what we can reach, e.g. all such k's will be finite, but then that leaves the endlessness onward. To address it, we may impose a generalisation that points across the endlessness, but then when endlessness itself affects the relevant property it may be unsafe to infer from finite to endless and so infinite. I suggest, stating results of ordinary mathematical induction modestly as in terms of what we may reach in succession from 0 by finite stage steps, may be advisable. This points to transfinite induction and its proof strategy, e.g. as Wiki outlines for convenience:

Transfinite induction is an extension of [--> ordinary] mathematical induction to well-ordered sets, for example to sets of ordinal numbers or cardinal numbers. Let P(a) be a property defined for all ordinals a [--> a is any ordinal of any class]. Suppose that whenever P(b) is true for all b lt a [--> all predecessors to a], then P(a) is also true. [--> notice the much stronger successor claim] Then transfinite induction tells us that P is true for all ordinals. Usually the proof is broken down into three cases: Zero case: Prove that P(0) is true. Successor case: Prove that for any successor ordinal a+1, P(a+1) follows from P(a) (and, if necessary, P(b) for all b lt a). Limit case: Prove that for any limit ordinal l, P(l) follows from [P(b) for all b lt l]. All three cases are identical except for the type of ordinal considered. They do not formally need to be considered separately, but in practice the proofs are typically so different as to require separate presentations. Zero is sometimes considered a limit ordinal and then may sometimes be treated in proofs in the same case as limit ordinals.

Let me add, as that is easiest, that the bridge to the real world is pivotal and comes through the presence of quantity and structure in concrete reality constrained by distinct identity of a given entity A that allows a world partition W = {A |~A} such that A has core characteristics that must be mutually coherent and mark it as distinct from what is not A. For simplicity say A is a bright red ball sitting on a table. Consequently A is never something like a square circle as in all possible, i.e. coherent worlds, properties for squarishness and circularity cannot be met at one and the same time under same circumstances in a given entity. Where, Mathematicsis not a magical poofed- into- being abstract entity that may make up its rules arbitrarily. For instance just to use symbols it must respect distinct identity, and of course proof of C by showing contradiction on asserting ~C is a classic technique in the core of mathematics. No, Mathematics is the logical study of structure and quantity, starting with the pre-theoretic concept that logic is about good reasoning connected to reality by the premise of coherence and clarity. Thus, we start from distinct identity and recognise that from such world partition the LOI, LNC and LEM follow instantly and self evidently. Denial of distinct identity being absurd. In this context, mathematical concepts are accountable to recognisable realities on pain of descent into absurdities. And ending in confusion. That is why test cases that are [quasi-]physical are very relevant. And the messages of the pink/blue tapes or the endlessly high ladder with its foot on the ground at 0, etc are relevant. In particular, we cannot traverse endlessness in finite stage steps. Where, whether or no we are inclined to acknowledge them, chained finite stage steps appear in many contexts, the successive natural counting numbers from 0 and anything building on such succession in particular. Including, ordinary mathematical induction. In that context, I again state, I find it at minimum paradoxical, and I fear it much worse than that, to see the presentation of the argument that there are infinitely many finite, +1 successive natural counting numbers starting from 0. Especially i/l/o the copy of the chained set so far issue and the problem of onward endlessness. Where imposing generalisations by pointing across the ellipsis of endlessness does not provide any relief. Hence, my suggestion that it may be wiser, sounder to highlight onward endlessness and circumscribe our conclusions by such, where that is material. With this case as a key exemplar. KF kairosfocus

Cabal @ 1306

To me, that is a demonstration that infinity is just a concept with no correspondence with reality. But, as a concept it may be very useful if you are into such things – I am not.

While there is no actual infinity, without the concept of something 'tending' towards mathematical infinity, many processes in science can't be calculated, so concept of infinity is crucial in modelling the real world. Me_Think

To the subject of infinity I'll only say it seems to me that infinity is a concept, not a reality. I don't see any reason why we can't have an infinte loop of infinity + 1. We may add any number of numbers to infiniy and we'd never reach the end. That's what infinity means, the quest is over. To me, that is a demonstration that infinity is just a concept with no correspondence with reality. But, as a concept it may be very useful if you are into such things - I am not. If we imagine an all-compassing, complete, catholic and total void, we have to assume that such a non-object is incompatible with a subject like infinity. Cabal

I thought I'd offer my thoughts on Aleta's questions in 1188

Consider the integers on a standard number line, with the positive counting numbers 1, 2, 3, … to the right of zero and their negatives to the left. 1. True or False: there are an infinite number of integers 2. True or False: Every integer is a finite number. What are your answers to questions 1 and 2. Note: this is a purely mathematical question. It is not about time, or ladders, or tapes – just math.

As I've said previously, I have no advanced math skills (something I'd like to remedy at some point when I have the time), so any answer I give that's based purely on math is likely to be of less than no value to anyone reading this thread. As such I'll take a different approach to the questions, as I share KF's view that the philosophy and logical analysis comes first. Question 1 - True or False: There are an infinite number of integers Aleta, I tend to think that you have a particular meaning in mind when you ask this question that would make a "true" answer reasonable, but as it is worded I find it has the potential to confuse the real issues, which are decidedly not purely mathematical. The illustrations, like that of the ladder, were intended to serve a few different purposes, but the ultimate purpose I had in mind in my comments was to stress the importance of maintaining mental distinctions between abstract concepts and concrete realities. Coming specifically to your question, as you know, numbers are abstract objects and they have no physical existence (though we can create physical representations of them). When we envision a number line with integers racing off from the zero point in both directions we're using our imaginations to give visual representation to abstract concepts. Obviously, there is no actual number line and there are no actual numbers. As such, I think it is misleading to simply say that "there are an infinite number of integers". After all, there is not an actually existing infinite set of integers just sitting around out there somewhere, and so we must question what is meant by the word "are" in your claim, since it would normally be a reference to existence. I think a more accurate way of stating matters would be to say that there is no arbitrarily large integer that would be the largest possible integer, and so the integers can continuously increase from the zero point towards infinity as a limit in both the positive and negative directions. The abstract concept of infinity can be used without problem by mathematicians, but that doesn't mean that an infinity can be translated into a concrete and coherent reality in the world. And that is what this thread is about. Question 2 - True or False: Every integer is a finite number. As the statement is written, I would answer that it's true. However, I once again think that the way it is written simply avoids the actual point at issue. The relevant question here is not whether every specific integer is a finite number, but whether every integer is reachable through a succession of finite steps. Now, it seems like several people here would be inclined to answer yes, however, from a logical perspective, that's simply not true. It would take a finite number of steps to reach a particular finite integer from zero or from any other specific finite integer, but it would take an infinite number of steps to reach any finite integer from infinity. And that is the point at issue in this thread. Getting from infinity to some finite number may or may not present a problem in the abstract realm of pure mathematics. I'm not going to pretend to have any clue at all what mathematical functions or formalities might be in place to effect such a transfinite maneuver. My concern in this thread is with the real world, and in the real world, any notion of traversing an actually infinite sequence, such as moving from an actually infinite beginningless past to a finite present moment, presents an utterly intractable problem, which I have attempted to illustrate with the example of a man engaged in an infinitely long descent down an infinitely high ladder who eventually climbs off the bottom rung (0) and says, "Done! I have finally finished an infinitely long descent." This is the kind of thing we're talking about when we try to translate infinity into the real world and hence my reason for saying that I think it's important for us to maintain a mental distinction between abstract concepts and concrete realities. The man's statement, and the entire scenario it relates to, is utterly nonsensical. It is absurd. And if anyone disagrees that such a thing results in absurdity, they must at least admit that it is not at all obvious that it doesn't result in absurdity. Getting on the same page Now, as far as I can tell, KF and Silver Asiatic seem to be saying essentially the same thing I am. That is, the concerns they are expressing about infinity are about the attempts to translate it from a mathematical concept to an actually existing reality in the world. It doesn't seem to me that either of them is saying that their concerns/issues relate to the simple notion of infinity as it is used in a purely mathematical context. On the other hand, Aleta and ellazimm, you seem to keep saying that your interest is purely in the mathematical issues here and not in the issues that arise when translating the abstract concept of infinity into a real world case like an infinite past-time, and you seem to expect that people are engaging you on those terms. But looking to the OP, this thread is and always has been about the latter, not the former, so it kinda seems like we're all sort of talking past each other here. Only daveS seems like he's trying to make some kind of connection between the math and the possibility of the real world case under discussion, though I don't find he's addressed any of the issues that actually arise with the real world case. Personally, I appreciate that we've all been able to have a civil discussion here over an extended time without resorting to insults and name-calling. I wish every discussion could stay at this level of civility, because it makes the discussion much more interesting and thought-provoking in my opinion. Nonetheless, it seems to me like the discussion would benefit from us getting on the same page as to what we're actually arguing about here. And, in fact, it might benefit even more from us getting on the same page about what we're not arguing about. Anyway, just some thoughts I had on the issue. Take care, HeKS HeKS

KF, 1. There is no infinite past. I have explained why in comment # 1141 2. Infinity exist only as a mathematical concept- there is no actual infinity 3. There is no point called 'endlessness' beyond infinity because there is no such concept in mathematics! I don't know what concept you are using to argue about 'endlessness'. Me_Think

KF,

As for primes, we can show they are without upper limit and are part of the endless nature of counting numbers. But we cannot attain to a prime that is endless — infinite — no more than we can succeed to endlessness in actually carried out +1 steps. Every prime we can reach is finite but we cannot reach all primes.

So, does that mean the following? 1) The set of primes is infinite, in the sense it can be put in 1-1 correspondence with a proper subset of itself. 2) You take no position on whether all primes are finite.

And on the chaining of ordinary mathematical induction, notice how the line of proof propagates, set up an initial case then also the chaining principle case k implies case k+1, thus to k+2 etc. The chaining is right there, but as it proceeds in +1 steps, we see the same issue that at any stage k we can go onwards endlessly in match with 0,1,2 etc. We may indeed point across the ellipsis of endlessness and impose a conclusion, but we can get into trouble if endless succession makes a material difference. KF

No, that's really not how it works, despite the usual domino illustration. That's because:

at any stage k we can go onwards endlessly in match with 0,1,2 etc.

is not allowed in proofs in the systems we are discussing. Consider a simple example, one that everyone sees when learning mathematical induction. Let n be any natural number 1 or greater. Let P be the predicate defined by P(n) = "the sum 1 + 2 + ... + n equals n(n + 1)/2". It's a well-known fact that P(n) = True for all natural numbers greater than 0. To prove this by induction, we carry out these steps:

1) 1 = 1(2)/2, so P(1) = True. 2) Now assume P(k) = True for some natural number k ≥ 1, so: 1 + 2 + 3 + ... + k = k(k + 1)/2. Then: 1 + 2 + 3 + ... + k + (k + 1) = [algebra elided] = (k + 1)((k + 1) + 1)/2 so we have shown P(k) → P(k + 1) for all k ≥ 1.

Here's what we don't do at this point:

P(1) → P(2), so 1 + 2 = 2(3)/2 P(2) → P(3), so 1 + 2 + 3 = 3(4)/2 P(3) → P(4), so 1 + 2 + 3 + 4 = 4(5)/2 * * * (ellipses of endlessness)

We're already done after step 2, where we have shown P(k) → P(k + 1) for k ≥ 1. The Axiom of Induction "forces" this theorem to be true already, with no do-forever loop or infinite chain of implications. daveS

How does "endless succession makes a material difference"? Do you mean material in the sense of physical or material in the sense of significant in respect to pure mathematics? I'd very much like to know what you mean by the quoted phrase. Thanks. Aleta

DS, the issue is simple, we cannot actually go to a transfinite extent with anything that is based on or constrained by sequenced counting sets aka counting numbers. We can show endlessness, but we cannot actually go there; we point to it. As for primes, we can show they are without upper limit and are part of the endless nature of counting numbers. But we cannot attain to a prime that is endless -- infinite -- no more than we can succeed to endlessness in actually carried out +1 steps. Every prime we can reach is finite but we cannot reach all primes. Onward endlessness blocks that. Something like the pink/blue tapes example shows the endlessness, in case someone is disinclined to accept it. And on the chaining of ordinary mathematical induction, notice how the line of proof propagates, set up an initial case then also the chaining principle case k implies case k+1, thus to k+2 etc. The chaining is right there, but as it proceeds in +1 steps, we see the same issue that at any stage k we can go onwards endlessly in match with 0,1,2 etc. We may indeed point across the ellipsis of endlessness and impose a conclusion, but we can get into trouble if endless succession makes a material difference. KF kairosfocus

KF, I suppose it's not worth repeating the "do forever loops" discussion again. I really am confused about your position on the primes, however. I gather you believe the set of primes is infinite, just as N is. I could be wrong on that, however. Regarding whether any primes are infinite, do you agree with any of these statements?

1) All primes are finite. 2) Some primes are infinite. 3) Neither of the statements "all primes are finite" nor "some primes are infinite" is true. 4) We can't currently answer this question, but exactly one of 1) and 2) is true. 5) We can't currently answer this question, but exactly one of 1), 2), and 3) is true.

daveS

Aleta #1296

What in the world could kf be concerned about here? All this continual talk of consequences but not able to say what they are.

I suspect he thinks it's all part of his perceived war against Biblical truth and such. He tends to cast every disagreement in that light at some point. Don't even start with homosexuality or gay marriage. He just doesn't seem to get that we are just talking about the mathematics here. Nothing to do with philosophy or values or cultural standards. If you're against him, in anything, then you're the enemy. ellazimm

KF Over and over again some of us have been trying to answer your queries. We seem to have failed in a very fundamental sense. What I'd like to know is: at what point, when you have been told over and over again by more than one person who knows the subject that you are wrong do you finally accept an outside (of yourself) conclusion? Or don't you ever? Just curious. ellazimm

KF,

DS, the chaining is right there in the k to k+1 succession. KF

You prove P(k) -> P(k + 1), for all k ∈ N, in finitely many steps. daveS

fear far worse than mere paradox

What in the world could kf be concerned about here? All this continual talk of consequences but not able to say what they are. And yes, often kf's sentences are a mish-mash of idiosyncratic language and syntax that they only make sense, in a way, because he's been over the points so often. What, or what, pray tell, are the consequences, dire as they may be, of there being an infinite number of finite natural numbers? Does the whole edifice of math come crumbling down? Aleta

KF #1294

DS, the chaining is right there in the k to k+1 succession.

Why is 'chaining' a mathematical problem? How has this NOT been addressed by the work or Cantor or what has been presented to you on this thread over the last 1200+ responses? You keep objecting about a problem that does not exist. All the mathematical issues have been considered and dealt with. ellazimm

DS, the chaining is right there in the k to k+1 succession. KF kairosfocus

KF #1289

EZ, I would suggest that k = 0 +1 +1 . . . +1 k times over shows how we get to k in successive +1 steps, which may be converted into successive collections of counting sets or a looping process. I have not spoken gibberish. In that context I suggest that ordinary mathematical induction starts with a case 0 or sometimes the like base case then extends on a do forever chain case k => case k+1, which depends crucially on chaining. this has import for what we may legitimately conclude from such, given that no such successive chain can actually complete to completed endlessness.

You have spoken gibberish.

or sometimes the like base case then extends on a do forever chain case k => case k+1, which depends crucially on chaining.

That is gibberish. Why can't you talk in normal mathematical language?

this has import for what we may legitimately conclude from such, given that no such successive chain can actually complete to completed endlessness

That makes no sense at all. It isn't even a sentence. Just give it up. ellazimm

KF,

In that context I suggest that ordinary mathematical induction starts with a case 0 or sometimes the like base case then extends on a do forever chain case k => case k+1, which depends crucially on chaining.

This is the misunderstanding of induction that I referred to in my post #1240. The Axiom of Induction does not include any "do forever chains". daveS

KF #1289

please pause and ponder why I would see a paradox at minimum and fear far worse than mere paradox in asserting that one has proved that there is an INFINITE — so, endless — number of FINITE successive counting numbers at +1 steps from 0.

I can't think of a good reason why you should object to that.

Notice, where I have gone to to see why there is no foundational flaw, namely our inability to exhaust endlessness in finite stage steps and the implication of ordinary mathematical induction depending on a case 0 and a chaining implication case k => case k+1.

That doesn't even make sense let alone stand as a sound mathematical argument. In fact, I'm not sure it is even a sentence. You've got some issue that is clouding your judgment. You best work on clearing that. ellazimm

Aleta and daveS What do you think? Time to stop beating our heads against the wall? KF clearly has some issue which prevents him from accepting tried and accepted mathematics. I think now that there is nothing we can do to change his inclination. So . . . time to quit? ellazimm

Aleta & EZ, please pause and ponder why I would see a paradox at minimum and fear far worse than mere paradox in asserting that one has proved that there is an INFINITE -- so, endless -- number of FINITE successive counting numbers at +1 steps from 0. Notice, where I have gone to to see why there is no foundational flaw, namely our inability to exhaust endlessness in finite stage steps and the implication of ordinary mathematical induction depending on a case 0 and a chaining implication case k => case k+1. KF PS: EZ, I would suggest that k = 0 +1 +1 . . . +1 k times over shows how we get to k in successive +1 steps, which may be converted into successive collections of counting sets or a looping process. I have not spoken gibberish. In that context I suggest that ordinary mathematical induction starts with a case 0 or sometimes the like base case then extends on a do forever chain case k => case k+1, which depends crucially on chaining. This has import for what we may legitimately conclude from such, given that no such successive chain can actually complete to completed endlessness. At some point we point across an implicit ellipsis of endlessness, but this may become a material issue. kairosfocus

KF #1285

I am suggesting that we cannot attain to spanning the endlessness of succession of counting sets and that this can have a material impact on conclusions we may legitimately draw from e.g. ordinary mathematical induction.

You really don't get the basic maths.

As I have said for weeks, we cannot exhaust endlessness in finite stage steps. In particular, an assertion that has been repeatedly put as though it is a no brainer at minimum has in it a deep paradox and may be much worse than mere paradox: that there are infinitely many FINITE counting numbers at +1 stage succession from 0. Which runs into issues of the successor at k+1 being a copy of the list of counting sets to kth stage from 0.

What does your last sentence mean? 'At +1 stage succession from 0. Which runs into issues of the successor at k+1.' There are no issues. This has all been dealt with. Over 100 years ago. What is your real issue here? The existence of an infinite past? We're not your adversaries in that. We're just talking about the maths.

So if this were to proceed to endlessness, there would be endless, non finite members. Howbeit, it cannot actually proceed to endlessness, we can only attain to finite values and point on to further endless succession from any specific k (which immediately calls forth k+1 etc endlessly IN PRINCIPLE).

Seriously, you are repeating yourself to the point of madness AND you are still wrong.

This entails that we cannot specify an infinite prime — obviously — but also that we cannot exhaust the list of primes, the endlessness is material. Likewise, there can be no finite prime removed from 0 by infinitely many +1 actually completed steps

Again, that is pretty much gibberish. Just give it up. ellazimm

KF,

In particular, an assertion that has been repeatedly put as though it is a no brainer at minimum has in it a deep paradox and may be much worse than mere paradox: that there are infinitely many FINITE counting numbers at +1 stage succession from 0. Which runs into issues of the successor at k+1 being a copy of the list of counting sets to kth stage from 0. So if this were to proceed to endlessness, there would be endless, non finite members.

As I've said from day 1, practically, the notion that N is infinite yet has only finite members is not paradoxical to me (nor to William Lane Craig, it would seem). But what exactly are you saying about primes? Clearly the set of primes can be put into 1-1 correspondence with itself, right? So if N is infinite, shouldn't P also be infinite? Edit: Just read this:

This entails that we cannot specify an infinite prime — obviously — but also that we cannot exhaust the list of primes, the endlessness is material. Likewise, there can be no finite prime removed from 0 by infinitely many +1 actually completed steps.

Hmm. Are you leaving the door open to the existence of primes which are infinite? I honestly can't tell. daveS

Aleta #1282

Yes, EZ. There is no arguing with someone who rejects foundational aspects of math without being able to say why other than because of vague concerns and unstated consequences.

KF has some agenda driven issue that has nothing to do with math. We are not agreeing or disagreeing with him about that other issue. We are just discussing the mathematics. But it seems to be a 'with me or against me' issue with him. ellazimm

DS, I am suggesting that we cannot attain to spanning the endlessness of succession of counting sets and that this can have a material impact on conclusions we may legitimately draw from e.g. ordinary mathematical induction. As I have said for weeks, we cannot exhaust endlessness in finite stage steps. In particular, an assertion that has been repeatedly put as though it is a no brainer at minimum has in it a deep paradox and may be much worse than mere paradox: that there are infinitely many FINITE counting numbers at +1 stage succession from 0. Which runs into issues of the successor at k+1 being a copy of the list of counting sets to kth stage from 0. So if this were to proceed to endlessness, there would be endless, non finite members. Howbeit, it cannot actually proceed to endlessness, we can only attain to finite values and point on to further endless succession from any specific k (which immediately calls forth k+1 etc endlessly IN PRINCIPLE). This entails that we cannot specify an infinite prime -- obviously -- but also that we cannot exhaust the list of primes, the endlessness is material. Likewise, there can be no finite prime removed from 0 by infinitely many +1 actually completed steps. KF kairosfocus

KF #1279

I trust the above shows just why I asked for something that is impossible, to draw attention to something that keeps on being missed in the discussion and confident assertion that there is an infinite set of finite successive counting sets in +1 steps from 0. Something that at minimum is deeply paradoxical, and may well be much worse than mere paradox

You think your point keeps on being missed but I say that is not true. I think you keep ignoring the explanations that have been offered to you and the vast amount of mathematics that has been done in the last 100+ years which addresses your 'concerns'. Seriously, I don't thing you're keeping up with the research. And you seem to have an agenda. ellazimm

Kf #1277

You cannot write down a prime that is finite and infinitely many +1 steps removed from 0, which illustrates a key point from the above, one that shows what happens when endlessness of succession in +1 or similar steps from 0 is material to a conclusion.

You are just making stuff up now, you do realise that. And you keep arguing against a stance that no one is taking. 'Is material to a conclusion'?

Yes we can show there is no specific largest prime leading to endlessness of this progressively sparser subset of the counting numbers but that is not the whole story. There is a difference between numbers we can actually reach by direct +1 succession from 0 or specifically represent in notations based on such and spanning or traversing the endless set of successive counting sets in finite stage steps.

I tell you what, I'll just stick with normal established and proven mathematics.

Any arbitrarily large specific number k we can write down will be finite and there will be an onward succession k, k+1 etc that can be put in 1:1 match with 0,1,2 . . . where this can then be repeated for a value we reach beyond k, and so on, showing that endless continuation cannot be exhausted as from any finite k, there is yet endless continuation onward

Great, so you can't count up to infinity. I think I said that.

The set of numbers reached by +1 increments IN PRINCIPLE from 0 is endless but we can only stop at a finite stage and point onward. This has specific implications for the conclusions we may properly infer from an ordinary mathematical induction, which depends on exactly such chaining, especially where endless succession may affect the force of the conclusion drawn. Of course, one may resort to axiomatic imposition of conclusions that point across the endlessness, but then the axiom becomes a forcing act.

That just doesn't make any sense at all. And doesn't address the issues we have been discussing. KF you are clearly outside of your comfort zone. Why not just admit it and get on with other things. Take the honourable way out. ellazimm

This has specific implications for the conclusions.

And what are those conclusions, kf?

Of course, one may resort to axiomatic imposition of conclusions that point across the endlessness, but then the axiom becomes a forcing act. KF

Yes, axioms have a way of doing that. It is axioms that lead to the creation of aleph null and w: do you object to those because they were forced upon you by axioms. Arrrgggghhhh. Yes, EZ. There is no arguing with someone who rejects foundational aspects of math without being able to say why other than because of vague concerns and unstated consequences. Aleta

KF, I think I'm a bit lost regarding your position.

you cannot write down a prime that is finite and infinitely many +1 steps removed from 0, which illustrates a key point from the above, one that shows what happens when endlessness of succession in +1 or similar steps from 0 is material to a conclusion. Yes we can show there is no specific largest prime leading to endlessness of this progressively sparser subset of the counting numbers but that is not the whole story.

Are you suggesting that there are primes somewhere in the "far zone" that are not finite? Or perhaps this: while you don't claim that infinite prime numbers exist, we cannot legitimately say "all primes are finite"? daveS

Aleta, it looks like I need to include you in what I just said. KF kairosfocus

EZ, I trust the above shows just why I asked for something that is impossible, to draw attention to something that keeps on being missed in the discussion and confident assertion that there is an infinite set of finite successive counting sets in +1 steps from 0. Something that at minimum is deeply paradoxical, and may well be much worse than mere paradox. KF kairosfocus

I agree. I got reinvolved in part because I'm interested in the nature of mathematics, but that subject never took off. Then I thought maybe the prime proof would make a difference. kf's remark at 1273 is really off the mark. Maybe we can find some new mathematical topic to discuss! :-) Aleta

Aleta (and attn EZ): you cannot write down a prime that is finite and infinitely many +1 steps removed from 0, which illustrates a key point from the above, one that shows what happens when endlessness of succession in +1 or similar steps from 0 is material to a conclusion. Yes we can show there is no specific largest prime leading to endlessness of this progressively sparser subset of the counting numbers but that is not the whole story. There is a difference between numbers we can actually reach by direct +1 succession from 0 or specifically represent in notations based on such and spanning or traversing the endless set of successive counting sets in finite stage steps. Any arbitrarily large specific number k we can write down will be finite and there will be an onward succession k, k+1 etc -- where k+1 already bounds k and shows it definitively finite -- that can be put in 1:1 match with 0,1,2 . . . where this can then be repeated for a value we reach beyond k, and so on, showing that endless continuation cannot be exhausted as from any finite k, there is yet endless continuation onward. The set of numbers reached by +1 increments IN PRINCIPLE from 0 is endless but we can only stop at a finite stage and point onward. This has specific implications for the conclusions we may properly infer from an ordinary mathematical induction, which depends on exactly such chaining, especially where endless succession may affect the force of the conclusion drawn. Of course, one may resort to axiomatic imposition of conclusions that point across the endlessness, but then the axiom becomes a forcing act. KF kairosfocus

Aleta I think it's time to stop arguing with KF and just acknowledge that he doesn't get it. No shame in that. But it's just the truth. ellazimm

KF

Aleta, the set cannot be spanned in succession of +1 steps or the like.

So? That is known and dealt with.

There is therefore a distinction between what we can reach and what is implied by traversing endlessness

What is endlessness in a mathematical sense? If it's infinity then that has been dealt with.

Which clearly means unlimited succession within the set that collects counting numbers that cannot be actually completed.

So?

The far zone being the zone of that endlessness beyond any relevant arbitrarily large finite.

Please, please, please learn to use standard mathematical terms and definitions. If you want to make a mathematical argument.

And were there a counting set that succeeds to endlessness, it would not be finite.

Already answered many times.

The solution is, we may succeed from 0 to an arbitrarily large but finite value, but in so doing any such value k faces onward endlessness that cannot be completed.

What does that mean mathematically? You've been asked over and over again to deal with this and you haven't done so.

We can only point across the endlessness and draw conclusions in that light.

You haven't brought up anything that hasn't already been dealt with. I cannot fathom what you are still objecting about.

leta, please write down for us a prime that is finite and an infinite number of +1 steps removed from 0.

OMG, you really have not grasped the basic concepts at all. After all these posts and you still haven't got the basic idea or the arguments we have been offering. I'm sorry KF but it's pretty clear now that you are just not up to the situation. There's is no shame in that but you shouldn't hold yourself up as someone who 'knows' when you clearly don't. Just let it go. ellazimm

That misses the point, kf. All natural numbers are some number of +1 steps from zero: All natural numbers are finite. The proof I showed does does not claim that some prime is infinitely far from 0 (infinitely far from 0 is a meaningless phrase) - it shows that there are an infinite number of primes. Those are two different things. Furthermore, the proof doesn't depend on knowing what the exact primes are. It just proves there are an infinite number of them. Surely you understand that. It seems like the statements that you made in 1273 are either irrelevant to the proof (knowing what the primes are) or incorrect about what the proof shows, for it shows that there are an infinite number of primes. I find it telling that you use the phrase "infinite number of +1 steps removed from 0". No number is an infinite number of steps from zero. The only infinite number relevant to this discussion is w, and it doesn't make sense at all to say the distance between a natural number N and zero is w. w doesn't measure a distance. Aleta

Aleta, please write down for us a prime that is finite and an infinite number of +1 steps removed from 0. KF kairosfocus

You keep saying that, kf, but you don't say what conclusions can be drawn. What about the prime number proof? It does not span anything in +1 steps. How do you account for that? It demonstrates that there is an infinite subset of the natural numbers (the primes) that are all finite numbers - no traversing needed. How do you explain that? Aleta

Aleta, the set cannot be spanned in succession of +1 steps or the like. There is therefore a distinction between what we can reach and what is implied by traversing endlessness. Which clearly means unlimited succession within the set that collects counting numbers that cannot be actually completed. The far zone being the zone of that endlessness beyond any relevant arbitrarily large finite. And were there a counting set that succeeds to endlessness, it would not be finite. The solution is, we may succeed from 0 to an arbitrarily large but finite value, but in so doing any such value k faces onward endlessness that cannot be completed. We can only point across the endlessness and draw conclusions in that light. KF kairosfocus

ellazimm,

I guess we’re just a bit odd eh? :-) Forget about concerns, jump in and play!!

Yes, maybe so. For me, mathematics is almost entirely a recreational activity. I'm not going to use it to solve any significant real-world problems, so I probably have a different perspective than many others. daveS

daveS #1268

One of my favorite examples of this type is Cantor’s Staircase.

More loveliness!! I remember when I took a measure theory class, absolutely stunning stuff. I know how it's always said that math is just applied logic but it always seemed to me that logic classes were pretty dull and boring compared to my math classes. I never found that logic went as far and got as weird and wonderful as math did. I used to have so much fun with stoned or drunk friends telling them about Achilles and the tortoise and watching them trying to wrap their heads around it. https://en.wikipedia.org/wiki/Zeno%27s_paradoxes (I bet Mapou would love the arrow paradox.) I miss that fun of seeing that stuff for the first time. It's hard for me to understand why everyone doesn't just fall in love with the wonderland of this kind of mathematics. Why parts seem hard to swallow. I guess we're just a bit odd eh? :-) Forget about concerns, jump in and play!! ellazimm

Aleta and ellazimm (and everyone else interested), One of my favorite examples of this type is Cantor's Staircase. Here's the animation from that page showing the construction of its graph. It's constructed much like the Cantor set. Instead of deleting the "middle thirds" of intervals, you lift them up a certain amount. You start by raising the interval [1/3, 2/3] from the x-axis to the level y = 1/2. Then continue. (Edit: In contrast with the Cantor set, we work with closed rather than open intervals). The function thus defined is continuous and differentiable except on a set of measure 0, which is a little strange, but not too hard to accept. Here's what I find surprising: The graph consists of pieces of the interval [0, 1] (which has length 1, obviously) "pushed upward" various distances. However, the arclength of the graph turns out to be exactly 2. daveS

That's exactly the thought I've been having: the limit as n -> infinity is absolutely central to modern mathematics. Aleta

Aleta! #1265

And how about the Sierpinski triangle, with an area of zero and an infinite perimeter.

Fabulous! I used that as an example in the sequences and series section once. The cube version is fun too!!. The whole idea of taking the limit to infinity runs so much through 100-level calculus I find it completely mundane! It's hard sometimes to see what could be misunderstood. Without that we'd have to throw out calculus and go back to mid-17th century mathematics. ellazimm

And how about the Sierpinski triangle, with an area of zero and an infinite perimeter. Aleta

Here is the Wikipedia page on Gabriel's Horn, a mathematical object which has a finite volume but an infinite surface area.. It was first studied in the 17th century. https://en.wikipedia.org/wiki/Gabriel%27s_Horn Like I said, lovely stuff. I first saw this as a freshman or sophomore at University. It's a very standard example in 100 level calculus courses. It was stuff like that which really got me thinking I'd like to study mathematics; I'd planned on being an engineer or doctor before that. Notice too how part way through the article it is proved that it's impossible for a 3D object to have a finite surface area and an infinite volume. Notice too how this was part of a dispute involving people such as Thomas Hobbes, John Wallis and Galileo. Like I said, all part of standard, non-controversial, even basic level mathematics. And we're a few centuries past that point now. ellazimm

SA and KF Here's one of my favourite examples to use while teaching solids of rotation. Take the function 1/x from x = 1 on (out to infinity) and rotate it around the x-axis. You get an infinitely long horn-shaped thing. By using calculus you can show that its volume is finite but its surface area is infinite. Lovely stuff. Hard to deal with in Philosophy or logic though eh? Math has great explanatory power, especially dealing with mathematical infinities. It's beautiful stuff. And, again, this is non-controversial, standard undergraduate level mathematics. ellazimm

KF #1260

That would imply ending the endless. It would also include a transfinite member of the set of counting sets. Which of course would not be a finite value.

No, that is not the case. You cannot count to the smallest infinite cardinal number but this is not a problem.

This instantly shows that there can be no infinite set of successively larger finites.

Also, incorrect. If you were correct then there would be a largest finite number which there clearly is not. You don't 'traverse' or 'span the endlessness'. Counting up from any finite integer never gets you to the end and it never gets you to the transfinite numbers.

We then extend our number concept to include w as representing succession to endlessness.

Sigh. Why not use standard mathematical vocabulary. I take it you're thinking that w is the cardinality of the positive integers, generally known as aleph-0 or aleph-nought or aleph-null. That's the smallest infinite cardinal number. Which is followed by aleph-1, aleph-2, etc. All of the cardinal numbers (i.e. 1, 2, 3 . . . and aleph-0, aleph-1, etc) form a well-ordered set which means if you give me any two of them I can tell you which one is larger. But it doesn't mean you can 'traverse' them all by counting. That is not correct. Yet you keep addressing that issue over and over and over again. Your 'concern' is not a concern. It's been addressed over 100 years ago. And the mathematics dealing with that is now mainstream and non-controversial. And it has nothing to do with the existence (or not) of an infinite past or future. That's a physics question (in my opinion). ellazimm

kf, yes you have used symbols to express your concern, but you have not explained mathematically what the concern is. You've never defined what the "far zone" is, nor what its "members" are. Without a mathematical formulation of the concern, your concerns are just informal and vague difficulties with accepting the mathematical concept of infinity, There is nothing in the definition of natural numbers that says that the stepwise process of adding 1 to the previous number ever "ends the endless". However, nevertheless, modern set theory postulates that the infinite set, as a whole, exists. And, as you point out, the extension of the number system to include w formalizes the existence of the infinite set - not as something which must be endlessly reaching towards completion but as something which is complete. I know this creates a sense of mystery in our minds, because we can't intuitively grasp the infinite, but that mystery doesn't override the fact that the math is solid. That is one of the beauties of math - that it can lead us to solid conclusions that are surprising and even puzzling. So let me repeat this: when you wrote,

Where w as limit ordinal has no specific, definable finite predecessor. All such definable finite counting numbers are behind a wall of endlessness so w is a limit ordinal. That seems to me to resolve concerns.

What concerns does accepting w resolve for you? It seems to me that you might be agreeing here with what I just wrote: that you realize the intuitive, subjective nature of your concerns, but that you also accept that mathematically they are resolved by the system of transfinite numbers and modern set theory. Is this what is resolved? Aleta

EZ, You exemplify my concern by attempted reversal of the order. Aleta: I have sufficiently shown -- including in symbols -- the basis of my concern, which can be boiled down to the at minimum paradox of an infinite succession of finite values from 0 in +1 increments where each successor is in effect the collection of counting sets so far. Were this to proceed to actual infinite extent [a collection of successive counting sets of infinite scope], this would include 0 +1 +1 +1 . . . to infinite extent, which cannot be finite, or would be a set that collects {0,1,2 . . . } endlessly. That would imply ending the endless. It would also include a transfinite member of the set of counting sets. Which of course would not be a finite value. Further, as the two tapes case shows, at any finite value k we are in effect only at the beginning of endlessness, we cannot successively by finite stage steps traverse the endless. This instantly shows that there can be no infinite set of successively larger finites. For, every successive finite is a fresh beginning to the whole process, it cannot span the endlessness. That is, k --> k+1, return this to the k register, repeat the assignment of a successor, do forever as was explicitly shown in 217 above. Finite, and forever facing the onward succession k, k+1, k+2 . . . that may be matched 1:1 with 0,1,2 . . . Instead, we may only represent -- notations such as scientific notation etc depend on finites and so face the same limits -- or reach by succession from 0 as specific counting numbers, finite values, and by ellipsis may see the process continues end-less-ly in principle. We then extend our number concept to include w as representing succession to endlessness. kairosfocus

SA #1253

The question is, can an infinite past actually exist? It can exist in poetry or math (which are about the same in this case). But could it exist in reality, in the universe?

I have no opinion on that matter. I don't see why not but I have no argument yeah or nay. I'm only interested in the mathematics. And I think that is independent of the universe as we experience it. ellazimm

kairosfocus: First, let me thank you for engaging in a civil discussion that has now gone on longer than anyone anticipated. hear hear Mung

ellazimm

Where does freedom exist? Where does justice exist? Where do you exist?

Some attempt to answer these through a materialist understanding. But the concepts of rational choice, being, virtues and moral value are not-reducible to matter and also non-reducible to mathematics. They're metaphysical questions the come prior to mathematics and which also transcend physical matter. From metaphysics, it's easy to recognize scales of value, being, perfections -- and those are the basic proofs for the existence of God, thus theology. Mathematics and logical systems support and contribute to our understanding but they're not the foundation. For example, math assumes that truth is better than falsehood. Or even beyond that, math assumes that truth is different in significant ways that falsehood. But it's actually philosophy that determines that. Humans are oriented towards truth - we assign a positive value to truth. Logic is based on that - it's dependent on that philosophical principle. It didn't create or invent it. We choose truth as a value over false. Math couldn't exist without that. Although it's certainly possible in principle to create a system where truth and falsehood have equal value (Politics, communism, advertising, manipulation ... even some branches of religious belief assert that falsehood has higher value than truth in some situations). That's one of the beauties of math. It segments results into true or false. There is a lot less ambiguity and less tolerance for deceptive answers. It offers real proofs in many cases. But in the case of infinite entities, mathematics lacks explanatory power and can give illogical conclusions (like an infinite past being actually possible). Silver Asiatic

Aleta: I really don’t know how seriously to take this question, because I can’t tell how serious Mung is in general, but I’ll give it a try. Thank you. :) I'm serious with a/an [un]healthy dose of levity tossed in to continually remind us to not get too serious. We're human, after all. Mung

KF,

PS: And it is quite clear that people like DS and Russell etc are talking about physically instantiated material and temporal infinities, arguing that such are not illogical and must be taken as serious possibilities.

Yes, I have talked about actual temporal infinities in the physical universe. My main point is that I don't believe you can show they are impossible using mathematics/logic/philosophy only.

That is the context in which issues of causal succession, stepwise finite stage traversal of the transfinite or endless and whether an actual infinity can be actualised quantitatively not just as a symbolic representation, abstract entity or useful fiction arise. The logic is telling us that endlessness has properties that make such claims highly dubious.

Well, I think WLC and others in this thread make a stronger claim, namely that an infinite past is logically impossible.

It seems we may readily see [quasi-]physical entities that are very large but not actually transfinite. For reasons connected to why we cannot build a square circle.

I don't think the problems with infinite ladders etc. are as severe as those with a square circle. The idea of a square circle is clearly contradictory, so such absolutely cannot exist. How would we know for certain that the universe does not contain an infinitely long ladder somewhere? At some point we have to rely on the empirical science to draw that conclusion, but of course all conclusions of empirical science are provisional. daveS

kf, you repeat a key "concern":

It may also toss out unexpected consequences, and one of these from what I have seen is that it may not be safe to extrapolate from a first case and a stepwise successor implication to properties of far zone members that would be influenced by endlessness. What ordinary mathematical induction establishes is that the members we can reach or represent are inherently finite cases and will hold the demonstrated properties. However this does not warrant us in drawing conclusions on things that pivot on endlessness. It is in this context that I have been concerned by conclusions drawn about an infinite actual number of FINITE natural numbers, succeeding one another in +1 increments from 0. In the far zone, there lies endlessness which cannot be plumbed or exhausted in stepwise succession.

But as I pointed out in my post about insights, you are completely unable to formalize your insights in a mathematical way that would allow others to evaluate them. What "unexpected consequences"? What is "not safe" about extrapolating "from a first case and a stepwise successor implication to properties of far zone members that would be influenced by endlessness." What is the world is the "far zone" and what "members" does it contain? You've never given any mathematical explanation of what any of these things might mean. However, you also say,

Where w as limit ordinal has no specific, definable finite predecessor. All such definable finite counting numbers are behind a wall of endlessness so w is a limit ordinal. That seems to me to resolve concerns.

Does it resolve your concerns that you mention in the first paragraph I quoted? Does the existence of w, which accepts and formalizes the infinite size of the set of natural numbers, resolve the problem you see with step-by-step accessibility by accepting the existence of the set as a whole. That is, are you saying that at this point, despite the strangeness and concerns you have, the issues are resolved mathematically by the acceptance of the set as a whole, as represented by it being defined to have a transfinite size? Aleta

ellazimm

You don’t have to write a number down to use it or show it exists.

A number is different than a formula that generates a hypothetical number. For something to exist is different than for something "to be hypothesized to exist". Mathematics can be correct but give false explanations about reality. Mathematics says that 10 hippos on my roof plus one is correctly 11 hippos on the roof. Math has no problem with that. Physics does though. Ten hippos cannot be on the roof. Nor can ten unicorns, although math has no problem with them either. Math is just the symbols of a logical language - it is independent of the physics of what actually can happen in reality.

I may be the first person to write down the number 3,456,777,112,890,543,023,111,467,902,222.45678901111111 but that doesn’t mean it didn’t ‘exist’ in principle before that.

Notice - you say "exist in principle". That is different than actually existing. The question is, can an infinite past actually exist? It can exist in poetry or math (which are about the same in this case). But could it exist in reality, in the universe? The concepts of "today" and "yesterday" are measures of reality. We can assign mathematics to them, but today exists outside of mathematics. That is, mathematics did not create or invent "today" or the reality we experience. Mathematics does not speed or slow the passage of time, even though it can measure it in different ways. Mathematics will not make your life one day or one minute longer or shorter than whatever it will be when you die. It's the same with the reality of the universe. An infinite past would require infinite time to reach today, and any string of time that has been extending infinitely cannot have a 'new future'. Any possible future had already been reached. So, an infinite past could not have existed, for reasons given. Even in principle, how do you add another day to the beginning of an infinite past? Over an infinite amount of time, anything that was possible already necessarily occured (in the definition of possible). If it was possible for the universe not to exist, then it would have already happened, because there already has been an infinite number of opportunities to realize that possibility. A new potential event cannot happen "all of a sudden" after an infinite amount of time. If it could have ever happened, in any possible way, at any possible time - it would have necessarily already happened. If it was one in a million chances - already an infinite million chances have occurred. It necessarily would have happened. That's how we calculate probabilities. If something would not have happened after an infinite number of chances, that's the definition of "not possible". After an infinite number of chances, tomorrow did not occur. Therefore, by definition, tomorrow is not possible. If tomorrow occurs, then there was not an infinite past - in reality, not in the imaginary world of mathematics. Silver Asiatic

KF #1250

I am always concerned when there is a divorcing of a province of learning from the parent discipline, philosophy. In the case of Mathematics, it in the end is the logical study of structure and quantity. Where, before we get to systems, logic is the study of good reasoning and is a main branch of philosophy.

I'm inclined to think it's the other way around: I'm more likely to assign mathematics as the parent topic with formal logic and philosophy growing out of it. But that is just my own personal, uninformed take on it. Which I can't support so I won't. I don't find the discussion all that interesting. I'm just interested in the mathematics. And whether or not there are an infinite number of primes. And a lot of other questions. Like the Goldbach conjecture. By the way, how do your rectify your philosophy with Euler's formula (e^(i x pi) = -1) which uses an imaginary number, i = sqrt(-1)? I know you find Euler's formula intriguing but how is it reflected in philosophy or logic? ellazimm

SA #1249

As I said, the universe may not be big enough for that number. The bigger the number the more resources it requires to write it down (not to mention energy, time and mental capacity resources).

You don't have to write a number down to use it or show it exists. I may be the first person to write down the number 3,456,777,112,890,543,023,111,467,902,222.45678901111111 but that doesn't mean it didn't 'exist' in principle before that. There is no largest number. There just isn't. If you think you can conceive of one then I'll just add one to it. Or add it to itself. Or square it.

If the universe is finite — then it cannot express an infinite size of numbers. So, the number set would be finite by necessity. It would stop at a certain size number and nothing further could be expressed.

Do you think there are an infinite number of prime numbers? There's a famous proof showing that there are, if you think that is wrong then where is the mistake in the proof? Do you think that sqrt(2) has a finite decimal expansion? The Greeks proved that there is no way to represent the sqrt(2) as the ratio of two integers (which you could do if it had a finite decimal expansion). Where is the mistake in their proof?

Since the expression and comprehension of a number is not constrained to the physical attributes of the brain, an immaterial soul can express an infinitely large size of numbers (to itself, at least). This is good evidence against materialism.

I don't think that follows. Just because you can (or cannot) conceive of something says nothing about the physical world.

However, if you want to think that the expression (or comprehension) of numbers is tied to the activity of neurons in the brain — then we don’t know what the largest number that can be comprehended by a human being is.

Good thing there isn't one then eh?

In any case, where do numbers exist if they don’t take any space in the universe?

Where does freedom exist? Where does justice exist? Where do you exist? Where does 1 mile exist? 1, 2, pi, sqrt(2), 3+4i are not 'things'. (Note, if you actually tried to measure 1 mile on the ground you'd get a different result depending on what length of measuring stick you used. Think about that.) Digits were invented to make it easier to compare the size of sets. It was easier than always putting the sets into 1-to-1 correspondence to see which was bigger. A kind of shorthand. The rest is mucking about or trying to solve some practical problems using the representations of numbers/quantities as a short-hand. Remember we say 2x2 is 2 squared because the Greeks thought of 2x2 as an area of a square 2 units on a side. Later we decided that 2x2 was also just another number. The really amazing thing turned out to be that some very weird and abstract areas of mathematics turned out to have practical applications after they were developed. Like topology. Or number theory. Or non-Euclidean geometry. Or, my favourite example, imaginary numbers. That is just the weirdest thing and I didn't believe it until I took a complex analysis course. It was a real eye opener. As was the class where we studied fractional dimensions using stuff like the Mandelbrot set. Deeply strange and hard to get your head around. Anyway, math uses concepts like infinity all the time. Even sound engineering procedures like Fourier Analysis have it buried deep inside. It is true that some people have tried to construct a whole system of mathematics with a smallest number but it doesn't have the beauty or grandeur of the 'real' thing. (Disclaimer: there used to be anyway a big discussion amongst mathematicians about where the numbers come from. I clearly am taking a particular side in that debate. If you disagree or you want to explore the other arguments be my guest. It's not a pretty sight.) ellazimm

EZ & Aleta: First, let me thank you for engaging in a civil discussion that has now gone on longer than anyone anticipated. I do, however, have some concerns. I am always concerned when there is a divorcing of a province of learning from the parent discipline, philosophy. In the case of Mathematics, it in the end is the logical study of structure and quantity. Where, before we get to systems, logic is the study of good reasoning and is a main branch of philosophy. Not theology, not physics, not personal feelings and idiosyncrasies. Especially in a time where there are indoctrinations and polarisations at work that warp ability to think straight when just even words such as just listed are introduced. Now, it seems that endlessness is being regarded as suspect, imprecise, undefined. End-less, without end or bound, going beyond the limits. Something that appears when one draws up an axis on a graph and puts an arrow head, and maybe plots a parabola increasing without bound or a hyperbola approaching the axis more and more but never reaching it at any finite level. Then, we see much the same in sequences, series and integration ranges. Pop over into complex frequency domain analysis and we see poles. So, going on without limit beyond any arbitrarily large but bounded value is inextricably entangled in a lot of mathematics and especially where it intersects with real world cases. Which are subject to the logic of structure and quantity. Which, is not quite the same as a "consensus" of the currently dominant schools of thought. Especially in a post Godel world in which no axiomatic system for a rich enough domain is complete and coherent and there is no constructive process for synthesising a known coherent axiomatic framework. In short, mathematics is an open ended, first plausibles -- axioms or whatever -- driven endeavour in which one provisionally but confidently trusts tested and reliable findings. (And yes, the often despised f-word, faith, is relevant.) Which brings the significance of test cases of various kinds to the fore. Which, let us not forget, is the immediate context of the current remarks. In this context, the pink vs blue punched tapes example draws out some significant aspects of endlessness, in particular highlighting why no finite stage stepwise cumulative process can traverse -- thus, end -- an endless succession or set. The three dot ellipsis of endlessness is highly significant. {} --> 0 {0} --> 1 {0,1} --> 2 . . . or, {0,1,2 . . . } shows how this is embedded in our concept of natural, counting numbers, and is foundational. Succession in +1 steps continues without limit and any successor is a valid member. At the same time, as k, k+1, k+2 etc can be put in 1:1 correspondence endlessly with 0,1,2 . . . this highlights that no finite stage process can actually traverse the full range. This leads to establishing the potentially infinite and pointing across the ellipsis. We use this to define infinite sets, and so endlessness is embedded in the definition as a key property leading to the ability to match a proper subset with the full set. So, the property of end-less-ness is important and to be respected. It may also toss out unexpected consequences, and one of these from what I have seen is that it may not be safe to extrapolate from a first case and a stepwise successor implication to properties of far zone members that would be influenced by endlessness. What ordinary mathematical induction establishes is that the members we can reach or represent are inherently finite cases and will hold the demonstrated properties. However this does not warrant us in drawing conclusions on things that pivot on endlessness. It is in this context that I have been concerned by conclusions drawn about an infinite actual number of FINITE natural numbers, succeeding one another in +1 increments from 0. In the far zone, there lies endlessness which cannot be plumbed or exhausted in stepwise succession. I fully agree that we cannot traverse the ellipsis and so are warranted in recognising a new domain of quantities starting with w. But w embeds that endlessness, it is not invented out of whole cloth when we say: {0,1,2 . . . } --> w Where w as limit ordinal has no specific, definable finite predecessor. All such definable finite counting numbers are behind a wall of endlessness so w is a limit ordinal. That seems to me to resolve concerns. And of course, there are onward issues on understanding the continuum [0,1] as a closed interval without gaps and the link from infinitesimals to transfinites and transfinite hyperreals. The surreals seem to offer the best coherent picture of the jungle. Where of course the study of quantity and its structures is pivotal to anything that uses quantities. KF PS: And it is quite clear that people like DS and Russell etc are talking about physically instantiated material and temporal infinities, arguing that such are not illogical and must be taken as serious possibilities. That is the context in which issues of causal succession, stepwise finite stage traversal of the transfinite or endless and whether an actual infinity can be actualised quantitatively not just as a symbolic representation, abstract entity or useful fiction arise. The logic is telling us that endlessness has properties that make such claims highly dubious. Hilbert's hotel, the issue of ending an endless succession and the problem of building and labelling an infinite ladder then climbing down to the ground on it all speak to that. It seems we may readily see [quasi-]physical entities that are very large but not actually transfinite. For reasons connected to why we cannot build a square circle. kairosfocus

Aleta

Mathematical infinity is actual infinity.

No, it's not. Mathematics is a symbolic language. The point at question is an "infinite past". Either that exists or doesn't - mathematics does not create it.

Infinity is a mathematical concept. All of us here have agreed, I think, that there is no physical instantiation of infinity in our universe.

No, daveS has been arguing that there could be an infinite past, in reality - not just in mathematical conjectures.

ellazimm: If there are a finite number of positive integers and if you wrote them all down you could always take the largest one and add 1 to it and get one that was not on your list.

That would be one way to experimentally test your theory that there is an infinite number of positive integers. Write down the largest positive integer. Then add one. Then display that number. Not the formula (where x is the biggest number ...), the actual number. As I said, the universe may not be big enough for that number. The bigger the number the more resources it requires to write it down (not to mention energy, time and mental capacity resources). If the universe is finite -- then it cannot express an infinite size of numbers. So, the number set would be finite by necessity. It would stop at a certain size number and nothing further could be expressed.

Aleta Numbers don’t take up space in the universe.

I might agree with you, since I believe in immaterial entities like the human soul. Since the expression and comprehension of a number is not constrained to the physical attributes of the brain, an immaterial soul can express an infinitely large size of numbers (to itself, at least). This is good evidence against materialism. However, if you want to think that the expression (or comprehension) of numbers is tied to the activity of neurons in the brain -- then we don't know what the largest number that can be comprehended by a human being is. In any case, where do numbers exist if they don't take any space in the universe? Silver Asiatic

Mung

I’m not sure that the statement that there is an infinite number of ‘x’ is even coherent. Shouldn’t we say that ‘x’ is without number, that ‘x’ cannot be numbered?

That's right. A number is distinct from "a formula that generates a hypothetical number". Even calling an infinite entity a "set" reduces an infinte to a finite construct. ellazimm

Endlessness may be a problem for theology or physics or you personally but it’s not a problem for mathematics.

That's why mathematics cannot accurately model reality. Infinite entities are not a problem for people who have active imaginations - and there is imaginary mathematics as well. To generate a number it has to be expressed somehow. That's not the formula for the number using variables but the number itself. Silver Asiatic

KF I would like to reiterate that 'endlessness' is not a well defined mathematical concept. If by endlessness you just mean an aspect of infinity then remember that, mathematically, infinity is not a controversial or problematic issue. For more than 100 years mathematicians have had solid, coherent ways of working with infinities and the concept was introduced well before Cantor. You can read about some of the history of it all in Dr Belinski's book A Tour of the Calculus or any history of math text. (By the way, Dr Berlinski considers Cantor's insight to be an example of 'mathematical genius'.) Endlessness may be a problem for theology or physics or you personally but it's not a problem for mathematics. And no mathematician is trying to say a thing about theology or anything else except the mathematics. Non-controversial, established, well understood mathematics. How anyone chooses to attempt to apply it is their business and I won't offer any opinions on that. I have no agenda whatsoever except to help explain the math. In that light you should easily be able to answer Aleta's two questions from a strictly mathematical point of view with a simple true or false. ellazimm

Mung writes,

How do you get from “therefore there is no largest integer” to “therefore there are an infinite number of integers.” I’m not sure that the statement that there is an infinite number of ‘x’ is even coherent. Shouldn’t we say that ‘x’ is without number, that ‘x’ cannot be numbered?"

I really don't know how seriously to take this question, because I can't tell how serious Mung is in general, but I'll give it a try. If Mung thinks that "an infinite number" is perhaps not coherent (his second sentence), I don't think there is any way I could answer his first question. "An infinite number" is a well defined mathematical concept, and kf has posted a definition a number of times.

Mathematics a. Existing beyond or being greater than any arbitrarily large value. b. Unlimited in spatial extent: a line of infinite length. c. Of or relating to a set capable of being put into one-to-one correspondence with a proper subset of itself.

The integers are an infinite set in sense a. above, and the proof I offered is essentially a definition of infinite. More formally any set that can be counted (put in a 1:1 correspondence) with a terminated subset of the natural numbers is finite. Any set that can, however, be put in a 1:1 correspondence with a proper subset of itself is infinite. (Definition c above) Cantor formalized this definition, and developed a great deal of further mathematics that starts with that definition. He also created a new kind of number, the transfinites, and named the first transfinite, aleph null, to represent the number of natural numbers. So, the phrase "an infinite number of somethings (where the somethings are discrete, like ladder rungs or steps or prime numbers)" is somewhat informal. It really means that the set of all the somethings is infinite to the same degree that the natural numbers are infinite. So if we know there is no largest number, then the numbers must be beyond any arbitrarily large value, and thus are infinite per a. above. Aleta

I agree with Ellazimm at 1243, but want to add my 2 cents. You write,

Theorems are proved from start points and already proved theorems, but the point of the process is what is in the axioms may well be surprising and hard to discover. Key cases, models, test examples etc are all also legitimate devices of insight.

Yes, studying examples and concrete cases can lead to insights. But insights can be wrong, so unless one can then formalize those insights back into mathematical language, they remain unverified and possibly wrong. A case in point: as related above someplace, I examined the expected value of choosing an upset out of four games in the NCAA tournament when q = probability of an upset was 30%. My insight, based on the result as well as experience with other types of situations, was that there would be a "tipping point" for a larger q for which it would be better to pick an upset. Then I worked out all the probabilities algebraically for the expected value as a function of q. And guess what! My insight was wrong. So kf, despite your concerns, insights, sense of strangeness, or whatever, you have never even attempted to formalize your concern in mathematical language. The tape example may give you reason to believe there is something at issue here, but it also may be misleading you. Unless you can formalize your ideas mathematically, all you have are unproven ideas: you really haven't supported, much less validated, your concerns. Aleta

Aleta:

Therefore there is no largest integer Therefore there are an infinite number of integers.

How do you get from "therefore there is no largest integer" to "therefore there are an infinite number of integers." I'm not sure that the statement that there is an infinite number of 'x' is even coherent. Shouldn't we say that 'x' is without number, that 'x' cannot be numbered? Mung

KF #1239

my point is the implicit often surprises us and typically requires considerable effort to draw it out. Theorems are proved from start points and already proved theorems, but the point of the process is what is in the axioms may well be surprising and hard to discover. Key cases, models, test examples etc are all also legitimate devices of insight

Sometimes yes, but the mathematics is the key. Real world examples can be helpful but they are subsidiary. And you really need to answer Aleta's question from post #1218. The questions are very straight forward, they don't require any fancy speechifying to answer. ellazimm

Since Aleta's questions about the prime numbers are still on the table, (post #1218), I thought I'd post a couple of interesting things I found on stackexchange today. Apparently Euclid gives a constructive proof of the infinitude of the set of primes, rather than a proof by contradiction, which is how I've always seen it presented. Of course the specifics of the proof look quite similar. Here's a very slick proof cited on this page:

N(N + 1) has a larger set of prime factors than does N.

Just a single declarative sentence, which is quite amazing. daveS

Hello all, Just popping to say that I haven't abandoned this discussion. I've been busy and away for the past few days and will be out all day again today but I'll try to offer a few thoughts later tonight or at some point tomorrow. Have a good one HeKS HeKS

KF, Yes, of course. But inexact "models" can be confusing as well. Now I think the Turing machine tape model is helpful in thinking about an infinite past, but it's very misleading to someone trying to understand mathematical induction or the construction of N. I'm quite certain that it is still misleading you, in fact. The fact that you refer to mathematical induction as involving "do forever" loops where the law of detachment is applied over and over again illustrates this. Likewise with the construction of N. We (your persistent interlocutors), and virtually all working mathematicians, do not think of N as being constructed through "finite stage steps", so your post #1234 is really beside the point to us. daveS

DS & Aleta, my point is the implicit often surprises us and typically requires considerable effort to draw it out. Theorems are proved from start points and already proved theorems, but the point of the process is what is in the axioms may well be surprising and hard to discover. Key cases, models, test examples etc are all also legitimate devices of insight. KF kairosfocus

Mung #1229

Would you like to try again?

You're just being nit-picky. See Aleta's post #1230. ellazimm

I find kf's position here about axioms and the failings of abstract symbolism strange, given the strong insistence he's placed on the "rules of right reason" and the fundamental laws of logic in other threads on this site. Aleta

KF and Aleta, If I may respond to KF's post:

Aleta, strictly there is nothing in a province of mathematics provable from its axioms that is not included in those axioms. Likewise, if a set of axioms are contradictory, there is nothing “more” that is provided by a reductio proof. So, why is so much effort exerted in proving theorems etc?

???? This kind of floors me. Would you be content if mathematics consisted simply of the ZFC axioms together with rules and symbols for first order logic, and where no one was interested in investigating what theorems follow? To me, the whole point of mathematics is to see what follows from various axiom systems and logics. Without the great effort that has been exerted in proving theorems, we would have no Fermat's last theorem, no Poincaré Conjecture (theorem now), no prime number theorem, no e^(iπ) = -1, and so on. It's extremely non-obvious what does follow from these axioms, and proving such theorems can be very difficult (taking centuries of cumulative effort). See the abc conjecture for a potential example of such a hard theorem being proved in real time. daveS

Aleta, for cause I do not trust abstract symbols by themselves and I do not trust test cases by themselves. I am only happy when the two come together in mutually reinforcing light. And it is clear to me above that the punched tapes example brings out explicitly many of the concerns at the heart of this thread. Starting with the often repeated but what is endlessness. KF kairosfocus

Aleta, please keep on going. Start, {} --> 0 {0} --> 1 Define +1 as an operation that extends and thus a growing, endless set of counting sets: {0, 1, 2 . . . k} --> Sk+1 --> k+1 Now, where . . . denotes endless succession and Sk+1 collects the set of sets Sk, the copy counting sets so far principle. Can you actually instantiate to endlessness, no, at any k we are finite and bounded by k+1, thus we see the onward endlessness that can be successively put in match with the set {0,1,2 etc}. This shows, first, we cannot traverse stepwise to the zone of endlessness, so we impose by pointing across an ellipsis of endlessness. Second, were we to attain to a zone of actually infinite successive members, there would be members with endlessness in them, infinite integers. It is crucial that we cannot succeed to such a zone in +1 or similarly finite stage steps. And, the case warns us that there may be a fallacy of composition in extending to endlessness what is true of strictly finite subsets or ranges. KF kairosfocus

Aleta,

But the tape doesn’t reveal anything that the abstract symbolism doesn’t cover: we all know that you can’t traverse the entire infinite set by stepping through the numbers one by one, and we all know that, because the set is infinite, it can be put into a 1:1 correspondence with a proper subset.

Yes, this is becoming more and more clear to me. I think in terms of physical analogies quite a bit, but in the case of the infinite, those analogies tend to break down at some point, whether they are "infinite" Turing machine tapes, ladders, clocks, whatever. Since we have not been able to resolve our differences using these analogies, I think it's time to set aside the tapes, ladders, and clocks, and use actual mathematical arguments (when discussing mathematics). daveS

kf, I very much appreciate applied math, and always made a point of showing my students physical applications and representations of the math they were learning. But I also very much wanted to impress upon them the nature and power of pure mathematics, and to convince them that ultimately things fall back to the pure math for their foundational validity. So I agree with you that models are useful, both because that is the only way to actually apply math to the real world and because it helps us understand the math better. But in this case we are experienced enough people to work with the pure math. Your tape example may help some understand better what the pure math is about (such as with the 1:1 correspondences). However, I think it fundamentally misrepresents the nature of an infinite set by implying that you have to step through the set in order to fully create it, which is false. Aleta

Aleta, strictly there is nothing in a province of mathematics provable from its axioms that is not included in those axioms. Likewise, if a set of axioms are contradictory, there is nothing "more" that is provided by a reductio proof. So, why is so much effort exerted in proving theorems etc? Or, on studying special cases of interest? Likewise, what is the benefit of setting up the case of a tank or bucket being filled with a liquid to study and clarify the meaningfulness and relevance of the core concepts of the calculus? Then its extension to a tank with both inflow and outflow? (And BTW, that actually helped me make much more sense of what lurked behind the usual symbols.) The answers to these will show why something like the case of an abstract pair of punched tapes that are endless can be instructive and can reveal things we would not have spotted from the abstract symbols alone. Of course, one also wishes to express the case in an accurate algebraic model and explore its properties . . . which was done in outline. This is a case of both and not either or. KF kairosfocus

Prove: there is a largest positive integer Proof by contradiction: assume there is a largest integer L Let N = L + 1 N is also an integer, and N > L This contradicts the assumption that L is the largest integer Therefore the assumption that there is a largest integer is false Therefore there is no largest integer Therefore there are an infinite number of integers. Q.E.D How's that - pure math, and no writing any numbers down.involved. Aleta

ellazim: Mathematics is a beautiful system of abstract thinking wherein you can handle things you can’t do exhaustively, ‘by hand’. If that is so, then why did you issue the following demonstration for the claim that there is an infinite number of positive integers? If there are a finite number of positive integers and if you wrote them all down you could always take the largest one and add 1 to it and get one that was not on your list. Would you like to try again? Mung

at 1222, methink asks,

Mathematical infinity or actual infinity

Mathematical infinity is actual infinity. Infinity is a mathematical concept. All of us here have agreed, I think, that there is no physical instantiation of infinity in our universe. Aleta

But the tape doesn't reveal anything that the abstract symbolism doesn't cover: we all know that you can't traverse the entire infinite set by stepping through the numbers one by one, and we all know that, because the set is infinite, it can be put into a 1:1 correspondence with a proper subset. What does the tape reveal that the abstract symbolism conceals? Everything you say in 1226, for instance, is not made any clearer by the tape example. Furthermore, the tape example conceals things the abstract symbolism reveals. Cantor's definition of orders of infinity, which start with naming aleph null as representing the first level of infinity - the size of the integers, is much more "revealed" with the abstract symbolism than it is with the tape. Furthermore, additional mathematics to which you often refer (higher orders of infinity, hyperreals, etc.) are not revealed by the tape example at all.) So I don't see the tape example as adding anything to the discussion. Aleta

MT: the essence of infinity is endlessness beyond any arbitrarily large finite (and bounded) case. This obtains for the natural numbers, and the scale of the continuum. Where, as mathematics is the logical study of structure and quantity, insofar as these features are manifested in abstract or concrete entities, that logic constrains possibilities and can even have causative effect; e.g. as core properties for circularity and squarishness stand in contradiction for one and the same entity and circumstances, the attempt to create a square circle must fail. As, was discussed above. One consequence of such, is that a stepwise finite stage incremental process, abstract or physical/concrete, cannot traverse a transfinite span. That is, one that is endless. How omega -- I have used w for convenience -- is the order type of {0,1,2 . . . } is inherently different from how 5 is order type of {0,1,2,3,4} because of that endlessness. KF kairosfocus

Aleta, I say again, that abstract symbolism often conceals more than it reveals, hence the place for the instructive case study. KF kairosfocus

kf, I can see perfectly well both the endlessness and the 1:1 correspondences between an infinite set and one of its infinite subsets by thinking and writing numbers in set notation. I don't need to visualize a tape or a ladder or a hotel. Physical analogies such as the tape are misleading because they make it seem like the step-by-step process is essential for accessing the infinite set, and mathematically it's not. Aleta

Aleta, a thought exercise often imposes an experimentum crucis that brings out the issue in ways that symbolism may conceal. Thus the power of Turing's machine as an example; which may then be algebraically symbolised. In this case, the issue is endless continuation, and the pulling of the blue tape by some arbitrary, large but finite k steps then placing rows k, k+1, k+2 etc in 1:1 match with the undisturbed print tape from 0,1,2 etc shows how endlessness entails that no finite stepwise advance from 0 can exhaust endlessness, or even scratch its surface. Thus, we see plainly and undeniably that the onward endlessness is a critical aspect of our understanding of natural numbers understood to be successive, cumulative counting sets. As a consequence of which, we see that ordinary mathematical induction with its k, k+1 chaining from case 0, is only capable of the potentially infinite and that onward endlessness materially affects consequences. That which then becomes indeterminate is the finitude of all integers. For, we can only ever attain to finite specific values by stepwise count, or representation in notations based on such, with onward undefined endlessness ever before us. So, the proper conclusion is that every integer we can determine or state or specify will be finite but there is an endlessness beyond all such. Thence, we define an order type of such endlessness, w. This is a new type of quantity recognised and represented. Then, we may proceed to operate on such, and it seems the surreals and hyper reals give us promising results. In my case, I find the catapult operation of multiplicative inverse and the hyperbola y = 1/x applied to the interval [0,1] especially very near to 0, [0,1] regarded as a continuum then lets me see interesting onward vistas. KF kairosfocus

KF @ 1216

We cannot exhaust the system (as the two tapes example illustrates), but every number we can write down specifically will be finite. Endlessness strikes again and gives a strange answer.

When you say ' Endlessness', what are you referring to - Mathematical infinity or actual infinity? Me_Think

Mung #1215

Your premise is that if there is a finite number of positive integers I could write them all down. I disagree. I think your premise is false.

How about have them written down? Or what's wrong with something like: 1, 2, 3, 4, . . . . L-2, L-1, L (where L is the 'largest' number)

If the positive integers are infinite I would not be able to write them all down. I cannot write them all down. Therefore, the positive integers are infinite.

Because that's like an argument from ignorance: I can't do something so it's impossible. Also, A -> B doesn't always mean B -> A. I cannot write down all the digits of sqrt(2) but the value of sqrt(2) is finite. Mathematics is a beautiful system of abstract thinking wherein you can handle things you can't do exhaustively, 'by hand'. ellazimm

KF #1216

Mung, EZ and Aleta, it seems the answer is indeterminate in a positive sense. We cannot exhaust the system (as the two tapes example illustrates), but every number we can write down specifically will be finite. Endlessness strikes again and gives a strange answer.

Well, I'm not sure what is indeterminate. I trust you're not just giving up. The beauty of Canto's work is that he found a way to deal with infinite sets and even determined that some infinite sets are 'bigger' than others. ellazimm

KF,

Mung, EZ and Aleta, it seems the answer is indeterminate in a positive sense. We cannot exhaust the system (as the two tapes example illustrates), but every number we can write down specifically will be finite. Endlessness strikes again and gives a strange answer. KF

Aren't you therefore forced to reject the law of the excluded middle? If we let A be the sentence "the set of integers is infinite", then A∨¬A is false? daveS

And I'll remind you that the proof I offered that there are an infinite number of primes does not depend on induction, or any traversal, or even knowing what all the primes are up to a certain number. What would be your answer to these two questions: 1. There are an infinite number of primes: True or False 2. All primes are finite:: True or False Aleta

The answer to what is indeterminate? My two questions in 1188? Your tape analogy just confuses the situation by conflating pure math with the physical world. Dave explained it well in 1203, and I've said the same thing:

To address your post, I think you and I are simply playing by a different mathematical rule book. I accept the Axiom of Infinity, which means I don’t need to think of N as being constructed step by step. The entire set just “exists”, and we proceed from there.

The infinite set of integers exist in a mathematical sense irrespective of whether we can write them down, or traverse them, or punch them out on a tape. Yes, "every number we can write down specifically will be finite" and every number we don't write down will also be finite. They're all finite whether we write them down or not. Infinity is strange. The fact that the answers to both my questions are "true" is part of that strangeness, but lots of strange things are true. Aleta

Mung, EZ and Aleta, it seems the answer is indeterminate in a positive sense. We cannot exhaust the system (as the two tapes example illustrates), but every number we can write down specifically will be finite. Endlessness strikes again and gives a strange answer. KF kairosfocus

ellazimm: If there are a finite number of positive integers and if you wrote them all down you could always take the largest one and add 1 to it and get one that was not on your list. Your premise is that if there is a finite number of positive integers I could write them all down. I disagree. I think your premise is false. You could try this: If the positive integers are infinite I would not be able to write them all down. I cannot write them all down. Therefore, the positive integers are infinite. :) Mung

Follow-on from #1213 If the sqrt(2) is not irrational then there must be a mistake in all the proofs (starting with some Greek guy about 2500 years ago) that sqrt(2) is irrational. If you think that sqrt(2) does not have an infinite, non-repeating decimal expansion then: can you find a mistake in one of the proofs? Additionally: if there are no infinite, decimal expansions then 1/3 does not have the decimal expansion 0.33333 . . . . . 1/3 would have the decimal expansion of 0.333 . . . . 3 with an, as yet, undetermined number of 3s. But then 3 x 1/3 would not be 1, it would be 0.999999999 . . . . . 9. Ooops. ellazimm

Silver Asiatic #1210

This assumes that the universe could contain one more than the largest. We can’t know that.

IF this is not an April Fool's Day response . . . If the Universe could only hold so many numbers then . . . Could it hold more 1s than 1000s? How about 1000000s? How about -2s? Or sqrt(2)s? (Sqrt(2) has an infinite, non-repeating decimal expansion.) How about 3+4i? Is 3+4i 'bigger' than 5 say? Their magnitudes are the same but do they take up the same amount of space in the universe? Which brings up another question . . . If there really is nothing that is infinite then sqrt(2) has a finite decimal expansion which means it's not an irrational number. Which means there are no irrational numbers. Which means (I think) that the real numbers are all rational numbers. Which means that the reals are countably infinite, i.e. have the same cardinality as the positive integers. Today's homework: what famous proof would this be a contradiction of? (That would put the continuum hypothesis to rest though.) ellazimm

Silver Asiatic,

“How many days?” = you’re setting that up for an answer that is a finite number. To say “Infinitely many” is to make that appear as a finite quantity.

I certainly wasn't expecting a finite number answer. If I say in an infinite past, the cardinality of the set of past days is infinite, would you agree to that?

The number of days elapsed from an infinite past is non-calculable. It’s the same as asking “how may days ago was the very first day in an infinite past”.

Non-calculable? I don't know. I'm thinking in terms of cardinalities here. I think everyone who has published on this topic takes an "infinite past" to mean the set of days elapsed to the present has cardinality aleph_0, so that's what I am assuming.

You’re basically saying that the answer is: “an infinite time ago”. But there’s no first day and it is impossible to say how many days have elapsed in total. An infinite string of days is all the days. You can’t add a day to it.

I don't agree. In an infinite past, all the days previous to today comprise an infinite string of days, but this leaves out today---so today could be added to the set. There's nothing problematic about adding an element to an already infinite set. daveS

This assumes that the universe could contain one more than the largest

??? Numbers don't take up space in the universe. So, SA, even though you are going offline, are you saying that mathematically we could reach a number that we couldn't add one more to because there would be no room for it on the number line? Aleta

If there are a finite number of positive integers and if you wrote them all down you could always take the largest one and add 1 to it and get one that was not on your list.

This assumes that the universe could contain one more than the largest. We can't know that. I will be off-line for 3 days - so silence does not equal consent, except with everyone I agree with. :-) Silver Asiatic

daveS

I meant something like this: How many days have elapsed to this point, assuming and infinite past? Infinitely many days. I guess I don’t understand your objection.

I explained this in detail. You cannot circumscribe an infinite. Your term "available" translated infinite amount into a finite quantity. You do the same above. "How many days?" = you're setting that up for an answer that is a finite number. To say "Infinitely many" is to make that appear as a finite quantity. But it's an amorphous amount. The answer to "How many days?" is that it is, by definition, "unknowable". To merely say "an infinite number" and then make that seem like a finite quantity is false. The number of days elapsed from an infinite past is non-calculable. It's the same as asking "how may days ago was the very first day in an infinite past". You're basically saying that the answer is: "an infinite time ago". But there's no first day and it is impossible to say how many days have elapsed in total. An infinite string of days is all the days. You can't add a day to it. To know something is to capture it - to comprehend it. Infinity is unknowable - by either science or math. Silver Asiatic

Mung #1207

I am going to go with false. If they cannot be numbered, there is not an infinite number of them. Plus, infinity is not a number, so there cannot be an infinite number of anything.

If there are a finite number of positive integers then how many are there? If there are a finite number of positive integers and if you wrote them all down you could always take the largest one and add 1 to it and get one that was not on your list. ellazimm

Aleta: 1. True or False: there are an infinite number of integers I am going to go with false. If they cannot be numbered, there is not an infinite number of them. Plus, infinity is not a number, so there cannot be an infinite number of anything. Mung

How do we get the man up on the rung of the ladder without him having to climb up the ladder? A ladder truck! Obviously. Mung

Silver Asiatic,

That doesn’t follow. The term “available” cannot be used with regards to an infinite amount. Available means something like “accessible” or “can be captured”. But by its nature, you can’t have “availability” to infinitude. If you did, it would be finite. The distance to travel is infinite. By its nature, nothing can “capture” or “have access” to that which cannot be circumscribed. An infinite amount of anything is never available. It always reaches beyond any terminus.

I'm not quite following this. Maybe the word "available" was a poor choice on my part. I meant something like this: How many days have elapsed to this point, assuming and infinite past? Infinitely many days. I guess I don't understand your objection.

Infinity is a oneness that cannot be realized in temporal terms – by definition.

Can you provide more context or a source? I have never heard this before.

You cannot say, “today I finally completed traveling for infinite amount of time”. If you started the journey, then it has a finite past. If you never started, then you have no measurement. If today ends an infinite journey, then yesterday was infinity minus one, which is impossible.

Well, yesterday would also have been the end of an infinite journey. There's no mathematical problem with that. If the set of days previous to today has cardinality aleph_0, then the set of days previous to yesterday has cardinality aleph_0 - 1 = aleph_0 as well.

You’re restating the problem but not solving it. For some reason, you want to apply the term “0” to today. But that’s arbitrary. Tomorrow would then be 1. The next day would be 2, etc. But we arrive at the next day, and you’re calling that 0 again. But you already called today 0. What you’ve done is selected an arbitrary point on the line and assigned a value. You could call a day a million years ago “0” (and ultimately, any day you call “0” drifts to the past).

Yes, the choice of the label "0" for today is completely arbitrary, but that often/usually is the case when you set up a coordinate system. But once I fix an origin at 0, then I can't call tomorrow day 0 again in that same system. It would have to be day 1, unless I reset my coordinates, in which everything would have to shift.

It would not be possible to pick the earliest point on the line and assign any value to it, positive or negative.

True. There is no "earliest" point in time, assuming an infinite past. daveS

daveS

There is an infinite time available with an infinite past, for one thing.

That doesn't follow. The term "available" cannot be used with regards to an infinite amount. Available means something like "accessible" or "can be captured". But by its nature, you can't have "availability" to infinitude. If you did, it would be finite. The distance to travel is infinite. By its nature, nothing can "capture" or "have access" to that which cannot be circumscribed. An infinite amount of anything is never available. It always reaches beyond any terminus.

But again, there is an infinite amount of time available, so you can both travel an infinite amount of time and arrive.

Infinity is a oneness that cannot be realized in temporal terms - by definition. You cannot say, "today I finally completed traveling for infinite amount of time". If you started the journey, then it has a finite past. If you never started, then you have no measurement. If today ends an infinite journey, then yesterday was infinity minus one, which is impossible. The idea that is possible to "have available" an infinite amount is made to appear as if "an infinite amount" is a finite thing that can be made available. But the universe does not have an infinite "available" since this quantity considered a completed infinite continues to expand. The universe does not have access to next year. So, it does not have next year "available". It cannot have available or accessible an infinite past because that quantity cannot be captured to be made available to anything. Nothing can "apply" an infinite amount to anything - again, because that amount cannot be circumscribed, captured, made available or made real in temporal terms.

…}, in order, wouldn’t work. The days could be labeled using {…, -3, -2, -1, 0}, however, which does have a maximum but no minimum.

You're restating the problem but not solving it. For some reason, you want to apply the term "0" to today. But that's arbitrary. Tomorrow would then be 1. The next day would be 2, etc. But we arrive at the next day, and you're calling that 0 again. But you already called today 0. What you've done is selected an arbitrary point on the line and assigned a value. You could call a day a million years ago "0" (and ultimately, any day you call "0" drifts to the past). The measurement is exactly the same, using positive or negative integers. You're driving to a destination an infinite distance away. Calling yesterday -1 doesn't make it possible to reach the destination. It would not be possible to pick the earliest point on the line and assign any value to it, positive or negative. Silver Asiatic

KF, Well, I'm sure I'm repeating myself, but I will say a couple of things. First, I will answer Aleta's True/False questions directly: True to both. This is a philosophical position, I understand, and not everyone will agree with me, especially on #1. But I have given answers in the proper format. To address your post, I think you and I are simply playing by a different mathematical rule book. I accept the Axiom of Infinity, which means I don't need to think of N as being constructed step by step. The entire set just "exists", and we proceed from there. From what I gather, the only legitimate mathematical constructions for you are those that could be carried out (in principle) on a digital computer, starting with {}, with finite but arbitrarily large storage, in a finite amount of time. Therefore you don't accept the Axiom of Infinity or mathematical induction the same way I do. I don't see any reason to assume the universe "respects" either of our philosophical positions. Now if you could derive a logical contradiction P∧¬P from the assumption of an infinite past, I would agree that would be a major problem for me. So far, I haven't seen one demonstrated. I don't believe the tapes example provides one, and yes, I fully comprehend the concept of endlessness as you have defined it. daveS

Aleta, people are dressing up these speculations in lab coats, and are using them in worldview construction. Those worldviews are then imposed in the name of science. More importantly, there are significant coherence issues to be resolved, so this is one case where Math and life issues intersect. Never mind that it is also desirable to more deeply understand mathematics in its own right. KF kairosfocus

DS: Could you let us know your response on the merits to:

. . . the ellipsis cannot be exhausted. All numbers we can reach will be finite but endlessness remains onwards; as the pink vs blue punch tape examples highlight [ --> these being a thought exercise in essence similar to the thought exercise of Turing's machine and used to show what endlessness implies]. And yes this points to limitations on what ordinary mathematical induction can reach by chaining, again only to the potentially infinite. And this is echoed in the problem of a claimed infinite succession of finite values at +1 increments from 0. The succession cannot be completed by any successive process and were it there is an incoherence involved as in effect the successor set to the last achieved is a copy of the sequence so far. [--> e.g. {0,1,2,3,4} --> 5] If completed to actual endlessness, there would be endless and non finite members. The answer is, the endless cannot be traversed in successive +1 steps from 0.

KF kairosfocus

Does anyone else want to answer Aleta's questions in #1188? If you look at her questions and KF's response in #1189, you will indeed see why this thread has 1200 posts as of now. daveS

Silver Asiatic,

You cannot project forward in time without an origin point. For example, in an infinite past, it took an infinite amount of time to arrive at yesterday.

I would agree that an infinite number of days had elapsed prior to yesterday.

So the universe had to wait an infinite amount of time to add another day (today). If the amount of time needed in order to add one more day to the string of time is infinite, then a new day would never be added.

I don't see how this follows. There is an infinite time available with an infinite past, for one thing. The universe is "adding" new days eternally, every 24 hours.

To wait an infinite amount of time means to wait an infinitely long time — it means to always be waiting. You wait infinitely to arrive at the present – or at any present moment. If it takes waiting an infinite amount of time before you arrive at today, then you can never arrive. If it takes an infinite amount of time, for example, for you to travel from one place to another, you can never reach your destination because you’ll be traveling for an infinite amount of time which means it’s not possible to ever arrive.

But again, there is an infinite amount of time available, so you can both travel an infinite amount of time and arrive.

With an infinite past, today would be the maximum number of an infinite string. Tomorrow would be that maximum (impossible) number plus one. Obviously that doesn’t work.

Are you referring to a problem with labeling each day with a number? If so, I agree that using {1, 2, 3, ...}, in order, wouldn't work. The days could be labeled using {..., -3, -2, -1, 0}, however, which does have a maximum but no minimum. daveS

I realize that those ideas are out there, but I think I've made it clear that my position is that metaphysical speculations about what is beyond our universe are just that - speculations, and if there is no experience we could have that would bear on their truth (and there isn't), then we should just live with the limits of our possible knowledge, and accept not knowing. That is why I've said several times that thinking about time as being modeled by a number line that extends back past the start of our universe is unwarranted. Whatever metaphysical background to our universe there is, assuming that there is one, may not exhibit either time or cause-and-effect continuity that is the same as, or even similar to, what we experience in our universe. Aleta

Aleta, multiverse speculations try to get around such a terminus, cf OP and folks such as Krauss and Dawkins etc. (who in effect try to present the primordial quasi-physical space as "nothing" . . . https://uncommondescent.com/intelligent-design/fine-tuning-of-the-universe/#comment-541398 and this OP from 3 years back: https://uncommondescent.com/philosophy/on-pulling-a-cosmos-out-of-a-non-existent-hat/ ) This is a context of this discussion. Previously, there were oscillating models. The logic of an infinite quasi-physical regress of causally linked states/ entities culminating in our world is something that needs to be resolved. That infinite regress achieving the present points to issues of coherence is something to be looked at. Traversing and ending the endless in finite stage steps in succession looks like running into coherence issues, those need to be resolved -- including, is this like a square circle? KF kairosfocus

FWIW, this debate took place about the time that the Big Bang theory was not yet established. Nowadays, and in this thread, I think everyone accepts that our universe is finite in time and space. Aleta

debate link: http://faculty.arts.ubc.ca/rjohns/cop_rus.pdf kairosfocus

This problem reminds me of the Copleston vs. Russell debate, during which Russell surprisingly didn’t have a problem with an infinite past of the universe, which conveniently provided him with a ground to deny the existence of the Uncaused Cause. Excerpt:

Copleston: Well, my point is that what we call the world is intrinsically unintelligible, apart from the existence of God. You see, I don't believe that the infinity of the series of events -- I mean a horizontal series, so to speak – (…) If you add up chocolates to infinity, you presumably get an infinite number of chocolates. So if you add up contingent beings to infinity, you still get contingent beings, not a Necessary Being. An infinite series of contingent beings will be, to my way of thinking, as unable to cause itself as one contingent being. Russell: I see no reason whatsoever to suppose that the total has any cause whatsoever. (…) I should say that the universe is just there, and that's all.

Origenes

HeKS @1169

No person, piece of equipment, or other sort of aid could help the man get onto the ladder from the other direction at an infinite point and begin a descent from infinity to the ground. If the man gets onto a rung, he does so at some arbitrary finite point, however large it may be, and begins a finite descent to the ground. When he finally does get to the ground, he can say that he’s been climbing down the ladder for a very long time, but he won’t be able to say that he has been climbing down the ladder forever, or from the infinite past.

I have no problem agreeing with that. I was responding to Mung's question @ 1162 about how the man got on to the rung. He can obviously start only from a finite point on the ladder. For the record, I don't believe in infinite past nor infinite space. (see comment #1141) Me_Think

With an infinite past, today would be the maximum number of an infinite string. Tomorrow would be that maximum (impossible) number plus one. Obviously that doesn't work. Silver Asiatic

daveS

Why not? The assumption is of a universe which is eternal, which always has existed. I don’t see how you can conclude such universe could not have reached a present moment.

You cannot project forward in time without an origin point. For example, in an infinite past, it took an infinite amount of time to arrive at yesterday. So the universe had to wait an infinite amount of time to add another day (today). If the amount of time needed in order to add one more day to the string of time is infinite, then a new day would never be added. To wait an infinite amount of time means to wait an infinitely long time -- it means to always be waiting. You wait infinitely to arrive at the present - or at any present moment. If it takes waiting an infinite amount of time before you arrive at today, then you can never arrive. If it takes an infinite amount of time, for example, for you to travel from one place to another, you can never reach your destination because you'll be traveling for an infinite amount of time which means it's not possible to ever arrive. Silver Asiatic

I know all that, kf. See 1170. Aleta

Aleta, you and I are both aware the ellipsis cannot be exhausted. All numbers we can reach will be finite but endlessness remains onwards; as the pink vs blue punch tape examples highlight. And yes this points to limitations on what ordinary mathematical induction can reach by chaining, again only to the potentially infinite. And this is echoed in the problem of a claimed infinite succession of finite values at +1 increments from 0. The succession cannot be completed by any successive process and were it there is an incoherence involved as in effect the successor set to the last achieved is a copy of the sequence so far. If completed to actual endlessness, there would be endless and non finite members. The answer is, the endless cannot be traversed in successive +1 steps from 0. KF kairosfocus

To Dionisio, Origenes, HeKS, Silver Asiatic, and anyone else coming late to this party: to help explain what has kept this thread going so long, let me ask each of the following two questions: Consider the integers on a standard number line, with the positive counting numbers 1, 2, 3, ... to the right of zero and their negatives to the left. 1. True or False: there are an infinite number of integers 2. True or False: Every integer is a finite number. What are your answers to questions 1 and 2. Note: this is a purely mathematical question. It is not about time, or ladders, or tapes - just math. Aleta

The universe has to start at the beginning in order to reach the present moment. However, given an infinite past, there is no beginning to start from. And if there is no beginning then nothing can reach the beginning. Origenes

Silver Asiatic,

Wherever you start would be (or have been) a present moment. But that present moment would have required an infinite amount of time to “become present”. Infinite past, necessarily, has no beginning – by definition. That which has no beginning has no starting point. An infinite past can never have gotten started.

I agree with that. An infinite past would not have a beginning.

That which has no beginning (an infinite past by definition) could never have had a present moment.

Why not? The assumption is of a universe which is eternal, which always has existed. I don't see how you can conclude such universe could not have reached a present moment. daveS

Silver Asiatic @1182 & @1183 If time is a dimension that got created along with the known 3 spatial dimensions at the beginning of this universe, then those concepts are rendered meaningless outside this universe. This is incomprehensible for our limited minds. Dionisio

HeKS @1180 Yes. Exactly. BTW, a while ago in another thread I think someone suggested that those 'persistent' interlocutors could be just agents working for this site in order to keep the discussions on, thus potentially increasing the website traffic. But I never took that story seriously. It sounded like a joke. :) However, this time I wonder... why not? :) All they have to do is repeat the same 'yerunda' (bzdura) over and over again until they are told to stop it. This time they've done a remarkable job! They've lifted this thread up to the top of the ranking! They should get a bonus! :) Check this out:

Popular Posts (Last 30 Days) Durston and Craig on an infinite temporal past . . . (2,390) A world-famous chemist tells the truth: there’s no… (2,239) Quantum Darwinism = Darwinism as woo-woo? (2,197) Homologies, differences and information jumps (1,386) An encounter with a critic of biological semiosis (1,323)

Wow! Dionisio

That which has no beginning (an infinite past by definition) could never have had a present moment. So, you can't 'pick a point and start there'. No points on the continuum could be realized unless there was a beginning that created/started the continuum. If there was a start or beginning to the continuum, that is, if it ever came into temporal existence then it would have a finite past, not infinite. If it can never come into temporal existence then it could never exist. Silver Asiatic

daveS

Regarding the bolded part, starting from where?

Wherever you start would be (or have been) a present moment. But that present moment would have required an infinite amount of time to "become present". Infinite past, necessarily, has no beginning - by definition. That which has no beginning has no starting point. An infinite past can never have gotten started. Silver Asiatic

This thread has turned funny indeed. Pure entertainment. It's like the 'deep breaths of relief' in professor Alon's Systems Biology classes at the Weizmann Institute for Science. Except that here one doesn't have to stay focused on the explanation for biological oscillators, FFL, and all those circuits. Apparently some of the most active interlocutors here forgot the title of this OP?

Durston and Craig on an infinite temporal past . . .

Or maybe they skipped the first paragraph of the OP?

[...] it seems the evolutionary materialist faces the unwelcome choice of a cosmos from a true nothing — non-being or else an actually completed infinite past succession of finite causal steps.

:) Dionisio

Dionisio

The impression one gets when reading a few comments here is that some of the most active interlocutors aren’t sure what exactly the discussion is about, hence they seem to talk past each other. That may explain why this thread has lasted so much.

And I'll say Amen to that. Based on ellazimm's latest comments I'm getting the impression that he/she may be one of those people who aren't sure exactly what the discussion is about ... or what arguments people have been making. I'm certainly unclear about who ellazimm thinks is 'bending the math to suit an agenda'. HeKS

Aleta #1178

Amen! :-)

hahahahahahahahahahahahahahahahahahahahahahahahahahahahahhaha Okay, I'm off to my local pub for quiz night. ellazimm

This isn’t about faith or beliefs or the origin of the universe. It’s just about mathematics. Accept the math and then see how it might apply to a given situation. Don’t bend the math to suit an agenda.

Amen! :-) Aleta

Aleta #1173

There are no points infinitely far from zero!!! All points are a finite distance from zero. “Infinitely far” is not a well-defined mathematical concept. See my comments at 1170 for the mathematical meaningless of this idea.

Amazing, after almost 1200 posts. You have the patience of a saint. I'd love to buy you a drink. Next time you're in the UK let me know. Look folks: infinity, which ever one you want, plus or minus, is not something you can count to, or is a step, or on a ladder, or a hole on a tape. All of those are finite, albeit sometimes very large, numbers. And there is always an infinite number of steps or rungs or holes after any one you pick. And those will be finite as well. 'Endlessnes' is not a problem. There a system for dealing with it. For different kinds of 'endlessness' in fact. If you can come up with a better system then great, lets see it. And you'll have to show why the methods developed by Cantor are lacking as well. This isn't about faith or beliefs or the origin of the universe. It's just about mathematics. Accept the math and then see how it might apply to a given situation. Don't bend the math to suit an agenda. ellazimm

Silver Asiatic,

daveS Likewise, not every “infinite past” scenario needs to have points in time infinitely far in seconds from the present.

I think, by definition, it does. With an infinite past, it takes an infinite amount of time to arrive at the present.

Regarding the bolded part, starting from where? Any particular point in time is only finitely many seconds "ago". WLC (and maybe KF) agree with me on this. daveS

That's what I said at 1170.

Negative infinity isn’t a place, and thus you can’t start there. This is a category error: you can’t start from a place that isn’t a place. No matter where you start, you are starting at a finite negative number.

The same would be true about starting at a finite positive number and moving "down" to zero. Aleta

HeKS @1169

Nobody said there was a problem with stepping onto the ladder from the ground or climbing up the ladder. The end on the ground is the boundaried end and there’s no problem with simply stepping onto it and starting to climb. You will simply never reach the other “end”. Stepping onto and climbing the ladder in this direction represents moving forward into a potentially infinite future but where no matter how far into the future we go, any day we get to will still be only a finite number of days from the Big Bang. The problem arises when we come to the idea of trying to get on the ladder from the other end – the unboundaried end, the infinite “end”, “location”, “zone”, or perhaps more appropriately, state – and start climbing down towards the ground, which represents traversing an actually (not just potentially) infinite past to arrive at the present. No person, piece of equipment, or other sort of aid could help the man get onto the ladder from the other direction at an infinite point and begin a descent from infinity to the ground. If the man gets onto a rung, he does so at some arbitrary finite point, however large it may be, and begins a finite descent to the ground. When he finally does get to the ground, he can say that he’s been climbing down the ladder for a very long time, but he won’t be able to say that he has been climbing down the ladder forever, or from the infinite past.

Does anyone in this thread disagree with the above quote? Dionisio

There are no points infinitely far from zero!!! All points are a finite distance from zero. "Infinitely far" is not a well-defined mathematical concept. See my comments at 1170 for the mathematical meaningless of this idea. Aleta

daveS

Likewise, not every “infinite past” scenario needs to have points in time infinitely far in seconds from the present.

I think, by definition, it does. With an infinite past, it takes an infinite amount of time to arrive at the present. Silver Asiatic

Mung @1161

This thread provides actual proof that one can begin at the top and descend down across an infinite number of posts.

Exactly! It reminds me of the old TV commercial with the Energizer bunny that kept going playing a drum. A never-ending story. On the bright side this thread has been the most popular this year! That means more anonymous visitors have read KF's interesting posts. KF's persistent interlocutors deserve some credits for keeping this discussion going. :) HeKS wrote something interesting @1145:

We may well be approaching that point, but it’s more satisfying to do that once you’re reasonably sure that the parties to the conversation have at least properly understood each other’s arguments. Then, if no agreement can be reached, so be it. At least you’ve hopefully had an interesting discussion.

The impression one gets when reading a few comments here is that some of the most active interlocutors aren't sure what exactly the discussion is about, hence they seem to talk past each other. That may explain why this thread has lasted so much. KF's OP and comments have been clear enough even for me to understand them. :) Dionisio

FWIW, my position from the beginning is that it doesn't make sense to think about starting at "negative infinity" and moving towards 0. Negative infinity isn't a place, and thus you can't start there. This is a category error: you can't start from a place that isn't a place. No matter where you start, you are starting at a finite negative number. Also, FWIW and IMHO and YMMV :-), a great deal of the confusion here is because we are confusing pure mathematics with metaphorical physical models, whether they be time, hotels, tapes, or ladders. From a mathematical point of view, the entire infinite set of integers exists as a whole without there being any "stepping" through them. We don't look at a number line and say "Zero can't really exist because you couldn't have got there from negative infinity," nor do we say "the number line must have a starting point somewhere to the left because otherwise we couldn't have got to 0." Those would be silly things to say about the number line. And yet when we try to apply the number line to a physical model we think there is a problem - but the problem is trying to force a mathematical model past its limits. The problems are not with the nature of infinity, but with our confusion between pure and applied mathematics. Aleta

Me_Think @1165

Well, the ladder is supposed to be on the ground. The distance between any two rungs has to be finite (other wise it is not a ladder!). There is nothing stopping someone from lifting and placing the person – by some equipment- on one of the rung of the ladder, or the person can climb the ladder and then descend down. The point is, if you assume the ladder can’t be climbed up or down, what is the point of the ladder metaphor ? KF’s tape metaphor will do.

You seem to have misunderstood the issue. Nobody said there was a problem with stepping onto the ladder from the ground or climbing up the ladder. The end on the ground is the boundaried end and there's no problem with simply stepping onto it and starting to climb. You will simply never reach the other "end". Stepping onto and climbing the ladder in this direction represents moving forward into a potentially infinite future but where no matter how far into the future we go, any day we get to will still be only a finite number of days from the Big Bang. The problem arises when we come to the idea of trying to get on the ladder from the other end - the unboundaried end, the infinite "end", "location", "zone", or perhaps more appropriately, state - and start climbing down towards the ground, which represents traversing an actually (not just potentially) infinite past to arrive at the present. No person, piece of equipment, or other sort of aid could help the man get onto the ladder from the other direction at an infinite point and begin a descent from infinity to the ground. If the man gets onto a rung, he does so at some arbitrary finite point, however large it may be, and begins a finite descent to the ground. When he finally does get to the ground, he can say that he's been climbing down the ladder for a very long time, but he won't be able to say that he has been climbing down the ladder forever, or from the infinite past. HeKS

KF,

PS: I find that there is still a serious problem of taking the endlessness in definition of positive integers or natural, counting numbers seriously. Every natural number we can reach will be finite, but there is an endlessness that has to be taken at its full weight. We cannot exhaust that endlessness through any finite stage stepwise process, going up or down.

Who says that we (or a deity of some sort) can't count down through all natural numbers given an infinite past? I still haven't seen a proof. The tapes example, while useful as an illustration of an infinite set, does not prove this. Edit: Recall the scheme I provided---the deity counts "n", n seconds ago for each natural number n. daveS

KF,

DS, let us just consider for a moment, is [0,1] a continuum?

Yes, I believe so.

If so then it enfolds every possible number in the interval, no exceptions, no gaps . . . something you glided over a little too easily for my comfort above.

Every possible real number, that is, assuming your notation [0, 1] means all real numbers between 0 and 1 inclusive.

If there are hard infinitesimals that 1/h –> hyper reals, then it follows as at least reasonable for exploration that there will be milder cases that go to 1/m –> A, where A = w + g, g a finite.

This is an example of what I was talking about. "Hard" and "mild" infinitesimals? Is your m a real number? If so, then we can stop right here, because no such m exist. Likewise, if your ω on the right is the first infinite ordinal, then again we can stop. Such an equation cannot hold. Edited: It can hold if we are working in the surreal numbers, but then I'm not clear how this relates to [0, 1]. If m is not real, and ω is not N, what exactly are they? I can't quite follow the rest. Are you concerned that there are gaps in [0, 1]? And that the infinitesimals are required to fill in those gaps? daveS

A number line will do. No metaphor is needed. The physical metaphorical representations have added nothing, really, and have perhaps confused some issues. Aleta

Mung @ 1162

I thought it was wonderful. How did the man get on to the rung above the rung you are talking about? Or did you just not think about that?

Well, the ladder is supposed to be on the ground. The distance between any two rungs has to be finite (other wise it is not a ladder!). There is nothing stopping someone from lifting and placing the person - by some equipment- on one of the rung of the ladder, or the person can climb the ladder and then descend down. The point is, if you assume the ladder can't be climbed up or down, what is the point of the ladder metaphor ? KF's tape metaphor will do. Me_Think

DS, let us just consider for a moment, is [0,1] a continuum? If so then it enfolds every possible number in the interval, no exceptions, no gaps . . . something you glided over a little too easily for my comfort above. If there are hard infinitesimals that 1/h --> hyper reals, then it follows as at least reasonable for exploration that there will be milder cases that go to 1/m --> A, where A = w + g, g a finite. And what is more, it is reasonable to see that we can identify n so that 1/n --> w + (g +1) and fill in the interval (n, m) such that the continuum there could in principle be taken to 1/p_k in (n,m) to map between the two, ultimately filling in a continuum from w on up. And yes, I have stated that I have a serious problem with the argument that near 0 there is a gap in the real line, as that would imply a break of continuity. So, for every hard infinitesimal, there should be a mild one once [0,1] is really a continuum. KF PS: I find that there is still a serious problem of taking the endlessness in definition of positive integers or natural, counting numbers seriously. Every natural number we can reach will be finite, but there is an endlessness that has to be taken at its full weight. We cannot exhaust that endlessness through any finite stage stepwise process, going up or down. Just now, I resorted to the surreals to make the point, and I point out that the last number in a chain of attained finites so far is finite but the naturals go on beyond what we can reach in the sort of stepwise +1 processes we have looked at and extensions to that. As the pink and blue tapes example shows, endlessness continues on beyond any finite k however arbitrarily large it is, and going up in steps can only span a potentially infinite but actually finite process, likewise going down. Claiming there is an infinite causal chain in the past in a quasi-physical world leading to us today runs into serious coherence problems, as just again outlined. kairosfocus

KF,

DS, I have no problem with a ladder rung labelled w say by way of a sticker on a roll with a label printer.

Really? Ok. But my point is not every infinite ladder needs to have these strange ω rungs. Likewise, not every "infinite past" scenario needs to have points in time infinitely far in seconds from the present. In case of an infinite ladder with rungs indexed by Z^-, no matter which rung you are on, you can descend to the ground in finitely many steps.

PS: The logic of structure and quantity is obviously highly relevant to making good sense of a world full of structure and quantity. Hence the inextricable entanglement of mathematics with physics. (Do you recall, the Lucasian chair held by Barrow then Newton was a Mathematics chair?)

Of course mathematics is useful in understanding the physical world. I don't mean this as an insult, but some of your arguments here have been, shall we say, not completely rigorous (m such that 1/m –> A, A = w + g just made another appearance, for example!). I think Aleta, ellazimm, I, and some other participants are mainly interested in purging these arguments of mathematical errors, and perhaps investigating whatever holds up. I actually would like to see a rigorous argument for a finite past, based only on mathematics, logic, etc., that I can't knock over. daveS

Me_Think:

I think ladder is a poor metaphor for the topic under discussion. If there is a rung below, the man can move. There is nothing that stops the man from descending – unless the distance between 2 rungs is infinite.

I thought it was wonderful. How did the man get on to the rung above the rung you are talking about? Or did you just not think about that? Mung

This thread provides actual proof that one can begin at the top and descend down across an infinite number of posts. :) Mung

DS, I have no problem with a ladder rung labelled w say by way of a sticker on a roll with a label printer. Using the surreals tree, keep on going down the ladder tagging successive rungs as you go, taking away just 1 at a time. Can you reach to a zone finitely remote from 0 at ground level? Futility of attempted traversing of the endless, again. And it matters not that you have any number of onward rungs w+1 etc. above w. KF PS: The logic of structure and quantity is obviously highly relevant to making good sense of a world full of structure and quantity. Hence the inextricable entanglement of mathematics with physics. (Do you recall, the Lucasian chair held by Barrow then Newton was a Mathematics chair?) kairosfocus

F/N: observe the number-tree diagram to see how for surreals w - 1 etc is reasonable. Obviously for finite steps (no matter how arbitrarily large) these are still of general order of magnitude w. This provides no escape from the zone of endlessness. KF kairosfocus

KF #1154 I've never considered these mathematical issues to be very helpful in dealing with the real world except in a limited 'modelling' sense. But I can't argue against that interpretation. daveS #1157

I like mathematics as much as the next person, but it doesn’t have a much to do with my “worldview” or my religious beliefs.

My view as well. I don't see how this mathematical discussion sheds any light on faith or beliefs at all. Not saying it's worthless though. ellazimm

Aleta,

to Dionisio re 1151: Actually the vast, vast majority of the discussion has been about the purely mathematical topic of infinity, and not about “two opposite irreconcilable worldview positions regarding the ultimate reality.”

I think this needs to be emphasized. I have also been focused mainly on pure mathematics in this thread, although I have ventured occasionally into issues of mathematical philosophy (to the extent that I am capable of, anyway). And ironically, when asked to give the roughest sketch of how an infinite past could have occurred, I have to rely on a theistic premise! I like mathematics as much as the next person, but it doesn't have a much to do with my "worldview" or my religious beliefs. daveS

Me_Think,

An infinite past would mean time existed before Singularity. It would also mean that time existed as part of ’empty space’. That is not our current understanding of how universe started – the Quantum fluctuation created Space-time, thus it is erroneous to assume infinite past.

Yes, from what little I know about physics, I would agree. daveS

HeKS,

By “that” I mean that the man happens to be at any particular rung on the ladder at all. The problem of infinity is not how it could be possible to get from some particular point on the spectrum to the boundaried end. Rather, it’s how you manage to get onto any particular point in the spectrum at all.

Thanks, that does help me understand your position more clearly. Obviously no human would be capable of this. I have given several similar examples which I think are less implausible, anyway. Suppose there exists a god outside of time, who created our universe. This god can perceive every instant in our universe simultaneously. Could this god count down through all the natural numbers (ending in 0), in a beginningless process? I don't see how we can rule that out. Could this god simply note the passing of each second (as a clock)? This would leave out the counting part, but still could take place in a universe with an infinite past. Or maybe this god created our universe to be eternal (beginningless and endless), with infinitely many Big Bang/Big Crunch cycles. In any case, my primary concern is identifying fallacious arguments against an infinite past, rather than demonstrating the plausibility of an infinite past. daveS

Aleta, infinity and the driving force of endlessness beyond any particular finite value are foundational issues all through the thread. As is the premise that mathematics is best understood as the logic -- and linked logical study -- of structure and quantity, where structure is of course abstract and concrete and where quantities are a whole domain of reality. This thread is one of the most foundational discussions I have had at UD and such issues are inextricably entangled and intertwined with both reality and our views on reality. It seems that there is a sense that logical, structural, quantity-linked coherence is pivotal to a sound understanding of reality. In that context clarifying infinity, numbers, infinitesimals and even ordinary mathematical induction as well as stepwise finite stage progressions and linked algorithms including do forever loop structures has been a major issue. That seems to be why this thread persists at coming on 1200 comments and two full months in. The Somme ran what, five months, and Verdun (the mincer), ten. Come to think about it, precisely 100 years ago this year. Contrast the one day clash at Jutland, also 100 years ago this year. KF kairosfocus

to Dionisio re 1151: Actually the vast, vast majority of the discussion has been about the purely mathematical topic of infinity, and not about "two opposite irreconcilable worldview positions regarding the ultimate reality." Aleta

KF Visited 5,361 times, 268 visits today 1,152 comments posted Over 4,200 visits that did not post comments? How many of them anonymous? That seems like a lot of lurkers out there. Dionisio

HeKS @1142

The problem of infinity is not how it could be possible to get from some particular point on the spectrum to the boundaried end. Rather, it’s how you manage to get onto any particular point in the spectrum at all.

That seems like "il cuore" of the "Zankapfel" in this whole thread that was so skillfully started by KF's OP. It seems like your comment helped to confirm -and maybe further clarify- what KF and others had reiterated a number of occasions in this apparently endless discussion. KF's OP started this discussion referring to an earlier discussion on the same topic. The title of KF's informative OP pointed to the persons involved in that early argument. Perhaps the multiverses and other 'convoluted' ideas being promoted these days in some academic circles are intended to provide a different solution to the problem you explained -i.e. how to get the man on a given rung within a hypothetical ladder that never had a starting rung (borrowing the analogy that has been used here for illustration purpose, assuming I've understood it well). Again, it seems like the whole discussion boils down to the conflict between two opposite irreconcilable worldview positions regarding the ultimate reality. On one end, those who believe that ultimate reality is based on matter and energy, which can't be created nor destroyed, but only transformed from one into another (i.e. WYSIWYG), the idea of an eternal past is required, hence demanded and not open for any kind of compromise. On the other side, those of us who strongly believe that the Ultimate Reality is summarized in the very first verse of the canonical OT and divinely described through the apostle John by the end of the first century of this age of grace:

In the beginning was the Word, and the Word was with God, and the Word was God. He was in the beginning with God. All things were made through Him, and without Him was not any thing made that was made.

In between those two extremely opposite irreconcilable worldview positions there appear to be gazillion viewpoints, some of them friendly or even supportive of the ID proposition, while others lean more toward materialistic concepts. This international website seems like an "eintopf" made of a wide variety of opinions. Dionisio

KF You started this thread last January 31. Exactly two months later we see this: Popular Posts (Last 30 Days) Durston and Craig on an infinite temporal past . . . (2,309) A world-famous chemist tells the truth: there’s no… (2,209) Quantum Darwinism = Darwinism as woo-woo? (2,194) Homologies, differences and information jumps (1,384) An encounter with a critic of biological semiosis (1,322) Wow! Congratulations! Apparently your OP really touched the right nerve. :) Dionisio

MT, the issue is endlessness, and descending a ladder stretching endlessly into the sky, or inspecting the rooms in Hilbert's hotel from the far end [oops, sleepy -- ZONE], or having an endless punched tape or using algebraic style representations all come down to the same challenge of getting from the endlessly remote w-order zone to a zone finitely remote from a zero point. All of these and the case of the intervening endlessly large Sahara to be traversed in finite scale steps, join together to show the underlying incoherence of the attempt to traverse the endless span in any arbitrarily large but finite number of finite stage actually completed steps. Note, at 217 above, I actually laid out an algorithm that draws attention to the problem. In this context, I am fully justified to assert there is a fallacy of ending the endless, to focus the key incoherence. If you want an endless set, you have to specify an action powerful enough to give all at one go. That typically entails setting up a potential infinite then pointing across an ellipsis of endlessness, but the above shows how this has limits, even with ordinary mathematical induction. KF PS: Note, this has been an exploratory thread, and positions were arrived at through discussion. My conclusion is that the ellipsis of endlessness is a pivotal part of defining the successive counting sets and that beyond any particular such set we can represent with typical forms there will always be an onward endless succession. Trying to cross that span going up or down will be futile, if one resorts to finite stage successive steps. That is also why I adapted the 1/x catapult to show how we can use a mathematical wormhole to leap across the endlessness. In response to onward debates on the different symbolisations that use omega, I suggested a model of taking 1/x on mild infinitesimals that gets you to a w + g type value and hard ones that get you to something like w + w + k where being inside a pair of transfinite zone ellipses of endlessness gives the property, no first value as well as no last value. Such also brings to bear the importance of the interval [0,1] and how this can be used as a dual to the transfinite zone. In that context the surreals make sense of the jungle of numbers great and small. kairosfocus

HeKS @ 1142

Any given rung, however high the number from the ground, is still a finite number of rungs from the ground, but that very same rung is also infinintely many rungs away from infinity, which is where the man finds himself. When I said that the man would always be infinitely far from any rung you might choose, no matter how high the number, I didn’t mean he would be in the process of moving from one rung to another where those rungs would be infinitely far from the rung you had chosen

I think ladder is a poor metaphor for the topic under discussion. If there is a rung below, the man can move. There is nothing that stops the man from descending - unless the distance between 2 rungs is infinite. Me_Think

Dionisio

Yes, that’s an interesting point. Thank you. Please, note that at the end of the text you quoted @1145 there was a :) which did not get copied. :) Have a good day.

You too. HeKS

HeKS Yes, that's an interesting point. Thank you. Please, note that at the end of the text you quoted @1145 there was a :) which did not get copied. :) Have a good day. Dionisio

Dionisio

(*) at least the interlocutors could agree on disagreeing

We may well be approaching that point, but it's more satisfying to do that once you're reasonably sure that the parties to the conversation have at least properly understood each other's arguments. Then, if no agreement can be reached, so be it. At least you've hopefully had an interesting discussion. HeKS

#1143 addendum Here are some stats: KF started this thread two months ago: January 31, 2016. Since then it has been visited 5,329 times (268 visits today). How much longer will it go? No one knows. :) Can this discussion reach a settlement* (agreement)? It could, but I doubt it. (*) at least the interlocutors could agree on disagreeing. :) More stats: Popular Posts (Last 30 Days) A world-famous chemist tells the truth: there’s no… (2,439) Durston and Craig on an infinite temporal past . . . (2,335) Quantum Darwinism = Darwinism as woo-woo? (2,319) Homologies, differences and information jumps (1,470) An encounter with a critic of biological semiosis (1,322) Dionisio

HeKS This seemingly endless discussion had a beginning at KF's OP. However, one could argue that this topic has been discussed earlier too. KF's OP marks the start of the current discussion thread, but not the beginning of this topic discussion. :) Dionisio

daveS, I think I'm starting to better understand your position, but I think you're still missing a central point in my argument and it has us talking past each other.

If the rungs are in 1-1 correspondence with the natural numbers, and they are all separated by the same finite distance, say 1 foot, then no, the man can never be infinitely far from the ground, regardless of which rung he is on, regardless of whether he is going up or down, regardless of how he got there. If you disagree, I will be happy to defend that point.

I don't disagree. I agree with you and Aleta that if the man is on a rung of the ladder, however high the number of that rung from the ground, it will always be a finite number from the ground. I've never argued against that. But this completely misses my point. Consider this comment I made earlier:

The big problem here is that you are simply imagining that this man could actually be in movement from one rung to another on an actually infinite, beginningless ladder, with no explanation for how that could be happening at all.

By "that" I mean that the man happens to be at any particular rung on the ladder at all. The problem of infinity is not how it could be possible to get from some particular point on the spectrum to the boundaried end. Rather, it's how you manage to get onto any particular point in the spectrum at all. Any given rung, however high the number from the ground, is still a finite number of rungs from the ground, but that very same rung is also infinintely many rungs away from infinity, which is where the man finds himself. When I said that the man would always be infinitely far from any rung you might choose, no matter how high the number, I didn't mean he would be in the process of moving from one rung to another where those rungs would be infinitely far from the rung you had chosen. I meant he wouldn't be able to get onto any particular rung at all and still be able to say that he had descended from infinity. Instead, the man would be in the same position you would be in if I asked you to count down from infinity to zero. Just like you would be stuck at infinity with no next number you could legitimately select in the project of counting down from infinity to zero, he would likewise be stuck at the state of being in infinity and without the ability to identify any rung that he could climb onto in order to begin his descent where he would still be able to say at the end that he had actually climbed down an infinite number of rungs. In both cases, the entirety of the problem of traversing infinity lies in the first step, in transitioning from an infinite state to a particular finite position on the spectrum headed towards the boundaried end, because what cannot be traversed is the change of state from infinite to finite. And so by envisioning a scenario where a man is in the process of an infinitely long descent down a ladder with an infinite number of rungs running in the upwards direction, you have already skipped right over the problem with the scenario and pushed the incoherent aspect back out of view. [For the record, I know I'm the one who used the illustration, having been inspired by KF, but I was using it to illustrate a scenario that I was arguing was incoherent and impossible] HeKS

daveS @ 1135

For example, Whitrow asserts that if there were an infinite past, then there must necessarily have existed a point in time infinitely many seconds before the present, and then argues based on this premise. I believe I (and several others) have shown this premise to be false, therefore Whitrow’s argument fails. Obviously there exist erroneous arguments that purport to show the past must be finite; I believe Whitrow’s is one of them.

An infinite past would mean time existed before Singularity. It would also mean that time existed as part of 'empty space'. That is not our current understanding of how universe started - the Quantum fluctuation created Space-time, thus it is erroneous to assume infinite past. Me_Think

I should proofread!

Well that solves all our problems. But if you are at w, I hope you don’t slip, cause it's a looonnnnggggg way to the next rung.

Aleta

Well that solves all our problems. But if you at w, I hope you don't slip, cause its a looonnnnggggg way to the next rung. Aleta

Aleta, Yes, an extremely unusual ladder! With the rungs arranged like these ordinals: 0, 1, 2, 3, ..., ω So you attach an ω rung at the end of the "far zone". :-) I don't know if this issue is what HeKS has in mind, but I thought I'd throw it out there. daveS

I thought we had agreed that w is a number about the infinite number of natural numbers, not a number in the set of natural numbers. But maybe that's what you mean by an "especially unusual infinite" ladder. :-) And yes, no matter what rung of the ladder you are on, you are a finite number of rungs from 0. Aleta

HeKS, To address this part of your post:

If you are saying that the man would never be infinitely far from any rung you might choose, then what you are doing is simply changing an actual infinite into a potential, and this is why I said earlier that, for all intents and purposes, you are confusing the past for the future. The statement that the man would never be infinitely far from any given rung would be perfectly coherent if he were starting at the ground and climbing up the ladder towards the infinite, in the same way we can say that even if the universe continues to exist forever, we will never arrive at a day that is infinitely far from the Big Bang. But this simply doesn’t work if we want to say that the man has climbed down the ladder from an infinitely high and unboundaried “position”, or that we have arrived at the present after an infinite past-time, because both of those scenarios involve a traversal of an actual infinite, not a potential infinite. Whether intentionally or not, your responses continue to effectively convert the former into the latter. If you want to say that we have not shown an actually infinite succession and its traversal to be incoherent, you can’t do it by pointing to the coherence of the existence and traversal of only a potentially infinite succession. But this is what you are doing every time. I’m not sure what other way I can say it.

First, let me make a correction: I should have said that the fact that this ladder is infinitely long is not sufficient to guarantee that some rungs of the ladder will be infinitely far from the ground. If the rungs are in 1-1 correspondence with the natural numbers, and they are all separated by the same finite distance, say 1 foot, then no, the man can never be infinitely far from the ground, regardless of which rung he is on, regardless of whether he is going up or down, regardless of how he got there. If you disagree, I will be happy to defend that point. If we are talking about an especially unusual infinite ladder, for example one where there is a distinguished rung "numbered" ω, which is further away from the ground than any other naturally-numbered rung, then yes, if the man were standing on that one, then he would be infinitely far from the ground. That's a very strange situation though, since the man would be unable to step down to the next lower rung. A hypothetical infinite ladder need not have such an ω rung of course. Do you have any objections to this? daveS

HeKS,

You are basically saying: “Here’s a proposition on the table. A man is descending an infinite ladder. There was no beginning or initiation to his descent, but he nonetheless manages to traverse all the infinite rungs of the ladder from infinite beginninglessness to reach the last rung closest to the ground and then step off onto the ground. Is this possible?”

I think you still misunderstand my position. More precisely, I'm asking "do the specific arguments presented by WLC, Durston, Whitrow, etc. show that it is impossible"? I claim they do not. If I point out some fallacy in their arguments, then I have demonstrated this. For example, Whitrow asserts that if there were an infinite past, then there must necessarily have existed a point in time infinitely many seconds before the present, and then argues based on this premise. I believe I (and several others) have shown this premise to be false, therefore Whitrow's argument fails. Obviously there exist erroneous arguments that purport to show the past must be finite; I believe Whitrow's is one of them. It's not my job to explain how an infinite past is possible or coherent; I'm simply attempting to weed out bad arguments which claim to show the past must be finite. daveS

daveS, Let me frame the conversation this way. You are basically saying: "Here's a proposition on the table. A man is descending an infinite ladder. There was no beginning or initiation to his descent, but he nonetheless manages to traverse all the infinite rungs of the ladder from infinite beginninglessness to reach the last rung closest to the ground and then step off onto the ground. Is this possible?" KF and I have said it is not possible and we have offered various reasons for why it would not be possible, with these reasons standing as at least potential defeaters of the coherency of the proposition that has been put on the table. If you want to maintain that our defeaters fail to establish the incoherency of the proposition, then you need to offer some kind of reasoning that addresses our defeaters. Defeaters of our defeaters, if you will. Simply offering explanations that ignore the infinity aspect of the problem and replace it with a more coherent finite problem does not count as addressing our defeaters. Throughout our discussion you have essentially been saying, "I'm not convinced that scenario X is incoherent because this other scenario Y seems perfectly coherent", where X and Y are not equivalent, and scenario Y is coherent specifically because it approaches the issue backwards and avoids the problem in question entirely. In other words, it's not that our arguments have not stood up to scrutiny. Rather, it's that what has been scrutinized is not actually our arguments in the first place. We are addressing the intractable end of the problem. You have skipped over addressing the intractable end of the problem by approaching from the tractable end and simply assuming the real problem has already somehow been resolved behind the curtain by the time you meet up with the man who is in the process of traversing the infinite, offering no explanation for how he could ever have gotten to a place where you could have met up with him.

[HeKS:]The man would always be infinitely far from any particular rung you might choose.

My response was that the man would never be infinitely far from any particular rung you might choose. And we can see that by setting up a coordinate system. Are we agreed on that point now?

No, we are definitely not agreed on that point now (unless you're simply asking me if I agree that you are making that claim). The big problem here is that you are simply imagining that this man could actually be in movement from one rung to another on an actually infinite, beginningless ladder, with no explanation for how that could be happening at all. If you are saying that the man would never be infinitely far from any rung you might choose, then what you are doing is simply changing an actual infinite into a potential, and this is why I said earlier that, for all intents and purposes, you are confusing the past for the future. The statement that the man would never be infinitely far from any given rung would be perfectly coherent if he were starting at the ground and climbing up the ladder towards the infinite, in the same way we can say that even if the universe continues to exist forever, we will never arrive at a day that is infinitely far from the Big Bang. But this simply doesn't work if we want to say that the man has climbed down the ladder from an infinitely high and unboundaried "position", or that we have arrived at the present after an infinite past-time, because both of those scenarios involve a traversal of an actual infinite, not a potential infinite. Whether intentionally or not, your responses continue to effectively convert the former into the latter. If you want to say that we have not shown an actually infinite succession and its traversal to be incoherent, you can't do it by pointing to the coherence of the existence and traversal of only a potentially infinite succession. But this is what you are doing every time. I'm not sure what other way I can say it. HeKS HeKS

HeKS,

I’m not saying that you’re thinking of the man as climbing in reverse time order, per se.

Yes, of course, I understood the point you were making.

I’m saying that you’re counting successive steps from an origin point at the ground heading towards a man that is in transit, allegedly descending down an infinite ladder that had no boundary in the measurement of direction from which he is travelling.

Yes, but that is simply how coordinates work, right? I don't know any other way to track the movement of the man as he descends. Let me bring back some context. In your first post, you stated:

The man would always be infinitely far from any particular rung you might choose.

My response was that the man would never be infinitely far from any particular rung you might choose. And we can see that by setting up a coordinate system. Are we agreed on that point now?

At some arbitrarily large number of rungs you imagine that you have found a man climbing down, rung after rung, and think he has proceeded from some infinite, undefined, unboundaried location.

I'm assuming that he has been climbing down for eternity from an infinite ladder, and testing whether there are obvious logical problems with that (I haven't found any).

In doing this, you are accounting for your own traversal of the ladder from an absolute beginning on the ground towards an endless, infinite, unboundaried location, but you are not accounting for the man’s traversal of the ladder from a beginningless, infinite, unboundaried location with the no true origin point.

By setting an arbitrary origin point somewhere along the ladder between the ground and the infinite beginninglessness you are again skipping right over the main the problem, which is that in order for the man to have reached that arbitrary origin – say 10^150 rungs from the ground (or seconds ago) – he would first have had to have traversed an infinite number of rungs to reach the one that is 10^150 rungs away from the ground.

Then why don’t you offer some explanation for how that might coherently take place without starting your count from the end point and imagining that you have caught up with the fellow on the ladder mid-climb at some arbitrarily large number of rungs from the ground.

Well, this seems to be part of the problem. We have offered reasons why this seems to be completely incoherent, and have at the very least made a case that it is not obviously coherent. You don’t seem to have offered a response to these points that doesn’t simply reframe the problem in a way that ultimately sweeps it under the rug. Your responses have reasonably established the coherence of something that was not in question (i.e. the ability to traverse a very large sequence), but they have not even begun to defend the coherence of the thing which is in serious question (i.e. the ability to traverse an infinite sequence).

I think these all fall into the same category, so I'll address them at once. I'm not trying to account for this traversal or explain how he did it, or even prove that the idea is coherent. I'm asking if we can show that it is incoherent or impossible through simple logic or mathematics, as WLC, KF, and others say. So the burden is not on me to prove that an infinite past is possible; my question is whether the arguments/proofs presented by WLC, et al, stand up to scrutiny. Several authors (whose papers I cited above) have stated that these arguments fail, and so far, I agree. I think my position is probably much less ambitious than you might have believed. daveS

daveS,

[HeKS:]But any time you point out that a given event or a given rung in a ladder is a finite distance from the direction of measurement that has a boundary, you are attempting (intentionally or not) to transfer the coherence of an ascent from an absolute origin point to a descent from no origin point whatsoever.

I don’t think so. If we’re going to use the integers (or real numbers) as our time axis, then we have to place the origin at some point in time, whether it is at the moment the man reaches the ground or at some other point in the past (or future, really). The placement of this origin is actually completely arbitrary. It is true that this will always result in there being a finite time interval between the man 1) stepping on a particular rung and 2) stepping on the ground, but it doesn’t mean I am thinking of the man climbing the ladder in reverse time order.

I'm not saying that you're thinking of the man as climbing in reverse time order, per se. I'm saying that you're counting successive steps from an origin point at the ground heading towards a man that is in transit, allegedly descending down an infinite ladder that had no boundary in the measurement of direction from which he is travelling. At some arbitrarily large number of rungs you imagine that you have found a man climbing down, rung after rung, and think he has proceeded from some infinite, undefined, unboundaried location. In doing this, you are accounting for your own traversal of the ladder from an absolute beginning on the ground towards an endless, infinite, unboundaried location, but you are not accounting for the man's traversal of the ladder from a beginningless, infinite, unboundaried location with no true origin point.

[HeKS:]If the man is descending from infinity, which is a lack of any boundary point at all, how can the rungs be finitely-numbered?

Well, we have an infinite supply of integers (positive and negative). If we set the origin of our coordinate system at the present, when the man reaches the ground, then the rungs could have numbers in the set {…, -3, -2, -1}. If we set the origin to be 10^150 seconds ago, then the rungs could have numbers {…, 10^150 – 3, 10^150 – 2, 10^150 – 1}. In either case, they all have finite-number labels.

This is why I said:

The only non-arbitrary way that it would be possible for the rungs to be finitely numbered is if you’re numbering from the boundaried end, which means counting in ascending order from the ground up

By setting an arbitrary origin point somewhere along the ladder between the ground and the infinite beginninglessness you are again skipping right over the main problem, which is that in order for the man to have reached that arbitrary origin - say 10^150 rungs from the ground (or seconds ago) - he would first have had to have traversed an infinite number of rungs to reach the one that is 10^150 rungs away from the ground. And you could increase that arbitrary origin of -10^150 and make it -10^500, -10^5,000,000, and no matter how far back you move the arbitrary origin from the ending point (e.g. the ground, the present, whatever), the man would have had to have first traversed an infinite number of rungs to reach that arbitrarily selected rung as well. However many rungs you assign finite-number labels to moving from the ground towards infinity, there is an infinite number of rungs that must be traversed before reaching any rung that has a finite-number label assigned to it. No matter how high you count starting from the ground, you never even begin to address the real problem.

Yes, I don’t see any reason why an actual infinite succession in the real world is incoherent, especially a temporal succession. KF and I earlie discussed models in cosmology (some still in active development) which posit an infinite past, and perhaps infinitely many Big Bang/Big Crunch cycles. The Steady State model also was taken seriously for quite some time. It would seem odd to me that all those cosmologists missed this elementary proof of the impossibility of such models.

Really? It shouldn't seem odd to you at all. The steady state model was championed by Hoyle specifically because he didn't like the theistic (and even Biblical) implications of the Big Bang model. In fact, a strong dislike for the implications of the Big Bang was a driving force in the development and defense of subsequent infinite past-time models, right down to the present. Arthur Eddington, an astronomer, said this: "Philosophically the notion of a beginning of the present order is repugnant to me. I should like to find a genuine loophole. I simply do not believe the present order of things started off with a bang ... the expanding Universe is preposterous ... it leaves me cold." The general state of affairs was summed up pretty well by an Astrophysicist named C.J. Isham. Here's what he said: "Perhaps the best argument in favour of the thesis that the Big Bang supports theism is the obvious unease with which it is greeted by some atheist physicists. At times this has led to scientific ideas, such as continuous creation or an oscillating universe, being advanced with a tenacity which so exceeds their intrinsic worth that one can only suspect the operation of psychological forces lying very much deeper than the usual academic desire of a theorist to support his or her theory." Really, the ongoing attempts of physicists and cosmologists to construct infinite past-time models should not be at all surprising for at least two reasons. First, Cosmologists (especially of the modern variety) have no special genius for philosophy. Second, they have a pressing motive for trying to "find a genuine loophole" in the need for an absolute beginning.

I don’t see why a beginningless traversal couldn’t make progress, and actually reach “completion”.

Then why don't you offer some explanation for how that might coherently take place without starting your count from the end point and imagining that you have caught up with the fellow on the ladder mid-climb at some arbitrarily large number of rungs from the ground. Any explanation that involves these elements will explain only how one might traverse an extremely large succession in a stepwise fashion - which is a possibility that is not in question here - but it will do nothing to explain how one might traverse the infinite number of rungs that must be traversed before ever reaching whatever incredibly large rung count you might specify. You said:

But I’m not trying to prove that the infinitely-long descent is possible, I’m asking KF or you to prove to me that it’s incoherent.

Well, this seems to be part of the problem. We have offered reasons why this seems to be completely incoherent, and have at the very least made a case that it is not obviously coherent. You don't seem to have offered a response to these points that doesn't simply reframe the problem in a way that ultimately sweeps it under the rug. Your responses have reasonably established the coherence of something that was not in question (i.e. the ability to traverse a very large sequence), but they have not even begun to defend the coherence of the thing which is in serious question (i.e. the ability to traverse an infinite sequence). HeKS

HeKS,

The ability to coherently ascend from one direction does absolutely nothing to increase the coherence of descending from the other direction.

Agreed.

But any time you point out that a given event or a given rung in a ladder is a finite distance from the direction of measurement that has a boundary, you are attempting (intentionally or not) to transfer the coherence of an ascent from an absolute origin point to a descent from no origin point whatsoever.

I don't think so. If we're going to use the integers (or real numbers) as our time axis, then we have to place the origin at some point in time, whether it is at the moment the man reaches the ground or at some other point in the past (or future, really). The placement of this origin is actually completely arbitrary. It is true that this will always result in there being a finite time interval between the man 1) stepping on a particular rung and 2) stepping on the ground, but it doesn't mean I am thinking of the man climbing the ladder in reverse time order.

So, I repeat, the problem seems to be that you are picturing a man descending an infinite ladder in mid-climb. This is like picturing a person counting down from infinity as saying, “1,000,000,000,000,003; 1,000,000,000,000,002; 1,000,000,000,000,001; …” Your ability to visualize a particular in-progress stage does nothing to argue for the coherence of the scenario as a whole, or for the possibility for the person to ever reach the particular stage you have visualized.

As a human, I really only have the ability to picture the man in mid-descent. An omnipotent deity who exists outside of time and who can perceive all timepoints in our universe simultaneously would have a different perspective. But I'm not trying to prove that the infinitely-long descent is possible, I'm asking KF or you to prove to me that it's incoherent.

If the man is descending from infinity, which is a lack of any boundary point at all, how can the rungs be finitely-numbered?

Well, we have an infinite supply of integers (positive and negative). If we set the origin of our coordinate system at the present, when the man reaches the ground, then the rungs could have numbers in the set {..., -3, -2, -1}. If we set the origin to be 10^150 seconds ago, then the rungs could have numbers {..., 10^150 - 3, 10^150 - 2, 10^150 - 1}. In either case, they all have finite-number labels.

The question is how he could ever have gotten to any particular rung at all if he was supposed to be coming from a direction without any boundary. You seem to simply be assuming that an actualized infinite succession in the real world is itself a coherent concept, and then picturing a person in-transit traversing it.

Yes, I don't see any reason why an actual infinite succession in the real world is incoherent, especially a temporal succession. KF and I earlie discussed models in cosmology (some still in active development) which posit an infinite past, and perhaps infinitely many Big Bang/Big Crunch cycles. The Steady State model also was taken seriously for quite some time. It would seem odd to me that all those cosmologists missed this elementary proof of the impossibility of such models.

If a succession of rungs is infinite and has no beginning then it is impossible for any traversal of the succession to ever begin or make any progress, in the same way it is impossible for a person to begin counting down from infinity or to ever make any progress in counting down from infinity.

I don't see why a beginningless traversal couldn't make progress, and actually reach "completion". And again, there is no "counting down from infinity" here. My scenario involves finite integers only.

The latter is impossible because an infinite set of numbers could never be actualized from the abstract to the concrete (even just within the mind) for the task to be begun or for any progress to be made.

I guess I just don't see why such an actualization couldn't take place. daveS

daveS, In my last post I was trying to illustrate for you the problem with trying to establish the possibility of an infinite series of past events that have finally arrived at the present by arguing that any given event would only be a finite number of seconds or events into the past. That fact no more helps to establish the possibility of traversing from an infinite past to the present than counting upwards towards infinity from 1 would help a person who is trying to count down from infinity. The ability to coherently ascend from one direction does absolutely nothing to increase the coherence of descending from the other direction. But any time you point out that a given event or a given rung in a ladder is a finite distance from the direction of measurement that has a boundary, you are attempting (intentionally or not) to transfer the coherence of an ascent from an absolute origin point to a descent from no origin point whatsoever. So, I repeat, the problem seems to be that you are picturing a man descending an infinite ladder in mid-climb. This is like picturing a person counting down from infinity as saying, "1,000,000,000,000,003; 1,000,000,000,000,002; 1,000,000,000,000,001; ..." Your ability to visualize a particular in-progress stage does nothing to argue for the coherence of the scenario as a whole, or for the possibility for the person to ever reach the particular stage you have visualized. You asked me:

Can you point out the incoherence with that without referring to the future, or to any “ascent stage”?

But look at your own description of what you're envisioning:

In the scenario I envision, the man is descending through finite-numbered rungs all the way.

If the man is descending from infinity, which is a lack of any boundary point at all, how can the rungs be finitely-numbered? The only non-arbitrary way that it would be possible for the rungs to be finitely numbered is if you're numbering from the boundaried end, which means counting in ascending order from the ground up, which returns us to the problem of entirely missing the incoherence of the whole scenario by visualizing it already in progress and from the wrong direction. The question is not how the man could get to the ground once he is at a particular rung that is a finite number of rungs from the ground. The question is how he could ever have gotten to any particular rung at all if he was supposed to be coming from a direction without any boundary. You seem to simply be assuming that an actualized infinite succession in the real world is itself a coherent concept, and then picturing a person in-transit traversing it. But the ultimate problem here is that the entire scenario is incoherent. If a succession of rungs is infinite and has no beginning then it is impossible for any traversal of the succession to ever begin or make any progress, in the same way it is impossible for a person to begin counting down from infinity or to ever make any progress in counting down from infinity. The latter is impossible because an infinite set of numbers could never be actualized from the abstract to the concrete (even just within the mind) for the task to be begun or for any progress to be made. The former is impossible for the same reason. HeKS

HeKS,

t seems that you picture winding the tape back from the point you find the man on a certain rung, and as you do you see the man climbing up the ladder and no matter how far back you go he’s in the process of climbing to another rung, but it’s a rung that is a finite distance from the ground. In essence you seem to be assessing the possible coherence of this scenario by envisioning yourself (or some imaginary camera) zooming up the ladder from the ground until you eventually run into this man, mid-climb, on a rung of the ladder an extremely large distance from the ground. But as I indicated in my last comment, to do so would be to visualize it from the wrong direction – a direction which has a specific beginning point (i.e. the ground) – and thereby avoid the conceptual problem altogether.

I actually agree that looking at the situation this way--from the wrong direction---is generally not useful. I think it's important to focus only on the descent of the ladder.

The problem we’re discussing here is the notion of traversing an actually infinite succession. An infinite succession is not just a really super big number but one that lacks any defining boundary point in at least one direction of measurement. If I were to tell you to start at the number 1 and count up to infinity, you could start counting, “1, 2, 3, 4 …”, but no matter how long you lived, even if you were immortal and never died, you would never finish counting. You would only ever be a finite number away from 1. But the key point here is that you could at least start the task of counting and measurably progress in that task because you know that if you start at 1, your next whole number is 2, then 3, etc.

Yes, agreed.

But now suppose I told you to count down from infinity to zero for me. After saying, “infinity”, what would be the very next number that you would say? I start tapping my fingers waiting for you to say the first next number less than infinity. I raise my eyebrows in expectation, but you just sit there with a furrowed brow. Feeling bad for you, I offer to help. “How about this? How about if I start counting upwards to infinity from 1 and when I reach the right number for you to start your count down from infinity, you let me know, then we can count it down together. Ready? 1, 2, 3, …” So here’s the question: At what point will I reach a number counting upwards to infinity that you can say, “There, that’s it, that’s my next number. Let’s count down”?

Well, counting down from "infinity" (in order) is impossible. But on the other hand, there is no rung labeled infinity on the ladder, just as "minus infinity" is not an integer. In the scenario I envision, the man is descending through finite-numbered rungs all the way.

And so it is with the man on the ladder. If the man is supposed to be descending an infinite ladder towards the ground from the direction of measurement that has no boundary, then it doesn’t matter how many rungs you ascend the ladder from the ground towards the direction of measurement that has no boundary, because you will never reach a rung that is the next rung in the man’s downward climb. Whatever rung you climb up to, it will be a finite distance from the ground but an infinite distance from the next rung in the man’s descent, because it would be impossible for the man to make any progress from the direction of measurement that has no boundary. And never the twain shall meet.

I think this illustrates the issues with "running the tape backwards" so that the man appears to be ascending the ladder. I would recommend not even bringing that up. The scenario involves the man descending throughout an infinite past, until he reaches the ground at the present, say. The bottom line is, I'm not assuming the man first climbed up the ladder, then reversed direction. Edit: And notice if you assume the man first ascends then descends, that implies the descent has a beginning, which I am assuming is not the case.

In principle, I agree. The reason I’m addressing events going into the future is because if you conceptualize “ending a beginningless sequence” by moving backwards from the ending towards the direction of the beginningless, then you are changing the concept of “ending the beginningless” into the concept of “beginning the endless”, but the two concepts are not in any way comparable.

Yes, I agree that it is usually unproductive thinking of "ending the beginningless" in reverse order. I'm sure I have done it a few times here, mainly to draw out the contrast between ω and ω*. I will suggest we try abstaining from thinking and writing about these sequences in reverse time order. So the man is descending the infinite ladder, period. Can you point out the incoherence with that without referring to the future, or to any "ascent stage"? daveS

KF,

DS, I think the issue is that endlessness is not being taken at full required force. Please see the pink vs blue punched tape examples.

I can assure you that I fully understand the tapes example. Regarding your usage of "endless", if all you mean is that for any positive integer k, cells number k or greater in one tape can be put into 1-1 correspondence with all the cells of the other, yes, I think we all get it. We are all very familiar with that concept. We are all taking it at full required force.

If one is to claim to traverse and exhaust or end the endless through a stepwise finite stage process — regardless of speed and/or duration of said process — that is to go to an incoherence. You can try to point across the ellipsis and impose something on all members of the set, but even that has its limits. KF

Well, I asked something of the form P∧¬P, rather than a nonspecific claim of incoherence. Can you make the contradiction explicit? Once more, "ending the endless" does not do, for reasons I've stated multiple times. daveS

daveS #1121

[HeKS:]As such, the absence of any beginning point for the man to have started a descent means that no matter what particular rung you might choose, however far from the ground it might be, the man could never have gotten even to that rung, much less to the ground. The man would always be infinitely far from any particular rung you might choose.

I don’t see how the last sentence follows from anything earlier in your post or any mathematical theorem. There is a clear correspondence between the natural numbers and the rungs of the ladder. Any two natural numbers are separated by a finite distance. Hence at any particular time in the past, the man would be finitely many rungs off the ground.

In my opinion, the problem you're having is that your ability to visualize a man mid-climb, on a particular rung up from the ground at a particular time, with a series of other rungs running off to a vanishing point above him, is tricking you into thinking that the overall scenario is coherent. It isn't. It seems that you picture winding the tape back from the point you find the man on a certain rung, and as you do you see the man climbing up the ladder and no matter how far back you go he's in the process of climbing to another rung, but it's a rung that is a finite distance from the ground. In essence you seem to be assessing the possible coherence of this scenario by envisioning yourself (or some imaginary camera) zooming up the ladder from the ground until you eventually run into this man, mid-climb, on a rung of the ladder an extremely large distance from the ground. But as I indicated in my last comment, to do so would be to visualize it from the wrong direction - a direction which has a specific beginning point (i.e. the ground) - and thereby avoid the conceptual problem altogether. The problem we're discussing here is the notion of traversing an actually infinite succession. An infinite succession is not just a really super big number but one that lacks any defining boundary point in at least one direction of measurement. If I were to tell you to start at the number 1 and count up to infinity, you could start counting, "1, 2, 3, 4 ...", but no matter how long you lived, even if you were immortal and never died, you would never finish counting. You would only ever be a finite number away from 1. But the key point here is that you could at least start the task of counting and measurably progress in that task because you know that if you start at 1, your next whole number is 2, then 3, etc. But now suppose I told you to count down from infinity to zero for me. After saying, "infinity", what would be the very next number that you would say? I start tapping my fingers waiting for you to say the first next number less than infinity. I raise my eyebrows in expectation, but you just sit there with a furrowed brow. Feeling bad for you, I offer to help. "How about this? How about if I start counting upwards to infinity from 1 and when I reach the right number for you to start your count down from infinity, you let me know, then we can count it down together. Ready? 1, 2, 3, ..." So here's the question: At what point will I reach a number counting upwards to infinity that you can say, "There, that's it, that's my next number. Let's count down"? The answer is quite obviously never. No matter how high I count, I will never reach a number high enough for you to join me in starting to count down to zero. My count will always be a finite distance from 1 and will always be infinitely too low for you join me in counting back down. There will never come a time where you can make any progress whatsoever in your count from infinity to zero. And so it is with the man on the ladder. If the man is supposed to be descending an infinite ladder towards the ground from the direction of measurement that has no boundary, then it doesn't matter how many rungs you ascend the ladder from the ground towards the direction of measurement that has no boundary, because you will never reach a rung that is the next rung in the man's downward climb. Whatever rung you climb up to, it will be a finite distance from the ground but an infinite distance from the next rung in the man's descent, because it would be impossible for the man to make any progress from the direction of measurement that has no boundary. And never the twain shall meet. Even if we allow for the possibility that such an infinite ladder could exist, if you start climbing it from the ground and towards its direction of measurement that lacks a boundary and you eventually run into a man climbing down it towards the ground, you can conclude with certainty that the man climbed onto the ladder at some particular, finitely numbered rung and started his climb down from that specific place and time.

On the other hand, if the past is beginningless then we immediately find ourselves with an actual infinite number of past days, minutes, seconds or events that have been traversed, one at a time, to arrive at the present. In other words, we have walked into a field and found a man stepping off the last rung of an infinite ladder, finishing an infinite climb that he never started.

Yes. Very strange, and obviously not possible for a mortal human who exists in time.

It's not just very strange. It's logically incoherent.

I think I agree with the part of your first sentence which says that considering infinite sequences of events going into the future does not help us with the past. I’m not clear on what you’re concluding, however. I will say that, as we are discussing potential “beginningless” sequences (or sets of order type ?*), then ideally we shouldn’t even have to bring up sequences of events going into the future. The two situations are not symmetrical, and having both types of sequences in the same discussion (and labeling both “endless”, certainly!) just adds to the confusion.

In principle, I agree. The reason I'm addressing events going into the future is because if you conceptualize "ending a beginningless sequence" by moving backwards from the ending towards the direction of the beginningless, then you are changing the concept of "ending the beginningless" into the concept of "beginning the endless", but the two concepts are not in any way comparable. For us in the present, the existence of an infinite past would be a case of "ending the beginningless". Conceptualizing this a starting from the present and moving backwards in time along a negative timeline would be to reconceptualize it as "beginning the endless", and thereby to reconceptualize an actually infinite past as being comparable to a potentially infinite future. Take care, HeKS HeKS

DS, I think the issue is that endlessness is not being taken at full required force. Please see the pink vs blue punched tape examples. If one is to claim to traverse and exhaust or end the endless through a stepwise finite stage process -- regardless of speed and/or duration of said process -- that is to go to an incoherence. You can try to point across the ellipsis and impose something on all members of the set, but even that has its limits. KF PS: I am specifically interested in causal chains of events from the remote past to now, e.g. singularity, expansion, galaxy formation, sol system and planet formation, OOL, OO Biodiversity, OO humanity, generations of ancestry down to us. Beyond the singularity, whatever triggered it, and so forth. Thus, we see a chain of causal succession. This chain is capable of being tagged ordinally. kairosfocus

Yeah, my wife was disappointed too. Her bracket was in ruins by that point anyway though. daveS

It's really too bad that E_0 isn't going to pan out! :-) Aleta

KF, One more significant correction to the end of #1120:

If there were, you should be able to display something of the form P∧¬P that follows from my posts.

daveS

KF,

DS, physical reality is causally connected in stages similar to stepping down rungs of a ladder and that is what allows applying a successive cumulative sequence to the process. Those who object to causality in physics need to ponder a fire and what is going on with heat, fuel, oxidiser and chain reaction. Note, necessary enabling factors and sufficient clusters of factors for something to begin or to continue in being, here a fire. Then, extend this case through family resemblance to many others. KF

Again, I'm not objecting to causality in general. I'm just saying I'm not assuming any causal relationships between the E_k. For example, say E_0 is the event of me choosing Kansas to win the NCAA tournament and E_(-1) is the event of some supernova exploding in the Andromeda galaxy (which could have happened, as far as we know). Maybe E_(-2) was AlphaGo winning game 5, where times are measured relative to some inertial reference frame. Clearly it is impossible for there to be any causal relationship between E_(-1) and E_0 or E(-1) and E_(-2); likewise, I doubt AlphaGo had any influence on my choosing Kansas, or vice-versa. Edit: Correction to #1120:

I [not "A"] reluctantly accept it if you insist on using “endless” as a synonym for “infinite”, but as I stated above, this invites confusion between sets of order type ω and ω*.

daveS

HeKs, Thanks, thought experiments are always welcome. Here's the key disagreement I have with your post:

As such, the absence of any beginning point for the man to have started a descent means that no matter what particular rung you might choose, however far from the ground it might be, the man could never have gotten even to that rung, much less to the ground. The man would always be infinitely far from any particular rung you might choose.

I don't see how the last sentence follows from anything earlier in your post or any mathematical theorem. There is a clear correspondence between the natural numbers and the rungs of the ladder. Any two natural numbers are separated by a finite distance. Hence at any particular time in the past, the man would be finitely many rungs off the ground.

Your notion that one might “end the beginningless” seems to come from an idea that there is some kind of symmetry between the future and the past with regard to infinities, but there isn’t. If we assume that the universe will simply go on existing forever, then the future would constitute a potential infinite, but as we move into the future, no matter how far we go, there would only ever be a finite number of days that had passed since the Big Bang and we would never reach a point where the universe was infinitely old and an infinite succession of days, minutes, seconds or events had been traversed.

I agree completely with the fact that the concepts of future and past infinities are not symmetrical (which is why I have been citing the distinction between ω and ω* repeatedly). I believe this has been a stumbling block in this entire discussion. This is what I believe: 1) If the past is finite, then at any point in time, only finitely many days have elapsed since the Big Bang. 2) If the past is infinite, then at any point in time, even 10^150 years ago, the universe already had an infinite past.

On the other hand, if the past is beginningless then we immediately find ourselves with an actual infinite number of past days, minutes, seconds or events that have been traversed, one at a time, to arrive at the present. In other words, we have walked into a field and found a man stepping off the last rung of an infinite ladder, finishing an infinite climb that he never started.

Yes. Very strange, and obviously not possible for a mortal human who exists in time.

The logic that allows us to recognize the future as a potential infinite that is never actualized because every particular point, day or event is only a finite distance from the Big Bang simply does not help us with the past. It doesn’t matter that every negative point going into an infinite past would be a finite distance from whatever zero-point we choose (e.g. the Big Bang) because the issue isn’t going into an infinite past … it’s having come from an infinite past. If you try to weigh the logical coherence of an infinite past by picturing a sequence that starts at a selected zero-time and proceeds infinitely into the past along a negative timeline then you’re going to come to false conclusions because you’re starting in the wrong place and, for all intents and purposes, confusing the past for the future.

I think I agree with the part of your first sentence which says that considering infinite sequences of events going into the future does not help us with the past. I'm not clear on what you're concluding, however. I will say that, as we are discussing potential "beginningless" sequences (or sets of order type ω*), then ideally we shouldn't even have to bring up sequences of events going into the future. The two situations are not symmetrical, and having both types of sequences in the same discussion (and labeling both "endless", certainly!) just adds to the confusion. daveS

KF,

DS, pardon but this begins to look like futile circles of semantics. Beginningless entails an endless past, one that recedes further into the past forever, beyond any arbitrarily large but finite value.

I would agree with the second sentence if we replaced the word "endless" with infinite. A reluctantly accept it if you insist on using "endless" as a synonym for "infinite", but as I stated above, this invites confusion between sets of order type ω and ω*.

That has been my point and you know that I find for cause a serious defect in claims about infinitely many finite and discrete, finite stage incremented values constituting a set of infinite cardinality — whether positive or negative direction. Such a set by definition if fully expressed MUST entail what we cannot get to in such discrete steps, a transfinite value that involves in itself a completed endlessness.

A question that just occurred to me: What, if any, sets of infinite cardinality do you accept without issue, if we remove the constraint about them being constructed in discrete steps and so forth?

In other words I am finding here assertions that can be put in words but which on inspection involve mutually contradictory required characteristics, similar to a square circle or a triangle with five vertices etc. KF

I can understand philosophical objections to "completed" infinite sets, but I don't think there are any obvious contradictions in the statements I have made. If there, you should be able to display something of the form P∨¬P that follows from my posts. daveS

DS, physical reality is causally connected in stages similar to stepping down rungs of a ladder and that is what allows applying a successive cumulative sequence to the process. Those who object to causality in physics need to ponder a fire and what is going on with heat, fuel, oxidiser and chain reaction. Note, necessary enabling factors and sufficient clusters of factors for something to begin or to continue in being, here a fire. Then, extend this case through family resemblance to many others. KF kairosfocus

HeKS, thanks, a very good thought exercise. With your permission, I would like to use it. MT, nope. My point is that endlessness quasi-physically actualised would entail a transfinite span that cannot be traversed in steps, even were it to go on with further endlessness beyond that point. The endlessness lies first in the succession of counting sets, let us open set and close it:

{

{}--> 0 {0} --> 1 {0,1} --> 2 . . . [Ellipsis of endlessness] . . .

}

So we now can go:

0, 1, 2 . . . EoE . . . w [--> omega], w+1, w+2 . . . w + g [= A], . . . EoE . . . w + w, w + w + 1, . . . w + w + f, . . . EoE . . . -->

thus fitting into the surreals tree on the RHS branch, cf. OP above. Where, it is reasonable to suggest that the hyper-reals catapult from "hard" infinitesimals h to one of the onward zones such that they are between EoE's beyond w, for example suppose 1/h --> w + w + f. This would mean that . . . per a model discussion . . . there is no first hyper-real, that they are catapulted to from hard infinitesimals near 0. And, that through taking continuity in [0,1] and by filling gaps between say . . . reverting to mild infinitesimals for the moment . . . 1/m --> w+g and 1/n --> w + (g+1) etc, we can fill in between successive transfinites, say w + (g-1), w +g and w+g+1 creating for exploratory purposes a continuum in the transfinite span. Between any two neighbouring values an intermediate acceptable value may be specified and we can do a cut at a point and identify vice-grip intervals of values on either side that squeeze it to a unique point. Indeed, that is what surreals notation does. So, first, it is less than helpful to suggest that I have been unclear about what I have meant by endlessness and by ellipses of endlessness [EoE]. Any number of times, I have pointed out just what such an ellipsis is, and have highlighted the standard definition of the infinite that it involves endlessness beyond any arbitrarily large finite value, k. Where the pink and blue punched tape examples have been put forward. And that is before we get to the common representations of number lines and axes of graphs with arrows pointing on to endless continuation. For example: 0 --|---|--> I used A a point beyond the EoE of the natural counting sets in succession and began by adapting the catapulting to the transfinite from the infinitesimal using the hyperbolic function y = 1/x as a means of mathematically getting there. Notice, I spoke in terms of mild infinitesimals: m such that 1/m --> A, A = w + g On all sorts of mathematical debates arising, that has led to the identifying A = w + g as just indicated, where w is order type of naturals, and to the eventual grand picture of the structure of quantities, numbers, given through the surreals. So no I have never contended that "there is a point beyond which infinity ends and ‘endlessness’ starts." No, I have looked at endlessness as is embedded in mathematical praxis, and the presence of onward transfinites. With DS' help, I have clipped the tree of numbers and added to the OP to make clear that there is a whole taxonomy of numbers great and small with an organised pattern. One that makes copious use of ellipses of endlessness. In that context it makes sense to speak of numbers endlessly removed from the common range 0, 1, 2 etc, and thus we have a framework in which we can reasonably discuss traversal of a transfinite span in finite steps. Can there be an Ath rung of a ladder in a quasi-physical realm used for thought exercises connected to the empirical world? If there is an endless ladder being climbed down, something like that would be needed. If such were possible then it would confront us with climbing down and traversing an endless span to reach ground. Let us say an Ath rung is beyond reasonable possibility. That leaves us with the implication of the pink and blue tapes, an endlessly extended ladder is such that one never begins a climb down and is only ever at a finitely removed rung with endless further rungs one would have had to climb down. The problem with such is that any stepwise process that traverses some span k, will never span endlessness. This is because, let us observe steps down we label 0, 1 , 2 . . . k. Once there is an endless onward span, we can in effect set k as the new 0 and keep on going, k, k+1, k+2 etc and we will never exhaust the endless span remaining. Traversing and completing endlessness in finite stage successive steps leads to incoherence and shows the fallacy of ending the endless. We are only warranted to conclude that a span that can be traversed in successive -- thus causally linked -- steps is finite. A physical world with successive finite causally linked stages is most reasonably understood as finite in the past, thus having a distinct beginning. Onwards, it may continue endless-LY, a potential infinity that simply continues in succession for ages of ages, but strictly never completes a stepwise finite stage succession to a transfinite number of steps. The arrow of time is credibly asymmetric, with a zero-point: 0 | ---|----| . . . ---|---|---> now ***|***|**** > (We can then postulate a use of an analogy to lines of longitude shown by the hash marks that converge to a north pole of time, in effect an eternity-point that is a portal to/from any time any place. Hyperspace, if you will. In the words of the Psalms, put in a fresh context, the throne-room of God on the sides of the North. Just, to give a picture.) KF PS: Let me add a f/n from 271 above, on Feb 15:

all of this points to the issue of claimed or implied actual completion of the endless, which is where we started. Viewing the cosmos as causal succession: . . . C_k –> C_k+1 –> . . . C_n, now we see that a causal succession embeds a succession of states. Is the LHS ellipsis a completed EoE so that we are in the zone w + g i.e. the past was transfinite? Nope, as EoE cannot be bridged or traversed in finite steps. Language alone is already trying to warn us. A finitely remote initial point is indicated, as was discussed already. This is just a contextual reminder. Nor does it work to say at any p in the past we are only finitely remote onwards from k and we can repeat endlessly: . . . C_p –> C_p+1 –> . . . C_k –> C_k+1 –> . . . C_n, now No, the ellipsis on the LHS is still there and would still be endless. Yet worse is the case where one implies an endless causal succession in the past to the present, which if it means anything means that for some p’: . . . EoE . . . C_p’ –> C_p’+1 –> . . . EoE . . . C_k –> C_k+1 –> . . . C_n, now Ending the endless is a fallacy. If you doubt this, kindly show such an actual step by step completion or algorithm that can bridge the implied transfinite span in steps. We need to live with a world that manifests an inherently finite past succession to date. A world that strongly points to a beginning, where — let’s augment — a Root R gives rise to the beginning B, from which temporal-spatial causal succession proceeds: R:B –-> . . . C_k –> C_k+1 –> . . . C_n, now Where, further augmenting, R is a necessary being root.

kairosfocus

HeKS @ 1116

If you try to weigh the logical coherence of an infinite past by picturing a sequence that starts at a selected zero-time and proceeds infinitely into the past along a negative timeline then you’re going to come to false conclusions because you’re starting in the wrong place and, for all intents and purposes, confusing the past for the future.

As far as I understand the thread, it was KF's contention that there is a point beyond which infinity ends and 'endlessness' starts - not daveS's. daveS -and many of us - are trying to understand KF's stance of 'endlessness' for the past hundreds of comments. Me_Think

I'd like to offer a few thoughts here, but I'm jumping in very late so please correct me if I've gotten anyone's position wrong. Also, I have no expertise when it comes to math, so I'm going to leave that aspect alone and simply deal with the logic. daveS, you said:

If you replaced the word “endless” with “beginningless” [i.e. "ending a beginingless succession" rather than "ending and endless succession"], or “order type ?*”, this would make more sense to me.

And

If I start counting through the natural numbers in order, starting at 0, then I’m “beginning the endless” in your language. There’s nothing contradictory about that right? Likewise, there’s nothing contradictory about “ending the beginningless”. It obviously is a very strange concept from our perspective, but I don’t see any straightforward logical problem with it.

It seems there is a fairly straightforward logical problem, whether we speak of "ending the endless" or "ending the beginningless". KF's example illustration of descending a ladder is quite apt. Imagine walking into a field and seeing a ladder running straight up into the sky as far as you can see. Near the bottom is a man climbing down the ladder towards the ground. As you get closer you hear him say, "3, 2, 1, done. Wow, I have literally been climbing down that ladder forever." Is his statement even coherent? Taken literally, this man is claiming to have ended a climb down a beginningless succession of rungs and to thereby have traversed an infinite sequence one step at a time. But if the ladder truly has an infinite number of rungs, such that there is no first, highest rung to the ladder, then the man could not have traversed all the rungs of the ladder to reach the ground, as there was no opportunity for him to begin his descent. That any particular rung is only a finite distance from the ground is irrelevant, because the man is climbing down the ladder towards the ground, not up the ladder and away from the ground. As such, the absence of any beginning point for the man to have started a descent means that no matter what particular rung you might choose, however far from the ground it might be, the man could never have gotten even to that rung, much less to the ground. The man would always be infinitely far from any particular rung you might choose. So, if we accept that the ladder truly has an infinite number of rungs and yet the man has reached the ground, the only logical conclusion is that the man began his descent down the ladder at some specific time and at some specific rung that was a finite distance from the ground and that that rung where he began his descent was preceded by an infinite number of other rungs. In other words, even if we were to allow the possible existence of actual infinities in the real world (which I don't), we would still be left with the impossibility of traversing those infinities through any stepwise chain, whether we're talking about seconds, causal events, or anything else. As such, even if some sort of time dimension could exist eternally in some sense, any physical type of space in which events, change, motion, or anything of the sort is capable of taking place would need to have an absolute beginning point. Your notion that one might "end the beginningless" seems to come from an idea that there is some kind of symmetry between the future and the past with regard to infinities, but there isn't. If we assume that the universe will simply go on existing forever, then the future would constitute a potential infinite, but as we move into the future, no matter how far we go, there would only ever be a finite number of days that had passed since the Big Bang and we would never reach a point where the universe was infinitely old and an infinite succession of days, minutes, seconds or events had been traversed. On the other hand, if the past is beginningless then we immediately find ourselves with an actual infinite number of past days, minutes, seconds or events that have been traversed, one at a time, to arrive at the present. In other words, we have walked into a field and found a man stepping off the last rung of an infinite ladder, finishing an infinite climb that he never started. The logic that allows us to recognize the future as a potential infinite that is never actualized because every particular point, day or event is only a finite distance from the Big Bang simply does not help us with the past. It doesn't matter that every negative point going into an infinite past would be a finite distance from whatever zero-point we choose (e.g. the Big Bang) because the issue isn't going into an infinite past ... it's having come from an infinite past. If you try to weigh the logical coherence of an infinite past by picturing a sequence that starts at a selected zero-time and proceeds infinitely into the past along a negative timeline then you're going to come to false conclusions because you're starting in the wrong place and, for all intents and purposes, confusing the past for the future. So, in short: Beginning the Endless = coherent Ending the Endless = incoherent Ending the Beginningless = incoherent Take care, HeKS HeKS

DS, pardon but this begins to look like futile circles of semantics. Beginningless entails an endless past, one that recedes further into the past forever, beyond any arbitrarily large but finite value. By contrast, stating a PARTICULAR value defines a distinct point in some notation system thus instantiating a finite and definite number in some system of units. Endlessness proceeds beyond any such value and resists trying to list it out and exhaust it, we resort to ellipses of endlessness. That has been my point and you know that I find for cause a serious defect in claims about infinitely many finite and discrete, finite stage incremented values constituting a set of infinite cardinality -- whether positive or negative direction. Such a set by definition if fully expressed MUST entail what we cannot get to in such discrete steps, a transfinite value that involves in itself a completed endlessness. In other words I am finding here assertions that can be put in words but which on inspection involve mutually contradictory required characteristics, similar to a square circle or a triangle with five vertices etc. KF kairosfocus

KF,

The problem with beginningless quasi-spatial causal succession is rather like saying one has endlessly since infinity past been descending a ladder.

Beginninglessly, rather than endlessly.

It entails that one once was at a rung that is endlessly remote — I do not claim it was the first — and has in steps descended to the present, traversing endlessness.

But this doesn't square with #1107, where you stated that "no particular actual past time point was infinitely remote in seconds". If the ladder is being descended at one rung per second, how many seconds ago were we at this endlessly remote rung? ∞, which contradicts #1107. No, just as there was no particular instant infinitely many seconds prior to the present, there is no particular rung "endlessly remote" from the bottom of the ladder.

As for objecting to causal succession, that is an objection to physical reality, why I have spoken here of rungs of a ladder.

No, I'm not objecting to causal succession, or to physical reality. Mainly I don't want to open another can of worms. We have been discussing sequences of events in the past, for example, points in spacetime. Suppose events E_k and E_(k + 1) are separated by a spacelike interval. Then E_(k + 1) could not have been caused by E_k. I have been making no assumptions about causal relationships between the events E_k all along. daveS

DS, we can set up ad start do forever loops, we can keep going at them, what we cannot do is thereby successively traverse an endless span. The problem with beginningless quasi-spatial causal succession is rather like saying one has endlessly since infinity past been descending a ladder. It entails that one once was at a rung that is endlessly remote -- I do not claim it was the first -- and has in steps descended to the present, traversing endlessness. And, ending it. As for objecting to causal succession, that is an objection to physical reality, why I have spoken here of rungs of a ladder. We know from the tapes example and the problem of going on from k, that the proposed span to be traversed cannot credibly be spanned in successive steps, as endlessness forever recedes before the kth value in succession. Thus also, the issue pivots on what it means to have a claimed infinite past. KF kairosfocus

KF, PS to this in my #1110:

If you replaced the word “endless” with “beginningless”, or “order type ?*”, this would make more sense to me. Infinite sequences of order type ?*, with a greatest element, do exist.

If I start counting through the natural numbers in order, starting at 0, then I'm "beginning the endless" in your language. There's nothing contradictory about that right? Likewise, there's nothing contradictory about "ending the beginningless". It obviously is a very strange concept from our perspective, but I don't see any straightforward logical problem with it. daveS

kf writes,

I am not mapping my beliefs, I am mapping what seem to be the ideas or implications of claims of multiverse-ish believers who hold to an infinite actual [quasi-?] physical past.

OK, that is clear. I'm not interested in these "multiverse-ish believers who hold to an infinite actual [quasi-?] physical past", so I'll quit expressing my metaphysical concerns. Aleta

KF,

DS, given causal succession of finite stages, I would agree that — absent a compelling reason to see otherwise — no particular actual past time point was infinitely remote in seconds, stages etc,

:O I think we agree on that point.

I take it, we agree there was an actual past that has causally descended to now . . . just as successive seconds are causally connected and accumulating. The issue is whether it is open and endless in the past like a negative going left axis without limit, with a zero point at say Big Bang then forward to now. KF

I do agree with most of this; I would prefer to say as little about causality as possible, but I think your description of the issue in the last sentence is right. Edit---From your reply to Aleta:

I further challenge the claim that there has been infinite quasi-physical past as implying an infinite past regress of causal stages, leading to implied traversal of and ending an endless succession of finite cumulative stages.

If you replaced the word "endless" with "beginningless", or "order type ω*", this would make more sense to me. Infinite sequences of order type ω*, with a greatest element, do exist. daveS

A, I am not mapping my beliefs, I am mapping what seem to be the ideas or implications of claims of multiverse-ish believers who hold to an infinite actual [quasi-?] physical past. Wherein, there is an onward past chain of antecedents beyond the singularity to endlessness in prior proposed time. My argument is we can IMAGINE such but once it proposes causally successive cumulative stages to the present, it is implicitly proposing a traversal of a proposed endless past in finite stages, running into serious concerns. Think of is it Linde's model of ever budding and expanding sub-cosmi as one example. I suggest a different mode of existence, eternity in common parlance, would be a relevant consideration. Also, that on pondering possible vs impossible being the latter has core characteristics in mutual contradiction and cannot be actualised in any world. Of possible, contingents are dependent on external enabling factors that if one or more are "off" the being cannot exist -- think fire and heat oxidiser fuel chain rxn. Necessary beings are so connected to the framework of a world that for any world to exist, they must be. Compounding, non-being has no causal influence and if there were ever utter non being such would forever obtain. The issue as there is an actual world, is which serious candidate necessary beings are possible. If possible, in any world and in our actual one, perforce. I further challenge the claim that there has been infinite quasi-physical past as implying an infinite past regress of causal stages, leading to implied traversal of and ending an endless succession of finite cumulative stages. Sorry, this stuff is complex and weird, but important to foundations of thought. It seems this is now dubbed the battle of infinity. Let us hope not a Verdun or a Somme. KF kairosfocus

kf, If we take zero to be the Big Bang, so that causally connected events appear sequentially in time up to the present moment, how do you know that a similar causally connected set of temporally ordered events preceded the Big Bang? What evidence do you have that the metaphysical world, in whatever form it may be, out of which our universe came, has the same properties of time and cause-and-effect as our universe does? Aleta

DS, given causal succession of finite stages, I would agree that -- absent a compelling reason to see otherwise -- no particular actual past time point was infinitely remote in seconds, stages etc, per the challenge of traversing the endless in successive finite stage steps. I take it, we agree there was an actual past that has causally descended to now . . . just as successive seconds are causally connected and accumulating. The issue is whether it is open and endless in the past like a negative going left axis without limit, with a zero point at say Big Bang then forward to now. KF kairosfocus

KF,

DS I already said just that re WLC, for any particular specified point or stage of cause-effect in the past.

Ok, I understand this to mean yes, you do agree with WLC on that point. You would not agree to the statement "no particular instant in the past occurred infinitely many seconds from the present", I take it? daveS

DS I already said just that re WLC, for any particular specified point or stage of cause-effect in the past. Beyond would lie onward endlessness. Insofar as mathematics is a logical study it should eschew contradictions in terms/core characteristics showing something like a square circle; here, traversing and ending the endless through stepwise finite cumulative stages. That logical factors constrain what is possible through needed coherence of core characteristics is a significant issue and a gateway to mathematics as a powerful analytical tool and even causal force. KF PS: B to weak B+ today, would have wished for a cost effectiveness case in point and exploitation of 800th of Magna Carta to point the way to reform rooted in ancient, rich principle. I am again sobered by how much impact manner esp confident seeming assertive manner has . . . not to mention dismissive negatives and put-downs; life is rhetoric more than logic. Such is life. kairosfocus

KF,

DS, pardon but the force of C S Lewis’ pennies in a drawer example is in key part that the logic of structure and quantity — a matter of pure abstract logic — constrains physical reality (providing an intervening unobserved operation is not being overlooked).

Yes, but I don't believe you have given any mathematical arguments which show that an infinite past is impossible, and the vast majority of mathematicians would say the same. Back to the WLC quote, then: do you agree with him than any particular instant in the past would be within a finite number of seconds of the present? daveS

Aleta, did you notice WLC's point, any PARTICULAR number -- one that you pick, i.e. state or represent as a specific value say k [here, actually - k]? There is a difference there that brings in the force of endlessness beyond any particular stated or picked numeral or value in place value or sci notation form or even algebraic form where the value say - k is constrained to be finite and definite to a particular case. In short, we cannot write down in that sort of form or pronounce in words a value that is achievable in finite stage steps from 0 that is transfinite, but we know from the tapes example that -- reverting to positives WLOG -- beyond any arbitrarily large but finite k, endlessness proceeds such that k, k+1 etc can be readily matched with 0, 1 etc. We cannot even scratch the surface of endlessness, and resort to the ellipsis then limit ordinal w BEYOND the span, and so on, on, on to the surreals and the tree of numbers most fruitfully large and small: which is not the least important point put on the table for general discussion through this thread. It seems the radical even shocking force of this has still to soak in fully. Before I definitely go back to budgie cheaping, I need to say take A = w + g and define a less one process so that A ~1 = [ w + (g - 1)], g of course finite and w is omega. Repeat ~1 until we exhaust g and are at w. That is the finite incremental part of A is wiped out in g steps of ~1. Now, continue k "further" times "beyond" w. Or, try. It fails, in effect, w ~ k --> w, precisely because w is a qualitative difference from finite values, there is no finite defined value v that is such that v +1 --> w. That is, w is a limit, the order type of first degree endlessness, and we have again seen the force of, you cannot traverse the endless in finite scale +1or ~1 steps. Which BTW is part of why VC's set subtraction exercises fail to work with transfinites. 0,1,2 etc, 0, 2, 4, etc and 1, 3, 5 etc are all ways to represent the same first degree endlessness and because of endlessness can be transformed the one sequence into the other. More radical, shocking properties. Oh, well, the budgie calls. Cheap, cheap, cheap. KF kairosfocus

DS, pardon but the force of C S Lewis' pennies in a drawer example is in key part that the logic of structure and quantity -- a matter of pure abstract logic -- constrains physical reality (providing an intervening unobserved operation is not being overlooked). Logic of abstract entities has causal constraining force in the physical world. Hence the famous remark by was it Wheeler on the astonishing power of mathematics in the physical sciences. My fav example was the objection to Young et al (and in particular Fresnel), that if a wave interference/ diffraction, Huygens wavelet type theory was right there should be a little dot of light in the centre of the shadow of a small ball under relevant circumstances. It was thought, so there, obviously no one has seen such. Then, someone did the experiment. The dot is there: https://en.wikipedia.org/wiki/Arago_spot . It seems, it is now also observed for beams of particles, i.e. the wavicle nature of matter at molecular scale is confirmed similarly. And, on the suggestion of a transfinite actual physical past, there are logic of structure and quantity [plus linked relations and operations etc] -- mathematical -- issues to be answered to. KF kairosfocus

MT (attn IE), kindly consult the pink and blue punched tape thought exercise which has been repeatedly discussed [and put up in the OP] and which draws out the significance of something being endlessly beyond any arbitrarily large finite value, especially putting k, k+1 etc in perfect correspondence with the un-shifted naturals. This can be repeated k times to the same effect, shifting by k^2 --> k'. Then do that k' times to get k", and so forth. At no stage of increasingly large finite steps have we even scratched the surface of endlessness. That is how radical the concept is, and the only way for it to soak in is by such a paradigmatic example, a fresh one as Hilbert's Hotel has become too familiar and ho hum. Beyond a certain point, too, enough has been said so to act as though it has not is to become fallacious. For, a definition by instructive example has been given. Yes, it is horribly shocking, but in that shock it tells us what the significance of w is. Including why trying to subtract a finite from w will be fruitless, you cannot span or traverse the endless in finite stage steps. You cannot even scratch the surface. Endlessness -- so often represented by a seemingly insignificant three dot ellipsis -- is pivotal. And, the struggle of this thread is to understand endlessness, given that mathematics is the logical study of structure and quantity. This thread is foundational and foundationally significant. Back to budgie cheaping away -- and yes that is a very low grade pun. But I have to find some way to laugh as I deal with grim things, that are so key I can only give snatches of attention here for the moment. Hopefully in a day or two. KF kairosfocus

KF @ 1097

DS, notice also, any PARTICULAR negative number will be finitely remote from 0. That is endlessness beyond any particular number is a relevant factor. Oddly, I had intent to pick up that exact point when the budgies stop cheaping . . . pardon the awful puns, but we have to be able to laugh at something.

You will pick a number beyond which 'endlessness' starts? What is your definition of endlessness? How is it different from infinity? Me_Think

KF,

DS, notice also, any PARTICULAR negative number will be finitely remote from 0. That is endlessness beyond any particular number is a relevant factor. Oddly, I had intent to pick up that exact point when the budgies stop cheaping . . . pardon the awful puns, but we have to be able to laugh at something. KF

Yes, he did say "any", so perhaps in the sense of Russell. I would be interested to know if he objects to the statement "all negative integers are finitely remote from 0". I suspect not, but who knows. Now, do you therefore agree than any particular instant in the past would be within a finite number of seconds of the present? daveS

WLC is quoted as saying,

For from any point in the infinite past at which God chose to create there is only a finite distance to the present, just as any negative number you pick is only finitely distant from 0, even though there are an infinite number of negative numbers.

That is, he says, 1a. Any negative number is finite 1b. Therefore all negative numbers are finite 2. There are an infinite number of negative numbers. kf, do you agree with WLC? Aleta

DS, notice also, any PARTICULAR negative number will be finitely remote from 0. That is endlessness beyond any particular number is a relevant factor. Oddly, I had intent to pick up that exact point when the budgies stop cheaping . . . pardon the awful puns, but we have to be able to laugh at something. KF kairosfocus

KF,

DS, endlessness beyond any finite value is the substance of infinity, the latter is just a label until endlessness is brought to bear, and indeed that is part of the underlying dynamic of the match with proper subset approach, it is because of the endlessness property that it works, even with say primes, as in the list of primes is endless in succession though obviously on average sparser and sparser as we go up in scale. KF

I'm not totally clear on the meaning of this, but is it consistent with the bolded sentence from the WLC quote? daveS

Re 1091: Electrons are cheap. There have actually been quite a few interesting points developed in this thread, for those interested in the topic. Aleta

DS, endlessness beyond any finite value is the substance of infinity, the latter is just a label until endlessness is brought to bear, and indeed that is part of the underlying dynamic of the match with proper subset approach, it is because of the endlessness property that it works, even with say primes, as in the list of primes is endless in succession though obviously on average sparser and sparser as we go up in scale. KF kairosfocus

Indiana Effigy, Is someone putting a gun to your head? mike1962

KF, Some additional food for thought, from WLC's website. Dr Craig is responding to a Muslim who is arguing for the possibility of an infinite past:

(Actually, as I think about it, it occurs to me that your argument is fallacious even if there was an infinite series of temporal points prior to creation! For from any point in the infinite past at which God chose to create there is only a finite distance to the present, just as any negative number you pick is only finitely distant from 0, even though there are an infinite number of negative numbers. From the fact that at any point in an infinite past God is able to create a world, it does not follow that God was able to create a world with an infinite past.)

(Some bolding added) daveS

I hate to be the bearer of the patently obvious, but this entire thread ranks right up there with the arguments over how many angels can fit on the head of a pin. What is mind boggling insane is that it has lasted over 1000 comments. Give it up. Everyone. It is just a waste of electrons. Indiana Effigy

KF, I'm not attempting any sort of "move". The definition you are giving of "endless" seems to coincide with the definition of "infinite" you quoted from the dictionary, so I'm wondering why you need two terms when just one will do. It would also make your statement above:

DS, my point is, that if there were an infinitely remote point in time as part of the past it would have to be endlessly remote.

tautological, which leads me to question why it needs to be stated. Is there any difference between infinite and endless sets? If so, what is the difference? Can you give examples of sets which are endless but not infinite (or vice-versa)? daveS

DS, endless means just that as per the pink and blue tape example as has been pointed out any number of times above. That is, for something that comes in distinct lumps or steps of finite scale, for any kth member of arbitrarily large but finite scale, k, k+1 and so forth can be put in 1 to 1 correspondence with 0,1,2 etc without limit. And by extension that can be repeated any number of times. I trust by now there is willingness to move beyond the let's demand the [already repeatedly given or adequately explained or exemplified] definition yet again move. Beginninglessness would be the much the same; save time is a key context of the lumps or stages, in the cases in view causal succession from past to present. As has also been repeatedly given including by use of symbolisations. KF kairosfocus

KF, Of course #4(b) is the relevant definition for us. #1(a) as well; an infinite past is unbounded. How does "endless" differ (in your usage---I've already stated how I think "endless" and "beginningless" should be defined). daveS

infinite (??nf?n?t) adj 1. a. having no limits or boundaries in time, space, extent, or magnitude b. (as noun; preceded by the): the infinite. 2. extremely or immeasurably great or numerous: infinite wealth. 3. all-embracing, absolute, or total: God's infinite wisdom. 4. (Mathematics) maths a. having an unlimited number of digits, factors, terms, members, etc: an infinite series. b. (of a set) able to be put in a one-to-one correspondence with part of itself c. (of an integral) having infinity as one or both limits of integration. Compare finite2 ?infinitely adv ?infiniteness n Collins English Dictionary – Complete and Unabridged, 12th Edition 2014 © HarperCollins Publishers 1991, 1994, 1998, 2000, 2003, 2006, 2007, 2009, 2011, 2014 kairosfocus

KF,

DS, my point is, that if there were an infinitely remote point in time as part of the past it would have to be endlessly remote.

Hmm. I would agree with this, simply because my understanding was that "infinitely" and "endlessly" were exact synonyms in your usage. Hence this would be true by definition. If they are not exact synonyms, what's the difference? More to the point, though, your definition of "infinite past" is different from that used by WLC, John Lane Bell (a mathematician and philosopher), and others who write on this topic. Their concept of an infinite past does not include any points infinitely remote in time. Are we clear on that? When WLC or JLB uses the term "infinite past", they are not asserting that the past includes any points infinitely many seconds from the present; in fact, quite the opposite is true. For WLC and JLB, every instant in this hypothetical infinite past is finitely many seconds from the present. And yet they both agree that the term "infinite past" is appropriate for that case. One can obviously consider the implications of removing this "finite accessibility hypothesis*" as JLB calls it (and he briefly does so), but then your definition of "infinite past" would be different from what everyone else is using, so we would have yet another clash of definitions, something which has plagued this entire discussion (see "endless" vs. "infinite"). My vote is we stick with the definition of "infinite past" used by WLC, et al, and consider only finite time coordinates. You are then welcome to show that WLC's usage of "infinite past" in this context is "dubious". ____ *JLB's finite accessibility hypothesis states that any two points in time are finitely many steps (seconds, say) apart. daveS

DS, my point is, that if there were an infinitely remote point in time as part of the past it would have to be endlessly remote. Where, infinite past requires endlessly -- infinitely -- remote past points in time, or there is no infinitely remote past. And as the issue is a causal succession, that would have to be associated with a transfinitely large past number of causal steps to get from the suggested then to now. The sequence of cause effect bonds from then to now would have to traverse and complete endlessness in finite stage steps. The very contradiction in terms involved shows why this is dubious, and those who propose an infinite -- so, endlessly remote -- past need to show good reason for their claims. The assertion that an endless string of only finite values in finite stage steps is similarly questionable. If finite then by definition not endless. Still too busy to do other than outline. KF kairosfocus

KF,

DS, very briefly, the point is that once there is a supposed infinite past, at some point there would have to be an endlessly remote — transfinitely remote — point. Does not have to be a start point, just, would have to be.

No, this is false. We have been over this "endlessly". WLC himself agrees with me. John Lane Bell agrees with me. You have not given any proofs showing that such points exists. When you get time, I challenge you to find such proofs in the literature on this subject (and not mere assertions). I have cited a few papers, even a couple where this same error crops up (Whitrow, e.g.), and where it is corrected (Bell).

And nope, the notion of endlessly remote finite values in a succession is dubious, a finite value is by definition not endlessly remote for one. More later, local issues have to take my main focus. KF

Certainly dubious, because they do not exist! That is, if you mean, in essence, natural numbers infinitely far from 0. If, on the other hand, you mean that the notion of infinitely many finite natural numbers is incoherent, then you're welcome to be a finitist as far as mathematics goes, but that doesn't mean the physical universe must obey this limitation. daveS

DS, very briefly, the point is that once there is a supposed infinite past, at some point there would have to be an endlessly remote -- transfinitely remote -- point. Does not have to be a start point, just, would have to be. Effectively by definition. The very fact that this is problematic is telling us something. And nope, the notion of endlessly remote finite values in a succession is dubious, a finite value is by definition not endlessly remote for one. More later, local issues have to take my main focus. KF kairosfocus

'There is a kind of religion in science; it is the religion of a person who believes there is order and harmony in the Universe…This religious faith of the scientist is violated by the discovery that the world had a beginning under conditions in which the known laws of physics are not valid, and as a product of forces or circumstances we cannot discover. When that happens, the scientist has lost control. If he really examined the implications, he would be traumatized.' [17] Hilarious last sentence... though evidently true. Axel

KF,

e –> The attempt to step down from A as a suggested transfinite = w + g to the finite range in neighbourhood of 0, runs into the nature of w as a limit ordinal, is in effect not a direct successor to the sequence 0, 1, 2 . . . but rather a value assigned as limit to the endlessness, as order type of the endlessness.

Once more, there is no attempt to count down from a transfinite A to 0 here. The counting (up) through all negative integers to 0 has no beginning, and hence no starting point A.

f –> I have argued that the stepwise +1 stage countup from 0 cannot be completed to the transfinite, that every value attained by this or extensions of it — every natural number we can specifically write own in effect — will be inherently finite, and that he pink/blue tapes example shows that for any arbitrarily large k in he succession, k, k+1, k+2 etc can be put in 1:1 correspondence with 0,1,2 etc, showing in succession that we actually never even begin to scratch the surface of endlessness by any finite stage incrementing cumulative process.

And I don't think anyone has disputed these points.

h –> Indeed even an endlessly sparser as we go subset the primes, is undefinably endless. There is no definable largest prime. Endlessness is a paradigm shift we have to swallow whole.

Not sure about "undefinably endless", but everyone here grasps the fact that there are infinitely many primes. We are not having trouble "swallowing" that idea.

i –> Note, I am NOT speaking to a continuum, a smooth timeline, but to a succession of stages, where going back to the big bang only gets us to 0. In short, the count is by generations of causal succession, not by an imagined clock. Rows in the punched tape, not the presumed tape that runs on with the holes in it.

I don't know about the distinction between a tape and a clock here. Surely you can't disqualify a ticking clock in a thought experiment involving the passage of time?

j –> In this context, it is to my mind readily apparent that an endless, finite stage succession inherently maps to a succession of ordinals and extensions of such, so if there is a logical constraint on the numbers it will extend instantly to what maps to this.

Eh? Can you make this more precise? What is this "mapping"?

k –> In short this is just as if 3 +1 +1 +1 + 6 –> 12, we cannot add three pennies, a three-pence coin and a sixpence without getting a shilling’s value.

I do agree that 3 + 1 + 1 + 1 + 6 = 12.

n –> In that context, proposing to complete an endless finite stage succession in steps, bridging the transfinite, is at minimum paradoxical and more plausibly is an attempt to effect the logically impossible.

Proposing to X the X-less would be paradoxical, I agree. Proposing to X the Y-less (END the BEGINNING-less) is not necessarily paradoxical.

p –> In this context, it seems clear to me that a claimed transfinite successive past of stages of cause-effect down to now tries to span the transfinite in steps. Never mind clever verbal steps or objections, the claim is quite plain on reflection.

It "tries" to span the transfinite in a transfinite number of steps, you could say.

r –> The past, plausibly is finite, on a constraint of logic. Logic of structure and quantity.

Most would agree that physical evidence indicates the past is probably finite, but I think you're overlooking the "obvious objection" to your argument that Bennett identifies in the quote from post #1078.

t –> And this seems there as a limit to observable reality imposed by logic, never mind that we cannot observe the remote past, or even the much nearer past. u –> I would actually challenge those who propose such while wearing or pointing to the lab coat: kindly, show us observational evidence.

If this is addressed to me, a reminder: my argument is simply that this "counting down from infinity" argument fails to show the past must be finite. I certainly don't have observational evidence of an infinite past. **** I would urge you to take another look at my post #1077. We're over a thousand posts in this thread alone, and you're still referring to a transfinite "starting point" A to this (beginningless!) process of counting through {..., -2, -1, 0}. That tells me you haven't dealt with the distinction between ω and ω*. daveS

Folks, While still busy, I will pick up a few things, let me start fairy early in the last set of exchanges:

A, 1059: >>I think the connection between the mathematics of infinity and metaphysical speculations about time and God are tenuous at best.>> DS, 1061: >>Can you explain how the punched tape example demonstrates that an omnipotent deity, existing outside of time, and who did not begin to exist, cannot create a universe with an infinite past?>> DS, 1063: >>I am merely saying that I see no logical problems with an infinite past, and I don’t think any such problems have been described here. In other words, it hasn’t been shown to be impossible.>> A, 1064: >>1. As far as is known, and as is generally accepted, our universe started about 14 billion years ago, so within our universe there is no issue about an infinite past: the amount of time since the universe began is finite. 2. We tend to accept the model of a number line starting at zero as part of the background framework of events happening in the world, as if time existing as a background clock in respect to which events happened steadily, and in one direction only. As with all applied math, this is a model which maps a mathematical concept to a real-world phenomena, and must be tested to see if it is a valid model. While it certainly suffices for the macroscopic world, we know that at the quantum and relativistic level this model breaks down in places. 3. We also have a model of the world being causally connected from moment to moment in time, each moment being a causal product of the moment before. However, even the implied continuity in the number line model breaks down at the quantum level, both in terms of discrete amounts of energy and time, as well as the introduction of genuine probabilities as opposed to strict deterministic cause and effect. 4. It is a completely untestable metaphysical speculation as to whether anything like the time we experience in our universe exists outside of our universe, including before our universe. To extend the model of a number line within our universe to whatever exists outside/before our universe is just not justified.>>

a --> The first issue is not about God or what he could create, save that not even God can make a violation of the first principles of right reason, For instance, that Canadian Christian children's TV programme title notwithstanding God cannot create a square circle. b --> Likewise, the question is not the evident finite past of our observed cosmos, but whether there is a chain of in some essential sense physical causal antecedents beyond it without limit. As I have modelled ever so many times in this thread, the implied argument is that there is a chain of causal stages Cj: . . . EoE . . . Ck+1 –> Ck –> . . . –> Cn, now. c --> Or, more elaborately, let me go to 7 above:

. . . what is warranted is that step by step finite succession cannot bridge to the transfinite. This is easiest to see starting at 0 and counting up, but it is patent that bridging the transfinite the other way to appear at the present has to bridge the same span. That is why I went to lengths to identify a reasonable ordered succession 0, 1, 2 . . . [TRANSFINITE SPAN] . . . w [--> omega], . . . w + g . . . and identify that A = W + g, a transfinite with w the first transfinite ordinal and g some large finite [so still of the scale aleph null] will be such that in a descent . . . A, A~1 [= w + (g – 1)], A ~ 2, . . . 2, 1, 0, 1*, 2* . . . n, n being now, we see A, A~1 [= w + (g – 1)], A ~ 2, . . . 0, 1#, 2#, . . . and so we run into a transfinite bridge and the count down will not reach from A to 0, no more than it can reach up from 0 to A.

d --> Of course much water has passed under the bridge since then and we have seen that the surreals allows us to make the sort of succession of numbers implied, cf the tree added to the op. Where it remains so that there is no basis for a stepwise spanning of the transfinite and there is no definable finite antecedent to w. e --> The attempt to step down from A as a suggested transfinite = w + g to the finite range in neighbourhood of 0, runs into the nature of w as a limit ordinal, is in effect not a direct successor to the sequence 0, 1, 2 . . . but rather a value assigned as limit to the endlessness, as order type of the endlessness. f --> I have argued that the stepwise +1 stage countup from 0 cannot be completed to the transfinite, that every value attained by this or extensions of it -- every natural number we can specifically write own in effect -- will be inherently finite, and that he pink/blue tapes example shows that for any arbitrarily large k in he succession, k, k+1, k+2 etc can be put in 1:1 correspondence with 0,1,2 etc, showing in succession that we actually never even begin to scratch the surface of endlessness by any finite stage incrementing cumulative process. g --> In short, endlessness has to be taken seriously as part of the definition of naturals and of reals too. So beyond any specific counting number, there is an endless onward succession that can be put in correspondence with the full set. h --> Indeed even an endlessly sparser as we go subset the primes, is undefinably endless. There is no definable largest prime. Endlessness is a paradigm shift we have to swallow whole. i --> Note, I am NOT speaking to a continuum, a smooth timeline, but to a succession of stages, where going back to the big bang only gets us to 0. In short, the count is by generations of causal succession, not by an imagined clock. Rows in the punched tape, not the presumed tape that runs on with the holes in it. j --> In this context, it is to my mind readily apparent that an endless, finite stage succession inherently maps to a succession of ordinals and extensions of such, so if there is a logical constraint on the numbers it will extend instantly to what maps to this. k --> In short this is just as if 3 +1 +1 +1 + 6 --> 12, we cannot add three pennies, a three-pence coin and a sixpence without getting a shilling's value. l --> Logical-mathematical realities can and do causally constrain the real world. If you put the above coins in a tin in a drawer and come back a week later to find less than a shilling's value, it is not logic or arithmetic but the laws of England that were broken, to paraphrase C S Lewis. m --> Mathematics is the logical study of structure and quantity. Laws of logic, likewise, are inextricably entangled into possible realities. n --> In that context, proposing to complete an endless finite stage succession in steps, bridging the transfinite, is at minimum paradoxical and more plausibly is an attempt to effect the logically impossible. o --> And yes, I accept that this shifts how I have to view ordinary mathematical induction. As was already addressed. p --> In this context, it seems clear to me that a claimed transfinite successive past of stages of cause-effect down to now tries to span the transfinite in steps. Never mind clever verbal steps or objections, the claim is quite plain on reflection. q --> Nor does it help to try to suggest an endless succession of finite values on mathematical induction; that too is caught up in the problem. r --> The past, plausibly is finite, on a constraint of logic. Logic of structure and quantity. s --> That is, it seems to me that a claimed infinite successive past is much like a square circle, by claiming to end the endless in steps. t --> And this seems there as a limit to observable reality imposed by logic, never mind that we cannot observe the remote past, or even the much nearer past. u --> I would actually challenge those who propose such while wearing or pointing to the lab coat: kindly, show us observational evidence. ______________ Okay, back to the local budget season rhetorical games and Cicero's point that rhetorical eloquence and wisdom (including the ethics of sustainability) too often never meet. Back in a day or so, DV. KF kairosfocus

Still busy but BA77 has a clip: https://www.facebook.com/philip.cunningham.73/videos/vb.100000088262100/1119397401406525/?type=2&theater kairosfocus

KF, I finally found paper which deals at length with many of the issues that have arisen here:

The Age and Size of the World Jonathan Bennett Synthese Vol. 23, No. 1, Kant and Modern Science (Aug., 1971), pp. 127-146

The first 11 pages or so are most relevant to our discussion. Here is a portion from the first pages which summarizes one of the points I have been making: Bennett begins by reviewing Strawson's essay on an infinite past:

When Strawson discusses this matter he pretends that "for as long as the world has existed, a clock has been ticking at regular intervals", and he then equates the world's age with the length of the series of past ticks. His 'ticks' do exactly the same work as my 'events'. Now, Kant argues like this. If the world never began, then it has been going on forever, and the series of past events---past ticks of Strawson's clock---has infinitely many members. But:

The infinity of a series consists in the fact that it can never be completed through successive synthesis. It thus follows that it is impossible for an infinite world-series to have passed away. (A 426)

That is Kant's argument---his presentation of the alleged conceptual difficulty in the idea that the world is infinitely old. The argument looks bad, because on the face of it it is open to an obvious objection. Kant says that "the infinity of a series consists in the fact that it can never be completed through successive synthesis"---that is, through a one-by-one enumeration of its members---but that is just false. A series of the sort Kant has in mind must, if it is infinite, be open at one end; it cannot have both a first and last member; and so the enumeration of its members, if started 'can never be completed'. But such an enumeration could be completed all the same, if it did not ever start but had been going on for ever.

daveS

KF, I'll take this opportunity to elaborate on the distinction between "endless" and "beginningless", using some of the notation and concepts that appear in the papers I mentioned. As we have seen, the set N has order type ω. If we have a (countably) infinite sequence of distinct events, E_i, where each i is an integer, then the set of all the E_i is ordered (chronologically). [Edit: Naturally I assume that no pair of these events occur simultaneously.] Now suppose we have a one-to-one, order-preserving correspondence between N and the set of all the E_i in such a sequence. Then by definition, the set of the E_i has order type ω as well, and it is appropriate to call the sequence endless. We have used the notation (E_0, E_1, E_2, ...) for endless sequences of events. On the other hand, the set of all nonpositive integers has order type ω*. We could denote that set by Z^-. Clearly there is no one-to-one, order-preserving correspondence between N and Z^-, so ω is not equal to ω*. I will call a countably infinite sequence of events beginningless if the set of all such E_i has order type ω*. You can of course represent such a beginningless sequence by (..., E_(-2), E_(-1), E_(0)). In these threads, we have sometimes used the word "endless" as a synonym for "infinite", but I think it's important, when discussing ordered sets, to reserve the term "endless" for sets of order type ω (for countable sets, anyway), in order to avoid any equivocation. A few observations:

1) No sequence of events in the past has an endless subsequence. 2) No sequence of events in the future has a beginningless subsequence. 3) Every infinite sequence of past events is beginningless. 4) Every infinite sequence of future events is endless.

Agreed so far? daveS

Aleta, Just now I do not have much time given local matters, I responded to a general point on relevance. The claim of an infinite past succession of causally linked stages is subject to the issue of actualising the infinite in successive finite stage steps which is tied to the logic of structure and quantity. Pardon me if I have not exactly intersected with your concerns and have gaps on things you asked, there is a major local development that requires my main effort just now. Similar to the recent trip that put me effectively offline for several days. KF kairosfocus

Thanks, Dave. And kf, I'll point out that not only do you address points to me about things that I don't claim, you also don't address points that I do claim, such as that the model of time as a number line extending beyond our know finite universe is an unjustified metaphysical speculation which renders meaningless the whole discussion about an infinite past time. Aleta

KF, I have to be away for several hours, but I will echo Aleta's request that you not address posts on these subjects to her. It seems to imply (falsely) that she has made certain claims (or taken certain positions) when she hasn't. daveS

kf, you once again address me about claims and positions I haven't made and don't have. Why do you do that? Did you even read 1070? Or do you just repeat your points irrespective of what someone else writes??? Aleta

KF,

Aleta (attn DS), the claim there is a completed infinite past entails completion of the endless. That is the fundamental issue where at minimum a paradox emerges.

I assume you're addressing me, primarily. :P Anyway, it would entail completion of an infinite set. Specifically, completion of "the beginningless", not "the endless".

And, if at ANY remote time in the past only a finite past has been subsequently traversed that points to there being only a finite past.

True. Of course I'm assuming otherwise.

By contrast an ellipsis of endlessness in {0,1,2 . . . } points to a process that is precisely beyond completion,

Perhaps, but again you're referring to a process with a beginning but no end. In the digits of pi example, the process has no beginning but has an end, so is not "endless". I think that while you have spent quite a bit of time discussing "endlessness", the real issue is "beginninglessness". After all, the central topic is an infinite past, which by definition has no beginning. Endlessness and beginninglessness are very different. daveS

Aleta (attn DS), the claim there is a completed infinite past entails completion of the endless. That is the fundamental issue where at minimum a paradox emerges. And, if at ANY remote time in the past only a finite past has been subsequently traversed that points to there being only a finite past. By contrast an ellipsis of endlessness in {0,1,2 . . . } points to a process that is precisely beyond completion, which is why for any definable thus finite k, there will be an onward endlessness k, k+1, k+2 etc that can be matched to 0,1,2 etc endlessly. The foot of the rainbow is ever receding. KF kairosfocus

kf writes,

Aleta & DS: Do you see the problem with claiming to complete — thus, end — an endless, transfinite traverse in finite cumulative steps?

kf, I have never, ever made that claim. Haven't I made that perfectly clear? I have also never, ever made the claim that one could somehow "start" at negativity infinity and proceed to 0 - that claim itself doesn't make sense. And, I have clearly stated that I don't think the number line is a testable model for time as it pertains to something metaphysical beyond our universe. So I really wonder why you keep addressing comments about these issues to me as if I were defending something that I'm not. Seriously, do you pay attention to the establshed positions of other participants in the discussion? Aleta

KF,

Aleta & DS: Do you see the problem with claiming to complete — thus, end — an endless, transfinite traverse in finite cumulative steps?

If the process has a beginning, yes, I see the issue. If an omnipotent deity begins counting through the natural numbers in order, one number per second, then at any point in the future, it will have only counted through a finite subset of N. At no point in the future will this "infinity" be completed. In a beginningless process, that is not an issue. Think of the example of the deity mentally noting the passing of each second through an eternal past. At the time of any particular tick, there has already been infinitely many other ticks previous to it. There is no point at which the number of ticks completed transitions from finite to infinite---it has always been infinite.

you cannot traverse in +1 steps from 0 as a reference, which also reverses to if one claims an endlessly remote past then to reach now such would have had to be traversed in finite stage steps, which runs into the issue of endlessness.

In the example of the beginningless deity, there is no starting point, nothing corresponding to the "from 0" that you have when counting 0, 1, 2, 3, ... . Edit: Something else to consider, which I'm stealing from the philosophy forum I linked to, based on an anecdote told by Wittgenstein. Consider an omniscient deity who never began to exist, and who exists outside of time. Now imagine this deity reciting the decimal digits of pi, one digit per second, in reverse order. He completes this task today, ending with 9, 5, 1, 4, 1, 3. Is that logically impossible? daveS

I've read some of the papers along with some additional sources (written by professional philosophers), and I have to say I think most of the discussion in these threads is at least comparable in quality. Both of the following passages leave me shaking my head. Here's a quote from WLC in his book on the Kalam Cosmological Argument (pages 200-201), with some emphasis added, and separated into paragraphs for readability:

If the universe had no beginning, then at least one temporal chain of events had no beginning. (By temporal chain of events is meant a sequence of discrete physical occurrences that has the usual properties of discrete chronological order.) If E is an event in this chain, then there is an important difference between an infinite past and an infinite future for E; one is actual and the other potential. That the future is a potential infinite means that (1) for any future event in E there will be future events and (2) any event in the future of E is separated from E by a finite number of intermediate events. On the other hand, the past is actual. Whitrow points out that when we try to think back over the series of past events, our train of thought yields only a potential infinite; but this process does not correspond to the actual successive occurrence of these events. Therefore, if the past events are infinite, they constitute an actual infinite. Consequently, if the chain of events prior to E is infinite, then there must be an event O that is separated from E by an infinite number of intermediate events. If not, then the number of events separating E from any event O would be finite, and thus the past would be only a potential infinite, which is impossible. But an infinite number of intermediate events raises two problems: (1) if E is an infinite number of events from O, then with regard to O the notion of the future as a potential infinite is destroyed, since both O and E do occur; (2) when in the temporal chain between O and E does the total number of events that have occurred since O become infinite instead of finite?

Pamela Huby says this in her 1971 paper "Kant or Cantor: That the Universe, if Real, must be Finite in Both Space and Time":

Similarly me may argue of things in space, that any object in space, however far distant, is a finite distance only from every other object. But between any object and any other there can then be only a finite number of objects, and therefore, however vast the total number of objects may be, it will still be finite.

??? daveS

Aleta & DS: Do you see the problem with claiming to complete -- thus, end -- an endless, transfinite traverse in finite cumulative steps? That is interesting. Especially when, over and over again anytime one attains to some finite but large accumulation, k, endlessness still sits there before one even as the foot of the rainbow is ever receding. Which, the pink/blue tape exercise plainly shows. Which then applies to a claimed endless succession of distinct finite causal stages along a timeline to the present. Oh yes, aleph null is the cardinality of first order endlessness, so speaking of aleph zero can be directly translated to endlessness, which then brings up the significance of the ellipsis of endlessness -- you cannot traverse in +1 steps from 0 as a reference, which also reverses to if one claims an endlessly remote past then to reach now such would have had to be traversed in finite stage steps, which runs into the issue of endlessness. And that has been pointed out above many times as a problem. KF PS: I cannot elaborate, main focus is on current local issues just now. kairosfocus

Hmm. Popper, John Lane Bell, and WLC all submitted replies to Whitrow's article, also to the BJPS. I suppose this would have been a good place (for me) to start reading on the subject. daveS

I haven't spent much time looking for publications by working philosophers on this issue, but there are quite a few. I picked one which appeared on the first page of google search results, but wasn't very impressed with this quote:

If n events occurred in sequence before E_0, then there must have occurred an event designated E_(-n), in my notation. Similarly if aleph-zero events occurred before E_0, then there must actually have occurred (in time past) events E_(-aleph-zero). But, starting from any one such event, it would have been impossible to attain the event E_0, just as from the event E_0 it will never be possible to attain events E_(aleph-zero) in the future. Consequently, the concept of an infinite sequence of past events is incapable of culminating in the present event. Hence, just as every future sequence of discrete events from E_0 onward will always be finite, in the sense that never will an event E_n be attained where n is not finite, so in every past sequence the total number of events, however large, can never be infinite.

where:

Similarly if aleph-zero events occurred before E_0, then there must actually have occurred (in time past) events E_(-aleph-zero).

is clearly incorrect. As we've seen here, the set N has cardinality aleph-null, but no element(s) aleph-null. It's not clear to me why he speaks of plural "elements E_(-aleph-null)" either. Source: On the Impossibility of an Infinite Past by G. J. Whitrow in The British Journal for the Philosophy of Science, Vol. 29, No. 1 (March, 1978). For some informal discussion, there are some posts on this philosophy forum that seem on the mark. daveS

At 1060, kf wrote,

Aleta, a past causal succession by finite stages runs into issues revealed by the punched tapes exercise. A proposed past-infinite succession like that tries to bridge the transfinite. KF

Hmmm, kf. I'm not sure why you addressed this comment to me. My previous comment at 1059 was about pure math and not at all about a "past causal succession by finite stages." I did make the comment that I thought "the connection between the mathematics of infinity and metaphysical speculations about time and God are tenuous at best." Let me expand on that. First, almost entirely (not completely) I've concentrated on the purely mathematical nature of infinity throughout these threads. Now I'll make some comments about the larger issue of time and an infinite past. 1. As far as is known, and as is generally accepted, our universe started about 14 billion years ago, so within our universe there is no issue about an infinite past: the amount of time since the universe began is finite. 2. We tend to accept the model of a number line starting at zero as part of the background framework of events happening in the world, as if time existing as a background clock in respect to which events happened steadily, and in one direction only. As with all applied math, this is a model which maps a mathematical concept to a real-world phenomena, and must be tested to see if it is a valid model. While it certainly suffices for the macroscopic world, we know that at the quantum and relativistic level this model breaks down in places. 3. We also have a model of the world being causally connected from moment to moment in time, each moment being a causal product of the moment before. However, even the implied continuity in the number line model breaks down at the quantum level, both in terms of discrete amounts of energy and time, as well as the introduction of genuine probabilities as opposed to strict deterministic cause and effect. 4. It is a completely untestable metaphysical speculation as to whether anything like the time we experience in our universe exists outside of our universe, including before our universe. To extend the model of a number line within our universe to whatever exists outside/before our universe is just not justified. Similarly, we have no idea if what we experience as a sequence of causes and effects happening in a temporally linear manner apples to whatever came before and/or is outside our universe. 5. That is why I think the whole argument about a "past infinite causal succession" is an empty topic. We have no idea if our model of time as a number line and events on it as modelled by successive points applies to the world outside our universe, and no way of testing if that is so. It is a misapplication of math to just assume the model is valid, and then to argue about things within the mathematics itself as if they automatically meant something about the world outside of mathematics, and especially about an inaccessible metaphysical world. Aleta

KF,

As for the issue can God make (A and ~ A) true shows that if something is a logical problem it is a problem. If one posits an infinite causal succession in stages, she needs to explain how such is possible. KF

Well, I am merely saying that I see no logical problems with an infinite past, and I don't think any such problems have been described here. In other words, it hasn't been shown to be impossible. daveS

DS, I spoke to something much more restricted, that endlessness is beyond any finite k no matter how large. That is not in itself any proof of omnipotence etc, but it dies show that claimed infinite stepwise causal succession is seriously problematic as it must span the transfinite. As for the issue can God make (A and ~ A) true shows that if something is a logical problem it is a problem. If one posits an infinite causal succession in stages, she needs to explain how such is possible. KF kairosfocus

KF, Can you explain how the punched tape example demonstrates that an omnipotent deity, existing outside of time, and who did not begin to exist, cannot create a universe with an infinite past? daveS

Aleta, a past causal succession by finite stages runs into issues revealed by the punched tapes exercise. A proposed past-infinite succession like that tries to bridge the transfinite. KF kairosfocus

I think the connection between the mathematics of infinity and metaphysical speculations about time and God are tenuous at best. For math to be applied via a model there has to be some way to test the model, and there is no way to test metaphysical speculations. As I've said before, I believe math, as an abstract system, has truth and meaning in and of itself, irrespective of any possible (and untestable) connections with metaphysics. From this point of view, I am more in line with Nelson's view that the math doesn't exist until we invent it than with the idea that all math, not matter how obtruse, has some metaphysical correlate. With that said, I also think the basics of math started as an abstraction based on reality - see my post about the invention of writing the counting numbers at 994. But once the abstract systems are set up, they take on a life of their own that goes beyond a direct correlate with physical reality also. In this way, I really liked Nelson's statement that

But numbers are symbolic constructions; a construction does not exist until it is made; when something is new is made, it is something new and not a selection from a pre-existing collection. There is no map of the world because the world is coming into being.

Aleta

KF,

I suspect it is coming to a point where it is clear that there are valid issues there, it is not as cut and dried as doing a class may suggest.

Well, the Russell and Nelson works have clarified some of these issues for me, certainly. Edit: As have our discussions here, including your own posts to be sure!

Bottomline, trying to traverse the transfinite in finite stage cumulative steps is problematic. As causal succession to our present world fits under that, the implication is suggesting an infinite past for the physical cosmos fails.

I don't really see a strong connection these mathematical/philosophical issues and the possible existence of an infinite past. The radical predicativist position that Nelson adopts in this particular book concerns abstract entities, while the question that kicked off these threads is an empirical one. How can skepticism about the principle of mathematical induction (for example) solve such a question? I believe all those arguing against an infinite past believe in an omnipotent deity, existing outside of time, who did not begin to exist. Who is to say that such a deity could not have arranged for our physical universe to have an infinite past, perhaps intervening occasionally to counteract the effects of the 2nd law of thermodynamics, etc? All the while this deity could note the passing of each second, much like an eternal ticking clock. I'm not convinced that these mathematical investigations have shown that such a deity could not accomplish this. daveS

Me neither. Ain't math grand. Aleta

Aleta, Wow, that's a very beautiful result. I didn't expect such a nice pattern. daveS

The basketball stuff is not related at all - it's just a complete tangent. Aleta

MT, The OP sets the frame, and the question of the infinite arose in that context. I suspect it is coming to a point where it is clear that there are valid issues there, it is not as cut and dried as doing a class may suggest. Bottomline, trying to traverse the transfinite in finite stage cumulative steps is problematic. As causal succession to our present world fits under that, the implication is suggesting an infinite past for the physical cosmos fails. Where also pulling a cosmos out of non being is even more problematic. We are looking at necessary being root of reality. KF kairosfocus

I can no longer figure out what this thread is about ! Me_Think

Those are all correct, and your answers are exact and mine had some rounding off errors. I worked on this today while watching the games. I set up a spreadsheet, which made me think carefully about the formulas, and made some interesting discoveries by changing the probabilities. I found out it's never better to guess an upset no matter what the odds are: the EV for going with the higher seed in every game, is always better than the EV for guessing one or more upsets. Then I worked out all the formulas and got formulas for EV(0 = no upsets), EV(1), etc. After doing that, I saw some results that were simple and made sense. This all followed a pattern I've noticed before in problem solving. First I work out an example with real numbers; Then I explore it algebraically because both the process and results of working with numbers give me some hints. Then, after doing things the long way, I see some results that have more direct routes. And finally some times I see that results make sense in some more intuitive, meaningful ways. Anyway, if p = probability of the higher seed winning, and q = 1 - p = probability of an upset with the higher seed winning. EV(0) = 4p (This is a duh! You have an expected value of p per game, and there are 4 games.) EV(4) = 4q. Same reasoning. The math doesn't care whether you are playing to win or playing to lose. EV(2) = 2 no matter what the odds. At first this was a surprise, but it makes sense because the math is symmetrical: two upsets is the same as two non-upsets, so you get 1/2 the possible 4 points no matter what. EV(1) = 2p + 1 and EV(3) = 3 - 2p = 2q + 1, which makes sense because the math is symmetrical as to p and q. Interestingly enough, the difference between any two EV's, such as EV(2) - EV(3) is always 2p - 1. Therefore EV(0) is always bigger than EV(1), with the amount of the difference depending on p. Thus, the bigger that p is, the more difference it makes to not pick an upset, which makes sense also. Aleta

Aleta, I just noticed I reversed the probabilities above, saying that 0.7 is the probability of an upset, when it's actually 0.3. Anyway, I got a few minutes to work in this, and did get an EV of 2.8 assuming we predict 0 upsets, and 2.4 assuming 1 upset, both exact. I'm not sure if I made a mistake with the 2.4, since it's a little different than your answer. I also got an EV of 1.2 assuming we predict 4 upsets. Is that what you're getting? I'll try the others tomorrow! I'm interested to know whether you can get a higher expected value by predicting 1 or more upsets if we increase the number of games or adjust the probabilities. daveS

Thanks, Aleta, that helps. I might take a shot at this later today. daveS

You got the basic picture. The first part of the problem, P(0), P(1), etc. is a straightforward binomial probability problem. I used to teach this in pre-calculus class. The second part is trickier. If you get one point for each correct pick, what is the expected value for picking no upsets vs picking one upset. That is, even though the odds are that there will be an upset, the odds are also that you will be pick the wrong game for the upset to occur. I wound up figuring out the EV for picking no upsets is 2.79 and the EV for picking one upset is 2.42, so in this case it's better not to guess. Aleta

Aleta, I don't know enough about the NCAA tournament to understand the question, so I had to resort to some googling. I take it we're talking about the four #5 seed vs. #12 seed games in round 1? And if so, are we trying to find P(0 upsets) and P(1 or 2 upsets) in round 1, assuming a 70% chance of an upset in each of the 4 games? I have a feeling you're asking about something much harder, which I wouldn't even know how to approach... daveS

Cool. So much of this math is stuff I know very little about, other then the broad outline of the issues, but it is fascinating. I particularly like probability. Here's a problem that I'm working on while I start getting geared up for March Madness: given that 5 seeds beat 12 seeds 70% of the time (an empirical fact based on the past 26 years, as of last year), what is the expected value of picking no upsets versus one or two upsets. What's the best strategy from a purely mathematical point of view. Totally off-topic, I know: no infinity involved, although I am skeptical about any metaphysical considerations. :-) Aleta

Aleta, Thanks. I think I'm more in agreement with you than with Nelson about these philosophical issues, but I do find the closing paragraphs of his chapter 1 quite poetic. Looking at his wikipedia page, sadly he passed away a couple of years ago. I didn't realize it until now, but he was the "Nelson" of the Hadwiger-Nelson problem, which has fascinated me for many years. An all-around genius, apparently:

Nelson made contributions to the theory of infinite-dimensional group representations, the mathematical treatment of quantum field theory, the use of stochastic processes in quantum mechanics, and the reformulation of probability theory in terms of non-standard analysis. For many years he worked on mathematical physics and probability theory, and he retained a residual interest in these fields, particularly in connection with possible extensions of stochastic mechanics to field theory. In 1950, Nelson formulated a popular variant of the four color problem: What is the chromatic number, denoted χ, of the plane? In more detail, what is the smallest number of colors sufficient for coloring the points of the Euclidean plane in such a way that no two points of the same color are unit distance apart? We know by simple arguments that 4 ≤ χ ≤ 7. The problem was introduced to a wide mathematical audience by Martin Gardner in his October 1960 Mathematical Games column. The chromatic number problem, also now known as the Hadwiger-Nelson problem, was a favorite of Paul Erdös, who mentioned it frequently in his problems lectures.

daveS

My spouse loves books, and has quite a collection. With that said, there's a Facebook meme going around that says:

Rule #12: The correct number of books to own is n + 1, where n is the number of books currently owned.

Yikes - no wonder we keep running out of bookshelf space. When will it ever end? :-) Aleta

Well this is very interesting. The last paragraph of Chapter 1 of Nelson's book brings up some major topics that tie into several different issues in this discussion.

It appears to be universally taken for granted by mathematicians, whatever their views on foundational questions may be, that the impredicativity inherent in the induction principle is harmless - that there is a concept of number given in advance of all mathematical constructions, that discourse within the domain of numbers is meaningful. But numbers are symbolic constructions; a construction does not exist until it is made; when something is new is made, it is something new and not a selection from a pre-existing collection. There is no map of the world because the world is coming into being.

Now I realize that Nelson's book is presenting a non-standard "radical" view, and without agreeing or disagreeing with all he says, here are some comments. I have argued differently: I have argued that via the symbolic abstraction of pure mathematics, we can embrace a totality - the infinite set of natural numbers. However, I have also argued that this need not refer to anything beyond mathematics: if does not refer to any actual infinity in the real, physical world, but nor does it need to refer to any speculative metaphysical reality such as a world of Platonic ideals, the mind of God, or the Tao. Nelson's notions are even further removed from metaphysics than my view, and there are some important ways in which I agree with him. He says,

But numbers are symbolic constructions; a construction does not exist until it is made; when something is new is made, it is something new and not a selection from a pre-existing collection. There is no map of the world because the world is coming into being.

This is the view that mathematics is invented, not discovered. In spite of the sense that the conclusions were "already there", so to speak, as we "bring them alive" via our logical constructions, they in fact don't exist until the moment our symbolic, logical system brings them into mathematical being. Until someone thought of using iterative functions with complex numbers to create what we now call fractals, and in fact explored the function that creates what we now call the Mandelbot set, there was no Mandelbrot set: math, according to Nelson's statement, is a world coming into being, not a map of some some pre-existing world that we tap into somehow. It is man-made, and its truth and meaning reside within itself, not in reference to anything outside itself. So even though I think that "there is a concept of number given in advance of all mathematical constructions, [and] that discourse within the domain of numbers is meaningful" (that is to say, that we can consider the infinite nature of the numbers as a completed whole), I also learn towards Nelson's view that when we create mathematics we are making "something new and not [making] a selection from a pre-existing collection." Very interesting find, dave. Aleta

Thanks, looks interesting, doing an OCR. KF kairosfocus

KF, I haven't found the source on Russell yet, but looking through another Feferman paper, I found this quote:

There is a radical form of predicativism which does not accept the natural numbers as a “completed totality”, i.e. over which unbounded quantification has a definite truth-functional value. This is the sense of [Nelson 1986]; Nelson’s system is much weaker than PRA, Primitive Recursive Arithmetic, whereas PRA itself is already acceptable to finitists.

which I think might be even closer to what we're discussing. Edward Nelson has actually made the entire book available on his website here. The first chapter (approximately 1 page long total) gives a nontechnical rationale for this radical form of predicativism that Feferman refers to. daveS

DS, okay, do let me know. I agree a specific stated value in PVN or Sci Not'n or the Knuth multiple up arrows notation or whatever will be finite, but due to endlessness there is an onward continuation per do forever that we cannot capture other than by indicating endlessness. This leads to numbers pointed to in general but not defined specifically as 2.8769 *10^2145 would be, in PVN 287690 0 0 . . . 0, where there are 2141 0's to follow. (Obviously writing wholes this way requires care not to put in an inadvertent fractional value.) KF kairosfocus

I asked Origenes some questions in a post at 994 that were a follow up to an earlier conversation. He may not have seen it, and even if he does may not want to respond (which is fine), but I thought I'd bump the issue one time. Aleta

KF, One qualification: I'll have to check the original source to be sure I'm not misstating Russell's position. I'm not clear on whether he allows universal quantification over infinite sets or not (as opposed to arbitrary classes). Note that the passage does make clear that this is allowed:

any particular proposition p is either true or false

but this isn't:

For all propositions p, p is either true or false

although the law of the excluded middle is often stated in that form. daveS

DS, It seems Lord Russell has a point. As I have noted above several times, particular, defined, stated numbers will either come as results of +1 stage finite cumulative steps from 0, or will be stated in forms that depend on such, place value, scientific, etc. The values we can reach will therefore be just as finite. But endlessness must be taken seriously. In that context w is in material part an emergence and recognition of a new quantitative phenomenon rather than a direct successor to any definite individual stated in particular value counting number k. The tapes exercise also shows the process can be repeated endlessly, any arbitrary number of times with the same result. Endlessness is truly extremely strange but pivotal. KF kairosfocus

KF, Reflecting a bit on my post #926, I'm more convinced that your position is quite similar to Russell's regarding N. The gist of that passage is that this is legitimate:

Any particular natural number is finite.

while it is not ok to say:

For all n ∈ N, n is finite.

Is that something you agree with? daveS

UD Editors: We are releasing this comment from moderation in connection with a permanent ban of VC. All commenters should be aware that the surest and fastest way to be shown the exit from these pages is to cast aspersions on our faith.

I guess that's a clear --and interesting-- statement. hrun0815

KF,

DS, every defined prime will be stated as a place value notation number or the like, so it will be finite and on Hamming distance will be finitely distant from 0. As a finite value, there will be endlessly more values beyond that are not defined other than being in the span of onward endlessness.

Can you elaborate on what the bolded "not defined" means? How do I distinguish between "defined" and "not defined" numbers?

What does the pink vs blue tape example indicate about that endlessness?

The pink and blue tape example illustrates that the set N can be put into 1-1 correspondence with proper subsets of itself, and therefore N is infinite. daveS

DS, every defined prime will be stated as a place value notation number or the like, so it will be finite and on Hamming distance will be finitely distant from 0. As a finite value, there will be endlessly more values beyond that are not defined other than being in the span of onward endlessness. What does the pink vs blue tape example indicate about that endlessness? KF kairosfocus

EZ, moderation as stated is not banning. VC has a chance to set himself to the right on attitude. OOPS, just saw the further interaction. He is now banned for cause. KF kairosfocus

UD editors I'm not disagreeing with you on banning Virgil Cain based on his comments and attitude. He was/is combative and antagonistic most of the time. And, it's your blog. You get to make the rules. I will however vote for allowing dissenting views their time on UD. I appreciate the fact that the UD editors have allowed this thread to continue on at great length. And for granting a forum for a discussion of a serious issue without attempting to influence or guide the debate. It is much appreciated. ellazimm

KF, Yes, I see how a physical science perspective could differ from a pure-mathematical perspective.

DS, I think it is more accurate to say that I hold that in the successive counting sets endlessness is a part of the core definition: {0,1,2 . . . }. Where, any specific value we can reach by +1 succession or by stating in notations based on that (e.g. sci notation) will be finite. I do not find it strange in that context that primes may be very far apart, and as we have an existence proof there is no specific largest prime, that far apart-ness has to reckon with the ellipsis of endlessness. However there is no prime we can represent in any specific notation such as place value binary or decimal or hexadecimal or the traditional sexagesimal that will be more than a finite span from the finite [and prime riddled] near neighbourhood of 0, as in 0,1,2,3 etc. KF

Hm. Does this leave open the possibility that there are primes infinitely far from 0? daveS

Virgil Cain is in moderation for responding in kind to his attackers. What kind of moderation punishers the responder and not the people who provokes him with lies, bluffs and personal attacks? Surely not Christians... UD Editors: We are releasing this comment from moderation in connection with a permanent ban of VC. All commenters should be aware that the surest and fastest way to be shown the exit from these pages is to cast aspersions on our faith. Virgil Cain

We look forward to seeing your system, Virgil. Aleta

Virgil

Bijective function, just as I have been saying all along.

So what is the bijective function between the positive integers and the prime numbers? And between sets A and B and the positive integers.

I have using set subtraction.

Except that no one agrees with you or uses the same technique.

That is incorrect. I asked for something specific and it has not been addressed.

Those were specific examples. Maybe you don't understand them.

OK so Jerad doesn’t have any support for his diatribe. All you had to do is say so, Jerad.

You still haven't figured out the relative cardinality of the primes or sets A and B above. The rest is just avoiding the failings of your ideas. If you want to figure out my view then you can read a standard book on set theory. Which I have suggested before. You will find no one using set subtraction regarding cardinality. ellazimm

UD Editors: Virgil Cain is in moderation until he apologizes for inappropriate tone and refusal to heed warnings. Barry Arrington

ez:

How did you figure out the relative cardinality of the evens is one-half that of the positive integers?

Bijective function, just as I have been saying all along.

If you disagree with long-standing and non-controversial mathematics then it is upon you to prove your case.

I have using set subtraction.

It’s two examples of how Cantor’s idea is used. It’s what you asked for.

That is incorrect. I asked for something specific and it has not been addressed. OK so Jerad doesn't have any support for his diatribe. All you had to do is say so, Jerad. Virgil Cain

Virgil

I do? I use it to see if there is a difference between the number of elements.

How did you figure out the relative cardinality of the evens is one-half that of the positive integers? That the relative cardinality of the multiples of three is one-third that of the positive integers?

Yes, it does and you aren’t anyone to say otherwise.

Only you say it does. And you can't find anyone else who agrees with you.

And we know that people who say that are ignorant or desperate

Just because you say so? Where is your academic support and references? If you disagree with long-standing and non-controversial mathematics then it is upon you to prove your case.

LoL! Please show me where I said that. If you cannot then please dismiss yourself from this discussion as you are too dishonest to be in it.

Then how do you calculate relative cardinalities?

And what, exactly, does that have to do with saying that all countable and infinite sets have the same cardinality?

It's two examples of how Cantor's idea is used. It's what you asked for.

Academic reference please. Or retract it.

Find an example where it is used in a mathematical research paper or book. It gives you ambiguous answers like when you use it to compare the primes to the positive integers. Cantor's work gives you consistent, workable answers. Instead of just asserting that you are right and everyone else is wrong please read through this: https://en.wikipedia.org/wiki/Countable_set and point out any mistakes you think were made. ellazimm

Aleta, okay. Indeed it is my value on coherence that flags to me claims about infinitely many +1 successive finite values from 0 as at least paradoxical. Where that has led me is to the conclusion that endlessness is pivotal and any arbitrarily large but finite k has endlessly many successors that can be put in 1:1 correspondence with the set from 0,1,2 on. And that forces a more cautious view of ordinary mathematical induction. KF kairosfocus

DS, I think it is more accurate to say that I hold that in the successive counting sets endlessness is a part of the core definition: {0,1,2 . . . }. Where, any specific value we can reach by +1 succession or by stating in notations based on that (e.g. sci notation) will be finite. I do not find it strange in that context that primes may be very far apart, and as we have an existence proof there is no specific largest prime, that far apart-ness has to reckon with the ellipsis of endlessness. However there is no prime we can represent in any specific notation such as place value binary or decimal or hexadecimal or the traditional sexagesimal that will be more than a finite span from the finite [and prime riddled] near neighbourhood of 0, as in 0,1,2,3 etc. KF kairosfocus

Aleta:

Of course Virgil didn’t say what those cardinalities are, because he has no system for naming them, but he certainly said that set subtraction can prove that infinite sets have different cardinalities.

Right but coming up with a system won't be that difficult. But thank you for your support. Virgil Cain

kf asks, "Aleta, at what point did I ever give any indication that I do not have a very high view indeed of coherence? " I didn't say you did, kf. I approved your statement about coherence, and was just making sure that you weren't expressing any reservations about proof by contradcition. Your statement that "I have always freely accepted proofs of a claim T by reductio ad absurdum of the denial ~T, which is what proofs by contradiction of the denial are about" makes that clear, and all is well. Aleta

When EZ wrote, "You say set subtraction can be used to calculate the relative cardinality of infinite sets", Virgil wrote,

LoL! Please show me where I said that.

Hmmm. In 261, Virgil wrote,

Let set A = {0,1,2,3,4,5,…} Let set B = {1,3,5,7,9,11,…} Let set C = {0.2.4.6.8.10,…} A – B = C, proving that all countably infinite sets do not have the same cardinality, ie the same number of elements. And only contrived mental gymnastics can get around that fact.

Of course Virgil didn't say what those cardinalities are, because he has no system for naming them, but he certainly said that set subtraction can prove that infinite sets have different cardinalities. Aleta

Aleta, at what point did I ever give any indication that I do not have a very high view indeed of coherence? Whether in the logical study of structure and quantity or elsewhere? Up to and including holding that coherence is a major worldview test and firmly affirming ex falso quodlibet? And, that self-evident truths are not only manifest to the person able to understand but that the attempted denial instantly lands in patent incoherence and so confusion. Frankly, I hold that the only place a contradiction can exist (beyond merely being stated and symbolised) is in a confused or conflicted mind and that it undermines ability to discern truth from falsehood as if one believes the false s/he is liable to reject the contrary truth that actually conforms to reality . . . but which reality may not be obvious. I have always freely accepted proofs of a claim T by reductio ad absurdum of the denial ~T, which is what proofs by contradiction of the denial are about. KF kairosfocus

ez:

It just doesn’t work with infinite sets.

Academic reference please. Or retract it. Virgil Cain

For DiEB: If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? Virgil Cain

DiEB:

1) Calculus is introduced today via the idea of sequences and limits. Manipulating limits, you often use these very ideas, by dropping a finite number of elements of the sequence, renumbering it, looking at sub-sequences etc.. 2) Think of topology: first-countable spaces, second-countable spaces, separable spaces – here it comes often handy that you can enumerate the bases…

And what, exactly, does that have to do with saying that all countable and infinite sets have the same cardinality? What would be affected if Cantor was wrong about that? Virgil Cain

DS, I think I am seeing something there. I think that as one whose home is physics and the like, I tend to look at phenomena and patterns as pointing, and possibly reliable, in a wider context of holding that here are powerful ordering laws in different aspects of reality forming a coherent whole. So if there is a pattern that becomes evident, I see no reason to doubt its continuation absent some countervailing evidence. Proofs are useful in that context but I bear in mind the problems Godel unearthed on axiomatic systems. A theorem in Math relative to an axiom system is not to me a sign of absolute truth but of high credibility and reliability especially in a field that has been around for enough time that the debugging of many eyes has had a chance to pick up readily detectable or even rarer marks of incoherence. Correlation to on the ground facts of math or physical reality or wider intellectual thought help support that confidence. That is part of why I tend to go to models, frameworks and thought exercises. In part, test cases, in part paradigmatic applications and anchorages to experienced reality including of the thought world. I understand mathematics to be the logical study of structure and quantity. Just as my profs taught and exemplified. I take that in the extended sense to include inductive explorations. So for instance when I see a pattern of increasing sparseness of primes in 1 - 1,000, and the dynamic that as we go up we have more and more primes to become prime factors, it is obvious that primes will be sparser as we go on to higher ranges, and indeed a log type decay is not surprising. No of primes per octave or decade of bandwidth is roughly linear in effect once we get far enough along to settle down. That does not prove a theorem but it makes it unsurprising. It is in that context that I found the claims being made on infinite set of finite successive +1 values from 0. At minimum paradoxical. On closer look, my take-away, is the ellipsis of endlessness is pivotal, as the pink vs blue tapes thought exercise underscores. This has implications for how I now look at ordinary mathematical induction, and at axioms that imply or express dependence on succession in steps of finite stage from 0. Endlessness is the heart of the primary sense of infinite, going endlessly beyond any arbitrarily large finite value. Which the tapes example shows cannot be traversed in finite stage steps of accumulated progress. This then speaks to causal chains that propagate in stages, and it makes a claimed infinite past for our world and its direct antecedents problematic or even dubious. KF kairosfocus

ez:

Well, you have yet to use set subtraction to figure out the relative cardinalities of the primes and sets A and B.

I do? I use it to see if there is a difference between the number of elements.

The proof says take all the primes you know and multiply them together.

Lol! That is what I said OK so set subtraction is supported by set theory. Good, we have made some progress today.

It just doesn’t work with infinite sets.

Yes, it does and you aren't anyone to say otherwise.

We do understand. We just know it doesn’t work with infinite sets.

And we know that people who say that are ignorant or desperate

You say set subtraction can be used to calculate the relative cardinality of infinite sets

LoL! Please show me where I said that. If you cannot then please dismiss yourself from this discussion as you are too dishonest to be in it. Virgil Cain

kf, you write,

PS: That we are relying on proof by contradiction to carry enormous weights is a deep and pervasive commitment to coherence of truth and the constraining power on reality posed by logic and its core three laws, identity, non contradiction and excluded middle.

I assume this means you support proof by contradiction, and have no reservations about its power - true? I just want to make sure that I understand your P.S. as a confirmation that proof by contradiction is valid logic. Aleta

KF, One more post before I have to go. Here's a thought experiment. Consider the set S of all natural numbers n such that there exist two consecutive primes p and q such that p and q are separated by a distance of at least n (so |p - q| ≥ n). 1 ∈ S because |3 - 2| ≥ 1. 4 ∈ S because |11 - 7| ≥ 4. (2 and 3 are clearly in S as well). In fact, it's elementary to show that S = N. If, as you say, there are infinite numbers in N, then that means there are two consecutive primes that are separated by an infinite distance! Does that sound right to you? That's one reason I believe you won't be able to prove the statement I posted at the end of #1004, a form of which you have presented in this thread. daveS

KF,

DS, that where specifically a prime will pop up is not currently predictable or reducible to simple readily carried out fast algorithm is worlds apart from, primes exist and can be expected to continue to crop up on an increasingly sparse but non-vanishing dynamic.

Why can they be expected to do so, without actually going through a proof? How do you know the density of primes continues to decrease on average? Again, without actually proving the prime number theorem. daveS

KF, Like I said, we use the term "obvious" in quite different ways, so I believe we're talking past each other to some extent.

Th primes pop up in the first two tens of numbers, showing many of their characteristics, and by 100 to 1,000 they are showing many rarer patterns such as increasing sparseness. But there is no reason to believe on a pattern of ever increasing and endless numbers that there will at some point be no further numbers that are prime. That is something that can be readily seen by one open to it.

Except perhaps the increasing sparseness one observes when one looks at larger and larger primes.

But there is nothing at all objectionable in saying that there is a pattern that is easily seen — is obvious — and would lead to expecting primes to continue cropping up, however sparsely.

True, and I never stated otherwise.

I do not see why you would be wanting to belabour so simple a matter as thought here must be something there that a 10 – 12 year old child could not spot, and as though there must be something wrong with pointing to patterns.

Again, I never stated there was something wrong in pointing to patterns. I think that's how mathematicians make conjectures and go on to prove theorems.

And yet, Aleta picked up the matter [I had not had anything to do with it] and pushed it in my direction in a way that suggests, let’s see you handle this (and even a presumption of a view I do not hold), and you have gone on post after post as though there is something wrong with seeing what I saw as a child and still see — a point that you have not actually answered to.

There is nothing wrong with what you saw as a child. We all observe patterns and make conjectures, even more so as adults. daveS

PS: That we are relying on proof by contradiction to carry enormous weights is a deep and pervasive commitment to coherence of truth and the constraining power on reality posed by logic and its core three laws, identity, non contradiction and excluded middle. kairosfocus

DS, that where specifically a prime will pop up is not currently predictable or reducible to simple readily carried out fast algorithm is worlds apart from, primes exist and can be expected to continue to crop up on an increasingly sparse but non-vanishing dynamic. Then, we can see theorems that support these expectations, moving from patterns and trends to proofs. Beyond, that so sparse a subset is also transfinite underscores the endlessness of counting numbers and the point that such cannot be exhausted in finite stage steps. With implications for claimed actually completed infinite past causal stage chains being seriously problematic. KF kairosfocus

Virgil

Spoken like a little baby who lost its bottle.

Well, you have yet to use set subtraction to figure out the relative cardinalities of the primes and sets A and B. You should work on that.

No, but it tells me that the cardinalities are/ can be different.

But not what they are. I can tell you what they are using a one-to-one mapping.

And yet it is part of the proof.

Not at all. The proof says take all the primes you know and multiply them together.

You have spewed so many false accusations that no one cares what you think.

Well I'm sorry but you don't seem to get how they work or what they mean.

I don’t know but YOU told me that infinity acts differently than the finite.

But the proof doesn't involve infinite numbers. Everything in the proof is finite.

OK so set subtraction is supported by set theory. Good, we have made some progress today.

It just doesn't work with infinite sets.

All this talk about my not understanding math and yet my detractors can’t even grasp the implications of standard set subtraction. Strange but true…

We do understand. We just know it doesn't work with infinite sets. Virgil, you claim you are right and Cantor was wrong. You say set subtraction can be used to calculate the relative cardinality of infinite sets. Show us how to use set subtraction to calculate the primes and sets A and B I defined above. DiEb

1) Calculus is introduced today via the idea of sequences and limits. Manipulating limits, you often use these very ideas, by dropping a finite number of elements of the sequence, renumbering it, looking at sub-sequences etc..

Taylor series, Fourier Analysis, etc. And that's just basic, undergraduate stuff. Virgil told me once he took a Calculus course. I would think he would know all this stuff already. ellazimm

DS, it seems there is a problem on appreciating the difference between the axiom, theorem proof approach and the wider patterns and dynamics of mathematics. Th primes pop up in the first two tens of numbers, showing many of their characteristics, and by 100 to 1,000 they are showing many rarer patterns such as increasing sparseness. But there is no reason to believe on a pattern of ever increasing and endless numbers that there will at some point be no further numbers that are prime. That is something that can be readily seen by one open to it. Proving such a result formally may be a bigger challenge, and the proof that there is a sparseness metric is yet harder to show. But there is nothing at all objectionable in saying that there is a pattern that is easily seen -- is obvious -- and would lead to expecting primes to continue cropping up, however sparsely. We can then go beyond to actual theorems, a different matter. I do not see why you would be wanting to belabour so simple a matter as thought here must be something there that a 10 - 12 year old child could not spot, and as though there must be something wrong with pointing to patterns. And yet, Aleta picked up the matter [I had not had anything to do with it] and pushed it in my direction in a way that suggests, let's see you handle this (and even a presumption of a view I do not hold), and you have gone on post after post as though there is something wrong with seeing what I saw as a child and still see -- a point that you have not actually answered to. The theorems came later in my experience, and yes they are important too but they are not the be all and end all. Where, obviously sparseness is sparseness. KF kairosfocus

@Virgil

Nope, you are lying, again. No one uses the concept that all countable and infinite sets have the same cardinality. It is useless and sterile.

1) Calculus is introduced today via the idea of sequences and limits. Manipulating limits, you often use these very ideas, by dropping a finite number of elements of the sequence, renumbering it, looking at sub-sequences etc.. 2) Think of topology: first-countable spaces, second-countable spaces, separable spaces - here it comes often handy that you can enumerate the bases... DiEb

KF,

primes exist starting with the first two cycles of 10 and pop up at points in the +1 succession from 0 where — beyond 2 — they must follow a pattern

Pattern? If so, it's a very complicated pattern. The intervals between discoveries of the largest known primes have been on the order of years in recent history, even with at least one distributed computing project searching for them.

Obviously, as one goes deeper into numbers, primes must become ever more sparse as the number of prime factors mounts up as each successive prime comes into play.

"Obviously"?

Now, where in this pattern is there anything that suggests primes will ever peter out to no further primes?

Well, the fact that we can observe empirically that they appear to become more sparsely distributed as one looks at finite subsets of large integers? The fact that it is elementary to construct arbitrarily large sequences of consecutive composite integers?

Indeed, per Wiki for convenience, “the prime number theorem, proven at the end of the 19th century, which says that the probability that a given, randomly chosen number n is prime is inversely proportional to its number of digits, or to the logarithm of n.” That is, there is a sparseness metric that gives an estimate of the density of primes at a given order of magnitude, of order – ln n.

Yes, of course, but the prime number theorem is much less obvious than the proof that Aleta gave!

The first is that, despite their simple definition and role as the building blocks of the natural numbers, the prime numbers grow like weeds among the natural numbers, seeming to obey no other law than that of chance, and nobody can predict where the next one will sprout.

The above quote explains why I would not say the primes follow a "pattern".

I highlight this side of things as the intuitive ability to see significant features and patterns (what appears in conjectures . . . ) is a highly significant part of Mathematics, indeed many key challenges that have moved the discipline forward have come about by addressing such.

Yes, but our intuition can be wrong. Lots of "obvious" propositions turn out to be false. I think you and I just use the word in different ways, and there is not much point in pursuing this particular issue further.

Now, obviously, I am not unaware that there is a longstanding proof of there being no greatest prime.

Of course. I suspect everyone here understood you were aware of Euclid's proof. I think the rest of your post is already on the table. I will repeat my request for a proof of the following:

Let S be the smallest set such that: 1) {} ∈ S 2) If n ∈ S, then n ∪ {n} ∈ S Then there exists a set m ∈ S such that m is infinite.

daveS

All this talk about my not understanding math and yet my detractors can't even grasp the implications of standard set subtraction. Strange but true... Virgil Cain

OK so set subtraction is supported by set theory. Good, we have made some progress today. Virgil Cain

ez:

It doesn’t seem to be helping you to figure out the relative cardinality of the primes or sets A and B

Spoken like a little baby who lost its bottle.

Pardon me for not summarising the complete foundation of modern mathematics.

And another bluff.

And it doesn’t seem to be helping you to figure out what the relative cardinality of the primes is. Or sets A and B.

No, but it tells me that the cardinalities are/ can be different.

The proof doesn’t require you to do that.

And yet it is part of the proof.

I’m not sure you really understand mathematical proofs.

You have spewed so many false accusations that no one cares what you think.

Like what? What could happen?

I don't know but YOU told me that infinity acts differently than the finite. Virgil Cain

Virgil ellazimm, Set subtraction is part of set theory. Perhaps you don’t know set theory. It doesn't seem to be helping you to figure out the relative cardinality of the primes or sets A and B.

People like you, mainly. That is people who are unable to tell us the utility, tell us who uses it and what it is used for. All you do is bluff and lie every time you try to answer. That says it all

Pardon me for not summarising the complete foundation of modern mathematics.

And I have told you over and over again that is meaningless drivel and doesn’t even address the concept we are debating. Look, obviously you have nothing but your bluffs, lies and misrepresentations. Now you seem to have forgotten that set subtraction is part of set theory!

I didn't forget, I use it when appropriate. And it doesn't seem to be helping you to figure out what the relative cardinality of the primes is. Or sets A and B.

1- You have not done the math until you have multiplied the primes

The proof doesn't require you to do that. You can deal with things abstractly.

2- All along you have been telling me that infinity is not intuitive and that it is different. Now, with primes, you are saying the opposite.

I don't think that is what she is saying at all.

And that is my point about validating the proof. Perhaps something strange happens with those large numbers.

Like what? What could happen? I'm not sure you really understand mathematical proofs. ellazimm

I don’t know who you think has to ‘use’ something until you consider it important.

How important can it be if no one uses it for anything? Do tell.. Virgil Cain

Aleta- Two things: 1- You have not done the math until you have multiplied the primes 2- All along you have been telling me that infinity is not intuitive and that it is different. Now, with primes, you are saying the opposite. And that is my point about validating the proof. Perhaps something strange happens with those large numbers. Virgil Cain

ellazimm, Set subtraction is part of set theory. Perhaps you don't know set theory. Nope, you are lying, again. No one uses the concept that all countable and infinite sets have the same cardinality. It is useless and sterile.

And you know this because

People like you, mainly. That is people who are unable to tell us the utility, tell us who uses it and what it is used for. All you do is bluff and lie every time you try to answer. That says it all

I have told you over and over again that Cantor’s ideas are fundamental to the foundation of modern mathematics and thus are ‘used’ every day by mathematicians.

And I have told you over and over again that is meaningless drivel and doesn't even address the concept we are debating. Look, obviously you have nothing but your bluffs, lies and misrepresentations. Now you seem to have forgotten that set subtraction is part of set theory! Virgil Cain

DS, primes exist starting with the first two cycles of 10 and pop up at points in the +1 succession from 0 where -- beyond 2 -- they must follow a pattern p_k = 2*x + 1, x a chain of at least one prime factor . . . (Obviously, this only says, they are odd from 3 on; evens beyond 2 must meet the expression 2*x. Primes will be such that in addition to being odd, they will have no factor f that evenly divides, ignoring 1) . . . where factorisation on primes is a specifically taught skill. Obviously, as one goes deeper into numbers, primes must become ever more sparse as the number of prime factors mounts up as each successive prime comes into play. Now, where in this pattern is there anything that suggests primes will ever peter out to no further primes? Nowhere, so there is an obvious pattern of endlessness of numbers and no good reason for us to expect primes to vanish. Indeed, per Wiki for convenience, "the prime number theorem, proven at the end of the 19th century, which says that the probability that a given, randomly chosen number n is prime is inversely proportional to its number of digits, or to the logarithm of n." That is, there is a sparseness metric that gives an estimate of the density of primes at a given order of magnitude, of order - ln n. Wolfram on primes notes:

Euler commented "Mathematicians have tried in vain to this day to discover some order in the sequence of prime numbers, and we have reason to believe that it is a mystery into which the mind will never penetrate" (Havil 2003, p. 163). In a 1975 lecture, D. Zagier commented "There are two facts about the distribution of prime numbers of which I hope to convince you so overwhelmingly that they will be permanently engraved in your hearts. The first is that, despite their simple definition and role as the building blocks of the natural numbers, the prime numbers grow like weeds among the natural numbers, seeming to obey no other law than that of chance, and nobody can predict where the next one will sprout. The second fact is even more astonishing, for it states just the opposite: that the prime numbers exhibit stunning regularity, that there are laws governing their behavior, and that they obey these laws with almost military precision" (Havil 2003, p. 171).

I highlight this side of things as the intuitive ability to see significant features and patterns (what appears in conjectures . . . ) is a highly significant part of Mathematics, indeed many key challenges that have moved the discipline forward have come about by addressing such. This skill of spotting patterns in mathematical facts and inferring dynamics that may be at work to be assessed and tested through logical connexion to axiom systems and already established key results . . . aka theorems . . . is in fact at the heart of serious praxis of Mathematics. That is already important and too often sadly neglected in overly utilitarian and theorem-proof approaches to learning and understanding Mathematics. Now, obviously, I am not unaware that there is a longstanding proof of there being no greatest prime. An important result. You will see above that I responded to a direct suggestion that I would be likely to reject it or have questions, by pointing to the need for insightful context not just bare bones proofs. Now, there is an onward import. Here we have a reasonably accessible proof that a subset of counting numbers, the primes, goes on endlessly, at points that we currently have no basis for predicting and there is none in prospect. So much so, large primes are used in coding. This highlights endlessness of counting numbers (by direct implication of a fairly accessible proof on the endlessness of a key subset, the primes), and the inability to span that endlessness in finite stage steps. Which I argue, should be recognised in our discussions and even in how we discuss ordinary mathematical induction. Lastly, let me add, that all of this ties to the point that no finite stage, successive, cumulative stepwise process can span the transfinite, can exhaust the infinite. Thus there is a logical constraint on any iterative or successive cumulative process, including causal succession in finite stages or generations. This makes assertions or implications of an infinite stepwise past causal succession of the observed physical cosmos or its suggested predecessors dubious. Which adds to the projected big bang, and to thermodynamic concerns etc on infinite past speculations. And arguments that at any point in the past we were finitely remote from now only manage to entail that the stepwise reachable past is finite. KF kairosfocus

Virgil #993

ellazimm, You are sadly mistaken as set subtraction refutes cantor’s claim wrt countable and infinite sets having the same cardinality. You can ignore that as you have always done but that reflects poorly on you.

I haven't ignored that. I've asked you over and over again to provide any kind of research or academic support you can find for your view. You haven't found any. I've asked you over and over again to use your 'concept' to find the relative cardinality of the prime numbers and sets A and B I defined above. You haven't been able to to those things. You claim that Cantor got it wrong but you have never been able to find a fault in any proof pertinent to the discussion. You ask people to take you seriously but you provide no cause for us to do so.

You are also sadly mistaken about the utility of the concept. You cannot show us who uses it nor what it is used for. And you have lied about that this entire time.

I have told you over and over again that Cantor's ideas are fundamental to the foundation of modern mathematics and thus are 'used' every day by mathematicians. I don't know who you think has to 'use' something until you consider it important. The discussion here is about mathematics. Would you consider the fact that there are infinitely many primes useless because you don't use it? You seem too to confuse theories and theorems. Only mathematics has theorems, things that have proven to be true. If you claim a theorem is incorrect then it's down to you to find a fault in the proof. If you can't, it stands and no amount of asserting or proclaiming matters. Nothing personal, purely objective.

Shame on you and shame on me for trying to have a discussion with you.

It hasn't been much of a discussion. I've asked you some pretty basic questions which you couldn't answer. Aleta I'd love to buy you a drink!! You are very patient and very right. ellazimm

For Origenes, perhaps Mike, and others. The question we discussed earlier, before mutually deciding to part, was something like this. (And Origenes is welcome to rephrase the questions: agreeing on what exactly we are talking about would be a good constructive step.) Where does the truth and meaning of math come from? Can math embody its own truth and meaning within itself as a logical system? Must math be grounded in either the physical world and/or some metaphysical theist/Platonic world to truly have truth and meaning? My answer is that math does embody its own truth and meaning within itself as a logical system. I also belief its foundation began with our experience of the physical world, but, just as with language, the ability to create symbolic systems that are logically coherent has enabled us to transcend that grounding in the physical world. We create math that may be applied back to the world, and that involves a further modeling process that builds on mathematical truths. Applying math to the physical world always is imperfect, if for no other reason than the mathematical concepts are abstractions which are perfect in a way the physical world never can be. I don't believe any metaphysical grounding of math is necessary to validate mathematical truths. I personally am quite agnostic about how and/or whether there is any correspondence between the math we develop and some metaphysical correlate of that math. So that's my position. In order to support it, I'd like to start at the beginning and tell some stories about the history of math. With that context, I will then be interested in any comments about my what people might have to say about the conclusions I reach. Learning to count, and the beginning of the natural numbers (P.S> Although I'm not going to cite sources, I think the stories I'm about to tell are supported by anthropological and archeological evidence.) The simplest way to see if two sets have the same number of items is to match them in a 1:1 correspondence. If I am trading you camels for cows, we can match them up and make sure we have five of each. But given that we have the ability to use language, sometime in the far pre-historic past, people developed words for small sets of objects. A single rock was "one", put another rock with it and that set is "two", etc. This established a 1:1 correspondence between objects and a set of words, so we didn't have to physically match the objects in two sets: we count count one set and then separately count the second to determine if the sets had the same number of items. (As I mentioned in an early post, children usually learn the set of words one, two, three, etc. before they actually understand that you have to apply them in a 1:1 correspondence in order to count properly.) All this happened before written symbols for the numbers were invented. Some interesting archaeological evidence from the Middle East leads to this story: Suppose I am sending 20 camels to India to trade for other goods, and I am entrusting my camels to a trader. However, I am concerned that the trader might not be honest: he might sell a couple camels along the way, and tell the guy in India I only sent 18 camels. We have no written numbers: what can we do? We count 20 small stones and bake them into a closed clay spherical pot, and inscribe our seal on the outside. When the trader gets to India, he gives the pot to the buyer, who breaks the pot, counts the stones, and thus ascertains that he is getting the correct number of camels. The next important step in the development of this very fundamental math was written symbols for the numbers. At some point, the idea of using hash marks (the traditional four vertical lines and a fifth line slanting across them) as a second set of physical objects to be in 1:1 correspondence with the first set was developed. So, in the case of the camel trader, he now scribes 20 hash marks on the outside of the pot. Interestingly enough, we have found these pots with both the stones inside and the hash marks: during this transition they didn't totally trust this new-fangled harsh mark business. :-) However, later we find just the hashmarks, and not the stones, on tablets (because the pot to enclose the stones is no longer necessary.) And thus, written symbols for numbers were invented. From there of course, things became more symbolic: five hash marks became a V, ten hash marks an X, etc. And eventually our modern Arabic numerals and the decimal number system became universal. Furthermore, symbolic representations of various facts beyond just counting were now possible, such as 2 + 3 = 5. Conclusions and questions At this point we have a progression concerning the start of the natural numbers: physical reality -> symbolic representation in words -> symbolic representation in written symbols. So the question is where is the meaning and truth of math at this point? It seems to me that it is clearly grounded in the 1:1 correspondence between the real world, on the one hand, and verbal and written symbols on the other. No metaphysical interpretation is necessary: 2 + 3 = 5 as a fact expressed in symbols has a corresponding truth in the real world when you put a set of two rocks with a set of three rocks. One might have a metaphysical belief about the truth of 2 + 3 = 5, but that is not really necessary at all for understanding the truth of 2 + 3 = 5: just look at the rocks. So my question is very broad: to what extent does Origenes, or anyone else agree with this last paragraph? And if one has disagreements, what are they? Aleta

ellazimm, You are sadly mistaken as set subtraction refutes cantor's claim wrt countable and infinite sets having the same cardinality. You can ignore that as you have always done but that reflects poorly on you. You are also sadly mistaken about the utility of the concept. You cannot show us who uses it nor what it is used for. And you have lied about that this entire time. Shame on you and shame on me for trying to have a discussion with you. Virgil Cain

KF,

DS, notice, I spoke to an obvious pattern. Plausibility fits under that, so I do not know why there seems to be a dispute over a point that sums up what I saw as a youngster based on dynamics and properties of the succession of counting numbers . . .

Well, the fact that the prime numbers do not follow an obvious pattern is one reason I don't feel it's "obvious" there are infinitely many of them. There is no formula for the nth prime, of course. Furthermore, it is known that there are sequences of (at least) 10^10^150 consecutive integers, all of which are composite (insert any large integer there that you please, in fact). A priori, it's not "obvious" that you don't eventually run out. As I stated before, there are infinite rings with only finitely many primes, so that's not inconceivable.

As to undefined onward values, I point out that the ellipsis is not a definition of specific values in the way 139,854 is nor is the do forever +1 succession process... I do not see why there is a belabouring of this.

I'm not understanding your argument here either. Given that 0 is one of these values, and S(n) = n + 1 for all n ≥ 0, what exactly are the undefined values? We have, for example 0, 1, 2, 3; what's the first undefined value? Anyway, I agree this is not very interesting. I really would like you to prove this:

Likewise, point to the copy of the sequence so far successor counting set principle. An endless repetition of successive defined counting sets would end up with one or more that are in themselves endless.

In other words, prove that the smallest set S such that: 1) {} ∈ S 2) If n ∈ S, then n ∪ {n} ∈ S contains an infinite element m. That is, m is in 1-1 correspondence with a proper subset of itself. Once again, I'm asking for a proof. daveS

DS, notice, I spoke to an obvious pattern. Plausibility fits under that, so I do not know why there seems to be a dispute over a point that sums up what I saw as a youngster based on dynamics and properties of the succession of counting numbers . . . I remember, my 2nd father painting a fence late of an afternoon and asking me to count, and on reaching 100 the first time saying ten-ty, then having the standard name given and going on realising I could just keep going and going. As to undefined onward values, I point out that the ellipsis is not a definition of specific values in the way 139,854 is nor is the do forever +1 succession process, and something like the pink and blue tapes exercise shows the significance of onward endlessness. I do not see why there is a belabouring of this. I take it, we both know that the next counting set is the order type of the counting sets so far, collected. KF kairosfocus

Virgil

I have and there is a largest known prime. That supports what I said.

Largest known is not the same as largest. As Aleta's proof shows there is no largest prime. And that has been known for a very long time.

As if. Everything is up for debate especially when it is easily contradicted by standard set subtraction.

I have asked you many, many times to find a fault in proofs of theorems which establish the facts we are discussing. As you have failed to do so then the results stand.

Nope, you are lying, again. No one uses the concept that all countable and infinite sets have the same cardinality. It is useless and sterile.

And you know this because . . . you are a mathematician? No, you are not. Because you are a physicist? No, you are not. How do you know that no one uses that fundamental result of Cantor's? Have you asked any mathematicians?

You can do it, Jerad. Or admit that you are not fit for this discussion. Heck you can’t even understand that infinity is a journey. And I doubt Cantor grasped that.

I assert that you cannot use set subtraction to determine the relative cardinality of the prime numbers. Or sets A and B I defined above. And a century of mathematicians agree with me. So, if you can't do it either then it's dead.

Again, Einstein isn’t the one who proved his ideas and cantor was ignorant of Einstein’s ideas. So excuse me for trying to drag cantor into the twentieth century.

What? Physics ain't mathematics. Physics has hypothesis and theories. Mathematics has theorems. Big difference. Look it up.

No one has validated the proof.

Find the mistake then. The first time Andrew Wiles thought he had proved Fermat's Last Theorem someone found a mistake and he had to go back and do it again. Find a mistake if you think the conclusion is incorrect.

I have already explained it, Aleta. No one knows what those alleged higher primes are. And without a bijective function your alleged “one-to-one correspondence” is nothing but a pipe dream.

Incorrect.

So go ahead, Aleta, start multiplying the primes. Let me know how well you do with the twenty known largest primes…

What? That's not what the proof says.

Do the math then

Aleta did the math, the proof. That's part of what math is, proofs! If you think it's wrong then find the fault. ellazimm

Virgil, can you show me the invalid part of the proof I've offered. It is the math. Again, I am not claiming that we can figure out what every prime is. We can't. But we can proof that there are an infinite number of them, which is what the proof does. I suppose that if your only point is that we don't know all of them, then of course I agree. But if the question is how many of them are they, the answer is an infinite number. Aleta

Aleta:

I’m not talking about a 1:1 correspondence.

I am. That is the whole point.

But the proof proves there is an infinite number of primes since it proves that there is no largest prime.

Do the math then Virgil Cain

KF,

Quickly, something is obvious, that something else should be the case. If there is a pattern of numbers turning up that are prime, why should that stop simply because the numbers are going on and on? That is so before a logical proof, and it makes an expectation reasonable. It may be hard to prove, but that is a different story.

Yes, based on inductive reasoning, it's plausible (and perhaps a good bet) that there are infinitely many primes. Similarly for the prime number theorem.

Next, beyond any given specific counting number there is an endless undefined continuation, going on endlessly.

How is it undefined? The way the sequence proceeds is perfectly well-defined.

That is, there is no endless counted out set stated and in fact we cannot exhaust the set in principle much less on the material resources available to us.

Well, I don't know what that means. Anyway, I would ask you to focus on this statement:

Likewise, point to the copy of the sequence so far successor counting set principle. An endless repetition of successive defined counting sets would end up with one or more that are in themselves endless.

I say there is no chance of proving this statement. You have a function which accepts finite inputs and can produce only finite outputs. How would it ever generate an infinite output? Remember that ω is a limit ordinal. By definition, it can never be the output of the successor operation. daveS

I'm not talking about a 1:1 correspondence. I just talking about the proof that there is no largest prime. Please note well that the proof does not claim to be able to find all the primes. It just shows that there must be a larger prime, but that larger prime will not the next prime. Example: p1 = 2, p2 = 3, P = 2*3 + 1 =7, which is prime. However, 5 is also prime. 7 is prime, but not the next prime after 3. No ones know a rule for finding all the primes. But the proof proves there is an infinite number of primes since it proves that there is no largest prime. Do you see anything wrong with the proof, or do you understand and accept the logic? Aleta

I have already explained it, Aleta. No one knows what those alleged higher primes are. And without a bijective function your alleged "one-to-one correspondence" is nothing but a pipe dream. So go ahead, Aleta, start multiplying the primes. Let me know how well you do with the twenty known largest primes... Virgil Cain

Virgil writes,

No one has validated the proof.

The proof in 896, or ones similar, have been accepted as valid for more than 2000 years. The first proof was by Euclid. Can you point to which line of the proof seems invalid to you? Aleta

Aleta:

The key word here is known.

That is key as all we can do is go with what we know.

But there is also a proof that there can’t be a largest prime.

No one has validated the proof. And yes they may exist but if you don't know what they are you cannot claim a one-to-one correspondence. Virgil Cain

DS, Quickly, something is obvious, that something else should be the case. If there is a pattern of numbers turning up that are prime, why should that stop simply because the numbers are going on and on? That is so before a logical proof, and it makes an expectation reasonable. It may be hard to prove, but that is a different story. That is what I mean by obviousness. Next, beyond any given specific counting number there is an endless undefined continuation, going on endlessly. That is, there is no endless counted out set stated and in fact we cannot exhaust the set in principle much less on the material resources available to us. This endlessness is the reason where we will see w turning up as a way to recognise the endlessness and see it as a quantitative phenomenon. KF kairosfocus

Virgil says,

I have and there is a largest known prime. That supports what I said.

The key word here is known. But there is also a proof that there can't be a largest prime. Therefore, there are larger primes than the largest known prime, but we don't know what they are. But the proof shows that they do exist. Aleta

If gives a different result than one-to-one correspondence for infinite sets.

Yes, it contradicts what you make of that one-to-one correspondence.

But using one-to-one correspondence provides a consistent result for infinite and finite sets.

Whatever that means. They look inconsistent to me.

Look it up. It’s easy to find.

I have and there is a largest known prime. That supports what I said.

Not at all. A theorem is a proven result, NOT up for debate.

As if. Everything is up for debate especially when it is easily contradicted by standard set subtraction.

Mathematicians use the concept every day in lots of ways.

Nope, you are lying, again. No one uses the concept that all countable and infinite sets have the same cardinality. It is useless and sterile.

I know what Cantor would say; I’m asking you to apply your ‘concept’ and tell me what those are based on that.

You can do it, Jerad. Or admit that you are not fit for this discussion. Heck you can't even understand that infinity is a journey. And I doubt Cantor grasped that. Again, Einstein isn't the one who proved his ideas and cantor was ignorant of Einstein's ideas. So excuse me for trying to drag cantor into the twentieth century. Virgil Cain

Virgil #977 & 978

Umm set subtraction is part of cantor’s work. Is there anything that prevents it? I mean besides the fact that it contradicts your beliefs.

If gives a different result than one-to-one correspondence for infinite sets. But using one-to-one correspondence provides a consistent result for infinite and finite sets.

Way to ignore what I said. As can easily be looked up no one knows a list of primes that goes on for infinity.

Look it up. It's easy to find.

Right, you just keep posting that which is being debated. I am pretty sure that is a sign of senility.

Not at all. A theorem is a proven result, NOT up for debate. Unless you can find a mistake in the proof. Can you do that?

Literally no one uses the concept I am debating.

Mathematicians use the concept every day in lots of ways. It's foundational to modern mathematics.

You are unable to grasp anything that I have said so far. And I am sure that what you ask can be done as nothing prevents it. Even YOU could do what you ask of me given everything I have told you. Well, that is if you were half the mathematician you want everyone to believe you are. But if you want to continue to make this personal I suggest we get off the internet, face each other and get it over with.

Beating people up doesn't establish mathematical ideas. If you think nothing prevents finding the results I'm asking about using set subtraction then please do so.

Given everything I have told ellazimm, if he was half the mathematician he wants us to believe he is, he should be able to figure out the following: The ‘relative’ cardinality of sets A and B I defined above. The ‘relative’ cardinality of the primes.

I know what Cantor would say; I'm asking you to apply your 'concept' and tell me what those are based on that. I am no great shakes as a mathematician but I do know enough about this topic. ellazimm

Given everything I have told ellazimm, if he was half the mathematician he wants us to believe he is, he should be able to figure out the following:

The ‘relative’ cardinality of sets A and B I defined above. The ‘relative’ cardinality of the primes.

Virgil Cain

EZ:

I’m just asking you to show some academic support for using set subtraction with infinite sets and to use that to determine the cardinality of the primes and some other sets.

Umm set subtraction is part of cantor's work. Is there anything that prevents it? I mean besides the fact that it contradicts your beliefs.

As can easily be looked up, there is a simple one-to-one correspondence between the positive integers and the primes.

Way to ignore what I said. As can easily be looked up no one knows a list of primes that goes on for infinity.

I’ve given you links and links to online material including some theorems which prove what I’m saying is true.

Right, you just keep posting that which is being debated. I am pretty sure that is a sign of senility. Also you have never posted any support showing there is a utility for saying all countable and infinite sets have the same cardinality. Literally no one uses the concept I am debating.

And you still haven’t been able to tell me:

You are unable to grasp anything that I have said so far. And I am sure that what you ask can be done as nothing prevents it. Even YOU could do what you ask of me given everything I have told you. Well, that is if you were half the mathematician you want everyone to believe you are. But if you want to continue to make this personal I suggest we get off the internet, face each other and get it over with. Virgil Cain

Virgil #975

Yes, ellazimm, you are sorry. And what I am debating isn’t established and can be proven false via set subtraction. It isn’t my fault that you don’t grasp the implications of set subtraction. It isn’t my fault that you cannot grasp my concept and have to act like a little brat every time we try to discuss it.

I'm just asking you to show some academic support for using set subtraction with infinite sets and to use that to determine the cardinality of the primes and some other sets.

And BTW YOU cannot show the primes and the set of naturals have a one-to-one correspondence. That is because you don’t even know the full list of primes. And it is a given that you will just handwave that away.

As can easily be looked up, there is a simple one-to-one correspondence between the positive integers and the primes. You don't have to take my word for anything I say, it's all easily verified by looking it up online. It's even in Wikipedia.

Academic support? I have been asking for that and you have failed to provide it.

I've given you links and links to online material including some theorems which prove what I'm saying is true. I've even suggested an easily obtainable book on set theory which would help clear things up. Nothing I have said is controversial or outside the bounds of a typical undergraduate course on set theory. Literally thousands of mathematicians would concur and have done research building on Cantor's work. This is not personal, it's about what is proven mathematics. And you still haven't been able to tell me: The 'relative' cardinality of sets A and B I defined above. The 'relative' cardinality of the primes. The cardinality of the rational numbers. Whether or not there is a 'smallest' relative cardinal number. ellazimm

Yes, ellazimm, you are sorry. And what I am debating isn't established and can be proven false via set subtraction. It isn't my fault that you don't grasp the implications of set subtraction. It isn't my fault that you cannot grasp my concept and have to act like a little brat every time we try to discuss it. It is my fault for responding to you, ie someone who obviously can't hold an honest discussion. And BTW YOU cannot show the primes and the set of naturals have a one-to-one correspondence. That is because you don't even know the full list of primes. And it is a given that you will just handwave that away. Academic support? I have been asking for that and you have failed to provide it. bye-bye. Virgil Cain

Virgil #973

I have already pointed out your lies, EZ. And like your true-self you denied them but couldn’t support that denial. And yes, yours is an interesting technique. You don’t know how to argue but you can defame and slander with the best of them.

I'm sorry you think well established and non-controversial mathematics are lies. But if you can provide some academic support for your view that there are relative cardinalities or answer some simple questions about the cardinalities of well-known sets, like the primes, then you might have some basis for your beliefs. ellazimm

I have already pointed out your lies, EZ. And like your true-self you denied them but couldn't support that denial. And yes, yours is an interesting technique. You don't know how to argue but you can defame and slander with the best of them. You are a sick puppy, Jerad Virgil Cain

Virgil #970

Why is it that people are allowed to lie but others are not allowed to point out their lies?

What was said that was a lie?

I apologize for my actions but if I was debating these people face-to-face I would have dropped them like a bad habit. And they would have to eat from a straw for months.

Interesting argument technique. ellazimm

Yes News, I am sure that someone complained about me and I would bet it was someone who has posted provocative and non-substantive posts about me. I wonder how you and KF would feel if the same was done to you. Heck many people have been banned for attacking the UD hierarchy. You guys don't seem to understand that if I wasn't attacked that my posts wouldn't be filled with calling out my attackers. Virgil Cain

OK I apologize for calling people liars and cowards even though the posts they made contained lies, false accusations, nonsensical phrases and unsupported claims. However I still do not understand why the messenger is being picked on and not the people who posted the lies, false accusations, nonsensical phrases and unsupported claims. Every time KF is attacked he attacks back. Every time Barry is attacked he attacks back. Every time News is attacked News hits back. How many times does a person have to be attacked before he can defend himself with the truth? Why is it that people are allowed to lie but others are not allowed to point out their lies? I apologize for my actions but if I was debating these people face-to-face I would have dropped them like a bad habit. And they would have to eat from a straw for months. So I don't understand why it is OK to provoke people into the type of posts I made but bad to respond to the diatribe and lies posted about me. Virgil Cain

KF, With some bolding added:

Kindly notice, I have never argued that endlessness entails infinitude of primes, but that the nature of primes and the endlessness of numbers make it obvious that there should be no end of primes though they should be increasingly sparse on a per +1 basis as we go further and further on. That is how it appeared to me in childhood, and it is how it looks still.

I think our ideas of under what conditions some mathematical proposition is "made obvious" are different. To me it means that a proof is immediate. If we changed the bolded part to "make it plausible", then it would sound about right to me. It's plausible to me that the primes are distributed in accordance with the prime number theorem, based only on the definition of prime and the understanding that N is infinite. I think most people would admit that it's far from obvious.

I suggest, further that this puts forth a context in which a largest, definable specific finite counting set is also not reasonable:

Definitely not reasonable. I think everyone here agrees with this.

This by iteration for k, k’ k” etc at successively higher values, indicates that there is no specific, definable maximum finite scale counting set,

Yes.

there is an endless succession indicated by the ellipsis of endlessness that goes beyond what we can specifically define.

Well, this is where you lose me. If we can't specifically define it, what are we talking about? I don't know of any ordinal numbers that are not "specifically defined". They are all in the sequence 0, 1, 2, ..., ω, ω + 1, ... .

Likewise, point to the copy of the sequence so far successor counting set principle. An endless repetition of successive defined counting sets would end up with one or more that are in themselves endless.

I don't think so. Can you give a rigorous proof? The successor function (on N) takes as input a finite set and outputs another finite set. It's impossible for it to output an infinite set. You are saying something like "if we roll a 6-sided die infinitely many times, eventually a 7 will come up". daveS

News (as mod): Virgil Cain, we have received a complaint about some of your comments, particularly 837 We appreciate your efforts to defend reason, evidence, and reality against the universal acid, but one must take care not to be contaminated oneself. We really must insist that you apologize for the things said there. UD is a family site in that teenagers and U students may be reading and participating. We try to model how mature adults debate a topic and welcome all efforts in that regard. I will watch this space. News

MT:

Infinity means too large or too far off to calculate accurately. It has nothing to do with Philosophical infinity.

I think endlessly beyond any arbitrarily large but finite (thus bounded by some successor) value is a better way to put it. (Hence, my use of the pink vs blue punched tape examples above cf OP to anchor our discussion to concrete realities.) Notice, as already noted above, per AmHD:

in·fi·nite (?n?f?-n?t) adj. 1. Having no boundaries or limits; impossible to measure or calculate. See Synonyms at incalculable. 2. Immeasurably great or large; boundless: infinite patience; a discovery of infinite importance. 3. Mathematics a. Existing beyond or being greater than any arbitrarily large value. b. Unlimited in spatial extent: a line of infinite length. c. Of or relating to a set capable of being put into one-to-one correspondence with a proper subset of itself. n. Something infinite. [Middle English infinit, from Old French, from Latin ?nf?n?tus : in-, not; see in-1 + f?n?tus, finite, from past participle of f?n?re, to limit; see finite.] in?fi·nite·ly adv. in?fi·nite·ness n. American Heritage® Dictionary of the English Language, Fifth Edition. Copyright © 2011 by Houghton Mifflin Harcourt Publishing Company. Published by Houghton Mifflin Harcourt Publishing Company. All rights reserved.

CED is similar:

infinite (??nf?n?t) adj 1. a. having no limits or boundaries in time, space, extent, or magnitude b. (as noun; preceded by the): the infinite. 2. extremely or immeasurably great or numerous: infinite wealth. 3. all-embracing, absolute, or total: God's infinite wisdom. 4. (Mathematics) maths a. having an unlimited number of digits, factors, terms, members, etc: an infinite series. b. (of a set) able to be put in a one-to-one correspondence with part of itself c. (of an integral) having infinity as one or both limits of integration. Compare finite2 ?infinitely adv ?infiniteness n Collins English Dictionary – Complete and Unabridged, 12th Edition 2014 © HarperCollins Publishers 1991, 1994, 1998, 2000, 2003, 2006, 2007, 2009, 2011, 2014

This gives us an understanding of a primary conceptual sense that mathematical explorations must reasonably answer to. And yes, the philosophical, conceptual sense is not something we can ring fence off and set to one side. Not if we respect truth as coherent and unified, saying of what is that it is and of what is not that it is not. KF kairosfocus

DS (Attn HRUN), If you will look at what I actually said above, you will see -- with all due respect -- you are barking up the wrong tree. (And, one that is revealing on the polarising nature of the divides that surround the underlying design controversies -- do, give us a little credit for understanding the difference between [a] plausibility, [b] proof relative to axiomatised schemes and [c] exploration of driving dynamics and facts, a sort of exploratory logic of structure and quantity analysis by analogy of statistical exploratory data analysis, not to mention [d] instructive thought exercise such as pink vs blue punched tapes . . . proof on axiom systems is not the be all, end all.) Kindly notice, I have never argued that endlessness entails infinitude of primes, but that the nature of primes and the endlessness of numbers make it obvious that there should be no end of primes though they should be increasingly sparse on a per +1 basis as we go further and further on. That is how it appeared to me in childhood, and it is how it looks still. The actual proof by contradiction of for argument positing a finite number of primes . . . thus a largest and finite maximum prime . . . then provides a proof of what is plausible or obvious on separate grounds. As HRUN should now recognise, I contextualised the proof above, to help those of us who may have concerns on seeing a proof presented in the fashionable bare bones no context style, understand the dynamics at work. The discussion on neighbouring pairs of primes shows the same difference, at a different degree of access to proof. I suggest, further that this puts forth a context in which a largest, definable specific finite counting set is also not reasonable: posit for argument that such exists, k. But on the framework of counting sets in succession we can proceed: {0,1,2, . . . k-1} --> k then by +1 successor operation and closure of the collection of counting sets: {0,1,2 . . . k-1,k] --> k+1 And thenceforward we may apply to reach k+2 etc, then exploit endlessness and place k, k+1, k+2 etc in 1:1 correspondence with 0,1,2 etc. (do the succession k times so k' is k^2) This by iteration for k, k' k" etc at successively higher values, indicates that there is no specific, definable maximum finite scale counting set, there is an endless succession indicated by the ellipsis of endlessness that goes beyond what we can specifically define. Call this the endlessly retreating rainbow effect. Likewise, point to the copy of the sequence so far successor counting set principle. An endless repetition of successive defined counting sets would end up with one or more that are in themselves endless. That is, we see why we cannot end the endlessness of +1 increment successive counting sets, even as we also may readily see why any particular set we can write down in say place value notation or scientific notation or by direct +1 stage cumulative succession from 0 will be finite. We cannot exhaust endlessness in +1 steps or procedures dependent on such. We then recognise endlessness of succession as a structural pattern and quantitative phenomenon inviting definition or assignment of a new class of number starting at: {0,1,2 . . . EoE . . . } --> omega (w for convenience) Then per the Ehrlich tree on surreals, etc we go to: w, w+1, etc. Thus we study the logic of structure and quantity. KF kairosfocus

NOTICE to Virgil Cain UD supports the following requirement: You are to provide an apology for your behviour as a token of making amends, or you will in the first instance go on moderation. You have a reasonable, short period in which to do so. GEM of TKI Thread Owner kairosfocus

Origenes @ 960

Dear onlooker, #954 contains a misconstrual of my simple and straightforward argument (see #912 and #934) by a person who asks clueless questions like: “why must math be grounded in something other than math? Why do you get to say that?

Infinity means too large or too far off to calculate accurately. It has nothing to do with Philosophical infinity. It is needed to calculate something (including real world problem) represented by a function where the limit approaches infinity. If you don’t like the word ‘infinity’, you can think of it as ‘too many to bother counting’ or ‘too far off to bother measuring’. There is nothing mysterious about infinity. Me_Think

Thanks, hrun0815. daveS

Re #961: I wish there was a way to like posts on this board. I there was, I'd 'Like' #961! hrun0815

KF, Well, most people would bet that the twin prime conjecture is true, but I think we agree that it does not follow from endlessness and the definition of prime, just as the infinitude of primes does not. BTW, there has been quite a bit of progress on the twin prime conjecture lately. Now it is known that there are infinitely many pairs of consecutive primes differing by 246. daveS

Dear onlooker, #954 contains a misconstrual of my simple and straightforward argument (see #912 and #934) by a person who asks clueless questions like: "why must math be grounded in something other than math? Why do you get to say that?". Origenes

Aleta:

But how do you that it can’t be expressed as fraction, and how do you know that the decimal never repeats (which is a question of infinity).

No one has been able to do so. Everyone who has tried has seen it never repeats and I am OK with infinity.

You seem to deride standard mathematical proofs, and yet you accept a couple of non-obvious facts about the sqrt(2).

I deride them when I can easily contradict them or they really are not proofs. And I have been through the sqrt (2) in math class- more than once. So I accept that it is irrational because I have actually done the math. Virgil Cain

But how do you that it can't be expressed as fraction, and how do you know that the decimal never repeats (which is a question of infinity). My point is that first fact is proved by a proof by contradiction, which you don't understand, and the second makes a statement about infinity. You seem to deride standard mathematical proofs, and yet you accept a couple of non-obvious facts about the sqrt(2). That's my point. Aleta

DS (attn Aleta), As a child, I could see that there should reasonably be endless primes; hence my reference to obviousness as opposed to proof; which is a different matter. I never pondered the pattern of existence of the neighbouring pairs of primes though obviously such exist even in the first 10 or 20 numbers. I would expect that such would follow a similar pattern of increasing sparseness but likewise endlessness, as a reasonable expectation; though that is not anything related to the areas of interest I have had for Mathematics. Cutting to the chase scene, Wolfram -- http://mathworld.wolfram.com/TwinPrimeConjecture.html -- >>There are two related conjectures, each called the twin prime conjecture. The first version states that there are an infinite number of pairs of twin primes (Guy 1994, p. 19). It is not known if there are an infinite number of such primes (Wells 1986, p. 41; Shanks 1993, p. 30), but it seems almost certain to be true. While Hardy and Wright (1979, p. 5) note that "the evidence, when examined in detail, appears to justify the conjecture," and Shanks (1993, p. 219) states even more strongly, "the evidence is overwhelming," Hardy and Wright also note that the proof or disproof of conjectures of this type "is at present beyond the resources of mathematics.">> KF kairosfocus

Aleta:

Virgil, how do you know that sqrt (2) is irrational?

It cannot be expressed as any fraction that I know of and in decimal form it is non-ending and non-repeating. IOW it fits the definition. Do you have a point? Virgil Cain

KF, What do you think of Aleta's post #947? Does endlessness imply the existence of infinitely many primes separated by 2? daveS

By, Origenes. Thinking that the truth and relevance of math is equivalent to fantasy fiction unless someone is a believer in some metaphysical speculation about math (even though there is no way all the various speculations could all be right), is an attitude that I have no interest in interacting with, either, so we agree to part. Aleta

Aleta,

Origenes: Clearly, to naturalism the ‘world of pure math’ is as real as ‘Rivendell’, the Elven outpost in Middle-earth.

Aleta: Hmmm. That last statement seems to be breathtakingly wrong.

One would expect an argument to be provided to support this strong statement. Now it just sits there looking like a toddler waiting to be fed. Are you proposing that naturalism holds that the ‘world of pure math’ is out there somewhere — near planet Kepler-452b? In post #919 I suggest a naturalistic grounding of mathematical ideas, like infinity, in certain configurations of brain chemicals of the mathematician.

Aleta: And why must math be grounded in something other than math? Why do you get to say that?

What’s your alternative madam? Math just is, wholly uncaused, eternal and no questions asked? Do you even understand your own question? What you are asking is this: why do things need an explanation? Frankly, I’m baffled. We are done talking. Origenes

Virgil, how do you know that sqrt (2) is irrational? Aleta

DS seeing something and proving it are not the same thing. Think, seeing Pythagoras' Th vs proving it. KF kairosfocus

Aleta:

Is the square root of 2, written sqrt(2), a rational or an irrational number?

Irrational. Virgil Cain

Aleta:

I see that you don’t understand proof by contradiction. Set subtraction has nothing to do with it.

And yet it contradicts Cantor's claim about the same cardinality for all countably infinite sets. Virgil Cain

Origenes writes,

Grounding infinity by a ‘world of pure math’ would indeed relieve the naturalist from his predicament. However, in order to achieve this, naturalism must be able to ground a ‘world of pure math’ and unfortunately this cannot be done. Clearly, to naturalism the ‘world of pure math’ is as real as ‘Rivendell’, the Elven outpost in Middle-earth.

Hmmm. That last statement seems to be breathtakingly wrong. And why must math be grounded in something other than math? Why do you get to say that? Here's one way to look at this: I can think of a number of different ways that people speculate on the metaphysical nature of math, such as Western theism, Hinduism, Buddhism, Taoism, neo-Platonism. These all can't be right. So why does someone who has one of these perspectives, even if it's wrong (because they all can't be right) have a superior perspective on the nature of math than one who believes that math derives its validity and meaning from its own internal structure without regard to any additional metaphysical justification. Aleta

Hi kf. You say the the fact that there are an infinite number of primes is "obvious" (931) and that "endlessness patently leads to the result that numbers keep cropping up that will be of the form discussed above which will be prime." (941). Twin primes are pairs of primes that are consecutive odd numbers, such as 17 and 19, as you mentioned in 931. Is it also obvious that, because of endlessness, there will be an infinite number of such pairs? Aleta

Aleta: But I think you are wrong. The naturalist is saying that infinity is meaningful within the world of pure math.

Grounding infinity by a ‘world of pure math’ would indeed relieve the naturalist from his predicament. However, in order to achieve this, naturalism must be able to ground a ‘world of pure math’ and unfortunately this cannot be done. Clearly, to naturalism the ‘world of pure math’ is as real as ‘Rivendell’, the Elven outpost in Middle-earth. So no, I wasn’t wrong. You were wrong by attempting to ground something by something else which cannot be grounded.

Aleta: Whether it is “real” in either a physical or metaphysical sense is not relevant.

If only such unsubstantiated “not-relevant” statements would have some merit to them, all problems could be easily solved. But no, to naturalism this distinction is highly relevant. Physical is real, metaphysical is not real.

Aleta: And what if I am (which is the closest to the truth) an agnostic about the metaphysical nature of math? Does that make my position “less awkward”, but still not quite valid?

Less awkward indeed. Origenes

KF,

DS, endlessness patently leads to the result that numbers keep cropping up that will be of the form discussed above which will be prime. KF

No, I don't think that does it. You would have to say more (for example, essentially repeating Aleta's post above). So far, everything you've said is consistent with the proposition that every 2x + 1 (for x sufficiently large) is composite, and more importantly, that only finitely many primes exist. If you have a proof, I would like to see it, provided that it isn't just a restatement of Aleta's post. daveS

Hi Virgil. Simple question: Is the square root of 2, written sqrt(2), a rational or an irrational number? Aleta

I see that you don't understand proof by contradiction. Set subtraction has nothing to do with it. Aleta

Aleta, Set subtraction is an example of proof by contradiction. Virgil Cain

DS, endlessness patently leads to the result that numbers keep cropping up that will be of the form discussed above which will be prime. KF kairosfocus

KF, Whatever the merits of your post #931, it is certainly not immediately obvious that the set of primes is infinite. There are infinite ("endless") rings with only finitely many primes, where the definition of prime matches the definition of primes in N. daveS

Virgil, a proof by contradiction begins by assuming the opposite of what you are trying to prove, and then showing that leads to a contradiction. We start out by assuming that pn is the largest prime in a finite set, and then show the contradiction: therefore there is no largest prime pn. I assume you are familiar with proof by contradiction - true? Aleta

HRUN, Did you observe that I set out only to provide clarifying context for those likely to be concerned then went on to explicitly state "Then with that context, the proffered proof can be seen to make better sense to the concerned. I find there is too often too much left too implicit"? Where, I set out to highlight why primes past 2 will be odd and will thus have form 2*x + 1, x being a chain of 1 or more multiplied primes? Where also the phenomenon of neighbouring primes (separated by +2) is relevant to the local "density" of primes in their close neighbourhood? KF kairosfocus

Aleta:

For the record, this is a nice proof by contradiction:

Or obfuscation...

Since P is bigger than pn, this means P can’t be a prime, because pn is the largest prime.

If there is a largest prime then obviously the set is not infinite Virgil Cain

EZ:

Fine, let’s see you do it. I say you can’t find the relative cardinality.

See, you do want to make this personal. That means you are totally out of touch with reality.

I can come up with a one-to-one mapping but it will just show that the cardinality of the primes is the same as the positive integers.

No one can as all the primes are not known. You lose. Virgil Cain

But I think you are wrong. The naturalist is saying that infinity is meaningful within the world of pure math. Whether it is "real" in either a physical or metaphysical sense is not relevant. Your position would claim that vast segments of mathematics, if not all of mathematics, was meaningless and unreal to a naturalist. Would this change how the naturalist does math? Would it make his math any different than the math done by a theist? The answer to both these rhetorical questions is "no", it wouldn't. And what if I am (which is the closest to the truth) an agnostic about the metaphysical nature of math? Does that make my position "less awkward", but still not quite valid? The math has meaning in respect to the system in which it resides, and it has as much "reality" as any other abstract concept. And your examples aren't good analogs. The meaning of a Bible verse is an opinion, and the nature of the Tao is a metaphysical speculation. Those are not the same thing as a proof that there are an infinite number of primes. (And I assume you accept the proof.) Aleta

Aleta, Let me put it another way. Can a naturalist weigh in on a discussion about the meaning of Psalm 82? Sure he can. And yes, he can also join a discussion about whether the Tao is all-knowing or not. He may even be a dominating knowledgeable participant in such discussions. However there is something awkward about his position, to say the least, since he holds that he is not discussing anything meaningful and real. My point is that a naturalist discussing infinity is in the exact same position. Origenes

The difference between #896 and #931 is an amazing demonstration of what some clarity can achieve. I am still puzzling out how #931 shows that there is no largest prime, rather than showing that all primes have the form 2x+1. And I am also trying to understand what the discussion of neighboring primes adds here? hrun0815

Origenes write,

a naturalistic context does not accommodate for infinity.

A "naturalistic context", as far as I know, doesn't believe there is actually an infinite number of anything in the real world. That's been stated here a number of times. But that doesn't mean that infinity as a concept within the basic mathematical system of numbers is meaningless. There is a difference, which I've described several times in above posts, between the self-contained system of pure mathematics and the application of math to the physical world. Also, you writes,

So yes, when a Taoist contemplates infinity it refers to something real.

So I can legitimize the mathematics of infinity if I am a Taoist but not if I am a naturalist? How can the validity of the math depend on such a distinction. The math is true or not irrespective of the metaphysical perspective of the person holding it. Can you imagine me teaching a course on Cantor, and starting the course by asking about the metaphysical positions of all the students so I could know who could actually, validly, accept the math I was about to teach and those who couldn't! Aleta

Aleta, it is immediately obvious there is no highest prime given endlessness and definition of primes, though they patently become sparser on average; that I have seen since childhood before doing any advanced mathematics. The (or in principle any) proof proffered may have issues or concerns so I would not start there but with first principles: a prime is not cleanly divisible by any lower whole number, disregarding 1. As a consequence 2 is prime and thereafter all primes must be odd starting with 3. This gives a conceptual bridge. Given any even will have odds as neighbours -- where any even will be 2 * x, where x may be a prime or a train of multiplied prime factors -- all primes beyond 2 will necessarily be 2 *x +1 (actually allowing x to go to 0 allows start at 1). This includes neighbouring primes such as 17 and 19, where 15 and 17 or 19 and 21 are not neighbouring primes, as well as, 25 and 27 are neigbouring odds but not primes. Then with that context, the proffered proof can be seen to make better sense to the concerned. I find there is too often too much left too implicit. KF PS: Successive primes, however discovered, can be ranked in order, and that order will continue endlessly in a counting sequence, i.e. first degree endlessness. At any prime in the sequence p_k, P-k+1 etc could be matched onward 1:1 with, 0,1,2 etc, yielding yet another transfinite pattern. kairosfocus

Aleta: People such as Origenes who believe that naturalists can’t have any validly grounded form of knowledge because we are “just matter” (...)

Your paraphrase of my point is off the mark. I've been very clear in #912: meaning depends on context and a naturalistic context does not accommodate for infinity — as far as I can tell. So, point out that I'm mistaken about that lack of accommodation or explain how meaning does not depend on context. But please don't distort my simple point.

Aleta: In respect to the metaphysical nature of math, I am basically an agnostic leaning towards Taoistic Platonism. Does that count? :-) Is my mathematics now meaningful?

The Tao is infinite. So yes, when a Taoist contemplates infinity it refers to something real. Origenes

DS, the ellipsis of endlessness -- part of the core concept. Cannot be attained to, cannot be spanned in +1 steps due to endlessness, just as the foot of the rainbow I looked at across the Caribbean this morning from an aircraft window cannot be reached from where one is (and looking at it did make me think of this thread). Can be envisioned, not reached. I think that has consequences. KF kairosfocus

Hi kf. The proof at 896 shows that there are an infinite number of primes without resorting to any induction or stepping-through process. Is it a valid proof, in your eyes. Does it convince you that the set of all primes is an infinite set? Aleta

MT:

If you don’t like the word ‘infinity’, you can think of it as ‘too many to bother counting’ or ‘too far off to bother measuring’. There is nothing mysterious and hateful about poor infinity.

First yes there are people hostile to infinity for various reasons, including things that are at best odd. Second, the above proffered concepts fail. Infinity is not just large or too big to bother but endlessly large beyond any finite value. And at the opposite scale, infinitesimal is all but zero small. Both become very important. One of the key properties which is in the wider context is that a transfinite span cannot be traversed in finite stage cumulative steps from 0 or a similar start point. It turns out that a lot pivots on this. Especially when we address causal succession by stages, or generations or iterations. KF kairosfocus

KF, I ran across this passage by Solomon Feferman in The Oxford Handbook of Philosophy of Mathematics and Logic, p. 593, edited by Stewart Shapiro. It concerns a distinction made by Bertrand Russell between the words "all" and "any", and perhaps is akin to a distinction you are making:

Before going into the actual structure of types in Russell’s setup, let me draw attention to an earlier section of the article, headed "All and Any" (ibid., pp. 156– 159). Here, in contrast to the first quotation from Russell above, a distinction was made between the use of these two words. Roughly speaking, in logical terms, the statement that all objects x of a certain kind satisfy a certain condition φ(x) is rendered by the universal quantification (∀x)φ(x) in which "x" now is a bound variable, while the statement that φ(x) holds for any x is expressed by leaving "x" as a free variable. In modern terms, the logic of the latter is treated as a scheme to be coupled with a rule of substitution. The importance of this distinction for Russell has to do with the injunction against illegitimate totalities. In particular, with p a variable for propositions, he would admit "p is true or false, where p is any proposition" (i.e., the scheme p ∨ ¬p, but not the statement (∀p)(p ∨ ¬p) that "all propositions are true or false" (in both cases using truth of p to be equivalent to p).

Edit: There appears to be no closing parenthesis at the end of the above quotation in the original. daveS

KF,

I note that for every value in T that we can define and see as finite there are endlessly more values that can be placed in onward succession in 1:1 correspondence with the counting sets from 0, 1, 2 on.

I agree.

In that context the most I think we can reasonably say is that every counting set or natural number reached in successive +1 steps from 0 as actually taken will be finite, and similarly, every represented number such as place value or scientific notation that depends on such will be finite and will be succeeded by an onward endless succession that can be placed in 1:1 correspondence with the naturals from 0.

I also agree with this, although I'm not sure of the meaning of "as actually taken". And by definition, there are no natural numbers not reachable in successive steps from 0. Certainly the counting set ω is not reachable in successive +1 steps from {}. daveS

VC, You have gone on and on beyond what you were warned about. KF kairosfocus

In respect to the metaphysical nature of math, I am basically an agnostic leaning towards Taoistic Platonism. Does that count? :-) Is my mathematics now meaningful? But seriously, whether math exists in some independent way, whether it be in Platonic ideals, the mind of God, the Tao, or whether it is a consequence of the creation of symbol systems not grounded at a higher metaphysical level, the math works within the symbol system itself. The proof that there are an infinite number of primes is true within the symbol system of natural numbers irrespective of the metaphysical nature of math. People such as Origenes who believe that naturalists can't have any validly grounded form of knowledge because we are "just matter" brings a much larger metaphysical element to this discussion that is, in my opinion, for me, not something I want to invest my time in here. And Mike, re my post at 911: If you are implying in your questions something similar to the same points Origenes is making - that math is in some way just clever manipulations of symbols unless it derives from some larger metaphysical source, then please say so. For instance, it would clarify your position for me if you would answer this question from 911:

My question to you is this: is any part of mathematics something other than a “clever manipulation of symbols and language”, or is all mathematics a “clever manipulation of symbols and language”? And if some mathematics is not a “clever manipulation of symbols and language” and some is, can you explain the criteria which separates the two, and give examples?

Aleta

DS (attn EZ): I note that for every value in T that we can define and see as finite there are endlessly more values that can be placed in onward succession in 1:1 correspondence with the counting sets from 0, 1, 2 on. And I do not know how to be clearer and more specific than that, in stating that I have come to view endlessness as a pivotal part of the definition of the naturals. In that context the most I think we can reasonably say is that every counting set or natural number reached in successive +1 steps from 0 as actually taken will be finite, and similarly, every represented number such as place value or scientific notation that depends on such will be finite and will be succeeded by an onward endless succession that can be placed in 1:1 correspondence with the naturals from 0. (And EZ, that is not dodging, I an trying very hard to go with what I see in the logic including that of ordinary mathematical induction. I think we should all take a pause ad realise that especially post Godel -- incomplete, open to possibility of incoherence -- axiomatic systems in mathematics are different from mathematical facts and are not to be equated to absolute, unquestionable truth. I seriously question the conclusion that has been presented as that there are infinitely many specifically definable successive finite numbers from 0. Not least were there such as the successor is in effect a copy of the list so far, there would be definable individual members that are endless sets in themselves. So, I have backed off to a more cautious position that pivots on endlessness being integral to the set, so there is an onward endless succession beyond any defined finite value.) KF PS: Back. kairosfocus

ellazimm: Well all the Christian mathematicians I’ve know have had the same view on mathematics and concepts like infinity as everyone else.

That is not possible by definition. Meaning depends on context and naturalists and theists don't share the same context. As I have pointed out (see #912) "infinity" has true meaning for the theist, it refers to something real. Not so for the naturalist.

ellazimm: IF the universe is strictly the product of unguided, natural forces then you’ll be wrong. You’re making an assumption before you know the situation.

In effect I'm saying that the idea that blind unthinking particles do mathematics is incoherent. You say (paraphrasing): "but if they do, then you would be wrong". I have to respectfully disagree. I would still claim 'incoherence' if the universe were such that blind unthinking particles are doing mathematics. Origenes

Origenes

My aim was to point out that the theist has an entirely different view on mathematics and mathematical concepts like infinity.

Well all the Christian mathematicians I've know have had the same view on mathematics and concepts like infinity as everyone else. To some extent math is a community effort and it's hard to do good work if you're too far from the village centre.

If you are asking me if the reduction of the mental, including (brilliant) mathematical ideas, to blind unthinking particles bumping into each other is a coherent idea, then I have to say no.

IF the universe is strictly the product of unguided, natural forces then you'll be wrong. You're making an assumption before you know the situation. ellazimm

ellazimm: Why couldn’t we come up with complicated mathematical idea even if our thoughts are just products of brain chemistry?

I didn't say that naturalism makes mathematical discoveries unlikely. What I'm saying is that, given naturalism — "if our thoughts are just products of brain chemistry" — there is no grounding for a "complicated mathematical idea" other than ... brain chemistry; blind unthinking particles bumping into each other. IOWs a "complicated mathematical idea" is nothing of itself and must refer to a certain configuration of brain chemicals. A perfected neurophysiology must be able to pinpoint e.g. "infinity" as a certain configuration of chemicals in the brain of the mathematician. My aim was to point out that the theist has an entirely different view on mathematics and mathematical concepts like infinity. If you are asking me if the reduction of the mental, including (brilliant) mathematical ideas, to blind unthinking particles bumping into each other is a coherent idea, then I have to say no. Origenes

Origenes

Whether said or not, you both should know by now, that theists, contrary to naturalists, do hold that there is “something in the real world that is infinite” and perfect. Also theists, contrary to naturalists, hold that “abstract mathematical ideas” refer to real objects grounded by a truly existent real mental realm. Under naturalism the mental (abstract mathematical ideas included) is a byproduct of brain chemistry — and/or reducible to it.

I can't comment on what theists think or conclude, that's up to them. Why couldn't we come up with complicated mathematical idea even if our thoughts are just products of brain chemistry? Aside from some just not believing it? ellazimm

Aleta & Ellazimm,

Aleta: I don’t think anyone in this discussion has said there is something in the real world that is infinite, just as there is no perfect circle.

ellazimm: Yes!! Exactly.

Whether said or not, you both should know by now, that theists, contrary to naturalists, do hold that there is "something in the real world that is infinite" and perfect. Also theists, contrary to naturalists, hold that "abstract mathematical ideas" refer to real objects grounded by a truly existent real mental realm. Under naturalism the mental (abstract mathematical ideas included) is a byproduct of brain chemistry — and/or reducible to it. Origenes

Aleta

I don’t think anyone in this discussion has said there is something in the real world that is infinite, just as there is no perfect circle. But, as I said before, using infinity in mathematics has led to powerful tools that are applicable to the real world (calculus, for instance). But again, and this is critical, there is a difference between pure mathematics, at all levels, as an abstract logical system, on the one hand, and the application of math to the real world.

Yes!! Exactly. I would add that it can be helpful to think of the written form of mathematics as a language or shorthand; it has its own grammar and syntax rules. Many of the symbols COULD be replaced with regular words but it would be much harder to scan. I used to have some of my students write out in English an infinite series and it took up a lot more room and was much harder than using the standard mathematical symbols. Some of them are falling out of use which is sad. Here is a partial list. Notice how long the 'translation' of some of the symbols are. https://en.wikipedia.org/wiki/List_of_mathematical_symbols ellazimm

Virg

What prevents it from being done? It is as easy as finding the bijective function. Or at the most difficult finding other relative cardinalities and plotting the counts against the primes.

Fine, let's see you do it. I say you can't find the relative cardinality. I can come up with a one-to-one mapping but it will just show that the cardinality of the primes is the same as the positive integers. You say that's not true but you can't prove your view.

It runs with the current notion of a bijective function. And that runs with current notion what makes them countably infinite sets.

If you're so sure then let's see you do it in such a way that you can find its relative cardinality.

Your lies, bluffs and false accusations just expose your desperation.

If you think it's possible to figure out the relative cardinality of the primes then lets see you do it.

I need a system, not just a concept. And set subtraction just shows there is a difference (or not) between the two sets. Also the bijective function that produces the one-to-one mapping between the two sets is the relative cardinality.

So, relative to the positive integers, you think the relative cardinality of the evens (or odds) is one-half, the relative cardinality of the multiples of three is one-third, etc. Now, figure it out for the primes. Or admit you can't.

Who cares? What is the highest known prime? And if that is the highest known prime then how do you know there is one higher?

There is a well known proof that there is no 'greatest' prime number. Aleta gave a nice version of it. ellazimm

Origenes writes,

Words and symbols must mean something, else they are (obviously) meaningless. In order to mean something a word or symbol must be, by definition, about something else.

I don't agree. Pure mathematics is not "about something else." It is about itself: it is a self contained, logically coherent abstract system. We can make it about something else by building a model which maps mathematical concepts to real-world objects, but that is then applying math, which is different than just doing math. The Mandelbrot set, or the identity e^(i*pi) = -1, to pick two common examples, are not about anything, but they are not meaningless. Origenes also writes,

At the moment I cannot come up with a naturalistic accommodation of infinity.

I don't think anyone in this discussion has said there is something in the real world that is infinite, just as there is no perfect circle. But, as I said before, using infinity in mathematics has led to powerful tools that are applicable to the real world (calculus, for instance). But again, and this is critical, there is a difference between pure mathematics, at all levels, as an abstract logical system, on the one hand, and the application of math to the real world. Aleta

mike1962 @ 907

Sorry, you do not understand the point of my posts. Please re-read and see if you can glean it.

mike1962 @ 905

What I’m asking beyond that is what does infinity mean, if anything? I hope my intent is coming through.

As I said in my earlier comment, Infinity-in practical terms- means 'too large to count' or 'too far off to measure'. For philosophers it might mean a power which they can't comprehend.

what does a perfect circle mean beyond the clever manipulation of symbols and language (which at very least, it undoubtedly is)?

Perfect Circle can exist only in mathematical realm but it can be used to compare it to imperfect circles in real world to see how imperfect our circle is. Sorry AFAIK, perfect circle has no meaning even in Philosophy. Me_Think

Mike1962, Words and symbols must mean something, else they are (obviously) meaningless. In order to mean something a word or symbol must be, by definition, about something else. Meaning depends on context. In a solipsistic universe "external world" has no meaning, since it isn't about a real object. In a naturalistic universe the term "God" has no meaning, since it isn't about a real object. IOWs "infinity" has a meaning if your philosophy can accommodate infinity. If you believe in eternal life and/or an "infinitely great being" then I guess infinity means something. At the moment I cannot come up with a naturalistic accommodation of infinity. If there is none, then for the naturalist "infinity" is nothing over and beyond clever linguistic and symbolic trickery. Origenes

So, Mike, can you explain more what your thoughts on this are. For instance, you wrote,

Now, since perfect circles are an impossible object in time and space, what does a perfect circle mean beyond the clever manipulation of symbols and language (which at very least, it undoubtedly is)?

My question to you is this: is any part of mathematics something other than a "clever manipulation of symbols and language", or is all mathematics a "clever manipulation of symbols and language"? And if some mathematics is not a "clever manipulation of symbols and language" and some is, can you explain the criteria which separates the two, and give examples? Thanks. Aleta

mike1962,

I understand the difference between the two with respect to mathematical definitions. I reject that uncountable sets actually exist.

Thanks. Your questions about the meaning of infinity are probably too hard for me. On the other hand, I'm sure we could discuss uncountable sets and be perfectly intelligible to each other, despite the fact that one of us doubts their existence. If I were to give you a list of infinite sets, you could tell me which were countable and which were uncountable (according to me, anyway). This suggests to me that the concept of infinity is something beyond clever linguistic or symbolic trickery. daveS

Aleta: What do you mean by asking what does it mean? I didn't simply ask what it means, but what it means beyond the manipulation of language and symbols. We can back down a level and deal with something simpler, if you like. For example, using Knuth's computer notation, what does 2^^^6 mean? This presumed finite quantity, which could never be counted in time and space, given all the resources available, presumably stands for a meaningful quantity? But does it really. In what sense could it be a meaningful quantity beyond the mere symbols themselves? mike1962

I guess I don't get your point. What do you mean by asking what does it mean? What do you think math means? Do you think that some concepts (like "2") have a meaning while some (like perfect circles) don't. Perhaps you ought to offer your own views on this subject? Aleta

Me_Think, Sorry, you do not understand the point of my posts. Please re-read and see if you can glean it. P.S. I love math. Infinity does not annoy me. mike1962

Mathematics is the language of science. Just because some one doesn't like mathematics, doesn't mean it is trickery. I don't know why infinity annoys people. If you don't like the word 'infinity', you can think of it as 'too many to bother counting' or 'too far off to bother measuring'. There is nothing mysterious and hateful about poor infinity. Pi (which determines the circle) is needed only up to 16 digits for all practical purposes. NASA uses 16 digits for the Space Integrated Global Positioning System/Inertial Navigation System (SIGI). Beyond that, more accurate Pi may be needed for calculating large tracts of universe volume. Again, there is no need to bother thinking about Pi beyond 16 digits for all practical purposes. Me_Think

Aleta: I just read 900. I think it’s pretty odd to call pure mathematics “clever linguistic/symbolic trickery.” I don't intend to minimize the brilliance of those who have developed the mathematics of infinity. That is not my purpose. Now, you certainly agree that at very least, the mathematics of infinity is certainly a clever manipulation of symbols and language, right? What I'm asking beyond that is what does infinity mean, if anything? I hope my intent is coming through. Should we not develop theorems about circles because perfect circles don’t exist. Of course, we should. Now, since perfect circles are an impossible object in time and space, what does a perfect circle mean beyond the clever manipulation of symbols and language (which at very least, it undoubtedly is)? Should we not use derivatives in calculus because they are based on limits as certain values go to infinity. Of course, we should. But I hope you see the point of my post now. mike1962

I just read 900. I think it's pretty odd to call pure mathematics "clever linguistic/symbolic trickery." Should we not develop theorems about circles because perfect circles don't exist. Should we not use derivatives in calculus because they are based on limits as certain values go to infinity. Should we not use natural exponential functions because continuous change of infinitesimal amounts don't actually exist? Those are rhetorical questions. If we don't develop the pure mathematics we don't have the tools to apply to the real world even if there is also a slight imperfection as we move from the pure mathematics to the application. What would you have mathematicians do? What part of pure math would you consider not "clever linguistic/symbolic trickery?" Aleta

Aleta: And what do you mean “actually exist.” Do you mean in the real world, Yes. or do you mean that they can’t even be posited as mathematical concepts? Of course, they can be posited as mathematical concepts. But what the meaning is, is another matter. Does infinity mean something beyond the clever manipulation of language and symbols? If so, what? mike1962

And what do you mean "actually exist." Do you mean in the real world, or do you mean that they can't even be posited as mathematical concepts? Aleta

daveS: Do you accept the distinction between countable and uncountable sets? I understand the difference between the two with respect to mathematical definitions. I reject that uncountable sets actually exist. mike1962

Aleta: Pure mathematics is about ideas, not about what can happen in the physical or temporal world that I agree. The mathematics of infinity are interesting, particularly to pure mathematicians, but have no pragmatic use. But it goes beyond this. What interests me, personally, is what it means. Does infinity really represent something meaningful beyond some interesting and clever linguistic/symbolic trickery? mike1962

mike1962, Do you accept the distinction between countable and uncountable sets? It would seem to me that if you reject the existence of infinite sets, then this distinction would make no sense. daveS

That is the discussion we'v been having for three threads and and well over a 1000 posts. There is a vast field of mathematics about infinity. Pure mathematics is about ideas, not about what can happen in the physical or temporal world that Do you think, mathematically, that there are infinitely many natural numbers? {1,2,3 ...} Or do you think it is nonsense to even talk about this set as a whole just because we could never count them all? Aleta

Aleta @ 896, What this proof by contradiction amounts to is that if we count indefinitely, we will never run into the last prime in our counting. But since it is impossible to count infinitely, what does this really mean beyond the fact that if we count indefinitely we won't run into the last prime in our counting? When you smuggle infinity into the proof you drag in a contention between temporal counting (something we can do) and transcendent infinity (something we can never reach by counting.) This changes the nature of the proof to something a lot less obvious. In effect, it makes it nonsense. Clever, and perhaps interesting to some, but useless as a proof that there are really infinitely many primes. If infinity as a quantity doesn't exist, then an infinity of primes as a quantity cannot exist. This leads to another interesting question, which should be obvious. mike1962

For the record, this is a nice proof by contradiction: Prove: There is no highest prime (which implies there is an infinite number of primes) 1. Assume there is a highest prime, so there are a finite number of primes. Let them be p1, p2, p3, ... pn, where p1 = 2, p2 = 3, p3 = 5 and pn = the highest prime. Now let P = (p1 x p2 x p3 x ... x pn) + 1 2. Since P is bigger than pn, this means P can't be a prime, because pn is the largest prime. 3. However, if you divide P by any of the known primes (p1 or p2 or ... pn), you get a remainder of 1, 4. Therefore P is prime because it has no prime factors. 5. But that contradicts 2, in which we showed that P wasn't prime. 6. Therefore, the assumption in 1 must be wrong because it leads to a contradiction. 7. Therefore, there is no largest prime. 8. Therefore there are an infinite number of primes. Q.E.D. Proofs by contradiction are lovely. Aleta

Do you see the number, Aleta? I would say that is a flaw. Virgil Cain

A proof that there is always a higher prime. Do you see a flaw, Virgil? http://www.math.utah.edu/~pa/math/q2.html Aleta

Cantor's approach: "The heck with it- call them equal and let's go have a beer." Pure mathematics at its finest. Now I know why Aleta and Jared love it so much. Virgil Cain

EZ:

I disagree, I don’t think it can be done.

What prevents it from being done? It is as easy as finding the bijective function. Or at the most difficult finding other relative cardinalities and plotting the counts against the primes. But you are right- you couldn't do it.

And it runs counter to other work showing what the cardinality of the primes is.

It runs with the current notion of a bijective function. And that runs with current notion what makes them countably infinite sets.

Your ignorance of the mathematics does not carry the day.

Your lies, bluffs and false accusations just expose your desperation.

Using set subtraction and your ‘concept’ do you think the set of relative cardinalities is a well-ordered set?

I need a system, not just a concept. And set subtraction just shows there is a difference (or not) between the two sets. Also the bijective function that produces the one-to-one mapping between the two sets is the relative cardinality.

Which of sets A or B has the higher cardinality?

Who cares? What is the highest known prime? And if that is the highest known prime then how do you know there is one higher? Virgil Cain

Virgil

It can be done, Jerad. Nothing prevents it. If you were half the mathematician that you think you are you could do it given everything I have told you about my concept. Unfortunately you are too stupid to understand what that means.

I disagree, I don't think it can be done. And it runs counter to other work showing what the cardinality of the primes is. Which is why I suggested it as a test of your 'concept'. And you haven't been able to figure out it out. So, if you can't show it then you 'concept' doesn't work. I fully expect you to continue to dodge the issue since you've been doing that for months and months now. But if your 'concept' can't handle cases that Cantor's approach can handle then your concept is like a lame horse. It can't get the job done. And what does your 'concept' say about the cardinality of the rational numbers? Are there more rational numbers between 1 and 10 than between 1 and 2? Can you prove your answer?

And your lies have been pointed out many more times. All you have are bluffs and lies.

Your ignorance of the mathematics does not carry the day. But it continues to serve to make you look ignorant and foolish.

Set subtraction is properly constructed math.

Using set subtraction and your 'concept' do you think the set of relative cardinalities is a well-ordered set? Which of sets A or B has the higher cardinality? ellazimm

daves:

There are endless examples. How about tackling the set of all labeled trees on any finite number of vertices? How does the cardinality of this set compare with the cardinality of N?

OK, if I develop a system I will give it some thought. Virgil Cain

EZ:

It looks like you can’t find the cardinality of the primes or sets A and B above since you haven’t done so.

It can be done, Jerad. Nothing prevents it. If you were half the mathematician that you think you are you could do it given everything I have told you about my concept. Unfortunately you are too stupid to understand what that means.

Your ignorance of its importance within mathematics has been pointed out to you many, many times.

And your lies have been pointed out many more times. All you have are bluffs and lies. Virgil Cain

Aleta:

There are an infinite number of of rationals between any two rationals. Example: between 0 and 1 there is {1/2, 1/4, 3/4, 1/8, 3/8, 5/8, 7/8 , …} These are truly dense, in the mathematical sense, and not just dense in the Virgilean sense of spread out within another set.

Clueless. And your set structure leaves much to be desired. But I would think a simple inversion and direct comparison would be at hand.

And yet the number of rationals is the same as the number of naturals: see http://www.homeschoolmath.net/.....ntable.php for an easy demonstration of the proof.

I am pretty sure that is what is being debated so just restating it doesn't help. And the "proof" leaves much to be desired.

Intuition does not help much in thinking about infinity,

That is only your opinion and is not an argument.

but properly constructed math does.

Set subtraction is properly constructed math. Virgil Cain

Virg #886

You can’t even follow along. That’s pathetic, Jerad. Thank you for proving that it is useless to have a discussion with you.

It looks like you can't find the cardinality of the primes or sets A and B above since you haven't done so. I can determine the cardinality of all those sets though.

There isn’t any importance to saying that all countable and infinite sets have the same cardinality and no one can verify it.

Your ignorance of its importance within mathematics has been pointed out to you many, many times. You're making yourself sound very foolish. Especially when you're also avoiding answer some simple math based questions. ellazimm

EZ:

I think I know what the cardinality of the primes is.

You can't even follow along. That's pathetic, Jerad. Thank you for proving that it is useless to have a discussion with you.

A ‘practical’ application has nothing to do with Cantor’s work being important and verified.

There isn't any importance to saying that all countable and infinite sets have the same cardinality and no one can verify it. Virgil Cain

VC,

What are they? I cannot say if my ideas apply unless I know what you are talking about.

There are endless examples. How about tackling the set of all labeled trees on any finite number of vertices? How does the cardinality of this set compare with the cardinality of N? daveS

Aleta #883

I wonder what Virgil thinks of that?

He thinks it's incorrect; I've mentioned it to him before. BUT he's never been able to find a mistake in any of proofs of that. So, he thinks there are different 'sizes' of infinity but he thinks there are 'classes' of infinity. Take the counting numbers and subsets of it. The cardinality of the evens or the odds would be one-half the cardinality of the positive integers. I asked him if he thought there was a smallest infinite cardinal number because the cardinality of the positive integers would be bigger than the cardinality of the evens which would be bigger than the cardinality of the multiples of three, etc. But he couldn't decide as I recall. I could be wrong about that. I should have asked him about {1, 1/2, 1/3, 1/4, 1/5 . . . } How fast would the ticker go then (using his 'infinity is a journey' metaphor). I'd avoid talking about theorems though, he thinks some are true and some aren't.

Intuition does not help much in thinking about infinity, but properly constructed math does.

Amen to that. Should we mention the imaginary numbers? Or the surreal numbers? Or the hyper-real numbers? :-) ellazimm

Consider the rationals. There are an infinite number of of rationals between any two rationals. Example: between 0 and 1 there is {1/2, 1/4, 3/4, 1/8, 3/8, 5/8, 7/8 , ...} These are truly dense, in the mathematical sense, and not just dense in the Virgilean sense of spread out within another set. And yet the number of rationals is the same as the number of naturals: see http://www.homeschoolmath.net/teaching/rational-numbers-countable.php for an easy demonstration of the proof. I wonder what Virgil thinks of that? The naturals are a proper subset of the positive rationals, which is the reverse of the evens being a proper subset of the naturals, and yet the rationals have the same cardinality as the naturals. Intuition does not help much in thinking about infinity, but properly constructed math does. Aleta

How about the set of all factorials? How dense is that? They get pretty spread out pretty darn fast! :-) Aleta

Virgil

t can be done, Jerad. Nothing prevents it. Even you could do it given everything I have told you. Stop trying to make this personal.

I think I know what the cardinality of the primes is. And we're talking about your counter-idea. So, lets's see you do it. Nothing personal about it.

It’s as if you think Einstein was refuted or a moron because someone else did the actual validation of his idea.

What? Are you comparing yourself to Einstein?

Make your case or stuff the innuendoes. Obviously you don’t understand the density argument. See, your childish accusation style just further provokes and adds nothing.

I think Aleta understands it very well. AND you could shut everyone up if you'd just prove you understood it by finding the relative cardinalities of the primes.

And the pursuit of the relative cardinalities would be a noble quest. And guess what? It is the same as the pursuit of the bijective functions that map elements from one set to the elements of another. Of course the natural matching doesn’t need a function and is very clear.

Great, do it.

And AGAIN, the reason for asking for a practical application of Cantor’s concept is that in the absence of it then no one can really say if cantor is right or not. If Cantor was wrong about the cardinality of infinite sets then really nothing happens and intuition rules. There seems like there would be a greater number of naturals than evens and that is because there are.

A 'practical' application has nothing to do with Cantor's work being important and verified. If you think he was wrong then find a fault with one of his proofs. That's how math is done.

What are they? I cannot say if my ideas apply unless I know what you are talking about.

Why don't you look stuff up yourself for a change? ellazimm

Aleta I know. I even suggested once he look over the prime number theorem for some help. He can calculate 'relative' cardinalities for the easy stuff: the evens, the odds, the multiples of 3, etc. But give him a geometric sequence or the primes and he can't handle those. ellazimm

daves:

Most of the countably infinite sets people are interested in are not sets of real numbers.

What are they? I cannot say if my ideas apply unless I know what you are talking about. Virgil Cain

VC,

That has nothing to do whether or not someone can come up with a relative cardinality for primes.

Hmm. So the set of primes does have a cardinality? Anyway, if you want to use densities to determine a notion of cardinality, I guess you could do that, but that would only work for subsets of R. And there are many ways of measuring densities, so you would have to choose one. Most of the countably infinite sets people are interested in are not sets of real numbers. It's not clear how your ideas will extend to those sets. daveS

And the pursuit of the relative cardinalities would be a noble quest. And guess what? It is the same as the pursuit of the bijective functions that map elements from one set to the elements of another. Of course the natural matching doesn’t need a function and is very clear.

Dance all you like but:

Yes logic and reasoning are beyond you. And AGAIN, the reason for asking for a practical application of Cantor’s concept is that in the absence of it then no one can really say if cantor is right or not. If Cantor was wrong about the cardinality of infinite sets then really nothing happens and intuition rules. There seems like there would be a greater number of naturals than evens and that is because there are.

Dance, dance, dance.

Your responses betray you, Jerad. You are incapable of understanding an argument and you can only parrot the party line. Virgil Cain

Aleta:

Here, of course, there is no clearcut “density” (an idea he doesn’t understand),

Make your case or stuff the innuendoes. Obviously you don't understand the density argument. See, your childish accusation style just further provokes and adds nothing.

because the primes, on the average, spread out as you encounter them. Therefore he has no idea what the cardinality of the primes might be using his ideas.

Yes, it could be determined and nothing prevents it. It would be a great mathematical pursuit Virgil Cain

EZ Jerad:

Can you or can you not find the cardinalities of the primes? Find the other cardinalities and make your comparisons. Or admit you can’t do it.

It can be done, Jerad. Nothing prevents it. Even you could do it given everything I have told you. Stop trying to make this personal. It's as if you think Einstein was refuted or a moron because someone else did the actual validation of his idea.

You don’t understand Cantor’s work

You are just a sore loser. Virgil Cain

Aleta: I think you mean by “non-realizable” not being tied to a clear real-world representation. Right. Not possible to instantiate in space and time. And by “beyond symbolic manipulation”, I think you are asking to what extent math is true beyond the fact that is internally logically coherent and consistent. I would put it this way: what extent math is "true" beyond the fact that the manipulation of the symbols (which is what we actually deal with) is internally logically coherent and consistent. mike1962

Hi Mike. As I was writing, I was aware of this truth issue, but I'm not sure exactly awhat you mean.

What does mathematical “truth” mean when dealing with the non-realizable abstract, beyond (interesting to be sure) symbolic manipulation?

I think you mean by "non-realizable" not being tied to a clear real-world representation. And by "beyond symbolic manipulation", I think you are asking to what extent math is true beyond the fact that is internally logically coherent and consistent. Do I interpret your question correctly? Aleta

EZ, you might recall that when Virgil talks about mappings, he's really just talking about what I called subset matchings, not a counting mapping. That's how he decided that the evens have 1/2 the naturals, because two naturals go by for every one match. In the case of the primes he would match 2 -> 2, 3 -> 3, 5 -> 5, 7 -> 7, etc. Here, of course, there is no clearcut "density" (an idea he doesn't understand), because the primes, on the average, spread out as you encounter them. Therefore he has no idea what the cardinality of the primes might be using his ideas. Aleta

Virgil Can you or can you not find the cardinalities of the primes? Find the other cardinalities and make your comparisons. Or admit you can't do it.

And the pursuit of the relative cardinalities would be a noble quest. And guess what? It is the same as the pursuit of the bijective functions that map elements from one set to the elements of another. Of course the natural matching doesn’t need a function and is very clear.

Dance all you like but: can you find the cardinality of the primes, yes or no?

And AGAIN, the reason for asking for a practical application of Cantor’s concept is that in the absence of it then no one can really say if cantor is right or not. If Cantor was wrong about the cardinality of infinite sets then really nothing happens and intuition rules. There seems like there would be a greater number of naturals than evens and that is because there are.

Dance, dance, dance. You don't understand Cantor's work and you clearly don't understand a mathematical proof. Can you find the cardinality of the primes or not? I'm not going to pay you but I am willing to bet some money you can't do it. Shall we say $10? $50? $100? ellazimm

Aleta: But also, note that the question of applicability is separate from the question of mathematical truth. I appreciate what you wrote @858. What does mathematical "truth" mean when dealing with the non-realizable abstract, beyond (interesting to be sure) symbolic manipulation? mike1962

And AGAIN, the reason for asking for a practical application of Cantor's concept is that in the absence of it then no one can really say if cantor is right or not. If Cantor was wrong about the cardinality of infinite sets then really nothing happens and intuition rules. There seems like there would be a greater number of naturals than evens and that is because there are. Virgil Cain

Aleta:

But to the pure mathematician, the reverse is true: math is worth pursuing, and has a truth of its own, irrespective of the ways we can apply it at this time, or ever.

And the pursuit of the relative cardinalities would be a noble quest. And guess what? It is the same as the pursuit of the bijective functions that map elements from one set to the elements of another. Of course the natural matching doesn't need a function and is very clear. Virgil Cain

EZ:

After Aleta made yet another effort to explain to you the importance of Cantor’s work

Umm, she was spewing irrelevant nonsense. And then started with the false accusations. All of which I was sick of days ago.

Then you, in your reply to daveS, showed that you do have a ‘system’ which you denied.

You just have reading comprehension issues. My statement was a hypothetical.

So, you and your approach cannot figure out the cardinality of the primes.

Of course we could. We just couldn't do it via some function. We would have to set other relative cardinalities and check those against the density of primes.

And yet Cantor’s system handles this case quite easily.

Yes just giving up and saying they are the same is easy. The hard part comes in getting around the set subtraction refutation of the claim. But again if you want me to do some work, work that you could do using what I told you about my concept and if you were really a mathematician, then you have to pay me. So time to own up or shut up. Virgil Cain

Earth to Aleta:

I think the bolded part is unacceptable, and should not be tolerated.

Most of what you posted in response to me is unacceptable and should not be tolerated. If you don't spew your diatribe then I don't post that response. Virgil Cain

daves:

Didn’t you say that right here?

That has nothing to do whether or not someone can come up with a relative cardinality for primes. Virgil Cain

Joe/Virgil After Aleta made yet another effort to explain to you the importance of Cantor's work you replied:

LoL! I appreciate the difference between mathematics and pure BS

And

I doubt that and just because you can say it doesn’t make it so. Most people understand that Cantor’s concept wrt the cardinality of infinite sets is counter-intuitive. So no, Aleta, what you say doesn’t have any merit.

And

That is just a pathetic way to “argue”, Aleta. So kindly go play in traffic. You have nothing but the rantings of someone who cannot make a case.

All very rude and disrespectful. Of someone who has had a lot more patience than anyone else I know of trying to understand what you are saying. You say over and over again that people don't even try and understand what you are saying and yet when someone does you treat them like that. Then you, in your reply to daveS, showed that you do have a 'system' which you denied.

The set of primes would have a relative cardinality based on its mapping function with, for example, the naturals. If you couldn’t devise such a function then you would have to figure out its relative density with some other method.

So, you and your approach cannot figure out the cardinality of the primes. Because you can't find an appropriate function nor do you have 'some other method'. And yet Cantor's system handles this case quite easily. As it handles sets A and B that I defined previously. If you think none of this matters then just say so and say you can't figure out the cardinalities I'm asking about. If you think it does matter then figure them out or admit you can't. Whatever it is make a statement. You dance and dodge and duck but you don't come up with the goods. Or admit you can't. Can you or can't you? Time to own up. ellazimm

Hey, kf,I know you're busy elsewhere, but at some point, take a look at 860

860 Virgil CainMarch 11, 2016 at 2:30 pm Aleta: ... That is just a pathetic way to “argue”, Aleta. So kindly go play in traffic. You have nothing but the rantings of someone who cannot make a case.

I think the bolded part is unacceptable, and should not be tolerated. Aleta

VC,

I didn’t say that.

Didn't you say that right here?

ellazimm: And you still haven’t figured out the cardinality of the primes. Virgil Cain: There isn’t one as cardinality refers to the NUMBER of elements and infinity isn’t a humber. You don’t even understand the very basics of mathematics.

daveS

daves:

The fact that VC has stated that the set of primes doesn’t even have a well-defined cardinality in his sense does not bode well.

I didn't say that. And seeing that mathematicians find figuring out the bijective function is worthwhile then it seems my concept is as well. My concept runs off of figuring out the mapping functions between given sets. The set of primes would have a relative cardinality based on its mapping function with, for example, the naturals. If you couldn't devise such a function then you would have to figure out its relative density with some other method. Virgil Cain

Aleta:

Virgil seems to think his question is critical to the discussion, perhaps not appreciating the difference between pure and applied mathematics.

LoL! I appreciate the difference between mathematics and pure BS

So, if Virgil’s question is in respect to pure math, the answer is that if Cantor was wrong that countable infinite sets having the same cardinality, which would imply that the underlying logic was wrong, a whole system of understandings about numbers would also be wrong.

I doubt that and just because you can say it doesn't make it so. Most people understand that Cantor's concept wrt the cardinality of infinite sets is counter-intuitive. So no, Aleta, what you say doesn't have any merit.

But also, note that the question of applicability is separate from the question of mathematical truth.

Or reality vs imagination or philosophy. What makes something the mathematical truth?

Virgil would have no use for the Mandelbrot set, or e^(i*pi) + 1 = 0.

That is just a pathetic way to "argue", Aleta. So kindly go play in traffic. You have nothing but the rantings of someone who cannot make a case. Virgil Cain

Aleta,

So, if Virgil’s question is in respect to pure math, the answer is that if Cantor was wrong that countable infinite sets having the same cardinality, which would imply that the underlying logic was wrong, a whole system of understandings about numbers would also be wrong. Given that this theory of set has been extensively studied, tested, and extended, and is a core of a great deal of math, the chances of Cantor’s basic idea about cardinality being wrong is pretty much zero.

Very interesting post. FWIW, my take on VC's question is that we certainly could try dividing the collection of countably infinite sets into sets of different "sizes" (provided we don't have two conflicting definitions of cardinality in force simultaneously). Mathematicians don't find that worthwhile, apparently. Moreover, it would clearly require a lot of ad hoc judgments. Probably many pairs of sets would be non-comparable. The fact that VC has stated that the set of primes doesn't even have a well-defined cardinality in his sense does not bode well. The mainstream mathematicians are "lumpers" while VC is a "splitter" in this instance. daveS

Virgil seems to think his question is critical to the discussion, perhaps not appreciating the difference between pure and applied mathematics. So even though it is not relevant to whether Cantor's ideas about cardinality are true or not, I'll say a few things. The question is

If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all?

Mathematics is a tremendously powerful and useful tool in understanding the world. However, to apply math you have to have some math to apply, so people, some people especially, like to develop pure mathematics irrespective of whether it a has an application. For instance, non-Euclidean geometry was developed out of purely mathematical questions concerning the parallel postulate, but the idea that spaces could have different types of curvatures and other properties has become a very useful tool. Reciprocally, practical questions often stimulate the creation of pure math that doesn't have an application. For example, questions about feedback loops in weather systems led to the invention of fractals which led to the discovery of the Mandelbrot set, which itself has no practical applications that I know of. So sometimes pure math has an affect in terms of practical understandings, and sometimes not. However, very often math is developed that at the time doesn't seem to have any applications, and then later is found to do so. Also, because pure math is an abstract system with idealized components, when math is applied it is always imperfect in some way: there are no perfect circles; there is not an infinite number of anything; natural exponential growth, which assumes continuity, most likely is never exact, and so on. So to apply math one must make a model relating the perfect concepts of pure math to the less than perfect aspects of the real world and our ability to know it perfectly. So, if Virgil's question is in respect to pure math, the answer is that if Cantor was wrong that countable infinite sets having the same cardinality, which would imply that the underlying logic was wrong, a whole system of understandings about numbers would also be wrong. Given that this theory of set has been extensively studied, tested, and extended, and is a core of a great deal of math, the chances of Cantor's basic idea about cardinality being wrong is pretty much zero. If Virgil's question is in respect to applied math, then the question becomes in what ways is the general topic useful. It may be that the specific fact that countable infinite sets have the same cardinality has no specific practical application, but the whole edifice of the set theory begun with Cantor is used all the time. But also, note that the question of applicability is separate from the question of mathematical truth. If applicability is one's hallmark of importance, a great deal of math would be irrelevant. Virgil would have no use for the Mandelbrot set, or e^(i*pi) + 1 = 0. Also, sometimes math is applied in fields one has no interest in or knowledge about, so one might think it made no difference, and yet someone else would find it critical. For instance fractals, which are based in theory on infinite iterations, has extremely important applications in studying turbulence, but Virgil might have no idea of that connection. But to the pure mathematician, the reverse is true: math is worth pursuing, and has a truth of its own, irrespective of the ways we can apply it at this time, or ever. From that point of view, if Virgil's question is about a practical affect, the answer is it doesn't make in difference as the mathematical truth: in the world of math, the evens have the same cardinality as the naturals, irrespective of whether that has a practical use anyplace. Aleta

Look, if neither of you are going to answer my question then there isn't anything else to discuss as obviously you are just going to continue your dishonest remarks. But thank you for proving my point! Virgil Cain

ellazimm:

Like I said, anyone who really understands set theory knows what is true.

BWAAAAAAHAHAHAHAHAHAHAHAHAHAHAHAHAHAHAHA Too bad not one of those people can answer my question.

You keep asking for answers that already exist

That is incorrect and proves that you are dishonest. But I do understand that is all that you have. Virgil Cain

Virgil

LoL! @ ellazimm- Nice cowardly non-response. The avoidance of my question speaks volumes. Thank you for continuing to prove my point.

Like I said, anyone who really understands set theory knows what is true. You keep asking for answers that already exist but you haven't read them and you don't understand them when they are pointed out to you. ellazimm

Aleta:

What’s wrong with being a woman?

ellazimm is proud to be a woman. Virgil Cain

ellazimm:

He wasn’t wrong.

How do you know? The concept doesn't have any practical applications so it is clear anyone can say anything and still be OK.

Over a hundred years of mathematicians agree.

That is neither an argument nor relevant.

And Cantor’s work gave a firm foundation of modern mathematics.

A useless concept isn't a foundation, Jerad. Virgil Cain

What's wrong with being a woman? :-) Aleta

LoL! @ ellazimm- Nice cowardly non-response. The avoidance of my question speaks volumes. Thank you for continuing to prove my point. Virgil Cain

Virgil

If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all?

He wasn't wrong. Over a hundred years of mathematicians agree. And Cantor's work gave a firm foundation of modern mathematics. Anyone who has studied real set theory understands that. It doesn't make a difference to toaster repairmen though. And anyone who has studied real set theory would be able to figure out the cardinality of the primes. And sets A and B that I defined previously. ellazimm

If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? The avoidance of my question pretty much says it all. Thank you. Virgil Cain

Aleta

Aleta @ 839- Thank you for proving to be totally clueless. Jerad attacked me and made it personal. Jerad can’t even deal with my argument and he cannot answer a simple question about Cantor’s claims. and you have avoided that question because you know that by answering it you will have proven my point.

Awww, he likes you!! ellazimm

ncorrect. ‘ellazimm’ was mine BEFORE ‘Jerad’. I switched because KF thought I was a woman.

You act like a woman. Answered my question yet? Too bad because if you did you would make my point. Virgil Cain

And you still haven’t figured out the cardinality of the primes.

There isn't one as cardinality refers to the NUMBER of elements and infinity isn't a humber. You don't even understand the very basics of mathematics. Virgil Cain

Virgil

Jerad was banned before. And then he created the fake ellazimm. And now he posts lies and false accusations because he cannot handle the arguments.

Incorrect. 'ellazimm' was mine BEFORE 'Jerad'. I switched because KF thought I was a woman. Got that wrong as well. Figured out the cardinality of the primes yet? Or of sets A and B defined above? I guess you can't do that. Better to just admit it and move on. ellazimm

Aleta @ 839- Thank you for proving to be totally clueless. Jerad attacked me and made it personal. Jerad can't even deal with my argument and he cannot answer a simple question about Cantor's claims. and you have avoided that question because you know that by answering it you will have proven my point. Virgil Cain

EZ Jerad:

Love your academic reasoning.

Look at the pap I was responding to. It was devoid of academic reasoning. Virgil Cain

Jerad was banned before. And then he created the fake ellazimm. And now he posts lies and false accusations because he cannot handle the arguments. Virgil Cain

Aleta

Hey kf, vouve warned Virgil, and now he posts 837. How long does it get to go on?

Joe was banned before. And then he created the fake Virgil. I wonder what pseudonym he'll use next? ellazimm

Virgil

ellazimm has been exposed as a poseur, a coward and a liar. Time to crawl back under your rock, Jerad

Missed your addendum the first time around. And you still haven't figured out the cardinality of the primes. Or the sets A and B defined earlier in this thread. Too bad Cantor could answer those questions. ellazimm

Hey kf, vouve warned Virgil, and now he posts 837. How long does he get to go on? Where are the snippers when we need them? ;-) Aleta

Virgil

ellazimm, Give it up, Jared. You don’t have a clue and you are too stupid to think for yourself. Add that to the fact that you choked on my question and we get it, you don’t know jack. However you have proven that you are a liar and spewer of false accusations. Nice job

Love your academic reasoning. ellazimm

ellazimm, Give it up, Jared. You don't have a clue and you are too stupid to think for yourself. Add that to the fact that you choked on my question and we get it, you don't know jack. However you have proven that you are a liar and spewer of false accusations. Nice job ellazimm has been exposed as a poseur, a coward and a liar. Time to crawl back under your rock, Jerad Virgil Cain

Virgil Give it up Joe. You've proven you don't really understand Cantor's work. Time to stop pretending you do. ellazimm

mike1962 @ 832

Physical body, correct.

Correct. In hindsight, I think my comment was insensitive. I apologize for it. Me_Think

Aleta:

Virgil, the density issue between the naturals and the reals uses exactly the notions of infinity that you reject.

Nonsense. Make your case and then answer the question that you have been avoiding: If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all?

If you look at the arguments that the rationals have the same cardinality as the naturals, but the reals don’t, you will find the exact same arguments that you reject when you say the evens are smaller than the naturals.

Make your case as opposed to just a bald accusation.

Also, what doe Cantor say about set subtraction with infinite sets?

Did he say something about it? Post it and we can all have a look. Virgil Cain

ellazimm #831 It's pretty clear that you are nothing but a horse's arse and a mathematical weenie. If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? It is very telling that my detractors refuse to answer that simple question. It’s as if they know that by answering it they will prove my point. That says it all Virgil Cain

Me_Think: OK, so in the end some of us are not even food for microbes Physical body, correct. mike1962

Virgil #829 It's pretty clear you don't really understand Cantor's work at all. You claim to agree with . . . Oh never mind. You'll never actually take anyone's word for it so I'd just be wasting my time. You claim to have an understanding that decades of mathematicians don't have yet you clearly haven't even understood that which you argue about and against. ellazimm

Virgil, the density issue between the naturals and the reals uses exactly the notions of infinity that you reject. If you look at the arguments that the rationals have the same cardinality as the naturals, but the reals don't, you will find the exact same arguments that you reject when you say the evens are smaller than the naturals. Also, what doe Cantor say about set subtraction with infinite sets? Aleta

EZ:

But that is part of Cantor’s basic premise!!

That's your opinion and only an opinion. However seeing that the claim is useless I doubt it is fundamental to his thesis.

That what he defines to be the smallest infinite cardinal number!!

That's redundant and wrong. For one cardinality refers to the number of elements. Also infinity is not a number.

What part of what he said do you agree with then?

Everything else. duh. That means everything dealing with finite sets as well as his saying that, due to the density issue, the reals have a greater cardinality than the naturals. If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? It is very telling that my detractors refuse to answer that simple question. It’s as if they know that by answering it they will prove my point. Virgil Cain

Mapou

I have been using Fourier analysis in my speech recognition research for years. It’s funny but I have never encountered anything infinite about it. In fact, I use a finite and discrete computer to do my work. How is that possible if, as you seem to claim, it uses infinities?

You never looked at the mathematical definitions then. Start here. https://en.wikipedia.org/wiki/Fourier_analysis Lots and lots of infinities there. On every integral and every series.

That is a lie as I do not reject Cantor. I just reject his notion that all countable and infinite sets have the same cardinality. If Jerad takes that to mean I reject cantor then Jerad is a bigger arse than I thought.

But that is part of Cantor's basic premise!! That what he defines to be the smallest infinite cardinal number!! What part of what he said do you agree with then? ellazimm

EZ:

But you and Virgil do have Cantor rejection in common.

That is a lie as I do not reject Cantor. I just reject his notion that all countable and infinite sets have the same cardinality. If Jerad takes that to mean I reject cantor then Jerad is a bigger {SNIP -- KF] than I thought. Virgil Cain

EllaZimm @825, I have been using Fourier analysis in my speech recognition research for years. It's funny but I have never encountered anything infinite about it. In fact, I use a finite and discrete computer to do my work. How is that possible if, as you seem to claim, it uses infinities? You know why? It's because, regardless of what you have been taught or may believe, neither calculus, nor Einstein's physics, nor Cantor's work ever use any infinities whatsoever. It's a big lie. You, like some religious people I know, have been believing in a lie. But that's OK with me. I don't care. This is my last reply to you. I got other things to be busy with. Have fun. Mapou

Mapou Our resident mathematical luddite. :-)

The reason that I’m so insistent on this is that I’m tired of mathematicians and theologians sending humanity on a wild goose chase and preaching their crackpottery to an unsuspecting public. If infinity does not exist (and it most certainly does not), then Einstein was right when he wrote to his friend Besso that “nothing remains of my entire castle in the air and of the rest of modern physics.”

And yet Einstein's work and that of many, many other physicians and mathematicians works and has great predictive power despite having a firm theoretical basis on something you say doesn't exist. I'll stick with the stuff that works I think.

Why? Because both GR and SR are based on the existence of infinity. Why? Because continuous structures (fields) assume infinite smoothness. And, by all means, we should not stop at infinity. The same can be said of time, distance and space. Pi and perfect circles, too, are non-existent. So any talk from the physics community of gravitational waves as ripples in spacetime is the ultimate in crackpottery.

Have you ever used Fourier analysis? Another very useful mathematical technique. Based on judicious use of infinite series.

Modern physics is swimming in crackpottery. It is sitting on a mountain of crap. How did it get this way? We can put the blame squarely in the mathematicians’ laps. Cantor comes to mind. Calling an abstract set “infinite” or claiming that some infinities are larger than other infinities is downright irresponsible. It smacks of some sort of mental disease. Cantor was a nut, wasn’t he?

Turns out that the mathematics community eventually recognised how insightful and powerful Cantor's arguments were. Very few people even try to do work without encompassing his ideas. But you and Virgil do have Cantor rejection in common. And neither of you has come up with a viable, rigorous alternative that can stand up to scrutiny AND handle pertinent situations. For example: are there an infinite number of prime numbers? Yes or no? Are there the same number of rational numbers as real numbers? Yes or no? Does f(x) = 1/x ever reach the value of zero? Yes or no? What is the value of f(x) = 1/x as x gets closer to zero? ellazimm

mike1962 @ 823

Nah, the dust of my cremated body will probably not be too appetizing for any other organisms. As for my consciousness, well, we’ll see, won’t we.

OK, so in the end some of us are not even food for microbes. Me_Think

Me_Think: In the end we are food for microbes, nothing else. Nah, the dust of my cremated body will probably not be too appetizing for any other organisms. As for my consciousness, well, we'll see, won't we. mike1962

Virgil Cain @821, You're insulting me, man. At this point, all can say is, pack it where the sun does not shine. See you around. Mapou

Mapou:

I see nothing infinite in a few symbolic markings on my screen.

Well educated people see what I wrote as a representation of an infinite set. So perhaps you should get an education. Virgil Cain

Virgil:

{1,2,3,4,5,…}- that is an infinite set.

You're kidding me? I see nothing infinite in a few symbolic markings on my screen. They look very much finite to me. All you have shown me is a mathematical formula on how to build a series of numbers. My question still stands.

If an infinite set exists, where is it?

The reason that I'm so insistent on this is that I'm tired of mathematicians and theologians sending humanity on a wild goose chase and preaching their crackpottery to an unsuspecting public. If infinity does not exist (and it most certainly does not), then Einstein was right when he wrote to his friend Besso that "nothing remains of my entire castle in the air and of the rest of modern physics." Why? Because both GR and SR are based on the existence of infinity. Why? Because continuous structures (fields) assume infinite smoothness. And, by all means, we should not stop at infinity. The same can be said of time, distance and space. Pi and perfect circles, too, are non-existent. So any talk from the physics community of gravitational waves as ripples in spacetime is the ultimate in crackpottery. Modern physics is swimming in crackpottery. It is sitting on a mountain of crap. How did it get this way? We can put the blame squarely in the mathematicians' laps. Cantor comes to mind. Calling an abstract set "infinite" or claiming that some infinities are larger than other infinities is downright irresponsible. It smacks of some sort of mental disease. Cantor was a nut, wasn't he? Mapou

EZ:

Proving Cantor wrong would mean having to come up with an alternative to his ‘system’...

That is false and exposes your ignorance. You can definitely prove a concept is wrong without having a replacement. If Eddington would have found that gravity didn't bend light in the way Einstein explained in his equations then Einstein would have been proven wrong and no replacement would have been attempted. Do you ever think? And this is why I don't take your criticisms seriously. Virgil Cain

Thanks, EZ, for your comments. Aleta

Aleta:

It appears that I now correctly understand your position about the “relative cardinality” of infinite sets in respect to the Cantorian cardinality of the natural numbers.

There isn't a Cantorian cardinality of the natural numbers and I haven't picked a standard yet. Virgil Cain

And again: If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? It is very telling that my detractors refuse to answer that simple question. It’s as if they know that by answering it they will prove my point. ellazimm choked and spewed a non-sequitur that he really thinks answered the question. Everyone can see that he didn't even address it. So do any other detractors care to answer it? If not then my point is made and you have nothing to say about it. Virgil Cain

Mapou:

If an infinite set exists, where is it?

{1,2,3,4,5,...}- that is an infinite set. Virgil Cain

ellazimm- we have nothing to discuss as all you do is lie and bluff. Set subtraction proves that Cantor was wrong. Again I have been over and over this with you and you still ignore it. And when you spew nonsense like:

And you keep pretending that since you have no personal knowledge of the ‘practical’ application of a core concept in Cantor’s work the whole thing doesn’t matter anyway.

It just proves my point about you. No one has any knowledge for the practical application of saying that all countable and infinite sets have the same cardinality. And no that is not a core concept in Cantor's work. You have serious issues, kiddo. Virgil Cain

Virgil, KF, Mapou I don't understand why but you all are dancing around questions that have been addressed to you that are pertinent to the way this thread has evolved. Virgil: you and I have discussed at great length (on your own blog) your system of relative cardinalities. You 'calculated' the 'relative' cardinality of many infinite sets. So why are you now saying you haven't given it much thought at the same time baldly declaring that Cantor was wrong and you have proved it? I have asked you over and over again on this thread to determine the cardinality of sets A and B (defined a long ways above) and you won't even say whether you can or not. And you keep pretending that since you have no personal knowledge of the 'practical' application of a core concept in Cantor's work the whole thing doesn't matter anyway. But you have proved him wrong? Proving Cantor wrong would mean having to come up with an alternative to his 'system' which means you have to be able to answer questions like the ones I keep asking you. KF, daveS asked you over and over again several straight-forward yes or no question that are purely mathematical and you danced around it as if answering would threaten your life. daveS appears to have teased out one answer but why did you not just address the issue directly? We're just asking you about the mathematics NOT the cosmology or theology. I don't understand why you write paragraph upon paragraph of prose that avoids answering simple, direct questions. Mapou, you like bringing up concepts and ideas that you know will get people riled up but this time, when Aleta addressed your statements and then asked you a question in return you stomped off. I have noticed you behaving that way on other threads. You think it's a good and important thing to question authority (I agree) but you seem to have a real problem when you are questioned in return. What was it about Aleta's question that you found so objectionable? I have been participating on the blog for a number of years. I have been ridiculed many times (as you will all remember) and have been banned for no stated reason as you will also remember. On this thread Aleta, daveS and myself (to a much lesser extent) have been trying to figure out what it is you believe about a neutral topic and have been doing so in a generally respectful manner. Why is it so hard to answer some questions? This thread is not part of some greater war, it's about mathematics. In academic environments you HAVE to be prepared to face intense questioning, it's how it works. You can't just say whatever and expect people to nod and smile and take it on faith. They are going to do their best to stress it and pull it apart before they bring it into the fold. That's the way it should be, that's how you make sure that new stuff actually makes sense: the crucible of scrutiny. It's nothing personal. But if you can't defend your ideas and, especially, if you don't even try, then people are going to stop paying attention. Maybe you don't care if anyone takes you seriously but I don't that very much. All three of you have written hundreds of posts declaring yourselves to be right about various topics. When someone is trying to take you seriously and figure out what exactly you are saying that is exactly the time to answer some questions. ellazimm

mike1962 @ 811

In the end. We die. Period. You make your peace with that. Whatever it is

In the end we are food for microbes, nothing else. Me_Think

In the end. We die. Period. You make your peace with that. Whatever it is. mike1962

KF,

DS, by definition of endlessness T will go beyond any arbitrarily large finite value and in that sense is endless or infinite. Every specific defined term of T will be finite but endlessness cannot be exhausted.

Thanks. It appears we agree that T is an infinite set, and every element of T is finite? daveS

DS, by definition of endlessness T will go beyond any arbitrarily large finite value and in that sense is endless or infinite. Every specific defined term of T will be finite but endlessness cannot be exhausted. The ellipsis that indicates endlessness is a key component of the set. KF kairosfocus

Thanks, Mike. I said approximately the same things at 798. Aleta

Aleta: does pi exist? It depends on what you mean by "exist." "Exist" can mean a number of things. At very least, Pi is an intellectual abstraction invented/discovered by humans, resolvable to various degrees using algorithms. Whether or not it "exists" outside of that is a matter of strenuous philosophical contention by those very humans. Ultimately, nothing makes sense. But Pi as an abstraction has demonstrable usefulness to humans pragmatically. (Pardon the semi-redundancy.) mike1962

P.S. I also believe "the universe is both finite and discrete". We're not talking about the physical universe. We're talking about abstract mathematical concepts which can be applied, always with some lack of precision, to the real world. But the question is about the natural numbers as a mathematical concept. Aleta

But in 795 you wrote,

Aleta, answer my question first. Then I’ll answer yours.

I answered yours. You don't agree with me, I assume, but I answered. Perhaps you should follow through and answer mine, even if I might not agree with you. How many natural numbers are there? Aleta

Aleta, Do not address me anymore. Our conversation is over. Mapou

Mapou, does pi exist? This has nothing to do with religion at all. Aleta

Aleta speaks just like a Darwinist/materialist/atheist or Christian fundamentalist. With a forked tongue. Mapou

Mapou, does pi exist? It is an abstraction. If abstractions don't exist, does mathematics not exist? How about "tree". It's an abstraction. By saying that abstractions don't exist you are denying the existence of everything that makes human knowledge possible. Aleta

KF,

Your T is the set of naturals from 1 on and again continues endlessly in succession. No particular member in T we can note down will be infinite and no finite value in T will begin to exhaust the set.

Would you please answer these questions directly? Is T an infinite set? Is every element of T finite? daveS

Abstractions do not exist, by definition. PS. This is the reason that the universe is both finite and discrete. Live with it. Mapou

Mathematical ideas are abstract concepts, and we're quite capable of inventing symbols for and thinking about them. Infinite sets are in the same place as perfect circles, ?, sqrt(-1), the Mandelbrot set, 10^200, and any other mathematical concept. Some people believe these exist in some Platonic realm, and some believe they exist only as symbolic abstractions that we have invented. But in any case, the question of "where is infinity" is not different than "where is" any other mathematical concept. Some mathematical concepts are tied more closely to physical reality than others. The counting numbers have direct physical representations, circles can come close to perfect, etc. Others concepts like e, the Mandelbrot set, and infinity don't have direct physical representations. But they all are, from a purely mathematical point of view, abstract ideas symblized in language and mathematical symbols. They exist within mathematics as such irrespective of whether we can point to something that exists in the physical world. Your turn: how many natural numbers are there? Aleta

Mapou, do abstractions exist? If so, transfinite sets do. KF kairosfocus

DS, your set S was reciprocals of naturals continued endlessly per ellipse. Your T is the set of naturals from 1 on and again continues endlessly in succession. No particular member in T we can note down will be infinite and no finite value in T will begin to exhaust the set. Endlessness is a crucial component and there is a continual pointing across it. Stepwise finite stage endless succession cannot be completed. And the definition of w and its status as a limit ordinal without definable predecessor reflects that. There is no definable specific finite natural number of endless degree of removal from 0 or 1; tied to inability to traverse endlessness in steps. KF kairosfocus

Aleta, Answer my question first. Then I'll answer yours.

If an infinite set exists, where is it?

Mapou

Hi Mapou. How many natural numbers are there? You know, N = {1,2,3,...} How many numbers are in that set? Aleta

Virgil @790, My point is that, before we can talk about infinite sets, we gotta ask ourselves the following question:

If an infinite set exists, where is it?

Unless and until we can answer the question, we are just urinating against the wind. We cannot just poof things into existence. IOW, if you can compare two things, they are not infinite. Mapou

Thanks, Virgil. It appears that I now correctly understand your position about the "relative cardinality" of infinite sets in respect to the Cantorian cardinality of the natural numbers. Aleta

If infinity exists, where is it?

Infinity is a journey and you are on it, albeit only for a very short time :cool: Virgil Cain

Mapou:

The idea that one infinity can be bigger or smaller than another is about as cretinous and brain dead as it can get.

Without context I would agree. But given the context it is easy to see that some infinite sets have a higher density than others. It also seems that we can quantitatively classify two different types of infinite sets. From that it follows that there are at least two different types of infinities when it comes to numbers and that one is going to have a higher density than the other. Virgil Cain

If infinity exists, where is it? If time exists, where is it? If space exists, where is it? If distance exists, where is it? If unicorns exist, where are they? PS. Don't mind me. I'm just imitating Immanuel Kant. Mapou

The idea that one infinity can be bigger or smaller than another is about as cretinous and brain dead as it can get. It beats the flat earth hypothesis by light-years. Mapou

kairosfocus- I copy that and thank you for your patience. Virgil Cain

Aleta, I would start with some accepted standard, yes. But I would allow for a cardinality greater than, equal to or less than that standard. It is all relative, hence the name. That way you don't need any special pleading to get around the ramifications of set subtraction.

Therefore, Virgil’s belief, based on his set subtraction method, is that there are an infinite number of levels of infinity, both less than and greater than the level infinity associated with the natural numbers.

And that follows from Cantor's reasoning behind small and big infinity- and again I am not sure if the naturals is what I would use as a standard. I haven't given it much thought but that is what I would most likely start with and then see if another standard is better. Virgil Cain

KF,

DS, again, ellipsis of endlessness and the k, k+1 etc vs 0, 1, 2 etc effect highlighted through the pink vs blue tapes, the ellipsis of endlessness again. And there is not a problem with an infinite array of values in the near neighbourhood of 0 as values run towards the infinitesimal, with of course yet another type of endlessness, endlessly smaller and smaller. KF

You're not responding to my question. I'm asking whether my set T is an infinite subset of N consisting only of finite natural numbers. daveS

As far as I can tell, Virgil's view is that every infinite proper subset of the natural numbers has a different cardinality. Much as Cantor named aleph null (A0) as the cardinality of the naturals and A1 as the cardinality of the reals, and then built a sequence of further levels of infinity from there, Virgil seems to have the idea that we can start with the cardinality of the naturals and build down from there. The evens have fewer members than the naturals, the set of all squares would have even fewer members, the set of all factorials even fewer yet. Interesting enough, the integers would have more members than the naturals, by the same argument Virgil uses for the odds and evens. Let I = the integers = {0,1,-1,2,-2,3,-3, ...}, N = the naturals = {1,2,3,...), and N- = the non-positive integers {0,-1,-2,-3, ...} Then I - N = N-, so N and N- have fewer members than I. One more example: let N = the naturals and let N1 = {2,3,4,..}, so that N - N1 = {1}. By Virgils reasoning, the cardinality of N1 is one less than the cardinality of N, although still infinite. Therefore, Virgil's belief, based on his set subtraction method, is that there are an infinite number of levels of infinity, both less than and greater than the level infinity associated with the natural numbers. This seems to be what he believes. Aleta

VC, the warning is there. Point out the errors or wrongs, but kindly do not resort to further inappropriate language. I do not have time to police, and will act on what I see. KF kairosfocus

DS, again, ellipsis of endlessness and the k, k+1 etc vs 0, 1, 2 etc effect highlighted through the pink vs blue tapes, the ellipsis of endlessness again. And there is not a problem with an infinite array of values in the near neighbourhood of 0 as values run towards the infinitesimal, with of course yet another type of endlessness, endlessly smaller and smaller. KF kairosfocus

kairosfocus:

VC, I am beginning to run out of patience, please fix your tone. KF

And I have already run out of patience, hence my tone. Strange that you confront me for my responses but let the attacks and lies I am responding to alone. Virgil Cain

EZ Jared:

We’ve discussed your system of ‘relative’ cardinalities many, many times on your blog.

We have discussed the concept but not the system as I don't have a system, yet. And you can't even grasp the concept. Virgil Cain

KF, Do you agree or not that I have shown an infinite subset of N consisting of only finite numbers? Let me take a fragment of one of your posts from above and edit it a little:

And when sets are isomorphic and endless they must have the same cardinality — scale index — shown by finding a 1:1 correspondence. Isomorphism can be shown by transformation: {1/2, 1/4, 1/8, 1/16, ...} [edited next three lines] x -> 1/x {2, 4, 8, 16, ...} The sets {1/2, 1/4, 1/8, 1/16, ...} and {2, 4, 8, 16, ...}[edited] have countable endlessness, first degree endlessness, cardinality aleph null.

Therefore {2, 4, 8, 16, ...} is an infinite subset of N consisting of only finite values. Edit: BTW, I agree there's nothing special about the set I've chosen here; it does not 'change' anything. I made the switch partly for variety's sake. daveS

DS, I notice again, ellipsis of endlessness. The pattern is, naturals we reach in steps or represent using notations dependent on such, will be finite, and so will their reciprocals. But that brings us to the k, . . . problem. Ellipsis of endlessness. 1/k, . . . headed to 0 as limit (thus, heading towards infinitesimal scale) does not materially change the situation. KF kairosfocus

DS (Attn Vc etc), First, I am not going to be available for some days, so no new thread just yet. Apart from the question, what would such a thread add? Second, I appreciate the loading issue, but with the tone problem I have not had time to police, and with me incommunicado for a time upcoming, a new thread is not advisable right now. Notice has been served on tone so I expect a marked improvement over the next several days. There will be no further warnings. KF kairosfocus

Got it, me_think. Aleta

Aleta @ 772

Virgil is right, me_think, about the cardinality of the reals and naturals: they are different.

The "Profound effect" comment @ 768 was supposed to be a snark, except that it backfired :-) ! Me_Think

#766 VC

LoL! I don’t have a system yet, jerk.

Oh don't be so shy. We've discussed your system of 'relative' cardinalities many, many times on your blog. Any you know what? You couldn't figure out the cardinalities of the primes then either! And a bunch of other infinite sets as I recall. And now you can't figure out the cardinalities of sets A and B from above. I can do all of those for you if you want me to. Just say the word. By the way, you are mis-spelling my first name. ellazimm

KF, First, would it be possible to set up a new thread to continue the discussion? This one isn't (always) loading properly.

Pardon but first the sequence 1/n of course goes to endlessly smaller numbers heading to the infinitesimals.

This is a side issue but no infinitesimals are involved. I'm only working with real numbers in this example. The numbers in the sequence are the reciprocals of the powers of 2, all (real) rational numbers. Do you at least agree that the set {1/2, 1/4, 1/8, 1/16, ...} is infinite? And that every element is positive? daveS

Virgil is right, me_think, about the cardinality of the reals and naturals: they are different. However, since Virgil rejects Cantor in general, it's odd that he would invoke Cantor at all. Aleta

VC, I am beginning to run out of patience, please fix your tone. KF kairosfocus

DS, Pardon but first the sequence 1/n of course goes to endlessly smaller numbers heading to the infinitesimals. The endlessness cannot be completed in steps of reciprocals either, and we are right back at the main issue. Ever multiplicative inverse we can reach in steps of succession will be finite, as the numbers in the main sequence are finite. Marking correspondences and leaving off zero: 1/1 --> 1 1/2 --> 2 1/3 --> 3 . . . 1/n --> n . . . lim 1/n --> 0 Again we see pointing across an ellipsis of endlessness. KF kairosfocus

LoL! @ Me_Think:

Of course there would be profound effect – you would have proven that the set of real numbers has greater cardinality than the set of natural numbers !

Cantor has already said that the reals have a greater cardinality than the naturals. small infinity, big infinity But thanks for the continued laughs, MT Virgil Cain

Joe @ 767,

If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all?

Of course there would be profound effect - you would have proven that the set of real numbers has greater cardinality than the set of natural numbers ! - because set of real numbers has the same cardinality as the set of all subsets of the set of natural numbers. Me_Think

Again: If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? It is very telling that my detractors refuse to answer that simple question. It’s as if they know that by answering it they will prove my point. Thank you for proving my point. Virgil Cain

EZ Jared:

You haven’t understood any of the answers or links to answers I’ve provided.

Liar. Also not one of your answers nor links even addresses my question. It's as if you are proud to be a bluffing loser.

You refuse to listen to anyone who disagree with you.

Nice projection

You can’t use your own system

LoL! I don't have a system yet, jerk. Virgil Cain

#760 VC

You are a legend in your own itty-bitty mind.

Ah, the Virg we know and love.

You haven’t answered the question so what is there to believe?

You haven't understood any of the answers or links to answers I've provided. You refuse to listen to anyone who disagree with you. You can't use your own system to figure out the cardinalities of sets A and B above. Or the primes. But Cantor's system can handle all those cases easily. ellazimm

Have you found a mistake in any of Cantor’s work?

Yes, standard set subtraction proves he was wrong. Virgil Cain

Aleta, I dare you to answer the question: If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? Will you choke like Jared/ EZ has or will you actually address the actual question? Virgil Cain

Aleta:

Therefore, the evens are both a subset of the naturals and countable by the naturals. Both are infinite at the same level so to speak: there are the same number of evens as there are naturals.

And yet standard set subtraction proves that there are not the same number of elements between the evens and the naturals. And your only asinine response is to say that you cannot use set subtraction in this case. Virgil Cain

If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? Jared:

If you won’t believe me then read a real book on set theory.

You haven't answered the question so what is there to believe? It is very telling that my detractors refuse to answer that simple question. It’s as if they know that by answering it they will prove my point. Virgil Cain

Aleta:

I think one reason Virgil reverted back to hostile, rude non-discussion because the points I’m making are coming perilously close to pointing out some confusions in his thinking.

You are a legend in your own itty-bitty mind. Virgil Cain

I think one reason Virgil reverted back to hostile, rude non-discussion because the points I'm making are coming perilously close to pointing out some confusions in his thinking. Consider the set of even numbers E and the set of natural numbers N Now let Ef (f for finite) be a finite set of even numbers, such as = {2,4,6,... 2000) Let Cf be a counting mapping for Ef. Cf is a subset of N (because counting is done with natural numbers), and Cf will only go up to 1000. Cf = {1,2,3,... 1000} 2 -> 1 4 -> 2 ... 2000 -> 1000 Notice that Ef is not a subset Cf. Counting mappings do not do the same thing as subset mappings. Ef has the same cardinality as Cf, which is 1000. Both sets have 1000 elements. If you are interested in subsets, you need to consider another set, let us call it Sf = {1,2,3,...2000} Here the mapping 2 -> 2, 4 -> 4, ... 2000 -> 2000 shows that Ef is a subset of Sf. However Sf has twice as many elements as Ef, because it also includes all the odds. This mapping, however, has nothing to do with counting. It just shows that for any number of evens Ef, there is a subset of the naturals that contains Ef, but this relationship doesn't count the number of elements in Ef. These are the two ideas that Virgil is conflating. ============= Now, how does this apply to the entire infinite sets of E and N? The argument above for Ef and Cf shows that for any finite even number, every element of Ef can be mapped to one of the natural numbers, and that the cardinality of the two sets are the same: if f = 2 billion rather than 2000, then there is still a counting mapping which shows that Ef has 1 billion elements. If we had another even number, the count goes up by one. Thus, by induction, any finite set of evens, no matter how large, can be counted by being mapped to a subset of the naturals. (And in all cases, the set of evens under consideration is not a subset of the set being used to count it.) However, when we consider the infinite sets, the two concepts, subsets and counting, merge. The evens are a subset of the naturals, as 2 -> 2, 4 -> 4, ... forever. The evens can be counted by the naturals, as 2 -> 1, 4 -> 2, ... forever Therefore, the evens are both a subset of the naturals and countable by the naturals. Both are infinite at the same level so to speak: there are the same number of evens as there are naturals. Aleta

#757 VC

If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all?

If you won't believe me then read a real book on set theory. I know you won't do that but you won't believe anyone who disagrees with you.

It is very telling that my detractors refuse to answer that simple question. It’s as if they know that by answering it they will prove my point.

Have you figured out the 'relative' cardinality of the sets A and B I defined above? Have you figured out the cardinality of the prime numbers? Have you found any academic support for your 'system'? Have you found a mistake in any of Cantor's work? ellazimm

If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? It is very telling that my detractors refuse to answer that simple question. It's as if they know that by answering it they will prove my point. Virgil Cain

Aleta:

I take it that Virgil is not interested in discussing this anymore.

You are changing things, Aleta. So no, I am not interested in your flailing change. Virgil Cain

EZ Jared:

It’s part of the foundation of Cantor’s work.

Look, you have already proven that you cannot follow along nor answer a simple question. And by doing so you have proven that no one uses the concept that countably infinite sets have the same cardinality. You are just a bluffing loser. And a foundation would have a practical use. Absent a practical use then anyone can say anything about it and they would be correct as no one could ever refute them.

Maybe he figured out you were going to prove him incorrect.

No one can do that absent a practical use for the concept I am debating. But obviously you are too dim to grasp that simple fact. Virgil Cain

#748 VC

The question pertains to that small part of set theory and does not pertain to the entire theory.

It's part of the foundation of Cantor's work. You really should take a real set theory course someday. And, by the way, counting elements in a set is creating a one-to-one mapping between the elements of the set and (and at least some of) the positive integers. #751 Aleta

Yesterday we were having a fairly civil discuss as I tried to understand your thoughts. I’m not sure why such a simple thing as discussing counting in the context of set mappings prompted your comment this morning.

Maybe he figured out you were going to prove him incorrect. ellazimm

I take it that Virgil is not interested in discussing this anymore. And yes, it would be kernels of coin and grains of rice. I edited my post. Aleta

Aleta:

Actually, it’s the mathematical explanation of what counting is.

As if.

Obviously I picked a very small set for illustration purposes, but if I threw a bushel of corn on the floor and asked you to count the grains one-by-one, you would go through the same process,

No, I would laugh in your face. Also corn has kernels and not grains. So I would be laughing really hard. Virgil Cain

to Virgil: re 749. You write,

No, it seems like an imbecile’s way to do so. Nice job.

Actually, it's the mathematical explanation of what counting is. Obviously I picked a very small set for illustration purposes, but if I threw a bushel of corn on the floor and asked you to count the kernels [was grains] one-by-one, you would go through the same process, using the names of the numbers as the counting mapping. You'd count {one, two, three,... X} until you got to the last kernel, and then X would be the number of kernels (the cardinality of the set). In the post I just wrote I explained how this is the process that little children go through when they first learn to count. There is also archeological evidence that pre-historic people in the Middle East used a similar principle of 1:1 correspondence before the invention of written numbers, baking a number of pebbles in a clay sphere to represent the number of camels being transported across the desert by a trader. Yesterday we were having a fairly civil discuss as I tried to understand your thoughts. I'm not sure why such a simple thing as discussing counting in the context of set mappings prompted your comment this morning. Aleta

Thanks to the discussion with Virgil yesterday, I now understand a distinction that I wasn't aware in our respective viewpoints that may help further the discussion about cardinality. I mentioned this last night, but will now summarize here. There are two different mappings being discussed, used for different purposes, which I will call a. the subset mapping, and b. the counting mapping the subset mapping Let A and B be two sets. The subset mapping maps every element in A with a matching element in B, if one exists. If every element in A maps to an element in B, A is a subset of B. If the mapping is 1:1, so that every element in B is also mapped to an element in A, A and B are identical sets. However, if B has at least one element that is not mapped to a matching element in A, A is a proper subset. Example: A = {a,c,d} and B = {a,b,c,d,e} All three elements in A have a matching element in B, but some elements of B {b,e} don't have a corresponding element in A. Therefore, A is a proper subset of B. Notice that this mapping has nothing to do with how many elements are in the sets. the counting mapping Let A be a set. The counting mapping maps every element of A to a subset C of the natural numbers, in order, in a 1:1 correspondence. Thus, the cardinality of A is the same as the cardinality of C. Example: let A = {a,b,c} and C = {1,2,3} Then a 1, b 2, and c 3 is a counting mapping, and A has three elements because the cardinality of C is three. Note several things: a. the elements of A can be any kind of thing: letters, numbers, objects, etc. b. the counting mapping has nothing to do with subsets. In the example above, A is of course not a subset of B. Even if A contained numbers, such as A = {5,10,15}, the counting mapping would still produce a cardinality of three without there being any subset relationship. c. With counting, the order of the mapping doesn't make a difference, because the number of elements doesn't depend on the order that you count them in. In the above example, b 1, c 2, and a 3 is an equally valid counting mapping. That is, with counting, there are more than one possible 1:1 correspondences which count the given set. As an aside, learning this 1:1 correspondence concept is one of a child's first mathematical developmental milestones. Most children learn the verbal counterpart of C when they learn to recite {one, two, three, four, five} before they learn to actually match each word with a unique object. Given five objects, they might count faster than they touch and winding up saying there are six or seven objects, or touch an object twice, or if the objects are not in a line get confused about where they've started and which objects they counted. Only when they learn to accurately match each word with each object in a 1:1 correspondence have they truly learned to count. Teachers of math watch for this development in pre-schoolers and kindergarten students. Summary, and another example The subset mapping and the counting mapping are two different things. However, in some cases where set A contains numbers, both mappings might seem like they come into play. Consider the set A = {2,4,6,8,10} and consider the counting mapping with C = {1,2,3,4,5} Notice that some elements of A, but not all, are also elements of C. Therefore, A is not a subset of C. However, that is irrelevant. We are just counting A, so it makes no difference whether it is a subset of C or not. The cardinality of A has nothing to do with whether A is a subset of C or not. Aleta

Aleta:

For example, I want to know the cardinality of the set A = {a,b,y,z} To do so, we create the mapping

LoL! As if one needs to create a mapping in order to count the number of elements in a finite set.

Does this seem to you like the proper way of finding the cardinality of a finite set?

No, it seems like an imbecile's way to do so. Nice job. Virgil Cain

EZ Jared:

I’ve told you over and over again that Cantor’s set theory is fundamental to the foundation of mathematics and so if he were ‘wrong’ the whole building would be unsteady.

LoL! I have told you over and over again that has NOTHING to do with what I am asking. What is wrong with you? It's as if you don't have a clue. I am asking about one small part of set theory and not about the entire thing. Obviously you have other issues. But thank you for proving that you don't have a brain and cannot think for yourself. Anyone else care to try to answer the question: If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? The question pertains to that small part of set theory and does not pertain to the entire theory. Virgil Cain

kf writes,

Accordingly, as causal succession meets that test, some have tried to suggest that the mathematical result claimed to be shown of there being an infinite number of finite naturals is good enough to claim a transfinite past succession.

I don't believe anyone in this discussion has claimed that. The fact that you think someone (other than you) thinks these are related is probably one of the main reasons why you resist the simple conclusion about all natural numbers being finite. Aleta

KF, After reading some of Aleta's recent posts, the following occurred to me. It's a way to explain how N has infinitely many finite elements, using the function y = 1/x, which has come up already. Let S be the set usually denoted by {1/2, 1/4, 1/8, 1/16, ...}. S includes the member 1/2 and if x ∈ S, then x/2 ∈ S. S is clearly an infinite set, as we can see through the assignment x -> x/2, which defines a 1-1 correspondence between S and one of its proper subsets. Furthermore, every element of S is positive. This means the reciprocals of elements of S are all positive and finite. So, let T be the set of all reciprocals of elements of S. Note that x -> 1/x is a 1-1 correspondence, so S and T have the same cardinality. But T is a subset of N, so N includes an infinite subset, all of whose members are finite. Therefore N has infinitely many finite members. daveS

D, the thread has indeed been on a tangential matter but that is sufficiently close to the proper focus that I have gone with it. It is clear that no one can defend the notion of a finite stage sequence of steps from 0 bridging or traversing a transfinite range. Accordingly, as causal succession meets that test, some have tried to suggest that the mathematical result claimed to be shown of there being an infinite number of finite naturals is good enough to claim a transfinite past succession. But in fact the evidence in hand is such a succession of finites is just that finite. For there to have been an actually infinite past, at some remote zone in time, there would have had to be an actual transfinite past time. Which will not fly. The pink vs blue tapes example shows why as the attainment of any k is always utterly less than endless tot he point that the remainder k, k+1 on can be put in 1:1 correspondence with the naturals from 0. The evidence is that a finite stage stepwise process is going to be finite, and the way we get to the transfinite in Math is by a leap of faith that points across a literally infinite span. It is going to be very hard indeed to argue for an actually infinite space-time physical past for our cosmos and its antecedents. At the same time, a contingent cosmos points to necessary being root, and we are very close to the issue of eternity vs time. Okay gotta run now. Your inputs welcome. KF kairosfocus

Aleta @681

Dionisio, re 679: I think it was fairly clear that when I wrote “to a believer, such as kf” I was referring to a believer in God. Thus when I answered your question “Aren’t you a believer, too?” in the negative, I was referring to God also. For you to now say “Oh, really? Don’t you believe anyone, anything or in anything? Absolutely not?” is not a reasonable response.

Why do you think that it was fairly clear that when you wrote “to a believer, such as kf” you were referring to a believer in God? Clear to whom? To you or to other readers? Is everyone expected to know what you are referring to if it is not explicitly stated in a clear manner? Words have meaning, even if many people don’t care about the exact meaning of words and the contexts they are written in. Please, believe me, it took me too long to realize that fundamental truth. Unfortunately, still many times I fail to pay as much attention to the meaning of words as I should. I share this with you, because I would have appreciated enormously had someone told me this long ago, when I was much younger. For a number of years I existed in that oblivious state of mind that seems prevalent in the world. Fortunately Someone very precious to me graciously opened my eyes and made me see everything much clearer. BTW, switching between Slavic, Spanish and English languages almost daily makes it a little more challenging to pay attention to details and to understand the meaning of what others say or write. The problem gets worse when we add to the scenario the fact that my hearing is not good. On top of that my reading comprehension is poor, my communication skills almost nonexistent. My IQ score is about the same as my age, but changes in the opposite direction. My mind works so slow, that when someone tells me a joke on the weekend, I get it by Tuesday, after my wife explains it to me. ? Have a good day. PS. Note that many comments posted in this site form an interesting philosophical and theological “eintopf”. That’s why ‘assuming’ someone’s worldview position in the discussions here may have a high probability of resulting very inaccurate, to say it mildly. My time off is almost over. I have to go back to work, hence might not find much spare time to look at what’s discussed here. Anyway, most of that discussion seems above my pay grade, but have learned a few things from it. Learning doesn’t end. ? BTW, in one of your posts you were not sure whether to refer to me as he or she. FYI - Dionisio is a Spanish male name, though maybe derived from a Greek male name. Dionisio

#722 VC

If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all?

I've told you over and over again that Cantor's set theory is fundamental to the foundation of mathematics and so if he were 'wrong' the whole building would be unsteady. Look, I know you don't have a vast background in mathematics and that means that, sometimes, you won't 'get' the implications of a concept you disagree with. No one is saying that Cantor's work affects everyday life for most people on the planet. And if that's all you're interested in then why are you arguing about it all so much? You keep saying you're right and Cantor was wrong AND you want to believe that Cantor's work didn't matter anyway. It seems to me you are fighting two battles you have no real interest in. ellazimm

velikovskys @721

Dionisio: Didn’t you understand my question? Perfectly, did you understand mine?

Perfectly? Really? Hmm... let's see: Dionisio @662

What’s the bottom line of this discussion thread according to KF’s OP?

velikovskys @671

If the volume of KF’s responses is an indicator, the discussion of mathematics . Why, what do you think it is?

Dionisio @677

Didn’t you understand my question?

velikovskys @721

Perfectly, did you understand mine?

My question explicitly said “according to KF’s OP” But you explicitly answered according to the volume of KF’s responses Do you see the difference? And you said you understood my question 'perfectly'? What does the word 'perfect' mean to you? Does the word 'perfect' mean 'kind of' to you? Or does it mean 'I guess' or 'maybe' or 'perhaps' or 'whatever'? :) Words have meaning, even if this world thinks otherwise. Please, believe me, it took me a long time to realize that fundamental truth. Have a good day. [emphasis mine] Dionisio

Yes, I agree Virgil, finding the cardinality of a finite set is easy. In informal language, we just count the members of the set. More formally, we put the set in a 1:1 correspondence with the natural numbers. For example, I want to know the cardinality of the set A = {a,b,y,z} To do so, we create the mapping a -> 1 b -> 2 y -> 3 z -> 4 Therefore, A has a cardinality of four. Does this seem to you like the proper way of finding the cardinality of a finite set? Aleta

With finite sets a one-to-one correspondence is easy as all you have to do is find the cardinality of each set. Try your example with an infinite set. Virgil Cain

to Virgil: Good, Virgil. I'm beginning to understand your thinking better. 1. You write,

Aleta, The natural way of matching is to take the same numbers and match them. That is how it is done to determine if one set is a subset of another. Let set A = {0,1,2,3,4,5,…} Let set B = {1,3,5,7,9,…} Set A has every element in set B covered by natural matching and set A has numbers that set B does not have.

The mapping you discussed back in #709 (2 -> 2, 4 -> 4, etc) shows that E (the evens) is a subset of N (the naturals) because every number in N is also in E. That is the natural way to map the numbers to show that E is a subset of N. Furthermore, since some numbers in N, the odds, are not in E, that means E is a proper subset of N. I think I get all that. 2. Now I think a 1:1 correspondence between sets is a different subject. For instance, in 730, I wrote,

Given A = {a,b,c} and B = {1,2,3), the mapping a -> 1 b -> 2 c -> 3 is a bijective function because it maps a 1:1 correspondence.

This is a 1:1 correspondence between two sets that don't have any elements in common. Also, mappings don't have to be in any particular order. For instance, with the sets above, a -> 3 b -> 1 c -> 2 is also a 1:1 correspondence. There can be more than 1:1 correspondence between sets. This is easier to see in a case such as this one where the sets don't contain the same type of thing as elements. Also, since there is a 1:1 correspondence, we know the sets have the same number of elements. 3. So we have two different things: a. proper subsets in which the sets have at some elements in common, but not all, but not necessarily the same number of elements, and b. 1:1 correspondences, in which the sets don't necessarily have the same types of elements, although they might, but do have the same number of elements. So, Virgil, do you agree with this summary of things about sets? Aleta

On the one hand, in reference to the first half of your post, I apologize, Dionisio. I understand that mistakes in what you would expect in proper English might be confusing. However, the very first set of exchanges we had were confusing because I didn't see that I had an extra "are" in the sentence. I think all my replies were friendly, and when I finally realized my mistake, I apologized. At that point, you asked this question: "Off topic, does this discussion relate to the ID concepts proposed in this blog? How?" That was off-topic, but I spent some time answering. At that point, you asked what I would consider a not-so-friendly question:

If you and your comrades were only interested in pure math, why did ya’ll get attracted to this site and specially to discussion threads started by OPs that were allegedly not about pure math? Aren’t there pure math discussion forums on the internet? Do you have so much spare time for reading things you’re not interested in? Just curious. :)

From that point on, most of your posts to me were challenging, and you have continued to question my motives. I don't know why you have chosen that approach - that's your business, but I wouldn't say that you have been a"person that is really interested in the discussions as a mutually beneficial exchange of information, where the involved persons enjoy learning and sharing information in a friendly chatting [way]." Aleta

Aleta @631

4. When ellazimm wrote, “I find the psychology of debates on this sight very interesting.”, Dionisio wrote, “English is not my first (native) language. Please, can you explain that English sentence?” I think Dionisio is being disingenuous here. His (or her) English seems quite good. He made a similar remark to me when I left a extra “are” in a sentence. I am virtually certain that he knows that ellazimm meant “site”, not “sight”, and that Dionisio knows what the sentence means.

My native language is Spanish. There have been situations where I have encountered phrases or sentences in Spanish that I have not understood clearly and have asked someone about their meaning, even though I recognized all the words in the given text. Some words in Spanish have different meanings when used in different countries. Sometimes when I read a text written in English language, I try to learn from it the contents, style, grammar and vocabulary. Basically I use every opportunity to learn the language, when time is available for that. I do the same when I read text written in other languages (mainly Slavic) that I have studied and currently use relatively frequently. There are many unknown to me English idiomatic expressions in different regions of the vast English speaking world. This case of ‘sight’ in lieu of ‘site’ could have been one of those regional idioms. This was not the case of a misspelling that rendered the word unknown. There are situations when I see what looks like an obvious grammar or spelling error. I may or may not let someone else know about it, depending on the particular case. For example, in the above quoted text, copied from your post @631, we read this sentence: “He made a similar remark to me when I left a extra “are” in a sentence.” This sentence could have been written: “He made a similar remark to me when I left an extra “are” in a sentence.” Do you see the difference? However, this minor change does not affect the meaning of the sentence, as far as I can tell. Hence, normally I would not report it at all. It’s not worth mentioning. I mentioned it now for illustration only. In the particular case of the statement “I find the psychology of debates on this sight very interesting.”, I could have asked the question differently. For example, I could have asked: “shouldn’t it read ‘site’ rather than ‘sight’?” or “is that sentence correctly written?”. But I chose a more indirect questioning form in order to see the author’s reaction to my observation or question. As I’ve said before, I’m interested in letting my potential interlocutor to reveal his/her true motives for engaging in the discussion early on before we get too deep into it. A person that is really interested in the discussions as a mutually beneficial exchange of information, where the involved persons enjoy learning and sharing information in a friendly chatting, will react to any observation or question in a more humble manner than what I perceived from you and the other interlocutors related to this particular situation. Definitely I perceived your and some of your comrades’ reactions to my simple questions were not as ‘nice’ as it would be expected from persons who don’t have any problems with others asking them questions or making observations about anything. Fortunately all our comments are written in this public forum and available for double checking anytime. Maybe my perception of your reaction to my questions was inaccurate, but it’s up to you to improve it. However, you don’t have to. BTW, as far as I’m concerned, you may ask me any question you deem interesting. Just keep in mind that I don’t have much to offer in terms of scientific knowledge. Perhaps I will have to admit that I don’t know the answer for many questions you could ask me. But definitely I won’t have any problems publicly declaring my poor knowledge of many topics, which disqualifies me from offering anything worth reading in most discussions in this site. Dionisio

KF:

endlessness, the sets have the same sort of endlessness

Yes but they have different densities. And that is the key. Virgil Cain

VC, endlessness, the sets have the same sort of endlessness and can be transformed into one another, e,g take n from set 1 and do 2n +1, 0 +1 = 1, 2+1 = 3, 4+1 = 5, etc. KF kairosfocus

Aleta, The natural way of matching is to take the same numbers and match them. That is how it is done to determine if one set is a subset of another. Let set A = {0,1,2,3,4,5,...} Let set B = {1,3,5,7,9,...} Set A has every element in set B covered by natural matching and set A has numbers that set B does not have. And because of that it is a logical contradiction to say that both sets have the same cardinality, ie the same number of elements. Virgil Cain

KF,

DS, my intent is the exact opposite, to OBJECT that were the set actually transfinitely completed as successive +1 increment members from 0 it WOULD then have at least one endless member, on the copy the list so far principle of succession.

I have to run now, but isn't this exactly what I said in #731? The set I described is assumed to be "completed". daveS

DS, my intent is the exact opposite, to OBJECT that were the set actually transfinitely completed as successive +1 increment members from 0 it WOULD then have at least one endless member, on the copy the list so far principle of succession. Which would undermine the all members are finite claim. This is linked to the notion of an infinite number of +1 successive counting sets from 0. Where in fact when stepwise succession gets to arbitrarily large but finite k from k-1, k is {0, 1, 2 . . . k -1} --> k where then k+1 is therefore {0,1, 2 . . . k} And so forth where {}--> 0; {0} --> 1; {0,1} --> 2 etc. So, transfinitely many successive finite members is problematic. Instead the successive process at any k, k+1 pair is still finite and we indicate unlimited onward succession that we cannot actually complete by the ellipsis of endlessness. It is that endlessness that leads to omega being without definable "less one" predecessor. KF kairosfocus

KF, PS to my #728: You need to prove that the set most mathematicians express as { {}, {0}, {0, 1}, {0, 1, 2}, ... } has an infinite member. We're into the thousands of posts on this topic now, and at this point, I'm expecting rigorous proofs. daveS

Hmmm. I'm confused, but maybe we can clear this up. Bijective function is just a name for a mapping that creates a 1:1 correspondence, I think. Example: Given A = {a,b,c} and B = {1,2,3), the mapping a -> 1 b -> 2 c -> 3 is a bijective function because it maps a 1:1 correspondence. So, I'm wondering what you mean by "artificial". You write,

"A bijective function is an artificial method of getting a one-to-one correspondence."

Couldn't you just write,

A bijective function is a method of getting a one-to-one correspondence.

? Could you explain if and how the word artificial changes the meaning of those two sentences? Aleta

Aleta:

Since the odd numbers in N don’t map to anything, it seems to me this would not be bijective. Is that true?

It is true. You don't seem to understand what I am saying. A bijective function is an artificial method of getting a one-to-one correspondence. I am saying it is, in reality, the relative cardinality between the two sets. The proof is that it gives a one-to-one correspondence. Virgil Cain

KF,

DS, the next set principle is long since established, it is the point that the order type is the list of sets so far and becomes the next in succession cf von Neumann. KF

Yes, of course. That in no way implies:

That were such to be suggested, as the next counting set is the copy of the list so far, that would require an endless thus non-finite, element in the set[.]

daveS

DS, the next set principle is long since established, it is the point that the order type is the list of sets so far and becomes the next in succession cf von Neumann. KF kairosfocus

Thanks, Virgil. In 709, I offered this mapping, which you said was what you had in mind:

2 (in N) maps to 2 (in E) 4 (in N) maps to 4 (in E) 6 (in N) maps to 6 (in E) etc.

Since the odd numbers in N don't map to anything, it seems to me this would not be bijective. Is that true? Aleta

Aleta, Yes the bijective function maps the two sets one to one. And it is also how to tell the relative difference in cardinalities of the two sets. For example n-> 2n means one is twice the size as the other, ie has two times the elements. Virgil Cain

Thanks, Virgil. Back at 665 you said that "the relative cardinality can be determined by the bijective function." I looked up bijective function, and it means 1:1: every element in the first set maps to one and only one element in the second set. Your mapping doesn't doesn't map 1 or 3 or any of the other odd numbers to any number in E. Therefore, your mapping doesn't seem to be a bijective functions because it doesn't create a 1:1 correspondence. Does this seem correct to you? Aleta

Yes Aleta- you have figured out how to determine if one set is a subset of another. See we already have a matching process so there is no need to invent another. Virgil Cain

EZ Jared:

The ‘count’ is not the size of the set.

Sure it is. As I have said you don't grasp the fact that infinity is a journey and you think your ignorance is some sort of refutation.

You can’t ‘count’ the size of the integers.

Cardinality refers to the number of elements. So yes counting is a valid way of determining that. If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? Everyone sees that you are too chicken to answer that. And by avoiding it you prove that you have nothing. Virgil Cain

Dionisio: Didn’t you understand my question? Perfectly, did you understand mine? velikovskys

Good, Virgil. I think I am understanding now. Tell me then, if this right: 1 (in N) doesn't map to anything in E 3 (in N) doesn't map to anything in E and so on. Therefore, when, for instance, 4 (in N) maps to 4 (in E), N has traversed four numbers (1, 2, 3,and 4) but E has only traversed two numbers (2 and 4). Therefore at that point N has twice as many numbers as E. Is this what you are saying? Have I figured this out correctly? Aleta

KF,

DS, I have pointed out where the problems lie, amounting at minimum to a paradox, and that has been reasonably shown not merely asserted. KF

No, I disagree. You haven't pointed to anything that I consider problematic. This assertion:

That were such to be suggested, as the next counting set is the copy of the list so far, that would require an endless thus non-finite, element in the set?

is in dire need of a proof. daveS

#714 VC

Wow, talk about a convoluted defense. The counters in question count forever. That means they are endlessly counting. And one counter will always have a higher count than the other- always and forever mean endlessly.

The 'count' is not the size of the set. You can't 'count' the size of the integers. If both counters ticked at the same rate but one started one tick before the other then you would say that the 'set' that started earlier was bigger. It doesn't work that way. That was what Cantor established. That is what is now accepted, non-controversial mathematics. ellazimm

Yes, Aleta, that is what I mean. That it took you so long to figure that out tells me you are not up for this discussion. That you refused to support your nonsensical claim about set subtraction cements that. Virgil Cain

LoL! @ EZ Jared:

At the moment is issue is that Virg is saying things that fly in face of well-established and non-controversial mathematics.

If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? TSZ ilk avoided that question at all costs and I am sure that my detractors here will do the same. Thank you for fulfilling my prediction.

Repeating it won’t make it correct.

That what I say fits the definition makes it correct. Virgil Cain

DS, I have pointed out where the problems lie, amounting at minimum to a paradox, and that has been reasonably shown not merely asserted. KF kairosfocus

KF:

In the case of two counters, one set to half rate, at finite values from the same reset point A will read about twice B. But that is not the same question as endlessness. No counter can bridge stepwise to actual endlessness.

Wow, talk about a convoluted defense. The counters in question count forever. That means they are endlessly counting. And one counter will always have a higher count than the other- always and forever mean endlessly. Virgil Cain

EZ Jared:

You don’t know what isomorphic means.

No, Jared, you are the one with definition deficit. Virgil Cain

KF,

DS, Do you see that my point is, the finites are finite and the transfinites are transfinite where omega is a limit ordinal with no definable immediate predecessor — as I said already in so many words?

Yes, I have seen you post words to that effect many times already. We both agree that is true, I take it.

That therefore to suggest an infinite collection of successive finite counting sets is problematic?

I've seen that assertion, but no proof.

That were such to be suggested, as the next counting set is the copy of the list so far, that would require an endless thus non-finite, element in the set?

An assertion again, but no proof. And likewise for the rest. What I understand you to be saying is that even the act of defining the (complete!) set: { {}, {0}, {0, 1}, {0, 1, 2}, ... } leads to contradictions. But that is exactly the definition of N (and of ω) so I don't see any option for you other than to reject the existence of the set N, and any other infinite sets as well. And therefore ω itself cannot make sense to you. But I thought we agreed above that ω was a well-defined ordinal? daveS

#708 VC

Sets are only isomorphic artificially.

You don't know what isomorphic means. ellazimm

#703 KF At the moment is issue is that Virg is saying things that fly in face of well-established and non-controversial mathematics. And he refuses to accept that he is wrong. Maybe you should try talking to him about that. #704 VC

If there is more than one correspondence then there isn’t any one-to-one correspondence. If I can match an element in your set D to more than one element in your set C, then there isn’t a one-to-one correspondence, by definition.

Repeating it won't make it correct.

LoL! All you have demonstrated is your ignorance. The definition is clear and it supports my claim. That you are trying to argue that proves that you are desperate.

What's the 'natural' mapping between sets A and B above then? I can show you a one-to-one mapping if you like. It's very easy. And see if you can figure out the 'relative' cardinality of sets A and B (defined above) and the set of primes numbers instead of just name calling. ellazimm

Oh, I see, Virgil. Tell me if this right: 2 (in N) maps to 2 (in E) 4 (in N) maps to 4 (in E) 6 (in N) maps to 6 (in E) etc. Is that what you mean? Aleta

Sets are only isomorphic artificially. The counter tests proves cantor was wrong. Set subtraction proves Cantor was wrong. Virgil Cain

VC, tone again. And when sets are isomorphic and endless they must have the same cardinality -- scale index -- shown by finding a 1:1 correspondence. Isomorphism can be shown by transformation: {0,1,2 . . . } n x 10 {0, 10, 20 . . . } The set and its proper subset have countable endlessness, first degree endlessness, cardinality aleph null. In the case of two counters, one set to half rate, at finite values from the same reset point A will read about twice B. But that is not the same question as endlessness. No counter can bridge stepwise to actual endlessness. That is why I pointed to the tapes example and added a case where a cream tape has holes every 0.2 inches. For a finite span from 0 the pink and blue will show the same increment and cream, half. But all three are endless to the RHS, and that is the material point. KF kairosfocus

Again your position fails the counter test. Two counters, one counting every second and one counting every other second. These counters count forever, ie they are infinite counters. One counter will always have a higher count than the other. Always and forever. Everytime someone looks one counter will always have a higher count than the other. always and forever. And having a higher count means it has more elements. Look my concept is the same as Cantor’s different sizes of infinity. Meaning both look at the density of the set. And my approach doesn’t lead to logical inconsistencies exposed by standard set subtraction. Virgil Cain

Aleta:

Could you show me the natural mapping more specifically, please.

So you are admitting that you do not know how to tell if one set is a subset of another? Then talking about set theory with you is a waste of time. The natural mapping is matching up the like numbers from two (or more) sets. Virgil Cain

EZ Jared:

The whole world disagrees with you and we must be lying.

The whole world doesn't disagree with me and I have explained your lie. Like the pathetic imp you are you won't even address it.

Your method doesn’t work.

That is your uneducated opinion.

No one uses it.

No one uses the concept that all countably infinite sets have the same cardinality. The concept is useless. If there is more than one correspondence then there isn’t any one-to-one correspondence. If I can match an element in your set D to more than one element in your set C, then there isn’t a one-to-one correspondence, by definition.

That is simply not true as I have demonstrated.

LoL! All you have demonstrated is your ignorance. The definition is clear and it supports my claim. That you are trying to argue that proves that you are desperate. Virgil Cain

EZ, Mathematics is the logical analysis of structure and quantity. It is not settled by majorities or schools of thought and axiom systems post Godel are very open to question. The issue I am seeing here is one on a claim that to my mind is problematic, an infinite succession of finite and discrete values incremented from 0 at +1 per step. Where the next member is the collected list so far. This implicates the ordinary proof by induction, on case 0 then case k => case k+1. This is a finite chaining, inherently, as case k is bounded by case k+1 and then in effect case k+1 is fed back into the case k register. Thus clearly the natural numbers we may count to will be finite. But the point of the ellipsis of endlessness is that there is no upper limit. Where as the pink/blue tape thought exercise shows, at any arbitrary k that is finite, there is always endlessness ahead that will go to 1:1 match between k, k+1 etc and 0,1, 2 etc. The endless is not traversed in +1 steps. We point across the ellipsis and conclude. The point then is that inductive chaining attains to the potentially infinite but does not in itself complete the infinite in chained steps. We add a sub axiom of pointing across the endless succession onward represented by an ellipsis. But in this case in view the claim seems problematic. That all naturals we can actually count to or specifically note down are finite is obvious, but we have to reckon with the force of endlessness. That is how I see it. Now, if I am wrong and there is a simple solution apart from a leap of faith across endlessness, it should be apparent. KF kairosfocus

Virgil says, "No, the obvious mapping would be the mapping used to determine if one set is a subset of the other. that is the natural mapping." Could you show me the natural mapping more specifically, please. That is, what does 1 map to, what does 2 map to, etc. Thanks. Aleta

#698 VC

Liar

The whole world disagrees with you and we must be lying. Your method doesn't work. You can't even tell me the 'relative' cardinalities of sets A and B defined above or the positive prime numbers. You cannot point to a single mistake in a single proof of the work Cantor did. Your method has no academic or research support. No one uses it. Because it doesn't work. You can't even make it work.

If there is more than one correspondence then there isn’t any one-to-one correspondence. If I can match an element in your set D to more than one element in your set C, then there isn’t a one-to-one correspondence, by definition.

That is simply not true as I have demonstrated. Would you like me to do another? Two sets can usually be matched up many ways, some one-to-one, some not. IF you can find even a single one-to-one matching then the sets are 'the same size'. It's not that hard to grasp. ellazimm

If Cantor was wrong about countable infinite sets having the same cardinality, what would be affected or would there be no effect at all? TSZ ilk avoided that question at all costs and I am sure that my detractors here will do the same. Virgil Cain

Aleta:

Let N = {1,2,3,…n,…} Let E = {2,4,6,…2n,…) Also, consider the obvious mapping between the sets: 1 -> 2 2 -> 4 3 -> 6 … n -> 2n

No, the obvious mapping would be the mapping used to determine if one set is a subset of the other. that is the natural mapping. Again your position fails the counter test. Two counters, one counting every second and one counting every other second. These counters count forever, ie they are infinite counters. One counter will always have a higher count than the other. Always and forever. Everytime someone looks one counter will always have a higher count than the other. always and forever. And having a higher count means it has more elements. Look my concept is the same as Cantor's different sizes of infinity. Meaning both look at the density of the set. And my approach doesn't lead to logical inconsistencies exposed by standard set subtraction. Virgil Cain

EZ Jared:

I’m not lying.

Yes you are lying and now you are trying to change the subject. You are lying about the utility of saying that all countably infinite sets have the same cardinality. You have lied about that for years. You say you have linked to the utility of saying that yet you never have. You are a liar. Well I showed above that simple set subtraction proves that the set of positive integers has more elements than the set of positive even integers and positive odd integers.

You were incorrect.

No, I am correct. You even did the math and came up with the same answer. If there is more than one correspondence then there isn’t any one-to-one correspondence. If I can match an element in your set D to more than one element in your set C, then there isn’t a one-to-one correspondence, by definition.

That is incorrect.

LoL! You are in no position to make such a claim. OTOH I have provided a definition which agrees with me. And if I can subtract one set from another and get a set with infinite elements then it is obvious that the three sets do not have the same number of elements.

Again, incorrect.

Again, your say-so is meaningless as you are a nobody.

You have been shown, many, many times, how your ideas fail.

Liar Virgil Cain

DS, Do you see that my point is, the finites are finite and the transfinites are transfinite where omega is a limit ordinal with no definable immediate predecessor -- as I said already in so many words? That therefore to suggest an infinite collection of successive finite cunting sets is problematic? That thus the key is that the ellipsis of endlessness entails that we cannot succeeed in +1 steps to the infinite? That were such to be suggested, as the next counting set is the copy of the list so far, that would require an endless thus non-finite, element in the set? That this becomes seriously problematic, underscoring the solution that we cannot succeed to the transfinite in +1 steps? That the ellipsis of endlessness is thus a vital component of the set of counting sets from 0 on? KF kairosfocus

#694 KF

That is we may only specifically attain to finitely many concrete finite values such as 1987 *10^2016 etc, values that depend on stepwise and surpass-able increments of +1 from 0 or (as illustrated) on representations such as place value or sci notation that use similarly dependent components. But the endlessness goes beyond what we can reach in that way. We can establish a pattern sufficiently in steps but then we must always point to the do forever onward that goes beyond what we can attain in finite stage steps from 0. Indeed notice the just above riff on Hilbert’s Hotel to see the point about endless steps of counting onward from a further k steps on. Thus also observe use of infinitesimals in the y = 1/x function to catapult to hyper-reals in the transfinite domain, cf Ehrlang’s tree of numbers.

You really must learn to espouse mathematics in a standard form. I asked if you had any academic publications or research work which supports or elucidates your view. I read your view over and over again and I'm asking if there is anyone other than you who thinks the way you do. Could you at least give me a mathematical definition of 'endlessness'? Please? ellazimm

KF,

And in the case of finitude of natural counting sets, that becomes material. For, on the copy of the set-list so far premise, actual succession to endless degree would include that some members in the far zone would have to copy in that endlessness into individual members. Which, would render such members non finite.

Let's assume than α is a nonfinite counting set as described above. Then we have a strictly increasing sequence: {}, {0}, {0, 1}, {0, 1, 2}, ... , α Now it is impossible that α is the least nonfinite counting set, because such a thing cannot exist. By definition, α = n ∪ {n} for some natural number n, which implies that n < α and that n is also infinite. However, this is at odds with the proposition that there is a least infinite ordinal ω. Are we agreed on this? daveS

EZ, the phenomenon of endlessness as shown by the ellipsis of endlessness is the heart of the conception of infinity routinely appearing in mathematics {0,1,2 . . . k, k+1, . . . } . The second ellipsis is unbounded, endless, as opposed to the first, and the expression is a commonplace. It should not be a debatable point. I find it amazing that you want yet another definition after the many in this thread, just scroll up: that which goes on beyond any arbitrarily large but finite value, in a nutshell, cf the pink vs blue tape and the k, k+1 etc matched to 0,1,2 etc to to see what this means. The thought exercise is WLOG and keeps the speculations anchored to realities in the empirical world -- which is important. The relevant case in point is the ongoing set of collected successive counting sets, which goes on and on beyond any arbitrarily large k that is finite and bounded by k+1; we therefore accept that we can only point and collect the ellipsis of endlessness INSIDE the set definition, giving omega as symbol of its order type. Third, that after k finite numbers there is a k+1th only illustrates that this too is finite, as we then feed the former k+1 into the value-k register and repeat, thus we only attain to finite values in steps. That is we may only specifically attain to finitely many concrete finite values such as 1987 *10^2016 etc, values that depend on stepwise and surpass-able increments of +1 from 0 or (as illustrated) on representations such as place value or sci notation that use similarly dependent components. But the endlessness goes beyond what we can reach in that way. We can establish a pattern sufficiently in steps but then we must always point to the do forever onward that goes beyond what we can attain in finite stage steps from 0. Indeed notice the just above riff on Hilbert's Hotel to see the point about endless steps of counting onward from a further k steps on. Thus also observe use of infinitesimals in the y = 1/x function to catapult to hyper-reals in the transfinite domain, cf Ehrlang's tree of numbers. KF kairosfocus

#692 KF

As a further result, it seems to me that we cannot automatically assume that per ordinary mathematical induction, properties of succession from case k to case k+1 will be unaffected by endless-NESS. The chain does show that any value we may reach is indeed going to behave in the specified way once case 0 and the chaining obtain, but such will not actually traverse the endless. And in the case of finitude of natural counting sets, that becomes material. For, on the copy of the set-list so far premise, actual succession to endless degree would include that some members in the far zone would have to copy in that endlessness into individual members. Which, would render such members non finite.

You can't be asserting that there is only a finite number of finite numbers because you can always find one more. Which means you can't point to a boundary or line which, when crossed, takes you into the infinite. Do you have any academic or research papers which explore your concept of 'endlessness' which you can link to. I'd like to see it defined and worked out rigorously.

Therefore, we need to revert to transfinite induction (and possibly recursion) for cases where the potential but not actualised transfinite is not good enough. But, as the very name implies, that goes beyond the finite.

Do you have an example of a case? ellazimm

VC (Attn A, DS etc), You are bringing out some of the ways first degree so-called "countable" endlessness changes everything. Which is a strategic result. Yes in a finite pattern, {0,1,2,3, 4 . . . . k}, k LT k+1 "less" {0, 2, 4, . . . [k]} "gives" {1, 3, 5 . . . [k]} But in the endless case the standard counting sequence, the evens and the odds become simply different ways of expressing first degree endlessness, as we can transform one pattern into the next. It is the endlessness that is here shown to be a decisive component of the structured sets. It literally changes the import of everything. This then refocuses the points of concern I have discussed above, starting from the argument from the easily seen bounded-ness of 0, 1, 2 etc, the closure under succession so k which is k x (+1) from 0 is then bounded by the k+1th step, k + 1 and the extension that therefore all naturals, endlessly, are finite. Endlessness counts and generates strange results but ought not to generate contradictions, so we modify our thinking if a particular approach ends in questionable claims. This is of course a summary of another famous proof technique, proof of claim X by demonstration of contradiction in its denial ~X. We notice, from the pink vs blue endless punched tape thought exercise, that truncating at k, k+1 etc and putting in 1:1 correspondence with the undisturbed sequence preserves an endless match. That is starting the succession from any finite k, k+1 is equivalent to (strictly, isomorphic with) starting from 0,1 etc. Because of onward endlessness. And this truncation and correlation process can be repeated endless-LY via do forever looping, with the same result every time. (Hilbert's Hotel has a similar result for bringing in new guests of endless number. Move the old guests in rooms n to rooms 2n and put the new guests into 1,3,5 etc endlessly. [In closer comparison with our case, consider an endless train of buses with k new guests lined up in front of the hotel which is full as usual. The manager broadcasts, present guests in room n move to room n+k, then puts the latest busload into rooms 1 to k. This can be repeated endlessly. This of course shows that such a hotel cannot be physically built. Magic step, the new guests are actually repair people and rooms 1 to k are going under repair, bus 1 is carpenters, bus 2 electricians, etc, so now rooms 1 to k go through first repairs, with guests moved to k+1 on. Bus 2 then shifts the first lot of carpenters to rooms K +1 to 2k, and the process continues. The whole lot of actual guess are still there even as the repair people keep on coming into the rooms 1 to k and earlier repair people shift up another k rooms. At no stage is there need for actual guests to leave, no matter that the crazy hotel was full to begin with. In short these thought exercises are telling us that endlessness produces weird results.] ) As a result, we see that no finite stage, stepwise succession can traverse endlessness. Instead we use this process to set up the pattern (the potential infinite) and project a leap of endless faith, often putting it into axioms, as has been discussed above. In the case of the claim that all naturals, are finite but there are infinitely many such finite natural counting sets, I think this is a step too far. For, it can be seen that the next counting set is the list of sets so far from 0. As a result if a list of such is wholly of finite elements, the members of the list, necessarily, will be finite. At the same time, the endless list has been assigned order type the first transfinite, omega, which is not a natural. The solution, to my mind, is that the endlessness cannot be completed in successive finite stage steps and so while every specific natural we can reach by stepwise finite stage process is indeed finite, we cannot exhaust the endlessness. The ellipsis of endlessness is a major, material component of the set that collects successive counting sets. As a further result, it seems to me that we cannot automatically assume that per ordinary mathematical induction, properties of succession from case k to case k+1 will be unaffected by endless-NESS. The chain does show that any value we may reach is indeed going to behave in the specified way once case 0 and the chaining obtain, but such will not actually traverse the endless. And in the case of finitude of natural counting sets, that becomes material. For, on the copy of the set-list so far premise, actual succession to endless degree would include that some members in the far zone would have to copy in that endlessness into individual members. Which, would render such members non finite. The solution to my mind is that ordinary mathematical induction extends to the potentially infinite, not the actual completion of endlessness. So we must reckon with a fallacy of composition on taking the leap to endlessness. Therefore, we need to revert to transfinite induction (and possibly recursion) for cases where the potential but not actualised transfinite is not good enough. But, as the very name implies, that goes beyond the finite. KF kairosfocus

KF @690 Very timely advice. Thank you. BTW, apparently this discussion thread remains popular: :)

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Dionisio

NOTICE: There is no need for the use of questionable vocabulary (e.g. Mathematics has nothing to do with questionable sexual behaviour) and accusatory verbal grenades. Where, if people are speaking with disregard to truth that will show itself well enough. I am asking for such language to be avoided in the interests of preserving a tone that is family friendly. Comment is a privilege on good behaviour, not a right. KF kairosfocus

Hi Virgil. I've been thinking about your comment about the number of elements in the even natural numbers, so I'm going to try to explain what I understand. Let N = {1,2,3,...n,...} Let E = {2,4,6,...2n,...) Also, consider the obvious mapping between the sets: 1 -> 2 2 -> 4 3 -> 6 ... n -> 2n ... Now, consider the 5th term of N, which is 5. The matching term in E is 10, but both N and E have 5 numbers at that time: N has 1,2,3,4,5 and E has 2,4,6,8,10 So at that time, for n = 5, they both have the same number of numbers. Now consider the 1 billionth term: the 1 billionth term of N is 1 billion and the 1 billionth term of E is 2 billion, but just as with 5, the number of terms in each set is the same. They both have 1 billion terms. Since the same argument can be made for any number, for any term n in N, the number of terms in N and E at that time are equal. The actual numbers are different (the number in E is twice that of the number in n), but the number of numbers in each set is the same. Since this is so for any n, how do numbers of numbers in N and E ever get to be unequal? Aleta

Well, this is interesting. I just found the post in which kf gave me a warning, at 644.

I especially won’t bother with people who don’t appreciate the importance of pure mathematics, irrespective of applied utility, and I also am not fond of discussing things with people who call others [SNIP — Aleta warning. KF]

Since kf snipped what I wrote we can't see what I said, but I remember that I had quoted Virgil in 643 as calling EZ a "cowardly wanker." Those were Virgil's words, directed at EZ, not my words. However, now 643 uses the phrase "mathematical weenie", which Virgil edited after my post at 644. It is clear that Virgil edited his post, because in 649, EZ quoted Virgil's original statement:

NOTE- I am NOT asking about Cantor’s set theory but just one small part of it. That means when Jared responds with Cantor’s set theory is fundamental he proves that he is a cowardly wanker who cannot support his position.

So now I understand the situation. Aleta

Virgil

But EZ is lying. You should be talking to him about that

I'm not lying. Everyone else agrees with me. You haven't yet told me what the cardinality of sets A and B (as defined above) are.

Well I showed above that simple set subtraction proves that the set of positive integers has more elements than the set of positive even integers and positive odd integers.

You were incorrect.

If there is more than one correspondence then there isn’t any one-to-one correspondence. If I can match an element in your set D to more than one element in your set C, then there isn’t a one-to-one correspondence, by definition.

That is incorrect. There can be many mappings between two sets. There can even be multiple one-to-one mappings. The key point is: IF there is even one one-to-one mapping then the sets are 'the same size'.

And if I can subtract one set from another and get a set with infinite elements then it is obvious that the three sets do not have the same number of elements.

Again, incorrect.

Again, cuz you say so isn’t an argument. That you refuse to even address what I said speaks volumes.

I have addressed your . . . proclamations. I gave you two sets, A and B defined above, which your set subtraction method doesn't work. And you haven't been able to tell me their cardinalities. Just like you've never been able to tell me the cardinality of the set of prime numbers. Your method doesn't work.

But anyway, seeing that you are a liar and I get reprimanded for calling you what you obviously are, we have nothing to discuss.

I'm not lying. You are incorrect.

He also says that an infinite set has to given all at once, which it obviously cannot be as infinity is a journey. Also mathematics isn’t a consensus and you can’t even answer a basic question.

You have been shown, many, many times, how your ideas fail. You have been given many, many references to correct information. You have been shown time and time again correctly worked out examples. You cannot find any academic support for your ideas. You have not been able to find fault with any proof of any mathematical theorem. NO ONE agrees with you. No one. Give it up. ellazimm

EZ Jared:

See Virgil, even KF disagrees with you. Like we said.

He also says that an infinite set has to given all at once, which it obviously cannot be as infinity is a journey. Also mathematics isn't a consensus and you can't even answer a basic question. Virgil Cain

If there is more than one correspondence then there isn’t any one-to-one correspondence. If I can match an element in your set D to more than one element in your set C, then there isn’t a one-to-one correspondence, by definition.

Clearly you are mistaken as I showed.

Except you didn't show anything. So clearly you are just a bluffing loser who cannot understand a definition. And if I can subtract one set from another and get a set with infinite elements then it is obvious that the three sets do not have the same number of elements.

Again, clearly you are mistaken.

Again, cuz you say so isn't an argument. That you refuse to even address what I said speaks volumes. But anyway, seeing that you are a liar and I get reprimanded for calling you what you obviously are, we have nothing to discuss. Virgil Cain

kairosfocus:

VC (attn EZ & A), well above I showed how the set of naturals can be directly transformed into the set of evens or the set of odds.

Well I showed above that simple set subtraction proves that the set of positive integers has more elements than the set of positive even integers and positive odd integers. Virgil Cain

kairosfocus:

VC, there is not any reason to toss verbal grenades such as “liar.”

But EZ is lying. You should be talking to him about that Virgil Cain

kf writes,

VC (attn EZ & A), well above I showed how the set of naturals can be directly transformed into the set of evens or the set of odds. Likewise for the set of tens or the set from k, k+1 on. That is they are all isomorphic and of the same cardinality.

Thanks, kf. That is a nice clear statement. Aleta

Dionisio, re 679: I think it was fairly clear that when I wrote "to a believer, such as kf" I was referring to a believer in God. Thus when I answered your question "Aren’t you a believer, too?" in the negative, I was referring to God also. For you to now say "Oh, really? Don’t you believe anyone, anything or in anything? Absolutely not?" is not a reasonable response. Aleta

kf writes, "Aleta, you are also warned on language. KF" Please let me know what post, and what language, you are objecting to Aleta

Aleta @631

3. WhenI wrote, “I think, to a believer such as kf, […]”, Dionisio wrote, “Aren’t you a believer, too?” No.

Oh, really? Don't you believe anyone, anything or in anything? Absolutely not? :) Dionisio

Dionisio,

“mainly interested in mathematics here” Your comrade used the word ‘only’ but now you say ‘mainly’? Do you see the difference? Do you see the conflicting (inconsistent) statements?

Well, Aleta and I are not the same person. We are bound to make conflicting statements now and again.

What’s your goal in this discussion? [emphasis mine]

I don't have a "goal" per se. I, like many people, enjoy discussing things on the internet. When I read a post that interests me, or that I perhaps disagree with, I will often reply. When I read something that I believe is definitely wrong, I will offer a correction. These threads actually have been quite productive for me, as I have learned a lot and have found a number of books and articles to add to my reading list. daveS

velikovskys @671

Dionisio: What’s the bottom line of this discussion thread according to KF’s OP?

If the volume of KF’s responses is an indicator, the discussion of mathematics . Why,what do you think it is?

Didn't you understand my question? [emphasis mine] Dionisio

#670 KF

I showed how the set of naturals can be directly transformed into the set of evens or the set of odds.

See Virgil, even KF disagrees with you. Like we said. ellazimm

#655 VC

You were supposed to be addressing the utility issue.

You always punt on that so I thought I'd just skip to the other bits.

It is contained in C and it is what the natural correspondence is

Are you sure? Look again. Read what I wrote. Please.

If there is more than one correspondence then there isn’t any one-to-one correspondence. If I can match an element in your set D to more than one element in your set C, then there isn’t a one-to-one correspondence, by definition.

Clearly you are mistaken as I showed.

And if I can subtract one set from another and get a set with infinite elements then it is obvious that the three sets do not have the same number of elements.</blockquote. Again, clearly you are mistaken.

ellazimm

daveS @667

Well, like Aleta, I am mainly interested in mathematics here, but certainly I have weighed in on a few tangential subjects. The post that started this whole discussion had to do with the possibility of an actual infinite past, so naturally that rises to the surface now and again. I think it’s typical of posters here to participate in the occasional side-discussion, especially in these lengthy threads.

"mainly interested in mathematics here" Your comrade used the word 'only' but now you say 'mainly'? Do you see the difference? Do you see the conflicting (inconsistent) statements? What's your goal in this discussion? [emphasis mine] Dionisio

#655 VC

Are you saying that you didn’t understand the relevance of what I posted? Figures

Not at all. I am suggesting that you are confusing a definition vs an example.

Who cares? If you did then you should be able to figure it out by yourself given everything I have told you. If you can’t figure it out then you aren’t the mathematician that you think you are.

I have an answer, I can address the question. Can you? Are the sets A and B as defined above the same size or not? I'll tell you my answer after you tell me yours. ellazimm

VC, there is not any reason to toss verbal grenades such as "liar." KF kairosfocus

Dionisio: What’s the bottom line of this discussion thread according to KF’s OP? If the volume of KF's responses is an indicator, the discussion of mathematics . Why,what do you think it is? velikovskys

VC (attn EZ & A), well above I showed how the set of naturals can be directly transformed into the set of evens or the set of odds. Likewise for the set of tens or the set from k, k+1 on. That is they are all isomorphic and of the same cardinality DUE TO ENDLESSNESS of the first degree. Endlessness counts, it is an important component of the relevant sets. And it has consequences that have been of concern to me. I have already showed how, consistently, the relevant sets are composed on finite stage stepwise cumulative increments from 0. This gives the peculiar characteristics and it is also the context in which I stress that a crucial part of several axioms is an infinite leap of faith across the ellipsis of endlessness. I think that has implications for inductive step by step conclusions. KF kairosfocus

Aleta @631

2. In response to my comment that “I once wrote the theological question, “Does God need an ellipsis”, Dionisio wrote, “Is that a scientific comment.” Of course not – it says clearly that it is a theological question.

Do you see the difference between 'comment' and 'question'? Since you claimed that you were interested solely in pure math issues when you entered this discussion thread, why did you write a non-scientific comment? If one wants to talk only about basketball, but the discussion also includes canoeing, shouldn't one move somewhere else where they only discuss basketball issues? Dionisio

Aleta, you are also warned on language. KF kairosfocus

Dionisio,

Well, maybe they were not ‘hidden’ but unclear. However, it seems like after some of you have answered a few questions your true motives have been clarified a bit. At least more details have come up to the surface. For example, you may look @659. :)

Well, like Aleta, I am mainly interested in mathematics here, but certainly I have weighed in on a few tangential subjects. The post that started this whole discussion had to do with the possibility of an actual infinite past, so naturally that rises to the surface now and again. I think it's typical of posters here to participate in the occasional side-discussion, especially in these lengthy threads. daveS

Aleta @663

re:662 I answered that question in 661 – maybe our posts crossed paths.

There are two questions @662. You tried to answer the first one @661 to no avail. Didn't answer the second one yet. Please, be concise. Thank you. Note that you don't have to answer any questions. But I appreciate that you do. Dionisio

Aleta:

2c. Does E have exactly 1/2 as many element as N?

As infinity is a journey it would all depend on when you looked. However the relative cardinality can be determined by the bijective function. Virgil Cain

Aleta:

More civil, rational, on-topic argument from Virgil.

LIAR! You have no shame and are a pathetic example of a human.

Considering that I was responding to a blatant lie, that was rational and on-topic. Virgil Cain

re:662 I answered that question in 661 - maybe our posts crossed paths. Aleta

Aleta @635

My “true” motives? What are they? Am I hiding them? I like to discuss things, and I like to have the opportunity to clarify and articulate my views. I’m interested in math, philosophy, and religion. I like discussing my thoughts on theism and atheism. Anything wrong with that? :-)

See @659 an example of your conflicting statements. How do you explain such an inconsistency? Your explanation @661 tries to justify things to no avail. What's the bottom line of this discussion thread according to KF's OP? Dionisio

It seems to me, Dionisio, that you are trying to make an issue out of something that doesn't exist. If you were to read all three posts on this topic, you would see that I multiple times said I was interested in the pure math, and not interested in the connection to other topics such as time or God. It wasn't until post 509 that I said anything about other than the pure math, and that actually had a point related to the math. I didn't bring up God again until you asked the question as to whether the pure math discussion had anything to do with the OP, and I replied to that. I quit discussing math with kf about post 530. You then brought up the topic of the connection to the purpose and interests of this site at 587. So my statement at 587 was a general statement about the vast bulk of my participation in the topic of infinity up until that point - it certainly wasn't a statement that math was the only thing I was ever interested in. My statement at 631 was a further statement that I have more interests than math. There are no conflicts here. I really don't get what point you are trying to make. You seem to be beating around the bush about something - how about just coming straight out and telling us what's on your mind? Aleta

daveS @651

Well, from my perspective it appears that way. We obviously have our disagreements, but I see no reason to suspect that kairosfocus, Aleta, ellazimm, or any of the other serious contributors have hidden motives.

Well, maybe they were not 'hidden' but unclear. However, it seems like after some of you have answered a few questions your true motives have been clarified a bit. At least more details have come up to the surface. For example, you may look @659. :) Dionisio

Aleta @587

[…] those of us involved in the discussion (daveS, ellazim, and myself) were only interested in the pure mathematics.

Aleta @631

[Dionisio to KF @618] 1. “BTW, I see that your interlocutors that claimed to be interested only in the math part of the discussion have gotten involved in non-math discussions too? :)”

Yes, I have. But up until just the last few days, we were discussing pure math. I have other interests than pure math.

Aleta @587 "[...] only interested in the pure mathematics." Aleta @631 "I have other interests than pure math." [emphasis mine] Doesn't the word "only" @587 seem to conflict with the statement @631? :) Dionisio

OK, Virgil, now you've got me curious about what you believe, so here are some questions. 1. Let N = the natural numbers {1,2,3,...} I assume you agree that there are an infinite number of members in this set? Is it true that you believe that? 2. Let E = even natural numbers {2,4,6,...} 2a. Is this an infinite set? I assume you believe it is infinite. Is it true that you believe that? 2b. Does this set have fewer members than N? I assume you believe it does because you said so in #261. 2c. Does E have exactly 1/2 as many element as N? I don't know whether you believe this is so, or not, Would you be willing to answer these few questions so I can be sure I understand your position? Aleta

More civil, rational, on-topic argument from Virgil.

LIAR! You have no shame and are a pathetic example of a human.

kf, I appreciate your giving Virgil a warning earlier. And I agree that it might be useful for you to add your two cents to a simple proposition: "The set of natural numbers has the same cardinality (aleph null) as the set of even natural numbers because a 1:1 correspondence between the two can be established." Aleta

How about it EZ- can you tell us the utility of saying all countably infinite sets have the same cardinality? And the alleged “one-to-one correspondence” is an illusion as there are more than one way to match the elements given one set is a proper subset of the other.

I have done the first many times

LIAR! You have no shame and are a pathetic example of a human. Virgil Cain

EZ Jared:

Congratulations for posting the definition of what a one-to-one mapping is but not whether or not it is the only mapping.

Are you saying that you didn't understand the relevance of what I posted? Figures

Is A or B (defined above) ‘larger’.?

Who cares? If you did then you should be able to figure it out by yourself given everything I have told you. If you can't figure it out then you aren't the mathematician that you think you are.

It was an example of how set subtraction was inadequate to address the cardinality of sets.

You were supposed to be addressing the utility issue.

I’m confused.

Yes, I know.

That isn’t what I defined C

It is contained in C and it is what the natural correspondence is

Are you saying my one-to-one mapping is not one-to-one?

If there is more than one correspondence then there isn't any one-to-one correspondence. If I can match an element in your set D to more than one element in your set C, then there isn't a one-to-one correspondence, by definition. And if I can subtract one set from another and get a set with infinite elements then it is obvious that the three sets do not have the same number of elements. Virgil Cain

#652 VC

No, it is true- one and only one. Even wikipedia agrees:

Congratulations for posting the definition of what a one-to-one mapping is but not whether or not it is the only mapping. Is A or B (defined above) 'larger'.? You still haven't answered.

An illustrative example of what? How does that demonstrate the utility of saying all countably infinite sets have the same cardinality?

It was an example of how set subtraction was inadequate to address the cardinality of sets. Can you say which of sets A or B is bigger?

It’s not my fault that the links you provided have nothing to do with what I am asking. It’s not my fault that all you can do is bluff you way through this. Too bad wikipedia disagrees with you one the one to one correspondence thing.

I'll let everyone else take the time to assault the hill you've dug in on.

And then there is the natural mapping used to determine if one set is a proper subset of the other: C={10,20,30,40…} D={10,20,30,40…} That means that Jared’s is not a one-to-one as there is more than one way to match the elements. And that goes against the definition.

I'm confused. That isn't what I defined C to be. Please pay attention. And I provide two different mappings between C and D (one one-to-one and one not) so I'm not sure what you're getting at. Are you saying my one-to-one mapping is not one-to-one? I can prove it. AND you still haven't said which is bigger, A or B. And you still haven't determined the relative (to the positive integers) cardinality of the prime numbers. ellazimm

Here’s an illustrative example. C = {1, 2, 3, 4 ,5 . . . } D = {10, 20, 30, 40 , 50 . . . } Here is a one-to-one mapping: 1 ~ 10, 2 ~ 20, 3 ~ 30 . . . 10 x element in C ~ element in D

And then there is the natural mapping used to determine if one set is a proper subset of the other: C={...,10,...20,...30,...40...} D={10,20,30,40...} That means that Jared's is not a one-to-one as there is more than one way to match the elements. And that goes against the definition. Virgil Cain

A one-to-one correspondence demands there be one and only one way to match the elements.

Incorrect.

No, it is true- one and only one. Even wikipedia agrees: bijection:

1. each element of X must be paired with at least one element of Y, 2. no element of X may be paired with more than one element of Y, 3. each element of Y must be paired with at least one element of X, and 4. no element of Y may be paired with more than one element of X.

and the bluff:

I won’t argue with you anymore since you are determined not to change your mind despite the evidence.

You have yet to present any evidence relevant to the question.

Here’s an illustrative example. C = {1, 2, 3, 4 ,5 . . . } D = {10, 20, 30, 40 , 50 . . . } Here is a one-to-one mapping: 1 ~ 10, 2 ~ 20, 3 ~ 30 . . . 10 x element in C ~ element in D Here is a non-one-to-one mapping: element in C ~ mod(element in D,10) or element in D mod 10

An illustrative example of what? How does that demonstrate the utility of saying all countably infinite sets have the same cardinality?

It’s not my fault you don’t understand the links I gave you many times or the basis of modern mathematics.

It's not my fault that the links you provided have nothing to do with what I am asking. It's not my fault that all you can do is bluff you way through this. Too bad wikipedia disagrees with you one the one to one correspondence thing. Virgil Cain

Dionisio,

daveS @634

Pardon me for jumping in, but isn’t it clear that most of us participating in this thread just like to discuss mathematics?

No, not at all.

Well, from my perspective it appears that way. We obviously have our disagreements, but I see no reason to suspect that kairosfocus, Aleta, ellazimm, or any of the other serious contributors have hidden motives. daveS

#645 KF Why don't you weigh in on this issue? Why not help clear up the mathematical disagreement? ellazimm

#642, 643 VC

LoL! A one-to-one correspondence demands there be one and only one way to match the elements.

Incorrect. You should have read those books on Set Theory I recommended.

You are pathetic as that has nothing to do with the question I asked. My question pertains to a small and obviously insignificant part of Cantor’s set theory. We have been over and over this many times and you still insist on spewing your cowardly nonsense.

I won't argue with you anymore since you are determined not to change your mind despite the evidence.

But you don’t even know what a one-to-one correspondence means.

Let's see what others think shall we?

LoL! Set subtraction works if you use it relative to a standard set. But obviously you are too dim to grasp that even though we have gone over it.

Fine then tell me whether or not sets A and B as above are the same size or not.

A one-to-one correspondence means there is one and only one way to match the elements. That is in the definition.

Incorrect.

How about it EZ- can you tell us the utility of saying all countably infinite sets have the same cardinality? And the alleged “one-to-one correspondence” is an illusion as there are more than one way to match the elements given one set is a proper subset of the other.

I have done the first many times and you're incorrect on the second. Here's an illustrative example. C = {1, 2, 3, 4 ,5 . . . } D = {10, 20, 30, 40 , 50 . . . } Here is a one-to-one mapping: 1 ~ 10, 2 ~ 20, 3 ~ 30 . . . 10 x element in C ~ element in D Here is a non-one-to-one mapping: element in C ~ mod(element in D,10) or element in D mod 10 (I'm forgetting my math as opposed to Excel notation.) (knowledgeable readers please leave VC to address the situation himself)

NOTE- I am NOT asking about Cantor’s set theory but just one small part of it. That means when Jared responds with Cantor’s set theory is fundamental he proves that he is a cowardly wanker who cannot support his position.

It's not my fault you don't understand the links I gave you many times or the basis of modern mathematics. You denying the evidence does not obligate me to restating the evidence over and over and over again. If you want to understand the arguments take a real set theory course. And now you have to decide which is 'bigger', A or B? Using your system. ellazimm

daveS @634

Pardon me for jumping in, but isn’t it clear that most of us participating in this thread just like to discuss mathematics?

No, not at all. Dionisio

Tell me Aleta- what kind of person responds to a question with an answer that doesn't even address the question and then runs around the internet claiming to have answered the question? This is exactly what EZ Jared is doing. Virgil Cain

LoL! @ Aleta- You just cannot support your claims, Aleta, and everyone knows it. I bother with people like Aleta and EZ Jerad because they can only "support" their claims by repeating what is being refuted/ debated. I love pure mathematics and I dislike condescending people like Aleta that pollute it. Virgil Cain

VC [SNIP– warning VC, KF] KF kairosfocus

Hi EZ. I see that you've been around the block with Virgil on this. I certainly won't bother. I especially won't bother with people who don't appreciate the importance of pure mathematics, irrespective of applied utility, and I also am not fond of discussing things with people who call others [SNIP -- Aleta warning. KF] So Virgil is not worth my time. Aleta

How about it EZ- can you tell us the utility of saying all countably infinite sets have the same cardinality? And the alleged “one-to-one correspondence” is an illusion as there are more than one way to match the elements given one set is a proper subset of the other. NOTE- I am NOT asking about Cantor's set theory but just one small part of it. That means when Jared responds with Cantor's set theory is fundamental he proves that he is a mathematical weenie who cannot support his position. Virgil Cain

EZ Jerad:

There usually are many different ways to math up elements of two sets. BUT if there is a matching that is one-to-one then the sets, finite or infinite, has the same cardinality.

LoL! A one-to-one correspondence demands there be one and only one way to match the elements.

I know, you never got the links I gave you about how Cantor’s set theory is fundamental to the foundation of modern mathematics.

You are pathetic as that has nothing to do with the question I asked. My question pertains to a small and obviously insignificant part of Cantor's set theory. We have been over and over this many times and you still insist on spewing your cowardly nonsense.

Again, IF there is a one-to-one correspondence between two sets then they have the same cardinality.

But you don't even know what a one-to-one correspondence means.

(I can give you ‘formulas’ for each if you like but your set subtraction method doesn’t work.)

LoL! Set subtraction works if you use it relative to a standard set. But obviously you are too dim to grasp that even though we have gone over it. A one-to-one correspondence means there is one and only one way to match the elements. That is in the definition. Virgil Cain

#640 Virg

EZ Jerad, still choking- How about it EZ- can you tell us the utility of saying all countably infinite sets have the same cardinality? And the alleged “one-to-one correspondence” is an illusion as there are more than one way to match the elements given one set is a proper subset of the other.

There usually are many different ways to math up elements of two sets. BUT if there is a matching that is one-to-one then the sets, finite or infinite, has the same cardinality.

And yes I am convinced that I am right as no one can demonstrate otherwise. To prove I am wrong one would have to show the consequences of what I say. Yet the only consequence I can find is that text books would have to be changed.

I know, you never got the links I gave you about how Cantor's set theory is fundamental to the foundation of modern mathematics. I won't bother posting them again, there's no point.

Have you figured out the utility in what Cantor spews, Jerad? Until you do you cannot say that I am wrong and you are right. However the definition of a “one to one correspondence” says that I am right. But you just ignore that.

Again, IF there is a one-to-one correspondence between two sets then they have the same cardinality. End of. No 'natural' or 'artificial' considerations. If you can find a one-to-one correspondence then you've proven the two sets have 'the same size'. Set subtraction doesn't work for all pairs of sets but one-to-one mappings do. A = {1, 2, 4, 8, 16, 32 . . . } B = {5, 6, 8, 12, 20, 36 . . .} Which of these sets is larger or are they the same size? (I can give you 'formulas' for each if you like but your set subtraction method doesn't work.) ellazimm

EZ Jerad, still choking- How about it EZ- can you tell us the utility of saying all countably infinite sets have the same cardinality? And the alleged "one-to-one correspondence" is an illusion as there are more than one way to match the elements given one set is a proper subset of the other. And yes I am convinced that I am right as no one can demonstrate otherwise. To prove I am wrong one would have to show the consequences of what I say. Yet the only consequence I can find is that text books would have to be changed. Have you figured out the utility in what Cantor spews, Jerad? Until you do you cannot say that I am wrong and you are right. However the definition of a "one to one correspondence" says that I am right. But you just ignore that. Virgil Cain

#636 Aleta

Virgil, however, is the one that is wrong. Not even kf would agree with Virgil here.

He will not ever budge from his erroneous position so I wouldn't spend much time arguing with him if I were you. He's got no published support for his views, he can't find any errors in work supporting Cantor's system and he believes in 'relative cardinalities' (i.e. that the cardinality of the positive even integers is half that of the positive integers) but he can't say what the 'relative' cardinality of the primes is. He's seen the one-to-one mapping argument many times so don't waste your breath on that. He's convinced he's right and will not back down.

However his alleged “one-to-one correspondence” fails in many cases as there is more than one way to correlate the two sets- one natural and one that is artificial.

Cantor’s mapping function actually gives us the relative cardinality. Not that Aleta will understand any of that.

See what I mean? Have you figured out the 'relative' cardinality of the primes yet Virg? ellazimm

A = {0,1,2,3,4,5,…} B = {1,3,5,7,9,11,…} C = {0.,2,4,6,8,10,…} If these sets all had the same cardinality, ie the same number of elements, then sets subtraction should prove that claim. And yet A-B=C. That means that Set A has more elements than both sets B and C. And more elements means it has a higher cardinality. Only mental gymnastics can get around that fact. Virgil Cain

LoL! @ Aleta- Aleta said that subtracting infinite sets is not allowed and yet could not provide any support for her claim. And yes, Cantor was wrong and there isn't any way to support his claims. However I have found a way to refute his claims. Cardinality refers to the number of elements in a set. Set subtraction proves that the cardinalities of certain countably infinite sets are different. Cantor offered a kluge to get around that. However his alleged "one-to-one correspondence" fails in many cases as there is more than one way to correlate the two sets- one natural and one that is artificial. Also no one can say what the utility is for Cantor's proclamation. Meaning saying that all countably infinite sets have the same cardinality is useless and meaningless and saying that they do not have the same cardinality changes nothing but text books. It also makes everything equal, meaning we use the same correlation for determining if one set is a proper subset of another as we would for determining the relative cardinality of the sets. Cantor's mapping function actually gives us the relative cardinality. Not that Aleta will understand any of that. Virgil Cain

Virgil believes that the sets A = {0,1,2,3,4,5,…} B = {1,3,5,7,9,11,…} C = {0.,2,4,6,8,10,…} have different cardinalities because A - B = C. Virgil believes the standard mathematics about infinite sets and cardinality, begun by Cantor, are wrong. Virgil, however, is the one that is wrong. Not even kf would agree with Virgil here. Aleta

My "true" motives? What are they? Am I hiding them? I like to discuss things, and I like to have the opportunity to clarify and articulate my views. I'm interested in math, philosophy, and religion. I like discussing my thoughts on theism and atheism. Anything wrong with that? :-) Aleta

Dionisio, Pardon me for jumping in, but isn't it clear that most of us participating in this thread just like to discuss mathematics? daveS

Aleta @631

Dionisio asks a bunch of questions

Anything wrong with that? :)

I am curious about the motivation or purpose behind this bunch of questions.

Simply to let you reveal your own true motives for participating in this discussion. No one else can reveal them better than you. The same applies to your party comrades and anybody else here or anywhere else. This is a universal valid approach I learned from my Master. It seems to work well. :)

Most of them seem to be more pointed comments disguised as questions.

Can you provide an example?

But, I answered them anyway.

Thank you. I appreciate you did. Probably other readers also appreciate you clarified further your motives. :) Dionisio

Aleta has already proven to be ignorant of mathematics with her unsubstantiated statement above that set subtraction does not apply to infinite sets. After she was exposed for that gaff she decided to ignore me and prattle on. So Aleta has made statements about infinity that are clearly wrong. Virgil Cain

Dionisio asks a bunch of questions: 1. "BTW, I see that your interlocutors that claimed to be interested only in the math part of the discussion have gotten involved in non-math discussions too? :)" Yes, I have. But up until just the last few days, we were discussing pure math. I have other interests than pure math. 2. In response to my comment that "I once wrote the theological question, “Does God need an ellipsis", Dionisio wrote, "Is that a scientific comment." Of course not - it says clearly that it is a theological question. 3. WhenI wrote, "I think, to a believer such as kf, […]", Dionisio wrote, "Aren't you a believer, too?" No. 4. When ellazimm wrote, "I find the psychology of debates on this sight very interesting.", Dionisio wrote, "English is not my first (native) language. Please, can you explain that English sentence?" I think Dionisio is being disingenuous here. His (or her) English seems quite good. He made a similar remark to me when I left a extra "are" in a sentence. I am virtually certain that he knows that ellazimm meant "site", not "sight", and that Dionisio knows what the sentence means. 5. When I wrote, "For what it’s worth, I’m a bit interested in my own psychology – why do I keep posting??? I’m sure I’m close to an end.", Dionisio wrote, "Almost 10 days later you’re still posting here? What did you mean by “close to an end.”?" Well, first, I have finally quit discussing infinity with kf, so I was close to an end for that. And second, as I said, I wonder why I post here sometimes. 6. Dionisio asks again, "Does the above quoted comment @613 [about the theological question God needing an ellipsis} belong in the ‘pure mathematics’ topic category that you mentioned in the above quoted comment @587?" Again, no. The word theological is pretty clear. 7. When I wrote, "I got started in this discussion because someone made some statements about infinity that were wrong, and so I became interested.", Dionisio asks, "What specific statements about infinity were wrong? What specifically was wrong about those statements?" I am not about to try to summarize the things that kf has said that I think are wrong - we spent three posts doing that. However, the first statement that was wrong, which I was referring to in the comment above, was

Infinity is illogical for a very simple reason. Nothing can be compared to infinity without introducing a contradiction. Why? It’s because any finite quantity is infinitely small compared to infinity, making the quantity both finite and infinitesimal at the same time. As simple as that.

That's wrong. I am curious about the motivation or purpose behind this bunch of questions. Most of them seem to be more pointed comments disguised as questions. But, I answered them anyway. Aleta

#629 addendum

"[...] a ‘finite’ number of anonymously visiting readers [...]"

Here's something about that 'finite' number: Apparently over 1.5k net visitors?

Popular Posts (Last 30 Days) A world-famous chemist tells the truth: there’s no… (15,811) Homologies, differences and information jumps (2,474) Durston and Craig on an infinite temporal past . . . (2,269) Larry Moran needs to do some more reading (1,716) A Little Timeline on the Second Law Argument (1,690)

Dionisio

ellazimm @628

My comments that you ask about were not part of the general discussion and were directed at Aleta in particular and they understood my meaning so I don’t feel the need to explain them.

No problem. In this case of an open forum with a 'finite' number of anonymously visiting readers who can draw their own conclusions, what you just wrote may serve as the explanation you're willing (or capable) to offer. :) No one has to answer any questions. However, sometimes the way one answers certain questions may reveal one's true motives. :) Thank you. Dionisio

#621, 623 Dionisio My comments that you ask about were not part of the general discussion and were directed at Aleta in particular and they understood my meaning so I don't feel the need to explain them. ellazimm

Full Definition of infinite

1: extending indefinitely : endless 2: immeasurably or inconceivably great or extensive : inexhaustible 3: subject to no limitation or external determination 4 a : extending beyond, lying beyond, or being greater than any preassigned finite value however large b : extending to infinity c : characterized by an infinite number of elements or terms

http://www.merriam-webster.com/ Dionisio

Mapou @609

The very word “infinity” is an oxymoron.

"Infiniti" is the brand name of a car made by Nissan, which is out of reach (pricey). :) Dionisio

Aleta @599

I got started in this discussion because someone made some statements about infinity that were wrong, and so I became interested.

What specific statements about infinity were wrong? What specifically was wrong about those statements? Note that after reading posts in this thread I can't answer those questions myself, hence I kindly ask you to answer them. Thank you. Dionisio

Aleta @587

[...] those of us involved in the discussion (daveS, ellazim, and myself) were only interested in the pure mathematics.

Aleta @613

This is the key point. I once wrote the theological question, “Does God need an ellipsis.” I think, to a believer such as kf, the answer would be “no”: God sees the whole set because he also is infinite.

Does the above quoted comment @613 belong in the 'pure mathematics' topic category that you mentioned in the above quoted comment @587? :) Dionisio

ellazimm @503

The whole culture is fascinating.

What did you mean by "culture" in the quoted statement? :) Dionisio

Aleta @499 February 26

For what it’s worth, I’m a bit interested in my own psychology – why do I keep posting??? I’m sure I’m close to an end.

Aleta @613 March 6 Almost 10 days later you're still posting here? What did you mean by "close to an end."? :) [emphasis mine] Dionisio

ellazimm @498

I find the psychology of debates on this sight very interesting.

English is not my first (native) language. Please, can you explain that English sentence? Thank you. :) Dionisio

Aleta @613

I think, to a believer such as kf, [...]

Aren't you a believer too? :) Dionisio

Aleta @613

This is the key point. I once wrote the theological question, “Does God need an ellipsis.” I think, to a believer such as kf, the answer would be “no”: God sees the whole set because he also is infinite.

Is that a scientific comment? Dionisio

KF 602 Yes, noted your interesting comment on that subject. Thank you. Here's my comment: https://uncommondescent.com/peer-review/retracted-scientist-makes-top-10-list/#comment-599419 BTW, I see that your interlocutors that claimed to be interested only in the math part of the discussion have gotten involved in non-math discussions too? :) Dionisio

kairosfocus:

...and Math must in the end try to be anchored to reality...

"One must be able to say at all times - instead of points, straight lines and planes - tables, chairs and beer mugs." - David Hilbert Mung

KF, I can't parse the first few sentences, but starting here:

So it seems to me that the reachable values are finite and the EoE is pivotal.

"Reachable" again, which I'm guessing means able to be generated by computer program in a finite number of steps. I don't think Aleta and I, or most working mathematicians recognize this limitation. I would emphasize I don't find anything "wrong" with finitism. It's an interesting approach, and it's surprising what finitists are able to achieve under such severe restrictions, but their rationale for the program doesn't do much for me.

I add, if we chain copy so far to endlessness — which is what infinity means — then w, w+1 etc should belong, or more specifically, endless individual copies of the list so far.

It seems to me such a fundamental fact would have been proven and published. Have you found any reference to this? Finally I don't want to get too meta, you posted this in another thread yesterday:

Z, the mere fact that you are unwilling to acknowledge the author of the remarks I cited, Nancy Pearcey, speaks volumes.

While at the same time avoiding my questions about {0, 1}^*. daveS

DS and A, in short take a leap of faith. The point is we see there in axiomatic frames and the way that we represent {0,1,2 . . . } and more exactly the +1 successive build out from 0 that is in Ehrlang's tree etc. On the idea of an infinite set of finite sequence members from 0, raises the issue of the successive case being copy of the set so far. Where ordinary mathematical induction pivots on succession from case 0. So it seems to me that the reachable values are finite and the EoE is pivotal. I add, if we chain copy so far to endlessness -- which is what infinity means -- then w, w+1 etc should belong, or more specifically, endless individual copies of the list so far. I don't want to be a finitist, but I think I see reason to hold that inductive chaining on case 0 and case k => case k+1 will have that stepwise spanning issue that becomes relevant when one says what is tantamount to there are infinitely many -- endless -- +1 stage successors to 0 and they are all finite. Paradox at minimum. KF PS: Time and space are not strictly necessary tot he issue I have pointed out, just succession in +1 steps from 0. At any k, k+1 we can put the onward endless succession in 1:1 correspondence with the undisturbed sequence from 0. Pink/blue tapes just illustrate the point. kairosfocus

MT, I am puzzled. End of space, apart from say heat death? I suggest it is well accepted our observed cosmos has a beginning the singularity. Do you mean my reference to the scale of the observed cosmos about 90 bn LY? Or what? KF kairosfocus

Dave writes,

Numbers are abstract things. Constructing the set N shouldn’t take up time or space, right? And most mathematicians accept that we can work with a completed set N, despite your concepts of “attainable”, “actualizable” sets, or sets that we can “directly reach”.

This is the key point. I once wrote the theological question, "Does God need an ellipsis." I think, to a believer such as kf, the answer would be "no": God sees the whole set because he also is infinite. Well, mathematics let's us do that too. Infinite sets are an abstraction, perfect circles are an abstraction, the Mandelbrot set (in its infinite detail) is an abstraction, God is an abstraction. We couldn't do math if we didn't idealize its components. If kf took the same attitude towards theology that he is taking here, objecting to infinity because our tape machine can't reach it, he would be much more humble about making pronouncements about such things as the "root of reality." Aleta

PPS to my #611: Feng Ye posted a draft of his book here. Also, some general discussion at stackexchange. daveS

KF,

DS, do you not see the point of concern:

I could understand the concern if I felt constrained to work only with those natural numbers that could be generated (in principle) by a program running on a digital computer in a finite time interval, starting with just 0 and the successor operation. In that case, I would be restricted to finite subsets of N only. I believe that most mathematicians don't work under such constraints. Numbers are abstract things. Constructing the set N shouldn't take up time or space, right? And most mathematicians accept that we can work with a completed set N, despite your concepts of "attainable", "actualizable" sets, or sets that we can "directly reach".

Similarly, ordinary mathematical induction hangs on case 0 then has a chaining premise by which case-k => case-k+1, which obviously is not going to actually complete the transfinite chain.

As I've said before, you therefore do not accept the Axiom of Induction.

So, I would modify the conclusion that there is an endless implicitly actualisable — infinite — succession of finite successor counting sets to {} –>0, into the more conservative point that actualisable successive members will be finite. However, as closure endless-LY is present that is now a part of the set, a quasi-member in effect.

No. I'm going to insist on no "quasi" this or that. Something either is or is not a member of a set. P or not P, right? PS: Do you have answers to my three questions about {0, 1}^*? That's about as simple as infinite sets get. I submit that if we can't agree on the answers to my three questions, then there is no hope of coming to terms on the mathematics of an infinite past. PPS: This looks like an interesting read. The blurb:

Strict Finitism and the Logic of Mathematical Applications, by Feng Ye This book intends to show that radical naturalism (or physicalism), nominalism and strict finitism account for the applications of classical mathematics in current scientific theories. The applied mathematical theories developed in the book include the basics of calculus, metric space theory, complex analysis, Lebesgue integration, Hilbert spaces, and semi-Riemann geometry (sufficient for the applications in classical quantum mechanics and general relativity). The fact that so much applied mathematics can be developed within such a weak, strictly finitistic system, is surprising in itself. It also shows that the applications of those classical theories to the finite physical world can be translated into the applications of strict finitism, which demonstrates the applicability of those classical theories without assuming the literal truth of those theories or the reality of infinity.

daveS

KF, What is at the end of Space ? How will you know the end of space? What differentiates space from nothing ? There is no way to construct a physical world with an end of space scenario. Me_Think

KF, The very word "infinity" is an oxymoron. It's a shame it has become the basis of a religion of cretins. See you around. Mapou

Mapou (and Joe if you are watching), the exercises above give me a whole new view on your position on many mathematical topics. Though I find that it is reasonable to see a transfinite realm and especially an infinitesimal one, I have come to more and more recognise that difficulties lurk. And I must always respect the premise that on matters of truth-seeking (and Math must in the end try to be anchored to reality) no consensus of some August magisterium and no imposed definition or axiom can be beyond question from first principles and Einstein's favourite tool of insight, thought exercises. KF kairosfocus

DS, do you not see the point of concern:

an actually completed endless and infinite set of successive +1 separated finite values from 0 on, where any next value is a copy of the list so far?

I suggest that the real solution is, such an endless list cannot actually be completed to endless-NESS. Second, that given the pink/blue tape example it can only proceed successively to finite extent leaving such endlessness onwards that it can always be put in 1:1 correspondence with the set from 0 on. Third, that were it actually completed it would have to include among the list of "copies of the set so far" at least one endless member, Fourth, instead we may see that in fact it is incomplete and the incompleteness is inherent in the collection so that we point across the ellipsis of endlessness to recognise this as a new type of quantity, omega the first transfinite. Which then is dependent on not only the finite counting sets we can reach in +1 succession accumulated from 0, but also -- critically -- on the endless-NESS of successive-NESS of said counting sets. (I use -ness to in effect point to a distinct identifiable concept that has been described by endless and successive acting as in effect [quasi-] adjectives . . . as in, adverbs. Sorry, I am fishing for precision.) So, we never actually can compose an endless string and sequence of successive counting sets, nor can we properly conclude that were such a string possible ALL of its members all the way to endlessness would be finite. Notwithstanding the copy of the set so far principle of succession. In short the do forever loop of succession inherent in defining successive counting sets cannot actually go to endless extent. We cannot complete and end a stepwise finite stage traversal of the endless. Instead what the exercises actually show is that the successive counting sets we can directly reach will be finite, that those we can actually represent in notations such as place value or scientific that give specific numbers are also dependent on the same inherently finite succession, and that the ongoing endlessness cannot be actually traversed. Attempts to move to a potential infinity and point across the ellipsis of endlessness in this particular case seem to me to run into the above challenges. So, pointing to the axiom of infinity . . . Wiki for convenience (as in 513 above):

In words, there is a set I (the set which is postulated to be infinite), such that the empty set is in I and such that whenever any x is a member of I, the set formed by taking the union of x [–> in context the succession from {} on thus far is in mind in a generalised case] with its singleton {x} [ –> this goes on to the next step] is also a member of I. Such a set is sometimes called an inductive set. This axiom is closely related to the von Neumann construction of the naturals in set theory, in which the successor of x is defined as x U {x}. If x is a set, then it follows from the other axioms of set theory that this successor is also a uniquely defined set. Successors are used to define the usual set-theoretic encoding of the natural numbers. In this encoding, zero is the empty set: 0 = {}. The number 1 is the successor of 0: 1 = 0 U {0} = {} U {0} = {0}. Likewise, 2 is the successor of 1: 2 = 1 U {1} = {0} U {1} = {0,1}, and so on. A consequence of this definition is that every natural number is equal to the set of all preceding natural numbers. [--> the copy the sequence so far principle, Notice, too, how this embeds a do forever succession (loop) in the heart of the definition of the list of natural counting sets] This construction forms the natural numbers. However, the other axioms are insufficient to prove the existence of the set of all natural numbers. Therefore its existence is taken as an axiom—the axiom of infinity. This axiom asserts that there is a set I that contains 0 and is closed under the operation of taking the successor; that is, for each element of I, the successor of that element is also in I. [--> notice, it says in effect each successor, endlessly -- an in principle process that cannot be actualised in finite stage steps, is a member. It closes the set as defining successors to be members and a finite reachable k will always have k+1 but this then falls under the point seen from the pink vs blue tape example, the traversal is not complete and onward endlessness obtains as can be seen by truncating the blue tape at k and putting k, k+1 etc in 1:1 correspondence with the un-shifted pink tape from 0,1 etc. If you want an inductive point this can be done k then k+1 times then k+2 times, the k+2th one showing that the kth case implies the k+1th case, and the k steps k times that the steps may be expanded to squaring without altering the point of never beginning to exhaust endlessness. For concreteness set k = 10^150 and square to 10^300, and see that such would not begin to exhaust endlessness. At 0.1 inches, each k-step would pull 10^144 miles of tape, the observed cosmos being some 10^23 miles across IIRC. Just for those who struggle with abstract values. ] Thus the essence of the axiom is: There is a set, I, that includes all the natural numbers. The axiom of infinity is also one of the von Neumann–Bernays–Gödel axioms

Similarly, ordinary mathematical induction hangs on case 0 then has a chaining premise by which case-k => case-k+1, which obviously is not going to actually complete the transfinite chain. I think as at now, that there is a premature pointing across the ellipsis of endlessness that is not sufficiently reckoning with the consequence of actualised +1 stage step completion. Instead I think we should embrace the forced fact of incompleteness of the succession and see that we never get to the stage where a copy of the set so far would have to be endless, reflecting an actualised endless succession. So, I would modify the conclusion that there is an endless implicitly actualisable -- infinite -- succession of finite successor counting sets to {} -->0, into the more conservative point that actualisable successive members will be finite. However, as closure endless-LY is present that is now a part of the set, a quasi-member in effect. And we then recognise an emergent phenomenon from this process, a new type of quantity, first degree endlessness of cardinality aleph null and involving the first transfinite ordinal omega [w for convenience] and its relevant successors w+1 etc. As a consequence we never actually complete an endless succession of "copy of the list so far" recursively growing finite counting sets. However by recognising the highly material endless-NESS component of the structured set of successive counting sets, we may then point beyond it to the transfinite ordinals. As one consequence w is both the order type of the set with the endlessness component -- {0,1,2 . . . k, k+1 . . . EoE . . . } -- and has no specific actually defined member of that set as a predecessor. It is a limit ordinal. Clipping again from Wolfram on limit ordinals:

Limit Ordinal An ordinal number alpha>0 is called a limit ordinal iff it has no immediate predecessor, i.e., if there is no ordinal number beta such that beta+1=alpha (Ciesielski 1997, p. 46; Moore 1982, p. 60; Rubin 1967, p. 182; Suppes 1972, p. 196). The first limit ordinal is omega.

This highlights the significance of the EoE component and implies the exact point that the +1 stage succession from {} cannot be actualised to endlessness. This is how I find myself, as guided by the premise that we seek coherence always. I don't have to like or desire it, but if that is what I see it is what I see thus far. KF PS: The implications of inherent and inescapable failure to traverse an endless span in +1 steps of course speaks to views that try to claim an infinite spatio-temporal causal succession culminating for the moment in our common now-world. And, no; pointing out that at any actual past we can show we are finitely remote is just that, finitely remote. I find the notion of an infinite past causal succession of all and only temporally finitely remote stages, is an attempt to traverse the infinite in finite stage steps and falls under the problem highlighted by both the contradiction in terms and the force of the two tapes example. kairosfocus

KF, I don't know what you're asking here, but the set you describe is the one assumed to exist by the Axiom of Infinity (the version posted first in this thread). daveS

DS, an actually completed endless and infinite set of successive +1 separated finite values from 0 on, where any next value is a copy of the list so far? KF kairosfocus

KF,

Do you not see the evident incoherence here? Were there an endless temporal-spatial, causally connected past of successive stages, then at some degree of remove from the present one or more of the terms in the train would have to be at a transfinitely large sequence remove from now.

I've seen this assertion many times here, but with no justification. Have you asked any actual mathematicians about this?

This is because a sequence can be seen as an ordered succession and duly labelled with counting subscripts will have to have reached to endlessness; which brings out the problem.

I don't know what "reaching to endlessness" means. The sequence we're talking about is infinite, no doubt. But so is the set of (finite) natural numbers.

The finite, inherently, is bounded and not endless in itself or endlessly removed in +1 steps from 0.

When you say "the finite", are you speaking of the set or its members? It would be helpful if you used finite/infinite/endless as adjectives rather than as nouns. I can understand "set A is finite" or "set X is infinite", but statements about a generic "the finite" are less clear. You brought up the fallacy of composition earlier. It really seems there is some conflation of the properties of the set with the properties of its members here. I'll ask once more for yes/no answers to these questions. There is nothing unfair about that. All the notation and concepts I will refer to are utterly standard. Some have appeared in this thread. If you can't give straight yes/no answers to these questions, then we simply don't have a basis for discussion.

1) The set {0, 1}^* is infinite. Yes/No? 2) Each element of {0, 1}^* has finite length. Yes/No? 3) The set of lengths of strings in {0, 1}^* is unbounded. Yes/No?

I will volunteer to answer first. The answer to each question is "Yes". daveS

DS:

This universe has an infinite past, yet every time coordinate is finite, and every instant in time is a finite number of seconds from the present.

Do you not see the evident incoherence here? Were there an endless temporal-spatial, causally connected past of successive stages, then at some degree of remove from the present one or more of the terms in the train would have to be at a transfinitely large sequence remove from now. This is because a sequence can be seen as an ordered succession and duly labelled with counting subscripts will have to have reached to endlessness; which brings out the problem. The finite, inherently, is bounded and not endless in itself or endlessly removed in +1 steps from 0. Where the counting set succession is such that any large reachable member k is: {0,1,2 . . . k-1} --> k Where for counting sets, the k, k-1 registers can be updated and the string extended to k, k+1 etc endless-LY. That is we see the successor is list of members so far principle and the boundedness of k by k+1. The do forever succession process,inherently is finite and bounded at any stage. At all stages, it never attains to endlessness as the far zone members would then have to include members that themselves are endless. An actually infinite successive string of counting sets that are all finite becomes a self contradiction. That is we should distinguish a succession of inherently finite elements from a completed traversal of endlessness. Where also, the pink and blue tapes thought exercise shows that for any k, k+1 etc, the onward subset can be put in 1:1 correspondence with the full un-shifted un-truncated set, that is the endlessness of successive counting sets cannot be spanned in finite stage successive accumulative steps. As a consequence we cannot have had an actually infinite succession of causal stages to date. The logic of successive counting sets joins many other lines of evidence in pointing to a bounded, finite actual past for our world. KF kairosfocus

D, noted: https://uncommondescent.com/peer-review/retracted-scientist-makes-top-10-list/#comment-599288 KF kairosfocus

Aleta Thank you for clarifying that. Have a good weekend. Dionisio

KF, Off topic, you may want to take a quick look at the article linked @1 about the paper referenced @3 in this thread: https://uncommondescent.com/peer-review/retracted-scientist-makes-top-10-list/#comment-599226 Dionisio

Dionisio asks some questions that contain some misconceptions:

If you and your comrades were only interested in pure math, why did ya’ll get attracted to this site and specially to discussion threads started by OPs that were allegedly not about pure math? Aren’t there pure math discussion forums on the internet? Do you have so much spare time for reading things you’re not interested in? Just curious. :)

First, I can't speak for others, but I've paid attention to this site off and on for many years, and participated in threads on a number of topics. This is the first pure math discussion I think I've ever had here. However I have participated in a number of threads about the philosophy of math and its applicability to the real world, which is quite relevant to topics that show up here regularly. So it is incorrect to state that I was "attracted to this site [] specially to discussion threads started by OPs that were allegedly not about pure math." Also, the mathematics of infinity is relevant because if one doesn't understand the math correctly, one won't be able to apply it to real world situations correctly. I got started in this discussion because someone made some statements about infinity that were wrong, and so I became interested. Hopefully these answers will satisfy Dionisio's curiosity. :-) Aleta

KF,

This also illustrates the point that subtracting a finite k from a first order endlessness does not alter the endlessness. Arguably, we may reasonably represent: w – k = w. Such, bridges to the idea of an infinite past as w+g stepped down g steps gets to w, and in trying to go beyond by k steps will meet the barrier that first order endlessness is in play.

Do you have a response to my #581? It is not the case that every number you can construct need be a valid time coordinate in every universe-with-an-infinite-past. I am assuming a universe with only real number time coordinates. No ω's or other infinite values allowed. This universe has an infinite past, yet every time coordinate is finite, and every instant in time is a finite number of seconds from the present. daveS

I think Spitzer explains the three types of infinities adequately. This will add more clarity for further discussion :

1. “A-infinity.”: “Infinite” frequently has the meaning of “unrestricted,” (e.g., “infinite power” means “unrestricted power”). It can only be conceived through the “via negativa,” that is, by disallowing or negating any magnitude, characteristic, quality, way of acting, or way of being that could be restricted or introduce restriction into an infinite (unrestricted) power. Therefore, “infinite,” here, is not a mathematical concept. It is the negation of any restriction (or any condition that could introduce restriction) into power, act, or being. 2.“B-infinity.” “Infinite” is also used to signify indefinite progression or indefinite ongoingness. An indefinite progression is never truly actualized. It is one that can (potentially) progress ad infinitum. Examples of this might be an interminably ongoing series, or an ever-expanding Euclidean plane. The series or the plane never reaches infinity; it simply can (potentially) keep on going ad infinitum. Thus, Hilbert calls this kind of infinity a “potential infinity.” 3.“C-infinity.” “Infinite” is sometimes used to signify “infinity actualized within a finite or aggregative structure.” Mathematicians such as Georg Cantor hypothesized a set with an actual infinite number of members (a Cantorian set) which would not be a set with an ever-increasing number of members or an algorithm which could generate a potential infinity of members. Examples might be an existing infinite number line, or an existing infinite spatial manifold, or the achievement of an infinite continuous succession of asymmetrical events (i.e., infinite past history).

Me_Think

Aleta @592 RE: your comments @587, @589 If you and your comrades were only interested in pure math, why did ya'll get attracted to this site and specially to discussion threads started by OPs that were allegedly not about pure math? Aren't there pure math discussion forums on the internet? Do you have so much spare time for reading things you're not interested in? Just curious. :) Dionisio

MT (attn D et al): In this thread, the focus has been on something different, further following up a concern expressed by Spitzer regarding a claimed infinite physical past of the cosmos we inhabit, in whatever form:

Infinities within an aggregating succession imply “unoccurrable,” “unachievable,” and “unactualizable,” for an aggregating succession occurs one step at a time (that is, one step after another), and can therefore only be increased a finite amount. No matter how fast and how long the succession occurs, the “one step at a time” or “one step after another” character of the succession necessitates that only a finite amount is occurrable, achievable, or actualizable. Now, if “infinity” is applied to an aggregating succession, and it is to be kept analytically distinct from (indeed, contrary to) “finitude,” then “infinity” must always be more than can ever occur, be achieved or be actualized through an aggregating succession. Any other definition would make “infinity” analytically indistinguishable from “finitude” in its application to an aggregating succession. Therefore, in order to maintain the analytical distinction between “finitude” and “infinity” in an aggregating succession, “infinity” must be consider unoccurrable (as distinct from finitude which is occurrable), unachievable (as distinct from finitude which is achievable), and unactualizable (as distinct from finitude which is actualizable). We are now ready to combine the two parts of our expression through our three common conceptual bases: “Infinite Past Time” “(The) unoccurrable (has) occurred.” “(The) unachievable (has been) achieved.” “(The) unactualizable (has been) actualized.” Failures of human imagination may deceive one into thinking that the above analytical contradictions can be overcome, but further scrutiny reveals their inescapability.

The direct form of this conundrum can be put: ending the endless, emphasising the contradiction in terms. However there is a linked issue as to an infinite, finite stage succession which opens up mathematical considerations. Those considerations show that a stepwise traversal of the endless is not feasible. This is also a context in which a fairly wide range of linked mathematical issues came up. Which became a main focus in this thread. As one result, Ehrlich's tree of numbers great and small has been put on the table as a point of reference. The upshot of all this is that Spitzer's point is crucial, and indeed in counting up or chaining in finite stages from 0 or its neighbourhood, we find that at any finite k, k+1 etc we may place the shifted truncated sequence -- and thus, proper subset from k on -- in 1:1 correspondence with the unshifted sequence and find that once endlessness is involved such stepwise processes cannot traverse it in stages. The pink/blue punched tape thought exercise as is illustrated in the OP provides further illustration. This also illustrates the point that subtracting a finite k from a first order endlessness does not alter the endlessness. Arguably, we may reasonably represent: w - k = w. Such, bridges to the idea of an infinite past as w+g stepped down g steps gets to w, and in trying to go beyond by k steps will meet the barrier that first order endlessness is in play. This supports the point that stepwise, finite stage traversal of endlessness is infeasible. Such has ontological import in a world in which there is a pattern of causal-temporal succession, but it is based on logical considerations regarding structure and quantity. The proposal of an infinite causal-temporal succession for our world in some form, credibly fails. Thus we see a beginning is seriously on the table on grounds of the logic of structure and quantity. (Which, is an expression that describes the focus and core method of Mathematics.) Moving forward, what is now on the table is the suggestion of a beginning from utter non-being (a real nothing). However as non being has no causal properties were there ever such utter nothingness, such would forever thereafer obtain. Patently, such is not the case. Therefore we contemplate the alternative: we inhabit an inherently contingent world with a finitely remote beginning. This then points onwards to the root of our world as a necessary being sufficient to account for a world such as we experience. Where, a NB can be characterised as an entity so connected to the framework for a world to exist that once any possible world is, it must exist. Indeed, further such beings are not dependent on external, enabling on/off causal factors. By contrast with say how a fire depends on heat, oxidiser, fuel and combustion chain reaction. A serious candidate NB will either be impossible as a square circle is, or it will be actual in any possible world. For instance, try to imagine a world in which distinct identity and two-ness (based on distinction of distinct entities) does not exist, or began to exist at some point or can cease from existing. The von Neumann construction on the empty set and successors alone is enough to put paid to such an imaginary world. Two-ness is inescapably integral to the existence of any world. It is also vital to the possibility of logic as distinct identity is the root of logic: World W = {A|~A}, from this law of identity, that of non contradiction and exclusion of the middle come. Without these, logical reasoning is impossible. For, we must have distinct identity to think and communicate, not least regarding structure and quantity. So, we are forced to the further conclusion that NBs are actual, necessarily present once any actual world exists. Which is another way of saying that if something -- a world -- now is, credibly, something always was. Something not caused, not dependent on enabling on/off external entities and not subject to either beginning nor end. Something that merits the term, eternal. Notice, such is a conceptual analysis on the recognised existence of an actual world. It is in this ontological context that we may then understand that God as understood in ethical theism is in fact a serious candidate necessary being root of reality and would be the fountainhead of rationality, mathematics and a world that is orderly and generally lawlike in its operations. With, the implication being, that either God is an impossible being (and we must seek another NB root of reality) or else he is actual. Such, is what is now on the table. And it is clearly a part of the wider context of thought relevant to the debates over design which will be relevant to the interest of those following that debate and cultural issue. It can further be said that mathematics and logic, once surfaced as meta issues, are always relevant to a scientific issue. Further lurking are the broader meta issues of philosophical considerations. If we are to discuss in a responsible, informed way, such will come up. But that does not change the core generic design inference principle: it is credible, on observed tested and reliable signs, to infer that the best current scientific/inductive explanation of certain features of the observed cosmos and of biological life in that cosmos, is intelligent design. Such is scientific/inductive in focus. KF kairosfocus

Well, according to Borde-Guth-Vilenkin if average Hubble constant is a positive value, the universe is past incomplete, which means there has to be a beginning- at least in classical metrics. This is where the concept of "there has to be a God to begin the universe and universe can't be infinite" came from. Me_Think

I'd like to take a look at Spitzer's thesis:

His doctoral dissertation (entitled, A Study of Objectively Real Time – Director: Paul Weiss, reprints through University Microfilms International, Ann Arbor, Michigan) is concerned with the fundamental nature and underlying conditions of temporality. He connects this ontology of time to the special and general theories of relativity.

daveS

Re 590. If you look at the very first post in the series of three on this topic at https://uncommondescent.com/philosophy/an-infinite-past-cant-save-darwin/ you'll see that the quote from Spitzer that started all this is from a book "New Proofs for the Existence of God". I didn't say "ID concepts = the existence of God". I did say, and it's true for many people here, that the existence of God has a relationship to ID concepts. For instance, a link about Spitzer that kf provided in the first thread, at http://magisgodwiki.org/index.php?title=Cosmology, starts thusly:

Cosmology The Magis God Wiki: Cosmology Is there Evidence of the Existence of God from Contemporary Physics? © Robert J. Spitzer, S.J. Ph.D./Magis Institute July 2011 This will be an overview of a more complex treatment which may be found in my recent book New Proofs for the Existence of God: Contributions of Contemporary Physics and Philosophy (hereafter “NPEG”). I have given a series of lectures on these matters in an on-line series called Physics and Metaphysics in Dialogue which can be accessed at our (hereafter “PID”) website – see lectures #1-6. It will be rather quick paced, and if some of you want a more thorough treatment you may want to refer to the book. I will divide the topic into three parts: 1. Can Science Give Evidence of Creation and Supernatural Design? 2. What is the Evidence for a Beginning and what are the Implications for Creation? 3. What is the evidence of Supernatural Intelligence from Anthropic Fine-tuning?

So saying that the beginning OP is related to both ID and the existence of God is fairly well supported, I think. Aleta

D, glance at the OP, you will see that a key issue is the idea of an actually infinite past. KF kairosfocus

Aleta @587

The original topic in the opening post three posts ago, when all this started, had some relationship to ID concepts (the existence of God), [...]

Where did you read that ID concepts = the existence of God? Dionisio

The nature of numbers is a mathematical issue. Linking mathematics to anything real via a mathematical model brings up the additional issue of applying mathematics. Our discussion (mine, anyway) has just been about the pure math. Aleta

D, passing through. Infinity is always of significance. So is the nature of numbers and so would be things linked thereto. KF kairosfocus

Dionisio asks, "Off topic, does this discussion relate to the ID concepts proposed in this blog? How?" The original topic in the opening post three posts ago, when all this started, had some relationship to ID concepts (the existence of God), but those of us involved in the discussion (daveS, ellazim, and myself) were only interested in the pure mathematics. Aleta

KF, Thank you for the detailed explanations posted @572-574, 579. Food for thoughts. Dionisio

Aleta @582

Re 578. Yes, I think that sentence is grammatically correct.

daveS @583

Aleta, I think perhaps the first “are” could be omitted?

Aleta @584

Oops! Of course! I really have a problem with reading what I think I wrote and not seeing what I actually wrote.

No problem. Join the club! We all have that kind of problem reading, seeing, hearing and interpreting written, spoken text or visual images accurately. Our minds seem to betray us on some occasions. If that simple and obvious error can go undetected, now let's think of more complex issues explained by other persons. How can we ensure that we get the exact meaning of what others are trying to tell us? "The trouble with every one of us is that we don't think enough." - Thomas J. Watson, NCR Co. 1911. BTW understanding someone else's message, idea or point of view doesn't mean agreeing with it. Off topic, does this discussion relate to the ID concepts proposed in this blog? How? Thank you. Dionisio

Oops! Of course! I really have a problem with reading what I think I wrote and not seeing what I actually wrote. My fault, Dionisio. The sentence should say,

A1.2 This definition ensures that all natural numbers are finite.

My apologies. Aleta

Aleta, I think perhaps the first "are" could be omitted? daveS

Re 578. Yes, I think that sentence is grammatically correct. Aleta

KF, Ok, but I will just say again that there are no ω's on my time axis. All the time coordinates I have been referring to are (real) integers. daveS

DS, that is my exact point, once one counts down to w the endlessness confronts. Cannot be bridged. We can only have a finite real world, operational succession. KF kairosfocus

D, I thought to add to 572 from another angle: >>[Let me expand for some r +1 as a proposed endless member:] {0,1,2 . . . k, k + 1 . . . Ellipsis of endlessness] . . . } –> r+1 Is there thus a definable immediate predecessor r: {0,1,2 . . . k, k + 1 . . . finite Ellipsis] . . . r -1} –> r Not at all, the value r+1 is a synonym for w and there is no immediate predecessor that is definable. Endlessness must be taken seriously. Instead of the meaningless r-1 and r, I therefore suggest that we accept the inability to exhaust the endless and then assign order type w to the whole, explicitly including endlessness. Where the modified conclusion would be, all natural numbers we can reach in finite stage steps from 0 will be finite (this takes in place value notation and scientific notation etc), but the set continues endless-LY and we recognise an emergent quantity, the order type of such endless continuation, w.>> KF kairosfocus

Aleta @575

Hi Dionisio. I’m not quite sure what part of the sentence you don’t understand: “A1.2 This definition ensures that all are natural numbers are finite.” “This definition” refers to A1.1. The natural numbers are the set {1, 2, 3, …}. Finite means having a particular value, as opposed to infinite.

As I mentioned @571, the text I copied from your post @462 and quoted @569 reads:

A1.2 This definition ensures that all are natural numbers are finite.

Is that sentence grammatically correct? It sounds a little confusing to me. But again, English is not my first language. Spanish is my mother tongue (native language). Thank you in advance for clarifying this before I continue reading your posts 462 & 505 as per your request. Dionisio

KF,

Where we can put in 1:1 correspondence endlessly: C(w+g) –>C(w + {g-1}) –> . . . EoE . . . and 0, 1, 2, . . . EoE . . . which cannot be bridged in finite stage steps.

Can you explain how the indices in the first sequence go? If g is a finite number, then: ω + g, ω + (g - 1), ω + (g - 2), ... reaches ω + 0 = ω in a finite number of steps. What is the next term in the sequence? daveS

KF, Thank you for explaining this again. I see your point. Dionisio

Hi Dionisio. I'm not quite sure what part of the sentence you don't understand: "A1.2 This definition ensures that all are natural numbers are finite." "This definition" refers to A1.1. The natural numbers are the set {1, 2, 3, ...}. Finite means having a particular value, as opposed to infinite. Aleta

D, coming back full circle to the OP, that then leads me to ponder the claim of an infinite actual past of causal steps to arrive at the present. A conceptual analysis shows this requires ending the endless by traversing the transfinite in finite stage steps. That is a contradiction in terms and a warning. Going back to earlier stages, let us do a down count of former stages of the proposed infinite past physical cosmos to 0 at singularity then up to now:

. . . {Ellipsis of endlessness] . . . Ck --> Ck-1 --> . . . C2 --> C1 --> C0 --> C1* -->C2* --> . . . [finite ellipsis] . . . Cn-1* --> Cn* that is, now

The claim advanced above is that at every actually remote time/stage ck, one is finitely remote from the singularity but there is an endless and so infinite list of such stages. My view has been, the out fails, as the only reasonable meaning of an actually infinite past is that we have traversed an endless succession, not just a finite one. So, the implication is we have been at:

C(w+g) -->C(w + {g-1}) --> . . . EoE . . . Ck --> . . . C1* --> C0 --> Cn*

Where we can put in 1:1 correspondence endlessly: C(w+g) -->C(w + {g-1}) --> . . . EoE . . . and 0, 1, 2, . . . EoE . . . which cannot be bridged in finite stage steps. So, we have good reason to hold the actual past to be finite. Where also, that something -- a cosmos -- came from non-being is questionable. Non-being has no causal powers so were there ever non being utterly, such would forever obtain. If something now is that works by causal-temporal succession, at finitely remote time and stage, it began to be and did not come from non being. This points to a necessary being cause of the observed cosmos. Where such a being is eternal as opposed to causally dependent. KF kairosfocus

D, I see you are likely to be at nearly the same point where I was. The argument is on reaching any k in the set of counting sets it is bounded by k+1 and so we can recycle the load k+1 into the k register endless_LY, then infer per axioms that this finitude extends to all naturals (reconceptualising the succession as identifying a typical case then generalising to the whole). Leaving, the conclusion at there are infinitely many successive natural numbers, all of which are finite. I found that quite jarring -- especially given the copy the set so far principle -- and so have reassessed ordinary mathematical induction and the sort of do forever succession involved with sequences, to come out as I commented just above. KF kairosfocus

Aleta & DS (attn D also), I would suggest that the issue that starting from k, k+1 and onward endlessly we can set the truncated numbers in 1:1 correspondence with the un-truncated natural numbers leads to the conclusion that on cycling k+1 into the k register and keeping on, there is never a point where the sequence from 0 in +1 steps begins to actually exhaust the endlessness. In that context, were we to actually ever reach to the far zone of an endless value the issue that the next member is a copy of the set thus far [let me add by way of example] {0,1,2 . . . k} --> k+1 . . . intervenes. If there is an endless list of natural counting sets redesignated [ --> successively, in the logic chaining sense . . . ] as numbers, then that would point to there being endless members in the set if the chaining actually attains the remote transfinite zone from 0. This is a key part of the concern I have been having. I think the resolution is that the k, k+1 cycle never actually begins to exhaust the succession of ordinals. Yes, it is always finite, but equally, the endlessness represented by the ellipsis of endlessness counts. In this case, to take a leap that in one swooping step we conclude -- [a]all naturals are finite, and at the same time-- [b] the list of such is endless . . . is a leap too far in my view. Instead, I suggest that the k, k+1 do forever can cycle endless-LY . . . adverb . . . in principle but will also never go beyond a finite value in practice. To extend the "we only reach finite values" is then problematic. Instead, we should accept the "only to finite values" and "never exhaust the endlessness" seriously. We then see the naturals as being defined on endless idealised succession, which cannot be completed in actuality. Then we take the whole process: {0,1,2 . . . k, k+1, . . . [Ellipsis of endlessness] . . . } and recognise that there is now a new phenomenon, first order endlessness, which we assign an order type, omega (let us use w): {0,1,2 . . . k, k+1, . . . [Ellipsis of endlessness] . . . } --> w Where we then go on w, w+1 etc in the transfinite, remote zone that cannot be accessed operationally by any do forever process that moves in finite stages. So, when I look at ordinary mathematical induction that embeds a first base case 0, or 1, then hangs from it a chain that case k => case k+1, I see such a chaining, which inherently cannot exhaust the endless, for the reasons captured by the thought exercise of the pink and blue punched tapes, which is WLOG. The cautious conclusion of such an induction is that for any value of k we can step up to, or express in forms dependent on stepwise processes, the conclusion will hold endless-LY as opposed to -- we have exhausted the endless in steps. What we are doing often is we take a leap of endless scale and assign the conclusion across the span. But in he case of the conclusion that all natural numbers are finite this is problematic as if there is an endless string of such, then the copy of the set thus far principle: {0,1,2 . . . k} --> k+1 . . . will imply that some such values are transfinite or endless as individual members of the set. [Let me expand for some r +1 as a proposed endless member:] {0,1,2 . . . k, k + 1 . . . Ellipsis of endlessness] . . . } --> r+1 Is there thus a definable immediate predecessor r: {0,1,2 . . . k, k + 1 . . . finite Ellipsis] . . . r -1} --> r Not at all, the value r+1 is a synonym for w and there is no immediate predecessor that is definable. Endlessness must be taken seriously. Instead, I therefore suggest that we accept the inability to exhaust the endless and then assign order type w to the whole, explicitly including endlessness. Where the modified conclusion would be, all natural numbers we can reach in finite stage steps from 0 will be finite (this takes in place value notation and scientific notation etc), but the set continues endless-LY and we recognise an emergent quantity, the order type of such endless continuation, w. Omega, w for convenience [never mind the Gk letter is a form of o], is then the first definable transfinite, capturing the endless character of the string of ordinals reflected in counting set succession from 0. In all this, I again thank and acknowledge DS for his providing the link to Ehrlich, which allows me to see numbers whole through a tree structure, the surreals. And which of course allows for mild infinitesimals such as 1/w and so also 1/(w +g) where g is a large but finite value. In turn this brings to bear the catapult hyperbolic function, y = 1/x, that moves between the very near neighbourhood of 0 and the transfinite domain. With room for creating a continuum between A = (w+g) and B = (w + {g +1}) by catapulting neighbouring infinitesimals between m = 1/A and n = 1/B, which then obviously points to a continuum onwards. Likewise in the finite zone near 0, continuum can be defined by shifting the continuum between [0,1] through the same process of reciprocals of neighbouring values, or simple addition. After all 1.7 = 1 + 0.7. And the usual hyper reals can be seen as hard infinitesimal reciprocals that are far along in the band from w beyond one or more onward ellipses of endlessness in that zone. This means there is no definable first hyper real. Thus I would now have on the table just one more main point of concern, namely the clash between [0,1] as a continuum and the way hyper reals and infinitesimals have been defined as such that the latter are below any real number, seemingly implying a gap as opposed to a continuum of the reals in the very near neighbourhood of 0. KF kairosfocus

Aleta, Thank you, but my question was about the text quoted @569, which was copied from your post. Is it correctly written? Please, note that English is not my first language, hence I try to read most English text very carefully, so that I can understand it and at the same time improve my knowledge of the language. Obviously, in a blog like this we can't be 'picky' about misspellings or even grammar errors, as long as they don't render the text difficult to understand. In this particular case, I could not quite get the exact meaning of the quoted text. Thank you. Dionisio

Refer back to A1.1. Rephrased slightly:

The natural numbers start with zero, and are such that for every natural number k, k + 1 is also a natural number

Since 0 is finite (has a particular definite value), and since adding 1 to a finite number gives a finite number, this definition ensures that every natural number is finite. Aleta

daveS Ok, thanks. Aleta, Thank you for pointing to those two posts. Let me see if I can understand them. What does the following mean?

A1.2 This definition ensures that all are natural numbers are finite.

Dionisio

to Dionisio: the idea of always being able to get to the next natural number by adding 1 is not at issue, nor is the fact that there is no end to this process. See posts 462 and 505 for a summary of where some disagreements lie. Aleta

Dionisio, Yes, the part you quoted is correct. I have no disagreement with that. daveS

KF

As every finite k has a k+1, then refresh the k register with contents of k+1 and repeat. At every k, k+1 etc can be placed in 1:1 correspondence with 0,1, 2 . . . yielding the reliable finding that we have not even begun to exhaust endlessness.

Isn't that simply fundamental? I still don't quite understand your interlocutors' argument. My poor mind is too limited to fully grasp the sense of infinity. What's the largest negative number one can think of? Whatever it is, just subtract 1. The same for the largest positive number, but then add 1 to it. Can it be an end to that iteration on either direction? Dionisio

KF,

DS, It seems to me that stepwise finite stage succession is fundamental and is inherently incapable of going beyond the finite. As every finite k has a k+1, then refresh the k register with contents of k+1 and repeat. At every k, k+1 etc can be placed in 1:1 correspondence with 0,1, 2 . . . yielding the reliable finding that we have not even begun to exhaust endlessness.

Depending on the conditions, that might be the case, as I stated in #561.

My further point is we take the whole construct of attainable finite succession followed by leap and recognise a new emergent numerical phenomenon, order type w, first degree transfinite.

Well, that seems reasonable, although I still am not clear on what "attainable" means regarding possibly infinite sets. daveS

D, welcome. I am thinking we need to put together a reasonably coherent picture of the number jungle and significance i/l/o claimed actually infinite past for the observed space-time world and its physical antecedents. KF kairosfocus

DS, It seems to me that stepwise finite stage succession is fundamental and is inherently incapable of going beyond the finite. As every finite k has a k+1, then refresh the k register with contents of k+1 and repeat. At every k, k+1 etc can be placed in 1:1 correspondence with 0,1, 2 . . . yielding the reliable finding that we have not even begun to exhaust endlessness. It is therefore my view as at now that the ellipsis of endlessness is a critical part of the relevant sequences etc, and that the result is that we take the infinite leap of faith, or axiom if you want to call it that -- why this is additional and imposed; my discussion seeks significance. My further point is we take the whole construct of attainable finite succession followed by leap and recognise a new emergent numerical phenomenon, order type w, first degree transfinite. Then we build out in the ever expanding world of the transfinies, which are themselves endless. And of course the tree points to building down in the near neighbourhood of 0. KF kairosfocus

KF This discussion thread and the article https://uncommondescent.com/mathematics/fyi-ftr-on-ehrlichs-unified-overview-of-numbers-great-and-small-ht-ds/ are very interesting. They take my mind on a refreshing tour of very fundamental and sometimes difficult mathematical concepts. Thank you. Dionisio

KF,

DS, it seems to me that it is readily adequately established that no finite step by step process can traverse the transfinite in stages.

If the process takes place in time and has a beginning, maybe so.

My response is any actual set we can attain to will be finite, but we may point to continuation endless-LY as opposed to actually attaining endlessness.

This depends on what you mean by "attain to". I accept that we can attain to the set N by invoking the Axiom of Infinity, one version of which simply asserts "there exists an infinite set". If you mean that the only subsets of N which can be attained to are those which could occur as the output of a program running on a digital computer, with no infinite loops, then I believe you have a different standard than is held by most mathematicians. (I'm assuming that the output of the program consists of a list of natural numbers in decimal form).

But when one claims to have both only finite sets in succession AND to attain to an unlimited collection, and endless collection that is in principle completed by closing off with an ellipsis of endlessness, that does become problematic.

I'm still not clear on the problem this raises. I've brought up the example of {0, 1}^*. Do you agree that's an infinite set? I think of the entire collection {0, 1}^* as having been attained to once we set out the definition. daveS

DS, it seems to me that it is readily adequately established that no finite step by step process can traverse the transfinite in stages. At any k it will still have endlessness ahead that can be put in 1:1 correspondence with the sequence from 0, 1, 2 on. Second, it is clear that the chaining logic involved in ordinary mathematical induction and in the axioms cited entails pointing across an ellipsis of endlessness, so falling subject to the point. What we do is by a step of faith of literally infinite scale, complete the span through pointing across that ellipsis of endlessness. In the case of successive counting sets, it is also the case that the next in series copies the list of sets so far thus cumulatively causing a growing list within the members in the succession. This was explored in 217 above, as has been repeatedly pointed out. That is unproblematic if the list of such sets is finite and limited. But when one claims to have both only finite sets in succession AND to attain to an unlimited collection, and endless collection that is in principle completed by closing off with an ellipsis of endlessness, that does become problematic. My response is any actual set we can attain to will be finite, but we may point to continuation endless-LY as opposed to actually attaining endlessness. I add, i.e. {0,1, 2 . . . k, k+1 . . . } where the last ellipsis is endless as opposed to the first. This is rather like the issue of the open interval which has no last member as such short of the limit value. I add, e.g. [0,1) implies that any number we can squeeze in just short of 1 will fit but not 1 itself which generally includes 0.9999999 . . . [ellipsis of endlessness] as an equivalent form boiling down to the series 9*10^-1 + 9*10^-2 + . . . + 9*10^-k + . . . [EoE]. The difference is, such endlessness in this case: {0,1, 2 . . . k, k+1 . . . } . . . is based on +1 steps and is divergent as a sequence heading for the infinite. So, the counting numbers we may attain to -- by direct count or representation using place values or scientific style notation which both depend on power series that will use counting numbers in them, etc -- will all be finite but the set is unlimited in extension. And in view of the endlessness, we impose that the order type of the transfinite set is w. That is, we recognise a "new" phenomenon has emerged and symbolise the identifiable quantity. Which then becomes a borderline case, emergent from a stepwise succession with the pointing across the ellipsis of endlessness. That seems to me a reasonable view so far. KF kairosfocus

KF,

The solution I see is that we do not actually complete, i.e. the ellipsis of endlessness is crucial to the set of successive counting sets. We see that whenever we get to a specific value we will have something finite that can be exceeded by imposing successor, but the set as a whole is plus endlessness. So we never get to that point.

Then I say that you just don't accept the Axiom of Infinity (and the Axiom of Induction as well). Which is your prerogative of course. There are a few mathematicians in the same camp, but they are rare. From my point of view, there is nothing to "operationalize" about the construction of N. It exists (mathematically) by virtue of the Axiom of Infinity, not as a result of some step-by-step endless process. daveS

PS: Post Godel, there are a lot of leaps of faith involved in doing Math etc. Passing over ellipses of endlessness is one of them. kairosfocus

DS, I could point to the Turing Machine as key exemplar and leave it at that, but let me elaborate slightly. Let us start with the idea of operational definitions (without locking ourselves into logical positivism). Wiki for convenience:

An operational definition is a result of the process of operationalization and is used to define something (e.g. a variable, term, or object) in terms of a process (or set of validation tests) needed to determine its existence, duration, and quantity.[1][2] Since the degree of operationalization can vary itself, it can result in a more or less operational definition.[3] The procedures included in definitions should be repeatable by anyone or at least by peers . . . . The Stanford Encyclopedia of Philosophy entry on the subject, written by Richard Boyd, indicates that the modern concept owes its origin in part to Percy Williams Bridgman, who felt that the expression of scientific concepts was often abstract and unclear. Inspired by Ernst Mach, in 1914 Bridgman attempted to redefine unobservable entities concretely in terms of the physical and mental operations used to measure them.[5] Accordingly, the definition of each unobservable entity was uniquely identified with the instrumentation used to define it.

Generalising, reduce the problem in hand to a model based on goal directed input, processing and output activities and associated idealised/abstract computational elements, similar to the processes used with a Turing machine or the like. Though obviously we are substituting an intelligent mathematical (or physical) reasoner for doing a detailed algorithm on a machine of specified architecture, which would require far more elaboration as the machine is utterly dumb. Where, substitutions, algebraic representations, transformations based on established theorems or axioms, register transfers or transformations, etc are associated with idealised processing devices -- mathematical operators in principle able to be executed by an electronic or electromechanical device, e.g. a logging amplifier or integrator or differentiator -- yes I have analogue as well as digital computational units in mind at least as abstractions. Thus we are looking at somewhat informal or summary step by step procedures executed on idealised apparatus on inputs to yield desired outcomes through steps. Think about how a function is viewed as an input value mapped to an output, and shift to how an input function is mapped to an output one. As another illustration. I do not need to get into well use an ideal capacitor and charge it up from a controlled input current that maps the input voltage analogue of the input function to form an integral as output. The von Neumann construction of the counting numbers as counting sets is a typical case for a stepwise process that has a do forever endless in principle loop, as has often appeared in this thread. The idea is what are you doing how, how does this yield the result. (Though that is at close to algorithmic level, and often resorts to things like finite state machines.) The key case in thread is generating or addressing counting sets (as was discussed in 217) and operations of moving along such stretched out in a string. Idealised punched paper tapes with colour codes, read heads, sprockets to move, counters and registers, process units etc as abstracted to a virtual machine of some level. Notice abstract reference to a printer or to storage units. On hotels, notice speaking about a public address unit with broadcast capacity, able to instruct guests in rooms n to go to room 2n. Guests are intelligent agents able to hear, understand and carry out the operation of moving from room n to room 2n. But obviously a variable would be stored and its value updated by the operation of doubling and symbol matching would be involved. In the tapes case, pink tape sits there, blue one is pulled in some large finite number of units, k. Match 1:1, maybe by optical alignment -- note additions to OP above. Endlessness is treated as an all at one go matter. (If you wish, optical alignment would be tested by shining through a light for each row looking for a match, with some sort of grand and gate to pick up a mismatch also a paper detector that operates similarly so if blue is now ended that would be picked up. of course, both are endless, and that was the key premise. Though strictly we cannot physically implement such, we can sufficiently represent this in a thought exercise. As it is transmission line analysis pivots in part on an infinite regress of filter ckt elements in a network, and then we can evaluate what we see "looking into" the line. Infinite case idealisation.) It is readily seen that row k, k+1 etc can be matched to the unmoved 0, 1, 2 etc, and that is enough to see that if done again, the same will obtain because of the endlessness. Thence the problem that no finite length pulled in will begin to approach the far endless zone. What we find ourselves doing is seeing through generalisation that we could do forever in principle and jumping over the ellipsis of endlessness tot he overall result. But in this case a key concern I have is that we need to track the counting sets. As next set is in effect a set so far copy, if the list of such sets is actualised as endless, then at some stage we are looking at making endless copies to be elements. Which would not be finite, by definition. (As in a finite entity will have something of the same type that goes beyond it, as k has k+1 as bound etc.) The solution I see is that we do not actually complete, i.e. the ellipsis of endlessness is crucial to the set of successive counting sets. We see that whenever we get to a specific value we will have something finite that can be exceeded by imposing successor, but the set as a whole is plus endlessness. So we never get to that point. Though the ordinary mathematical induction has shown that for any specific case k, we can go to k +1. The result chained form case-0 will hold to any specific k. But the set as a whole has transfinite architecture represented by the ellipsis of endlessness. Its order type is then symbolised as w. Then we begin again as w+1 etc are successors. With a finite incrementing process. To see the sets or whatever we may call them in the end whole, we use ellipses of endlessness and the sort of pointing past generalisation already noted. Going to numbers great, and to numbers small. With of course much more specialised procedures for generating successors. Operations are being carried out that move form input to process to outputs, i.e we see operationalisation. And the process of tying to thought exercises, generalising and abstracting from the sort of machines etc we have looked at, help tie us to reality. And make it more likely to spot where things have gone wrong. Or to help us spot things we would otherwise miss. KF kairosfocus

KF, I still don't know what you mean by "operationalizable", or how you determine what is or isn't operationalizable. My guess is that you would regard only constructs (i.e., finite strings in some language) which would be accepted by some finite automaton as operationalizable, but I'm not sure. That's not the view of most mathematicians, I believe. [Edit: Well, that's probably not quite what I have in mind. Perhaps I will rephrase it later when I find the words]. As to the use of the term "leap of faith", I don't know. It's unknown whether ZFC is even consistent (and that's practically speaking not going to solved). However, it is thought to be consistent and has delivered valuable results so far, so going by track record, working within ZFC appears to be productive. daveS

H'mm: it strikes me that the sub-axiomatic step of pointing onward across an ellipsis of endlessness from a point of potential [but not operationalisable] infinity has a descriptive title as to the mental operation involved: an endless (thus literally infinite) leap of faith. I add to answer DS's q, this is not an operational step and though such a leap of faith is appropriate and necessary for many things, we should understand its true (and humbling . . . ) nature when we take it. We should also understand operational import, as in for instance when we do ordinary induction, we chain on by such a leap not by what can be reached stepwise by a chain of case k => case k+1, then iterate value of k to what was previously k +1 . . . the use of computational variables and abstract storage registers for present value practically beg for us to recognise them. Then, we face the implication of endlessness, i.e. at no finite k, no matter how large, have we even begun to exhaust endlessness; we can line up the blue tape with the pink again and lo and behold it is as if we are back to 0,1, 2 etc. We must walk by faith and not by sight [stepwise operations]. KF kairosfocus

Mung,

I think this has been part of the problem all along here. Mathematics divorced from reality.

Yes, I think that is ultimately true. daveS

KF,

DS, operationalised definitions and constructs are commonplace in mathematics. Including in contexts highly relevant to the matters we have discussed.

I know about operational definitions, but I'm asking what the "operational" constraints are. The Axiom of Infinity states that there is an infinite set, but you are saying that we can only reach finite values "operationally", which is unclear to me. Is it "operationally" illegitimate to simply apply the Axiom of Infinity to construct the set N all at once? daveS

daveS: If I sit down and do some mathematics, I don’t worry about any “operational” constraints on sets I can construct. I think this has been part of the problem all along here. Mathematics divorced from reality. Mung

PS: Illustrations added to show tapes and Turing Machines, used in operational form, abstract mathematical models which are thought exercises set up to explore the logic of structure (abstract and spatial alike) and quantity (here involving the tree of numbers great and small based on defining sets etc). kairosfocus

DS, operationalised definitions and constructs are commonplace in mathematics. Including in contexts highly relevant to the matters we have discussed. Observe, courtesy Wiki:

In mathematics, a Dedekind cut, named after Richard Dedekind, is a partition of the rational numbers into two non-empty sets A and B, such that all elements of A are less than all elements of B, and A contains no greatest element. Dedekind cuts are one method of construction of the real numbers. The set B may or may not have a smallest element among the rationals. If B has a smallest element among the rationals, the cut corresponds to that rational. Otherwise, that cut defines a unique irrational number which, loosely speaking, fills the "gap" between A and B. In other words, A contains every rational number less than the cut, and B contains every rational number greater than or equal to the cut. An irrational cut is equated to an irrational number which is in neither set. Every real number, rational or not, is equated to one and only one cut of rationals. Whenever, then, we have to do with a cut produced by no rational number, we create a new irrational number, which we regard as completely defined by this cut ... . From now on, therefore, to every definite cut there corresponds a definite rational or irrational number .... —?Richard Dedekind[1] More generally, a Dedekind cut is a partition of a totally ordered set into two non-empty parts A and B, such that A is closed downwards (meaning that for all a in A, x LTE a implies that x is in A as well) and B is closed upwards, and A contains no greatest element. See also completeness (order theory). It is straightforward to show that a Dedekind cut among the real numbers is uniquely defined by the corresponding cut among the rational numbers. Similarly, every cut of reals is identical to the cut produced by a specific real number (which can be identified as the smallest element of the B set). In other words, the number line where every real number is defined as a Dedekind cut of rationals is a complete continuum without any further gaps. Dedekind used the German word Schnitt (cut) in a visual sense rooted in Euclidean geometry. His theorem asserting the completeness of the real number system is nevertheless a theorem about numbers and not geometry.

and:

A Turing machine is an abstract machine[1] that manipulates symbols on a strip of tape according to a table of rules; to be more exact, it is a mathematical model that defines such a device.[2] Despite the model's simplicity, given any computer algorithm, a Turing machine can be constructed that is capable of simulating that algorithm's logic.[3] The machine operates on an infinite[4] memory tape divided into cells.[5] The machine positions its head over a cell and "reads" (scans[6]) the symbol there. Then per the symbol and its present place in a finite table[7] of user-specified instructions the machine (i) writes a symbol (e.g. a digit or a letter from a finite alphabet) in the cell (some models allowing symbol erasure[8] and/or no writing), then (ii) either moves the tape one cell left or right (some models allow no motion, some models move the head),[9] then (iii) (as determined by the observed symbol and the machine's place in the table) either proceeds to a subsequent instruction or halts[10] the computation. The Turing machine was invented in 1936 by Alan Turing,[11][12] who called it an a-machine (automatic machine).[13] With this model Turing was able to answer two questions in the negative: (1) Does a machine exist that can determine whether any arbitrary machine on its tape is "circular" (e.g. freezes, or fails to continue its computational task); similarly, (2) does a machine exist that can determine whether any arbitrary machine on its tape ever prints a given symbol.[14] Thus by providing a mathematical description of a very simple device capable of arbitrary computations, he was able to prove properties of computation in general - and in particular, the uncomputability of the Hilbert Entscheidungsproblem ("decision problem").[15] Thus, Turing machines prove fundamental limitations on the power of mechanical computation.[16] While they can express arbitrary computations, their minimalistic design makes them unsuitable for computation in practice: actual computers are based on different designs that, unlike Turing machines, use random access memory.

In the case in view, the two tapes with a read head and with blue advanced to k are in question, or the recursive stepwise setting up of a potential infinity or endlessness then pointed across by use of an ellipsis of endlessness. KF kairosfocus

From the PS:

Thus the essence of the axiom is: There is a set, I, that includes all the natural numbers.” [–> which becomes endless in principle though operationally we may only succeed to finite specific values...

What do you mean by "operationally" here? If I sit down and do some mathematics, I don't worry about any "operational" constraints on sets I can construct. daveS

KF,

Recursion and unfolding all the way up and down.

Recursion is achieved in one (or finitely many steps). See here for various examples. The definition of N we have been using:

0 ∈ N If k ∈ N, then k + 1 ∈ N N is the smallest set satisfying the above two conditions.

is recursive and constructs N in finitely many steps. Erlich is using suggestive language (unfolding, etc.) here, but if you find a formal construction of the surreal numbers in a first-order language, then you will see that it consists of finitely many steps. A "proof" with infinitely many steps is not possible. [Edit: At least in first order theories. Infinitary logic does exist which allows such things, but that is certainly not involved with the proofs we are discussing pertaining to N, and I'm fairly certain the surreal numbers as well. See here for a discussion]. I don't know if anyone has bothered to write out such a construction; usually mathematicians stick to natural-language proofs because they are more comprehensible.

However, the other axioms are insufficient to prove the existence of the set of all natural numbers. Therefore its existence is taken as an axiom—the axiom of infinity. [–> forcing the result by pointing across the ellipsis of endlessness]

I don't know if I would call it "forcing the result", but that's in the right ballpark. We assume that an infinite set exists, period. No additional steps need, now we have N. daveS

PPS: Cf headlined as PPS here, with illustrations: https://uncommondescent.com/mathematics/fyi-ftr-on-ehrlichs-unified-overview-of-numbers-great-and-small-ht-ds/ kairosfocus

PS: For convenience Wiki on Ax inf:

In words, there is a set I (the set which is postulated to be infinite), such that the empty set is in I and such that whenever any x is a member of I, the set formed by taking the union of x with its singleton {x} is also a member of I. Such a set is sometimes called an inductive set. Interpretation and consequences This axiom is closely related to the von Neumann construction of the naturals in set theory, in which the successor of x is defined as x U {x}. If x is a set, then it follows from the other axioms of set theory that this successor is also a uniquely defined set. Successors are used to define the usual set-theoretic encoding of the natural numbers. In this encoding, zero is the empty set: 0 = {}. The number 1 is the successor of 0: 1 = 0 U {0} = {} U {0} = {0}. Likewise, 2 is the successor of 1: 2 = 1 U {1} = {0} U {1} = {0,1}, and so on. A consequence of this definition is that every natural number is equal to the set of all preceding natural numbers.

[--> the copy set to date principle highlighted in 217 above; this is where my concern that were N to be all finite values but extends endlessly, at some point it would need endless members. Of course -- like the ever receding foot of the rainbow -- that cannot be reached and so we have the ellipsis as a crucial part of N, i.e. we may only actually operationally succeed to finite values but may do so without upper limit. The endlessness of first order is then transferred to its order type w]

This construction forms the natural numbers. However, the other axioms are insufficient to prove the existence of the set of all natural numbers. Therefore its existence is taken as an axiom—the axiom of infinity. [--> forcing the result by pointing across the ellipsis of endlessness] This axiom asserts that there is a set I that contains 0 and is closed under the operation of taking the successor [--> which is endless in principle but operationally is ever limited to finite and bounded individual values]; that is, for each element of I, the successor of that element is also in I. Thus the essence of the axiom is: There is a set, I, that includes all the natural numbers. [--> which becomes endless in principle though operationally we may only succeed to finite specific values and as the pink/ blue paper tape thought exercise shows, for every k of arbitrarily large but finite scale we can truncate the tape so far and set k to correspond to 0 in the unmoved pink tape, k+1 to 1, etc and obtain an endless 1:1 match, that is endlessness is pivotal and cannot be traversed stepwise]

I have commented on points. kairosfocus

F/N: Ehrlich, with emphasis: >>Among the striking s-hierarchical features of No is that much as the surreal numbers emerge from the empty set of surreal numbers by means of | a transfinite recursion that provides an unfolding of the entire spectrum of numbers great and small (modulo the aforementioned provisos), the recursive process of defining No’s arithmetic in turn provides an unfolding of the entire spectrum of ordered fields in such a way that an isomorphic copy of every such system either emerges as an initial subtree of No or is contained in a theoretically distinguished instance of such a system that does.>> Recursion and unfolding all the way up and down. Where AmHD:

re·cur·sion (r?-kûr?zh?n) n. 1. Mathematics a. A method of defining a sequence of objects, such as an expression, function, or set, where some number of initial objects are given and each successive object is defined in terms of the preceding objects. The Fibonacci sequence is defined by recursion. b. A set of objects so defined. c. A rule describing the relation between an object in a recursive sequence in terms of the preceding objects.

In short a pattern is established then it is universalised by pointing across ellipsis of endlessness. Which is also embedded in relevant axioms. KF kairosfocus

KF,

PS: kth successor –> successive what . . . ?

Natural number? You can construct any finite set {0, 1, 2, ..., k} using the successor operation. To construct the set N requires the Axiom of Infinity. daveS

F/N: Ehrlich, pp 7 - 8:

Among the striking s-hierarchical features of No is that much as the surreal numbers emerge from the empty set of surreal numbers by means of | a transfinite recursion that provides an unfolding of the entire spectrum of numbers great and small (modulo the aforementioned provisos), the recursive process of defining No’s arithmetic in turn provides an unfolding of the entire spectrum of ordered fields in such a way that an isomorphic copy of every such system either emerges as an initial subtree of No or is contained in a theoretically distinguished instance of such a system that does.

KF PS: kth successor --> successive what . . . ? kairosfocus

KF, That's the misleading aspect of the domino model I referred to somewhere above. It implies that mathematical induction is simply the application of the law of detachment over and over, which is not the case. Without the Axiom of Induction, you would be right. But this axiom does the "heavy lifting" that you refer to, omitting the do forever loop. It in essence says you can replace these "do forever" loops with one (or just a few) steps. Edit:

the induction axiom describes an essential property of {N}, viz. that each of its members can be reached from 0 by sufficiently often adding 1 [–> do forever looping creating stepwise succession]

This simply states that any natural number is the k-th successor to 0, for some finite k. It doesn't say anything about do forever loops, and that's not how N is constructed. daveS

F/N: Wiki has an interesting remark on ordinary mathematical induction:

Having proven the base case and the inductive step, then the structure of {N} is such that any value can be obtained by performing the inductive step repeatedly. It may be helpful to think of the domino effect. Consider a half line of dominoes each standing on end, and extending infinitely to the right (see picture) [--> similar to the punched tape]. Suppose that: The first domino falls right. If a (fixed but arbitrary) domino falls right, then its next neighbor also falls right. With these assumptions one can conclude (using mathematical induction) that all of the dominoes will fall right. [--> strictly, that the dominoes in sequence from the first will be subjected to a chaining process propagating stepwise from one to the next, however this then runs into endlessness of the chain as set up] If the dominoes are arranged in another way, this conclusion needn't hold (see Peano axioms#Formulation for a counter example). Similarly, the induction axiom describes an essential property of {N}, viz. that each of its members can be reached from 0 by sufficiently often adding 1 [--> do forever looping creating stepwise succession]

That is, we see the do forever iteration implicated in the process. This runs into the problem that for any k achieved in k finite steps, from k, k+1 on is just as much able to be put in 1:1 correspondence with the undisturbed set as before. This illustrates a case in point of pointing across an ellipsis of endlessness. KF kairosfocus

F/N: Headlined (HT DS), the numbers sandbox is now officially open for play. KF kairosfocus

PS: Footnoted to OP is a picture of Ehrlich's grand number tree. This sets a context for discussion in a unified context with room enough for pondering numbers great and small through the surreals. Not to mention rather unusual operations on surprising numbers. kairosfocus

DS, That does look promising, Abstract:

Abstract. In his monograph On Numbers and Games, J. H. Conway introduced a real-closed field containing the reals and the ordinals as well as a great many less familiar numbers including [lists] to name only a few. Indeed, this particular real-closed field, which Conway calls No , is so remarkably inclusive that, subject to the proviso that numbers—construed here as members of ordered fields—be individually definable in terms of sets of NBG (von Neumann–Bernays–Godel set theory with global choice), it may be said to contain “All Numbers Great and Small.” In this respect, No bears much the same relation to ordered fields that the system R of real numbers bears to Archimedean ordered fields. In Part I of the present paper, we suggest that whereas R should merely be regarded as constituting an arithmetic continuum (modulo the Archimedean axiom), No may be regarded as a sort of absolute arithmetic continuum (modulo NBG), and in Part II we draw attention to the unifying framework No provides not only for the reals and the ordinals but also for an array of non-Archimedean ordered number systems that have arisen in connection with the theories of non-Archimedean ordered algebraic and geometric systems, the theory of the rate of growth of real functions and nonstandard analysis. In addition to its inclusive structure as an ordered field, the system No of surreal num-bers has a rich algebraico-tree-theoretic structure—a simplicity hierarchical structure—that emerges from the recursive clauses in terms of which it is defined. In the development of No outlined in the present paper, in which the surreals emerge vis-a-vis a generalization of the von Neumann ordinal construction, the simplicity hierarchical features of No are brought to the fore and play central roles in the aforementioned unification of systems of numbers great and small and in some of the more revealing characterizations of No as an absolute continuum.

KF kairosfocus

KF,

But what I am really saying is, how does the jungle get set in order with a tree of unifying relationships? Particularly among the trans-finites? Surreals? Whatever?

I don't know anything about this, but last post on this page at stackexchange discusses the relationship between hyperreals and surreal numbers, with a link to this paper. Theorem 1 states:

Whereas R is (up to isomorphism) the unique homogeneous universal Archimedean ordered field, No [the surreal numbers] is (up to isomorphism) the unique homogeneous universal ordered field.

The precise definitions are given in the paper, but the key one is (paraphrased):

An ordered field A is said to be universal if every ordered field whose universe is a class of NBG can be embedded in A.

Apparently every ordered field can be embedded in the surreal numbers, so it's "large as possible" in some sense. This is based on the NBG axiom system for set theory rather than ZFC. daveS

Aleta, pardon but k is transfinite, o is not. I suggest that makes a difference for looking at them. I notice as follows as a simple clip at Wolfram:

Transfinite Number One of Cantor's ordinal numbers omega, omega+1, omega+2, ..., omega+omega, omega+omega+1, ... which is "larger" than any whole number.

which is suggestive. I essay no proof-claim there, I just notice a resemblance that would "fit" with a hard infinitesimal catapulting to something in say the bolded range or one of its many onward cousins. But what I am really saying is, how does the jungle get set in order with a tree of unifying relationships? Particularly among the trans-finites? Surreals? Whatever? This being beyond main focus but relevant to the principle that knowledge claims should be unified where possible. GEM kairosfocus

kf writes,

PS: k as defined looks like enclosed by two ellipses of endlessness within the transfinites, i.e. it sits far out among transfinites.

That's a strange thing to say. We could write the integers as {... -3, -2, -1, 0, 1, 2, 3, ...} 0 sits between two ellipses: Is it "far out" among the integers? Is it more or less far out than 70 billion billion billion? Aleta

DS, I just noted, there are two ellipses of endlessness surrounding the transfinite k and neighbours, which looks interestingly inviting of a siting suitably remote from w among transfinites. But this is just a look not an argument. My real point is there is a jungle out there that has strange critters of unknown linkages inviting some unification. On that front try: http://shelah.logic.at/files/825.pdf on candidates to be "the" -- even that is controversial it seems -- hyper reals. KF kairosfocus

Due to problems displaying Greek letters, here's a correct 528: Supporting Dave in 522: In the hyperreals

There is infinitude of infinite integers, i.e., not finite elements of PA1infinity: ... k - 2, k - 1, k, k + 1, k + 2, ..., 2 k, 3 k, ..., k² - k, ..., k² - 1, ... which shows that our choice of k was pretty much arbitrary. It's more common to use the symbol omega instead. However, there is certainly a danger of confusing it with the first infinite ordinal number. The latter is of course defined uniquely.

[Note: a Greek K shows up on the website where I have typed k, and a Greek w where I've typed omega.] http://www.cut-the-knot.org/WhatIs/Infinity/HyperrealNumbers.shtml Aleta

KF,

DS, what is the least ordinal greater than any 1 +1 +1 . . . +1 where the string is not transfinitely long? KF

The least ordinal greater than any 1 + 1 + ... + 1 is ω. The least hyperinteger greater than any 1 + 1 + ... + 1? There is no such thing. See Aleta's link. daveS

Aleta, point taken, but I think the same question applies as was just posed to DS. KF PS: k as defined looks like enclosed by two ellipses of endlessness within the transfinites, i.e. it sits far out among transfinites. kairosfocus

DS, what is the least ordinal greater than any 1 +1 +1 . . . +1 where the string is not transfinitely long? KF kairosfocus

Thanks for hunting that down, Aleta. daveS

Supporting Dave in 522: In the hyperreals

There is infinitude of infinite integers, i.e., not finite elements of PA1?: ... ? - 2, ? - 1, ?, ? + 1, ? + 2, ..., 2?, 3?, ..., ?² - ?, ..., ?² - 1, ?², ... which shows that our choice of omega was pretty much arbitrary. It's more common to use the symbol omega instead. However, there is certainly a danger of confusing it with the first infinite ordinal number. The latter is of course defined uniquely.

[Note: the Greek w shows u on the website where I have typed omega.] http://www.cut-the-knot.org/WhatIs/Infinity/HyperrealNumbers.shtml Aleta

Khan Academy vid https://www.khanacademy.org/math/recreational-math/vi-hart/infinity/v/kinds-of-infinity . . . a look at the jungle. kairosfocus

KF,

DS, there is a first transfinite ordinal w and there are hyper integers.

Yes, but there is no first transfinite positive hyperinteger. The ω in the hyperreal wikipedia article is not a von Neumann ordinal. daveS

EZ, denialism -- a term you tossed in like a live grenade -- is so loaded a term that it is beyond the pale of civil discussion. Second, I have pointed out sufficient above that shows there is a jungle out there full of strange critters. And, the concept that we can tie hyper reals etc together is demonstrably on the table. It is also quite clear to me that ordinary induction is successive and that ever so many core points embed or imply do forever loops. Notice how a definition of reals progresses on what premise just above. So we do have to look at endlessness, which is indeed doing a lot of heavy lifting. The y = 1/x catapult does seem very fruitful. KF kairosfocus

DS, there is a first transfinite ordinal w and there are hyper integers. The construction pointing to w seems reasonable to me as w being first ordinal greater than any chain of +1s from 0, interpreted on the von Neumann construction. Why, then, a call for specific reference on that? KF kairosfocus

#513 KF

Rhetoric about denialism — which is horrifically loaded with Holocaust denial — does not help settle the matter. Nor does the notion, we do not dispute this, it is settled so there, only the ignorant, stupid, insane and/or wicked denialists would challenge the Consensus. EZ, I am looking at you here.

You throw this into a purely academic discussion. YOU are loading the discussion. YOU are trying to make this into something else. YOU are poisoning the waters. Why, I don't know. This discussion has nothing to do with Holocaust denial. So why bring it up? Why?

And EZ, motive mongering or how I came up with the idea of pink and blue paper punch tapes is of little value. In fact, as Turing tapes of endlessness were discussed and as coloured 3+5 punched paper computer tapes exist, it seemed reasonable to look at parallel tapes running off endlessly and to ponder in ways that are anchored to an intuitive, simple entity. Thought exercises and abstracted models thereof are commonplace in several linked fields. And there is Hilbert’s hotel.

And there is Hilbert's hotel. Let me ask you this: have you had any of your work looked at by a group of reputable mathematicians? Have you submitted any of your ideas to any kind of magazine or peer-reviewed journal? Have you presented any of your ideas to a conference or gathering of bone fide mathematicians? I'm not trying to be rude I just want to know if you've HONESTLY had your contentions examined and critique by people who know the field. ellazimm

KF,

1 LT omega, 1+1 LT omega, 1+1+1 LT omega, 1+1+1+1 LT omega, . . . . [–> Obviously w is the first transfinite and is recognised as being in the hyper reals *R but not the reals R]

Eh? Do you have a reference? The problem is there is no "first transfinite" in the hyperreals. Given any positive infinite hyperinteger k, there exists infinitely many other positive infinite hyperintegers less than k. That means the ω above cannot be the same as the ordinal ω we have been referring to. daveS

Aleta, I have said w is not in N. What I have said is that the set we label N will have w as its order type and the ellipsis of endlessness is pivotal to its meaning. Where w does not appear out of nothing or sneak in magical properties, it is the order type resulting from endless succession that cannot be operationally completed stepwise. KF PS: Let me add, every number we can reach in N by a +1 stage sequence or extensions to that such as writing down in place value or scientific notation etc (all of which will involve series) will be finite and have another number beyond that will by iteration be finite. But due to endlessness we cannot exhaust N. Taking the +1 succession and the equivalent succession of sets, to go to actual endlessness -- infeasible -- would entail copying the set as a whole, endlessness within endlessness. But also this is the set we count by, if it has endless continuation there is an open endedness we CANNOT exhaust. That is where w steps in to point past the ellipsis. kairosfocus

PS: FWIW, Wiki on hyper reals:

The system of hyperreal numbers is a way of treating infinite and infinitesimal quantities. The hyperreals, or nonstandard reals, *R, are an extension of the real numbers R that contains numbers greater than anything of the form 1 + 1 + . . . + 1. [--> so these will be transfinite], Such a number is infinite, and its reciprocal is infinitesimal. [--> hence the use of the catapult function y = 1/x to go between the neighbourhood of 0 and the relevant range] The term "hyper-real" was introduced by Edwin Hewitt in 1948.[1] . . . . The idea of the hyperreal system is to extend the real numbers R to form a system *R that includes infinitesimal and infinite numbers, but without changing any of the elementary axioms of algebra. Any statement of the form "for any number x..." that is true for the reals is also true for the hyperreals. [--> not for any x in R, x is finite] For example, the axiom that states "for any number x, x + 0 = x" still applies. The same is true for quantification over several numbers, e.g., "for any numbers x and y, xy = yx." This ability to carry over statements from the reals to the hyperreals is called the transfer principle. However, statements of the form "for any set of numbers S ..." may not carry over. [--> okay] The only properties that differ between the reals and the hyperreals are those that rely on quantification over sets, or other higher-level structures such as functions and relations, which are typically constructed out of sets. Each real set, function, and relation has its natural hyperreal extension, satisfying the same first-order properties. The kinds of logical sentences that obey this restriction on quantification are referred to as statements in first-order logic. The transfer principle, however, doesn't mean that R and *R have identical behavior. For instance, in *R there exists an element omega such that 1 LT omega, 1+1 LT omega, 1+1+1 LT omega, 1+1+1+1 LT omega, . . . . [--> Obviously w is the first transfinite and is recognised as being in the hyper reals *R but not the reals R] [--> cf below, this w may be further along than the previous, i.e. there is a construction below that has predecessors and successors with surrounding ellipses of endlessness. That invites exploration but that is not primary for this thread's purpose. Note my suggestion on mild infinitesimals above vs hard ones, on analogy of the catapulting function 1/x] but there is no such number in R. (In other words, *R is not Archimedean.) . . . . The hyperreals *R form an ordered field containing the reals R as a subfield. Unlike the reals, the hyperreals do not form a standard metric space, but by virtue of their order they carry an order topology. The use of the definite article the in the phrase the hyperreal numbers is somewhat misleading in that there is not a unique ordered field that is referred to in most treatments. However, a 2003 paper by Vladimir Kanovei and Shelah[4] shows that there is a definable, countably saturated (meaning omega-saturated, but not of course countable) elementary extension of the reals, which therefore has a good claim to the title of the hyperreal numbers. ---> in short just who are these guys is a debate but there is a suggestion as to how to unify] Furthermore, the field obtained by the ultrapower construction from the space of all real sequences, is unique up to isomorphism if one assumes the continuum hypothesis . . .

And on surreals

In mathematics, the surreal number system is an arithmetic continuum containing the real numbers as well as infinite and infinitesimal numbers, respectively larger or smaller in absolute value than any positive real number. [--> I note my remaining qualms about the closed interval [0,1] and how it must be continuous] The surreals share many properties with the reals, including a total order LTEQ and the usual arithmetic operations (addition, subtraction, multiplication, and division); as such, they form an ordered field. (Strictly speaking, the surreals are not a set, but a proper class.[1]) If formulated in Von Neumann–Bernays–Gödel set theory, the surreal numbers are the largest possible ordered field; all other ordered fields, such as the rationals, the reals, the rational functions, the Levi-Civita field, the superreal numbers, and the hyperreal numbers, can be realized as subfields of the surreals.[2] It has also been shown (in Von Neumann–Bernays–Gödel set theory) that the maximal class hyperreal field is isomorphic to the maximal class surreal field; in theories without the axiom of global choice, this need not be the case, and in such theories [--> norice, we are now in the zone of exploratory theories in Maths which work as explanatory models] it is not necessarily true that the surreals are the largest ordered field. The surreals also contain all transfinite ordinal numbers; the arithmetic on them is given by the natural operations . . . . In the first stage of construction, there are no previously existing numbers so the only representation must use the empty set: { | }. This representation, where L and R are both empty, is called 0. Subsequent stages yield forms like: { 0 | } = 1 { 1 | } = 2 { 2 | } = 3 and { | 0 } = -1 { | -1 } = -2 { | -2 } = -3 The integers are thus contained within the surreal numbers. (The above identities are definitions, in the sense that the right-hand side is a name for the left-hand side. That the names are actually appropriate will be evident when the arithmetic operations on surreal numbers are defined, as in the section below). Similarly, representations arise like: { 0 | 1 } = 1/2 { 0 | 1/2 } = 1/4 { 1/2 | 1 } = 3/4 so that the dyadic rationals (rational numbers whose denominators are powers of 2) are contained within the surreal numbers. After an infinite number of stages [--> do forever loops again with ellipses of endlessness pointed across . . . ], infinite subsets become available, so that any real number a can be represented by { La | Ra } [--> reals imply do forever loops], where La is the set of all dyadic rationals less than a and Ra is the set of all dyadic rationals greater than a (reminiscent of a Dedekind cut). Thus the real numbers are also embedded within the surreals. But there are also representations like { 0, 1, 2, 3, … | } = omega { 0 | 1, 1/2, 1/4, 1/8, … } = epsilon where omega is a transfinite number greater than all integers and epsilon is an infinitesimal greater than 0 but less than any positive real number. Moreover, the standard arithmetic operations (addition, subtraction, multiplication, and division) can be extended to these non-real numbers in a manner that turns the collection of surreal numbers into an ordered field, so that one can talk about 2*omega or omega - 1 and so forth.

Looks like its a positive jungle out there full of stranger and stranger critters. kairosfocus

w is not in N. Every number in N is finite. w is not in N, so it doesn't negate the fact that all numbers within N are finite. Aleta

DS, I thank you for sharing a link. However, I remain at a point where the concept of an actualised infinity of successive finite only values from 0 on in steps of +1 cannot seem reasonable. The largest finite values attained -- being successively collections of prior sets in the succession (as was noted already in discussing axiom of infinity) -- obviously would be inherently finite and will copy the sequence of counting sets so far. That was highlighted back in 217. So, it seems to me that an actualised collection of an infinite string of . . . finite value only . . . counting sets from 0 is not feasible. From what I see, the assertion that all that lurks under the ellipsis of endless continuation in {0,1, 2 . . . } will be finite will fail. How it fails is not that there are infinite attainable values, but that the transfinite zone cannot be operationally attained to. Ordinary induction chains and has the same counting embedded, as do the axioms. When we complete the domain conceptually by pointing across the ellipsis, we enfold a span that cannot be counted out. The all at once step, however, does not lead to oh all in the collection are finite. For the copy- of- the- set- so- far reason above. Instead, it seems to me that the ellipsis of endless continuation of counting sets and succession to such taken as a whole {0,1,2, . . . } lead rather to the transfinite order type w and onward as a concept, an idealisation beyond actual counting. That seems to resolve my concern, we only can operationalise finites but the succession may continue endless-LY and has order type w, cardinality aleph null. Then we may speak of the endless collection as a whole understanding we cannot operationally complete it. An endless tape, therefore obviously cannot be physically actualised no more than HH can, but the thought exercise is instructive; hence my remark that the tape records inspection reports on the HH rooms, one byte/row per room in succession. This points to the extended ordering of successive numbers from w on, beyond an impassable ellipsis of endlessness. That would be the remote far zone that could be contemplated, counting sets in succession cannot be extended operationally to a point of: "the next set k is now transfinite." But endlessness -- the key issue -- has implications that can be used in an analysis, one of which is counting onwards from k, k+1 etc will 1:1 match the original order from 0, 1 etc, i.e. the set of endless successive rows is infinite and attempting to traverse the endless in steps will be futile; it will never attain to a transfinite value. Bringing in the ellipsis, {0,1,2 . . . } --> w, we are instantly at the zone of w on, which cannot be physically realised or attained to in a do forever loop but may profitably be mathematically discussed on an all at one go basis for {0,1,2 . . . }. So an endless continuation of tapes is conceptual and one may therefore reasonably suggest the far zone is the recognised transfinite one -- in effect the tape dissolves into the extended ordered numbers. Where on this w etc would be beyond the naturals or reals. Resolving that concern-point. There is a qualitative difference thanks to the ellipsis of endlessness. The transfinite emerges from the endless-NESS of successive counting sets which can only be operationalised to finite extent. We cannot operationally complete an endless traverse of +/-1 steps. Which is the main point after all, and it is what brings a logical focus to the issue of a proposed endless causal succession as the past leading to the world of today. Such a proposed endless space-time past does not seem to be a tenable view. We cannot traverse an endless span in finite stage steps. (The issue of from k, k+1 on we can match the from 0,1 on shows how such will be frustrated. Endlessness is not realisable operationally in steps.) From that, we then may ask questions as to a unified far zone. KF kairosfocus

PS to my #516: This appears to be a (relatively) accessible introduction to the hyperreals. I challenge you to read it and decide whether you are more comfortable working with the hyperreals vs. the natural and real numbers. daveS

KF,

Thus w is first transfinite ordinal, and all numbers feasibly reachable by +1 steps of succession from 0 will be finite and bounded by onward equally finite successors. Which is all that ordinary mathematical induction can reach.

That actually sounds more or less accurate. With ordinary mathematical induction, you prove statements such as "the sum of all positive integers at most n is n(n + 1)/2". This applies only to natural numbers, each of which is finite.

m –> 1/m –> A = w + g

Ugh. You're throwing around equations which have no solutions again. As I stated earlier in the discussion, this is like an assertion that a particular square is congruent to a particular circle.

No claims for truth are made, only pragmatic utility tied to unification of a range of things that apart from unification are puzzling in a cognitive sense. *** At this stage I feel a much lessened sense of concern, regarding what I have been looking at.

Well, if you are interested in the truth, you should still have a great deal of concern, as there are numerous errors in the above posts. If you really want to pursue this, I suggest reading up on the construction of the hyperreals (not an elementary textbook such as Keisler's). daveS

KF,

A, I must note to you that you are resorting to refusing a given answer stated in the explicit context that there is a gap in views that can make simplistic y/n without explanation meaningless.

In the context of ZFC and standard definitions, there is no reason you cannot give a clear yes or no answer to Aleta's question.

Where, by definition of the tape, all along their length they have punched rows. Accordingly, it is hard to reject the point that there are spatially endlessly remote rows which duly have row-counts that are endlessly larger than any arbitrarily high but finite row value k. Which is the long way round to, these are infinitely far away. With appropriate row numbers.

I've asked you to name a row which is infinitely far away from row 0. We have labels for each row (use any system of numerals you want). Can you do so?

So now we come to labelling and giving values to rows in the tapes. For finite extension in steps that is not an issue. But the onward pointing to endlessness does raise an issue that is not resolved by saying ordinary induction takes them all in in one step. For, as the finite stepwise chain hits any k an endless succession always lies beyond. Bridging by an implicit sub axiom of pointing across an ellipsis of endlessness will be freighting that implicit step with the heavy lifting to reach the conclusion. Which leads to the point, why take that step?

Are you asking why people generally accept the Axiom of Induction? If so, that's an entirely separate issue from what I have been discussing, which is simply what theorems can be proved using this axiom.

Concrete and readily represented, even turning glyphs into simple keyboard graphics: Pink, with near end: |0 === . . . k, k+1 ====> . . . Blue, pulled in k and cut just before k, continuing on to RHS endlessly: |k, k+1 ====> . . . Both can be set in 1:1 correspondence, and pull in k and match can be endlessly repeated beyond case o as above. (I just used do k times to get to k*k rows pulled in.) What mathematical language can we use to address that endlessness, resolving paradoxes?

Well, the set of natural numbers is in 1-1 correspondence with the set of natural numbers k or greater, for any natural number k. Where's the paradox? I think we've given adequate explanations of that fact in standard mathematical language. Have you found any sources which describe the same concerns you have, by the way?

DS, BTW, a PA system vs chaining in sucession on Hilbert’s Hotel brings out the difference between all at once setwide processes and inherently finite chained successive ones. I don’t know about you but instantly on hearing of the hotel and what happens to provide room for fresh guests the issue is, how do you get the guests to all go to room 2n from room n? A PA system, with broadcast capability. By contrast with trying to propagate in a chain of steps.

I think that particular detail is left unspecified. The room reassignment puzzle demonstrates a purely mathematical issue, and if you start worrying about logistics, you're missing the point.

For me, it first makes me a lot more wary of discussions of the infinite and the mathematics connected therewith. I have a lot of sympathy for the non standard analysis approach. Hyper reals and infinitesimals. I am now much more wary of discussions of naturals and of reals.

Er, have you looked at the construction of the hyperreals? If you are wary of the natural and real numbers, you should be doubly so of the hyperreals. It's a rather strange set. And of course, the natural numbers and reals are embedded in the hyperreals, so you are not going to get away from them in this way. daveS

F/N: I think I can summarise what seems to make sense to me, for the sake of record. First, the two tapes are pivotal, as is the difference between all at once, stepwise +/-1 processes and the sort of convergent series completed in finite spans of space and time that crop up in Zeno's paradoxes. (For these last, the rapid trend to infinitesimals in time and space converges to a very finite limit in both space and time as a trajectory plays out.) Second, the ellipsis of endlessness is crucial to distinguish the near 0 zone and the transfinitely far one. As it cannot be bridged in stepwise +/-1 processes, there is an operational barrier between the zones. In that context, it is a plausible step to assign the transfinitely remote zone values such as w, w+1, . . . w+g, . . . so succession continues in stepwise +/-1 processes, but one conceptually catapults to get there. The y = 1/x function applied to mild infinitesimals as a suggestion, would be such a catapult. What I can now do is to take [a] the inherent finitude of +1 increments from 0, and [b] the issue of a do forever loop from 0 that [c] goes on endless-LY but never spans the ellipsis of endlessness and [d] use the three to synthesise a picture that I think (thus far; this is exploratory . . . ) is coherent. The counting succession from 0 in +1 steps is endless in succession process via do forever, but cannot exhaust endlessness. Indeed at any given k, k+1 etc the shifted blue tape can be put back in 1:1 correspondence with the unshifted pink one. This guarantees the span cannot be completed and shows how endlessness beyond any specified finite kth step of arbitrarily large scale, is no nearer to ending the endless than when it all began at 0. The succession of such counting steps goes on endlessly but by virtue of that is never completed in the sense of spanning the endlessness. I can see the sense in which the natural counting numbers are defines by that summary and constraint. What we can ever reach is finite but the succession continues, and at any k we then set a bound on k by the k+1th step following. The picture of the natural numbers (and the near 0 zone of the tapes), then would be:

An endless-LY continued sequence of finite numbers comprising a set that in aggregate -- as ideally pointed to across an ellipsis of endlessness -- is indeed just such; endless.

The successor to and order type of that block is then w, followed by its own successors w+1 etc. The far zone of the tapes. Thus, per Wolfram:

http://mathworld.wolfram.com/OrdinalNumber.html In formal set theory, an ordinal number (sometimes simply called an “ordinal” for short) is one of the numbers in Georg Cantor’s extension of the whole numbers. An ordinal number is defined as the order type of a well ordered set (Dauben 1990, p. 199; Moore 1982, p. 52; Suppes 1972, p. 129). Finite ordinal numbers are commonly denoted using arabic numerals, while transfinite ordinals are denoted using lower case Greek letters. It is easy to see that every finite totally ordered set is well ordered. Any two totally ordered sets with k elements (for k a nonnegative integer) are order isomorphic, and therefore have the same order type (which is also an ordinal number). The ordinals for finite sets are denoted 0, 1, 2, 3, …, i.e., the integers one less than the corresponding nonnegative integers. The first transfinite ordinal, denoted omega, is the order type of the set of nonnegative integers (Dauben 1990, p. 152; Moore 1982, p. viii; Rubin 1967, pp. 86 and 177; Suppes 1972, p. 128). This is the “smallest” of Cantor’s transfinite numbers, defined to be the smallest ordinal number greater than the ordinal number of the whole numbers. Conway and Guy (1996) denote it with the notation omega={0,1,…|}. From the definition of ordinal comparison, it follows that the ordinal numbers are a well ordered set. In order of increasing size, the ordinal numbers are 0, 1, 2, …, omega, omega+1, omega+2, …, omega+omega, omega+omega+1, …. The notation of ordinal numbers can be a bit counterintuitive, e.g., even though 1+omega=omega, omega+1>omega. The cardinal number of the set of countable ordinal numbers is denoted aleph_1 (aleph-1).

Thus w is first transfinite ordinal, and all numbers feasibly reachable by +1 steps of succession from 0 will be finite and bounded by onward equally finite successors. Which is all that ordinary mathematical induction can reach. But the ellipsis of endlessness sets an impassable gulch to the far zone from w on. The tapes tell the tale:

Pink, with near end: |0 === . . . k, k+1 ====> . . . Blue, pulled in k and cut just before k, continuing on to RHS endlessly: |k, k+1 ====> . . . Both can be set in 1:1 correspondence, and pull in k and match can be endlessly repeated beyond case o as above. (I just used do k times to get to k*k rows pulled in.)

Where it is perhaps noteworthy that as Wolfram notes:

The first transfinite ordinal, denoted omega, is the order type of the set of nonnegative integers (Dauben 1990, p. 152; Moore 1982, p. viii; Rubin 1967, pp. 86 and 177; Suppes 1972, p. 128). This is the "smallest" of Cantor's transfinite numbers, defined to be the smallest ordinal number greater than the ordinal number of the whole numbers. Conway and Guy (1996) denote it with the notation omega={0,1,...|}.

The bar at end of the ellipsis of endlessness is then highly significant, and we could write: {0, 1, 2, … |} --> omega, omega+1, omega+2, …, omega+omega, omega+omega+1, …. To parallel with: 0, 1, 2, …, omega, omega+1, omega+2, …, omega+omega, omega+omega+1, …. Where the rows on the tapes now have a natural sense. Exploring further (I add: as the tapes are just that, continuous tapes with punched holes, so the issue of a continuum naturally arises . . . ), mild infinitesimal m --> 1/m --> A = w + g, beyond the span of the naturals and so also reals as usually conceived. Then m has neighbours such that descending from m to n we have 1/n --> B = w + (g +1), and as there is a continuum in [0,1] we can fit between m and n a range of mild infinitesimals that catapult to fill in the continuum between A and B. This is WLOG so it would make reasonable sense to suggest this as a continuum beyond the span of the naturals and reals, linked to infinitesimals close to 0 in the span [0,1], a continuum. Could this be a picture of the hyper real line emerging? (Though, I find the notion of a continuum [0,1] with infinitesimals near 0 that are effectively a gap of non reals, a bit troubling. I note, a practical definition is a number so small that m^2 ~ 0. That's how Engineers, Applied Scientists and Physicists treat them. {10^-300}^2 = 10^-600 after all which vanishes in additions dominated by order 10^-300. Of course suitable steps have to be taken to yield a particular value and not just its closely near neighbourhood, hence limit approaches.) That would for me be a reasonable conjecture of coherent utility suitable for modelling type approaches as opposed to setting out on a chain of proof from a set of axioms. No claims for truth are made, only pragmatic utility tied to unification of a range of things that apart from unification are puzzling in a cognitive sense. A tentative so far explanation, not a proof. A suggestion, it looks like this might help make sense of, not a claimed proof. And, obviously such a view fits with the primitive, primary sense of the infinite seen in say the arrow pointing on forever on axes of a graph of the Cartesian plane or the Argand Plane. At this stage I feel a much lessened sense of concern, regarding what I have been looking at. KF kairosfocus

Aleta, EZ & DS: I notice, a pattern that needs to address an underlying structure in Mathematical thought. For, there is a major shift of approach that happens when one moves to axiomatic systems. Such in effect set up abstract model worlds that may be fruitful but -- ever since the 1930,s -- face Godel's two point challenge. For no suitably complex system will we have both consistency and completeness, and there is not a constructive approach that guarantees consistency even at the price of limitations. Such is fundamental, and one of the implications is that test cases (in Mathematical contexts, often abstract thought exercises) are important. In the general area being disputed in the above thread, Russell's paradox on sets (and the illustration of the village Barber for whom as he shaved himself it was undecidable to assign him to the set choices shave self vs shaved by Barber leading to fatal ambiguity) forced reformulation. Similarly, Hilbert's Grand Hotel Infinity was a challenge to understand implications of the concept, infinity. A, I must note to you that you are resorting to refusing a given answer stated in the explicit context that there is a gap in views that can make simplistic y/n without explanation meaningless. I have put up the case of the pink/blue punch tapes running off endlessly precisely to put on the tape a primary, concrete case. In that on pulling in the blue tape any arbitrarily large but finite number of rows, k, the remaining tape from k, k+1 etc on can be put in 1:1 correspondence with the unshifted pink tape. Indeed, the exercise may be done k times over, each time j showing that the j-1th try has left the endlessness intact and so empowering an ordinary mathematical induction that any finite pull in does not terminate endlessness and so also the property of being infinite. By generally accepted principle, infinite sets of the relevant class can be put in 1:1 correspondence with proper subsets. Where, by definition of the tape, all along their length they have punched rows. Accordingly, it is hard to reject the point that there are spatially endlessly remote rows which duly have row-counts that are endlessly larger than any arbitrarily high but finite row value k. Which is the long way round to, these are infinitely far away. With appropriate row numbers. How does that fit with endless succession? That becomes an issue for paradox, as we see that ordinary mathematical induction starts with case-0 or 1 then adds a chaining pattern of implication and typically projects to all cases, pointing across an ellipsis of endlessness. My concern here is this point across is carrying all the weight of the conclusion, and a more conservative statement would be that all we can reach by finite stage, step by step processes will carry the stepwise propagated property. The point of the ellipsis of endlessness is in part that there is a far zone that cannot be spanned in finite stage successive steps. In particular, steps of +1. The two tapes illustrate in a thought exercise, how that result comes across. In the context of the various axioms, it has been pointed out above, that the set of axioms embeds stepwise processes that get to a potential infinity bridged by pointing across an ellipsis of endlessness. For convenience, Wiki discusses the Axiom of infinity:

In words, there is a set I (the set which is postulated to be infinite), such that the empty set is in I and such that whenever any x is a member of I, the set formed by taking the union of x [--> in context the succession from {} on thus far is in mind in a generalised case] with its singleton {x} [ --> this goes on to the next step] is also a member of I. Such a set is sometimes called an inductive set. This axiom is closely related to the von Neumann construction of the naturals in set theory, in which the successor of x is defined as x ? {x}. If x is a set, then it follows from the other axioms of set theory that this successor is also a uniquely defined set. Successors are used to define the usual set-theoretic encoding of the natural numbers. In this encoding, zero is the empty set: 0 = {}. The number 1 is the successor of 0: 1 = 0 U {0} = {} U {0} = {0}. Likewise, 2 is the successor of 1: 2 = 1 U {1} = {0} U {1} = {0,1}, and so on. A consequence of this definition is that every natural number is equal to the set of all preceding natural numbers. This construction forms the natural numbers. However, the other axioms are insufficient to prove the existence of the set of all natural numbers. Therefore its existence is taken as an axiom—the axiom of infinity. This axiom asserts that there is a set I that contains 0 and is closed under the operation of taking the successor; that is, for each element of I, the successor of that element is also in I. Thus the essence of the axiom is: There is a set, I, that includes all the natural numbers. The axiom of infinity is also one of the von Neumann–Bernays–Gödel axioms.

In short, there it lies, the potential infinity established by pointing across an ellipsis of endlessness. With von Neumann's construction closely embedded. The concern I have had, then is about that pointing across and its implication in cases like the two tapes. One import I see is that the effective definition of the successive counting sets deemed natural numbers makes that set to be the reachable by stepwise do forever successor process that cannot actually be completed due to endlessness. This sets up a paradox between finite stepwise process and endlessness. So now we come to labelling and giving values to rows in the tapes. For finite extension in steps that is not an issue. But the onward pointing to endlessness does raise an issue that is not resolved by saying ordinary induction takes them all in in one step. For, as the finite stepwise chain hits any k an endless succession always lies beyond. Bridging by an implicit sub axiom of pointing across an ellipsis of endlessness will be freighting that implicit step with the heavy lifting to reach the conclusion. Which leads to the point, why take that step? Or, is there not a difference between the primary sense of endlessness of succession and definitions and axiomatic steps that in effect lead to an infinite number/succession of finite, +1 stage separated values, leading to something like infinite finitude. Paradox, it appears. Rhetoric about denialism -- which is horrifically loaded with Holocaust denial -- does not help settle the matter. Nor does the notion, we do not dispute this, it is settled so there, only the ignorant, stupid, insane and/or wicked denialists would challenge the Consensus. EZ, I am looking at you here. And, A, right from the beginning, I have pointed to the primary sense of the infinite, the endless succession that lurks in the arrow we put on graph axes, origin, line of reals with wholes as milestones marked, arrow of endlessness. Whatever we find by way of axiomatic algebraic model or labels, that succession to endlessness beckons. This issue is not some vague mystery that I have been evasive about, I have asked, how can one find a reasonable answer as to how one rejects that an endless succession goes to a zone of endlessness, i.e. beyond finite bounds? And what does this primary, primitive sense have to say to our axiomatisation? To date, I find no satisfactory resolution. Given say the thought exercise of tapes, I cannot dismiss endlessness, and given the inherent finitude of deeply embedded stepwise +1 stage procedures of succession, joined to pointing across an ellipsis of endlessness, I cannot see that a model that converts the whole number succession into an infinite chain of the finites is less than paradoxical verging on outright contradiction. The finite is ended, the endless by definition is not. The endless tape exercise points to a far zone with onward succession not subject to spanning in +1 steps. How to capture that in reasonable terms seems unanswered. And EZ, motive mongering or how I came up with the idea of pink and blue paper punch tapes is of little value. In fact, as Turing tapes of endlessness were discussed and as coloured 3+5 punched paper computer tapes exist, it seemed reasonable to look at parallel tapes running off endlessly and to ponder in ways that are anchored to an intuitive, simple entity. Thought exercises and abstracted models thereof are commonplace in several linked fields. And there is Hilbert's hotel. Think of the tapes as the inspection report on the HH rooms if you will, a one- ascii character symbol denoting room condition. Matters not how they are marked, the point is here are the pink and blue tapes running endlessly to RHS from a zeroth row to begin with. With every row punched in some way. Patently, if stretched out with rows going off at 0.1 inch pitch, then if endless there is a remote endless zone just as there is a near ended, zero row neighbourhood zone. Concrete and readily represented, even turning glyphs into simple keyboard graphics: Pink, with near end: |0 === . . . k, k+1 ====> . . . Blue, pulled in k and cut just before k, continuing on to RHS endlessly: |k, k+1 ====> . . . Both can be set in 1:1 correspondence, and pull in k and match can be endlessly repeated beyond case o as above. (I just used do k times to get to k*k rows pulled in.) What mathematical language can we use to address that endlessness, resolving paradoxes? Obviously, one point is, the endless by the very force of that concept cannot be ended in actuality. (And that is not a dubious, dismissible worldview point, it is basic logic.) DS, BTW, a PA system vs chaining in sucession on Hilbert's Hotel brings out the difference between all at once setwide processes and inherently finite chained successive ones. I don't know about you but instantly on hearing of the hotel and what happens to provide room for fresh guests the issue is, how do you get the guests to all go to room 2n from room n? A PA system, with broadcast capability. By contrast with trying to propagate in a chain of steps. Infinite sets dealt with in steps run into the potential infinite then point across the ellipsis of endlessness issue. A broadcast system by contrast operates on the whole at once. And -- as fair comment given deteriorated tone at this point as you had exchanges just above -- it is a significant conceptual gap that you responded to that with an exclamation mark of dismissal. A, we can, broadcast, posit an endless tape with punched rows all along its length, as was done. Then that sets up the issue of stepwise processes vs the transfinite. That allows exploration; which lets us begin to identify the limitations of stepwise processes and to observe how such are embedded from the roots even in axioms. Is there anything inherently dubious in positing endlessness all at once, then thinking on how that relates to counting set based approaches? I think not. Where, of course, seeing the tape whole and not created by a do forever loop of succession gives a different perspective. Indeed moving to pointing across the ellipsis of endlessness is exactly a pulling back to the original single glance at the whole approach. So, where does this all come out? For me, it first makes me a lot more wary of discussions of the infinite and the mathematics connected therewith. I have a lot of sympathy for the non standard analysis approach. Hyper reals and infinitesimals. I am now much more wary of discussions of naturals and of reals. When trying to down count from the transfinite runs into headaches so easily, that is a warning flag. Tapes, think of a sprocket drive and read head in the far zone decrementing by 1s, -1 steps. Can it reach to a k-neighbourhood of 0 in steps? No, it would have to span endlessness. It can move from some start point and move a finite distance leftwards in steps but absent a definite start point it cannot arrive from the far right zone of endlessness, just as a similar drive and head at k cannot span in steps to the far zone. Where of course, easy to discuss concrete thought mechanisms force out things that are easily lost in forests of abstract symbols. That is why thought exercises can be very strategic. If we cannot readily resolve one, then that is a sign that we have not got the whole act together yet. At the same time, I have a much deeper appreciation for the force of Spitzer's point. Implicitly ending the endless on successive finite stages is an absurdity and fallacy. And, pointing to the tapes, there is need for an adequate discussion of endlessness as a whole not just do forever loops of the potentially infinite completed by pointing. KF PS: The LOGIC of necessary being and of ontological roots of a contingent world is a point in philosophy not theology. Indeed, it is antecedent conceptually. And the eternal is different from the temporal. The pink and blue tapes thought exercise rests on neither but on glorified common sense abstraction from very real computer technology of several decades past. kairosfocus

#511 daveS

Good points. I hadn’t thought how the tape model could reinforce these misconceptions, but I think I understand now.

I wouldn't worry about it, KF has an agenda and for various reasons he was bound to disagree with something somehow. If you check his own website stuff you'll see how he can mangle even straightforward mathematics. His motivations aren't about the mathematics but about what he can support with what he thinks he understands. #510 Aleta

A theological question: Does God need an ellipsis?

Well, if s/he/it is the alpha and omega, the beginning and the end then sometimes you must find a way to fill in the intermediate space! More seriously, it's we who need the ellpsii. Ellipsises? Whatever. But really they're just short hand for "and so on in the same fashion". Like much of mathematics, we replace thoughts and procedures with symbols 'cause they're easier to write down. Get your students to write out entirely in words a simple algebra problem sometime. ellazimm

Aleta, Good points. I hadn't thought how the tape model could reinforce these misconceptions, but I think I understand now. daveS

A theological question: Does God need an ellipsis? Aleta

No guilt, of course! But I do think the concrete nature of the tapes has helped fuel kf's confusion. As we discussed previously, the tape reinforces the idea that the natural numbers must be traversed one-by-one to come into existence, rather than already existing in their totality by virtue of the definitions. Concretely, there can be no endless tape in any material sense: the tape is endless in the sense that the process of unrolling it further can never stop, but thinking of a concrete thing being infinitely long conflates the metaphor with the abstraction. So I think the tape has been a confusing metaphor. Also, and I'll mention this now that the discussion is over, I also think a source of kf's confusion is that the beginning stimulus of the topic concerned time as a model for the natural numbers (the integers, actually.) Two problems with this: one is that we envision ourselves, or the world, as being in time, moving through it step by step, and that we see ourselves as only being able to move in one direction. So time, like the tape, emphasizes the view from any particular point rather than a mathematical view of the set as a whole. Ironically, what I am saying is that, rather than a view from inside the natural numbers, mathematically we have a "God's eye" view of the set as a whole, from outside the natural numbers. This is what Cantor did when he declared/created w and aleph null as transfinite numbers: he looked at the whole infinite set of natural numbers and began doing mathematics with its infinitude as a concept in and of itself. And, to perhaps further the irony, and the idea of a God's eye view, how would God see the natural numbers? Given that God is supposed to be outside of time, and infinite in scope, would he have any problem seeing that all the natural numbers were finite, and yet at the same time be able to see the entire infinite set of them? :-) Supposedly God can both see the world from any particular moment in time, now, and simultaneously see all moments of time: all the past and all the future. If he can handle that with the entire universe, surely he cold handle it with the natural numbers. P.S. This last point is of course not a real topic of conversation, but I think it is interesting to perhaps tie the topic of mathematical infinity to the speculative theological beliefs of kf and others here at UD. KF just wrote in the thread that Dave mentioned that "If a cosmos now is, something always was, a root of the reality we experience." So theologically kf is willing and seemingly able to accept the existence of an infinitude as a whole, from a God's eye point of view, in respect to "the root of reaity", but not so able mathematically when contemplating the infinitude of the set of finite natural numbers. Just some thoughts. Aleta

Aleta, IIRC, I am the one guilty of bringing in the Turing machine tapes, just because I thought they illustrated the Hilbert Hotel (and the set N) well. I also thought they would enable KF to understand our point of view, but unfortunately that didn't happen. I brought up the tapes sometime after KF made reference to the PA system (!) in the Hilbert Hotel, and I was looking for a way to strip away all the irrelevant implementation details. daveS

#506 daveS

Well, I don’t think you or ellazimm or I are having any difficulty with the tape, and I find their freeswinging origins arguments unpersuasive at best, but it’s an interesting contrast.

The only trouble I had with the tapes stuff was why it was introduced. I guess it was some example KF found and, in his usual copy-and-paste style he threw it in to make the discussion sound more . . . academic. I tend to stick with KISS myself when trying to explain complex things. Maybe he's used to being able to convince people by throwing wave after wave of hard to understand stuff and eventually they agree with him even if they really don't understand what he's talking about. Anyway, we seemed to have scared KF off. He hasn't been on UD at all since his last comment above. Maybe he's just busy. ellazimm

Aleta, I think you're right. I had a glimmer of hope when I read this from KF:

DS, My point is that there are endlessly more onward members than any specific finite value as proved not merely asserted.

but things seem to have reverted. After spending quite a bit of time in these threads, I found it interesting to look at this post, which begins:

Crimnologist and former atheist Mike Adams summarizes the three foundational philosophical alternatives to the Cosmos:

First, we can say that it came into being spontaneously – in other words, that it came to be without a cause. Second, we can say that it has always been. Third, we can posit some cause outside the physical universe to explain its existence.

We are here struggling to understand a paper tape (albeit infinite), and they are over there solving the origin of the cosmos. Well, I don't think you or ellazimm or I are having any difficulty with the tape, and I find their freeswinging origins arguments unpersuasive at best, but it's an interesting contrast. daveS

A parting shot: kf will not answer my direct questions, we know, so I am going to answer them for him. The issue is this: we claim all natural numbers are finite. kf does not agree this is so. We all agree that the set of natural numbers N is infinite. We agree that means that for any natural number k there are an endless, infinite number of further natural numbers. In fact it is this property - the fact that we can put any proper subset of the natural numbers in a 1:1 correspondence with the set of natural numbers itself, that is the characteristic that defines the infinite nature of the natural numbers. We all agree about all of the above paragraph. Now there are only two logical possibilities: A: Every natural number is finite, or B. There are natural numbers that are not finite. kf rejects A. Therefore, kf concludes B: there exists non-finite natural numbers. That is, he believes there is a least one, or more, numbers X which are greater than any finite natural number. This is consistent with his vague, unspecified language about "passing the ellipsis" into the "far zone", which is "infinitely far from" all finite natural numbers. This is what kf believes: he believes in the existence of non-finite natural numbers that are greater than any and all finite natural numbers. He believes in a kind of transfinite number within the set of natural numbers. For kf, N = {1, 2, 3, ... k, k + 1 (the finite naturals) ... the transfinite naturals} This is, I think, the inescapable conclusion to be reached from discussing this issue with him for quite a lengthy time. Aleta

Yep - more good points. I agree with all you say. Aleta

#499 Aleta

For what it’s worth, I’m a bit interested in my own psychology – why do I keep posting??? I’m sure I’m close to an end.

It is like a bag of Doritoes isn't it? You crave them and then when you eat too many you feel a bit ooky. I find the perpetual denialism, especially about things that are not in any way controversial, interesting and perplexing. It's a real insight into agenda driven thinking and cognitive biases. The whole culture is fascinating. ellazimm

This part of my post #501 needs correction, and conveys the opposite of what I meant:

There are many mathematical objects that cannot be constructed in a finite (or even countable!) number of steps. The real numbers are even worse.

For example, I mean in the Cauchy sequence version of the construction of R, you do not iterate through all (classes of) Cauchy sequences in Q one after another and build up R one element at a time, even though that might appear to be the case if you try to conceive if it as a looping process. The real proofs and constructions of such objects consist of a finite number of steps. daveS

KF,

Let that value be k, it can be attained from 0 in k steps, and exceeded in the k+1th. That can be seen for any arbitrarily large finite row number, but the problem is the tape goes on endlessly beyond that, by definition and with rows punched in all the way. Something we cannot attain to in steps.

Perhaps not, but who said it could? [Edit: I'm assuming beginningless processes are off the table here!] There are many mathematical objects that cannot be constructed in a finite (or even countable!) number of steps. The real numbers are even worse. Most mathematicians don't envision even the natural numbers as being constructed in a sequence of steps. There's the Axiom of Infinity, and that's that.

If the tape goes on endlessly beyond any arbitrarily large value (and that is required to retain 1:1 matching) then as the rows have a finite pitch of 0.1 inches, rows are not merely arbitrarily far apart. For, it seems that between the zone we can attain to in finite +1 steps and the far zone of endlessness there will be rows that are transfinitely far apart, endlessly far apart.

Specifically which rows are infinitely far apart? You have natural number labels for each row, so if this were the case, wouldn't you be able to name some of these rows? In the sentence: "Row 0 and row ____ are infinitely far apart", what number goes in the blank? In reality, there is just one "zone", consisting of all rows finitely distant from row 0. I don't follow most of the rest, but this:

And that means that w does not suddenly emerge as the follow on to any particular member but that it is emergent on pointing to endlessness as completing step. By use of the ellipsis. It is a conceptual leap on recognising endlessness.

seems at least partially correct. As we have seen, ω is not a successor to any ordinal. ω is not of the form α ∪ {α} for any other ordinal α. It is literally the union of all finite ordinals. Or, put another way, ω = N. daveS

to kf. I'll note that you repeat, again, all sorts of things you've said many times before. But you won't answer a simple and obvious question.

Is it true that one or the other of these must be true: either all natural numbers are finite or some natural numbers are not finite?

Aleta

All good points, EZ, and I too find the psychology interesting. I especially agree with you about the difference between pure mathematics and the task of modeling the world with mathematics - I've had some long conversations here about that before. For what it's worth, I'm a bit interested in my own psychology - why do I keep posting??? I'm sure I'm close to an end. Aleta

#491 Aleta

But I’ve enjoyed conversing with dave and ellazimm! :-) Thanks.

You are a star. With a lot more patience than me. I find the psychology of debates on this sight very interesting. You and I are used to being in an academic situation where you get things wrong at times. And we've learned to own up to our mistakes and move on. But if you're not used to that (and if you feel like you're besieged on all sides) then you can't afford to concede on anything. You're constantly afraid that any hole in the damn might become a flood that will drown you. I get that but, in this case, we are just talking about objective mathematics. I have no intention of wading into the question of the existence or non-existence of an infinite past for the universe. And the solution to that conundrum is a matter of using the correct model NOT the mathematics underlying the model. So KF's basic approach (attack the mathematics to uphold the world view) fails at the gate. And he's wrong about the mathematics as well. But he's in 'circle the wagons' mode. And his real 'battle' has nothing to do with mathematics. ellazimm

DS, The basic point is endlessness. In effect, pick any arbitrarily large value k, pull in the blue tape by k rows, k times. Every one of those k times the remaining tape will still match the unpulled tape 1:1, providing both are endless. That is the sets of rows on both tapes are infinite. The paradox I perceive comes in in claiming at the same time that EVERY row corresponds to a finite ordinal value. Let that value be k, it can be attained from 0 in k steps, and exceeded in the k+1th. That can be seen for any arbitrarily large finite row number, but the problem is the tape goes on endlessly beyond that, by definition and with rows punched in all the way. Something we cannot attain to in steps. Represented so innocently by three dots in an ellipsis. (And the one who, above, dismissed the use of y = 1/x as what I have called a catapult needs to look to the discussion of hyper reals and infinitesimals in nonstandard analysis. I just pick up another point, it seems there is little point in replying to every dismissal when given in such sharp terms.) If the tape goes on endlessly beyond any arbitrarily large value (and that is required to retain 1:1 matching) then as the rows have a finite pitch of 0.1 inches, rows are not merely arbitrarily far apart. For, it seems that between the zone we can attain to in finite +1 steps and the far zone of endlessness there will be rows that are transfinitely far apart, endlessly far apart. This does not seem to be consistent with the argument that as case 0 is finite and case-k being finite entails case-k+1 is finite, then ALL cases for rows will be finite in label and finitely remote. At minimum, there is a paradox there to be resolved. Or at least, that is how it seems. Next, it seems to me that inherently the sort of ordinary induction just outlined itself crucially relies on +1 step chaining and is subject at every step to the onward unreachable endlessness. Moving to the assumption that cases b less than a case a are all so entails case a for all a in A [as a new form of accumulation], with less than only implying a built in ordering relationship, then leads to the issue as to the span of A. (Is A finite or transfinite and if the latter does it necessarily enfold only finite members, or is there an implicit involvement of the transfinite in individual members? In effect, where do we close off the curly braces, and what does this entail when an ellipsis of endlessness is involved or implied? In the case, {0,1,2 . . . k, k+1, . . . [ellipsis of endlessness . . .]} that seems to entail order type w, cardinality aleph null and that assigning w [omega] to the whole {0,1,2 . . . k, k+1, . . . } --> w does not suddenly introduce a new property on the RHS. It is there on the LHS already. That is, the span is endless and implicitly, members in the far zone from 0 will hold endlessly large values. As, each member from 0 on in succession is the collection of the preceding members so endlessness of the whole will be attained by endless collection in particular members. The incrementally emergent set in effect self copies its members so far endlessly to create new members, until we point onward from the potentially infinite to the whole and somehow symbolise the whole. At least, that is how it looks. And that means that w does not suddenly emerge as the follow on to any particular member but that it is emergent on pointing to endlessness as completing step. By use of the ellipsis. It is a conceptual leap on recognising endlessness. At least, again, that is how it looks.) That is how it looks, not a happy picture [e.g. a set incrementally swallowing itself like the proverbial snake to emerge anew as extended to successor is instantly uncomfortable as we look to the set as a whole endlessly continued], but that is the picture I see. KF kairosfocus

Aleta, There is a logical issue at stake, and when you and DS asked me about it, I replied in logical terms. Cf 487 - 8 & 492. KF PS: Let me borrow from 497 below:

If the tape goes on endlessly beyond any arbitrarily large value (and that is required to retain 1:1 matching) then as the rows have a finite pitch of 0.1 inches, rows are not merely arbitrarily far apart. For, it seems that between the zone we can attain to in finite +1 steps and the far zone of endlessness there will be rows that are transfinitely far apart, endlessly far apart. This does not seem to be consistent with the argument that as case 0 is finite and case-k being finite entails case-k+1 is finite, then ALL cases for rows will be finite in label and finitely remote. At minimum, there is a paradox there to be resolved. Or at least, that is how it seems. Next, it seems to me that inherently the sort of ordinary induction just outlined itself crucially relies on +1 step chaining and is subject at every step to the onward unreachable endlessness. Moving to the assumption that cases b less than a case a are all so entails case a for all a in A [as a new form of accumulation], with less than only implying a built in ordering relationship, then leads to the issue as to the span of A. (Is A finite or transfinite and if the latter does it necessarily enfold only finite members, or is there an implicit involvement of the transfinite in individual members? In effect, where do we close off the curly braces, and what does this entail when an ellipsis of endlessness is involved or implied?

kairosfocus

kf has several times written whole posts about the importance of basic logic as a foundation for right reason. And yet, when faced with a simple logical statement (either all natural numbers are finite or some natural numbers are not finite), he refuses to address it. This has nothing to do with red and blue tapes, or with the fact that we all agree that there is an endless number of natural numbers past any particular finite number k, or about authority. This is just, as kf says, about logic and structure. Address the logic, kf! Is it true that one or the other of these must be true: either all natural numbers are finite or some natural numbers are not finite? Stay true to your principles here and address the logic. Aleta

KF, I'm getting lost in that italicized sentence. It might be helpful to list the assumptions, one by one, which supposedly lead to a contradiction. For example: 1) The tape is endless (that is, infinite). 2) The rows are each labeled with finite natural numbers in increasing order (so row 0, row 1, row 2, etc). 3) The "span" of the tape is endless (?) I don't really know what this means, other than there are rows in the tape arbitrarily far apart. For example, there are rows 10^150 inches apart. There are also rows 10^150^150 inches apart. There are rows any finite number of inches apart. And so on. daveS

re 490: I am appealing to logic, and kf is failing. See 484. Aleta

Folks, I again simply point to the tapes thought exercise. If every value for the number of a row in the succession in the endless tapes is finite, the value will necessarily be some k (i.e. kth row), exceeded by k+1 and achieved in k increments of 0.1 inches. This finite value cannot be endless, being completed in k steps and then bounded and exceeded by k+1. How then is the span of the tape with rows every 0.1 inches along its length in succession from row 0, endless, apart from that for any finite k, there will be k+1, etc onward without limit, and by limitlessness violating the claim that every value corresponding to a natural number in the sequence 0, 1, 2 . . . without end is finite? And no I am not pretending to be cleverer than all Mathematicians etc, I am asking how is an apparent paradox to be resolved without falling into contradiction? KF kairosfocus

I give up also. See my post at 462 where I summarize the ways in which kf avoids specificity, repeats things we agree on, and will not answer direct questions that would help us understand what he means (such as a very simple question at 484). But I've enjoyed conversing with dave and ellazimm! :-) Thanks. Aleta

EZ & Aleta: (& DS, attn HRUN . . . who needs to learn what has been pointed out several times but studiously ignored: that Mathematics sometimes advances by challenging the consensus so appeal to authority rather than the logic of structure and quantity, fails . . .),

kf, I actually understand perfectly well and you just reaffirmed it. You are right and DS is wrong. And if math disagrees with you it is obviously wrong as well. There is no appeal to authority, just a description of the situation from your point of view. hrun0815

KF,

DS, I am trying to see how it can be reasonably concluded that there are infinitely many finite natural numbers. The two tapes thought exercise is in that specific context. To my sense, it would seem hard to avoid that every finite k is reachable in k finite steps and is exceeded on the k+1 step, so no span from 0 of finite stages in cumulative succession can be transfinite, can end the endless.

The Turing Machine tape is an excellent thought experiment. And yes, it is true that every finite k is reachable in k finite steps. It is also true that no "span" from 0 consisting of finitely many steps can be transfinite. In other words, {0, 1, 2, ..., k} is always a finite set.

Therefore I incline that the sets of ordered counting sets in endless succession should reach a zone which each member will itself be endless.

I don't know why this would be necessary. The collection of finite "counting sets" is "endless", no?

I could see with the naturals being defined on an unending succession of finite steps where every number actually attainable in finite-stage increments to k number of steps will be finite [where k may be arbitrarily large but not transfinite], but that points beyond to the endlessness. KF

Yes, the first part describes the natural numbers accurately. In fact, the Peano axioms specify that each natural number is obtainable by applying the successor operation to 0 finitely many times, so you cannot generate any members of N at infinite distance from 0. daveS

DS, I am trying to see how it can be reasonably concluded that there are infinitely many finite natural numbers. The two tapes thought exercise is in that specific context. To my sense, it would seem hard to avoid that every finite k is reachable in k finite steps and is exceeded on the k+1 step, so no span from 0 of finite stages in cumulative succession can be transfinite, can end the endless. Therefore I incline that the sets of ordered counting sets in endless succession should reach a zone which each member will itself be endless. What such is labelled or classified as is secondary. I could see with the naturals being defined on an unending succession of finite steps where every number actually attainable in finite-stage increments to k number of steps will be finite [where k may be arbitrarily large but not transfinite], but that points beyond to the endlessness. KF kairosfocus

EZ, again is or is not each tape receding to the endlessly remote. If not the tape is finite. If it is, it is infinite and there will be rows infinitely remote. Infinite in the primary sense. These cannot be reached by any cumulative process of finite stage steps but on attaining the potentially infinite we may point to the endlessly remote zone. As is routinely done in practical mathematics. A look at the ordinary mathematical induction shows that it embraces a do forever loop in steps from case k to k+1 in succession. Also, when we look at the set of natural counting sets in succession we see: {} --> 0 {0} --> 1 {0,1} --> 2 . . . or, {0,1, 2 . . . k, k+1 . . . Ellipsis of endlessness . . . } That is there is a span of endlessness within the set, which by definition cannot be bridged in finite steps. That's where I would expect to find a far zone that is ideally there but cannot be finitely attained to in steps. Where for every finite k, regardless of how large, k is bounded by k+1 and is finite and attainable in k +1 increments from 0. The ordinary induction on case 0 or case 1 and the chaining principle Case-k => case-k+1, is inherently finite though open ended. Whatever model we need to account for our tape as a thought exercise needs to account for these phenomena. And sorry, this is mathematics, appeals to modesty in the face of collective authority are not enough. There is a thought exercise on the table, close to the traditional Turing Machine. We need a reasonable scheme that adequately accounts for an endless tape that recedes from row 0 to the RHS with rows of holes all the way. Actually, two, one pink, one blue. The blue is pulled in k rows, k times over. Due to endlessness, at each k-pull, it must still match pink 1:1 because of endlessness. Which entails that there are infinitely many rows, accumulating at 0.1 inch per row to the RHS: |0, 1, 2 === . . . k, k+1 [finite values] . . . ===> . . . |k, k+1 [finite values] . . . ===> . . . (matching 1:1) KF kairosfocus

Aleta,

3. So either, by force of logic, every one of the infinite number of natural numbers in N is finite (our position), or there are numbers in N which are not finite (which seems to be your position.) Which is it, then: is every natural number of finite, or are there numbers in N that are not finite.

By the rules of right reason, as a matter of fact! :-) Surely KF cannot avoid answering this question? daveS

#483 KF

Note my concern is pivoting around the claim there is an infinite number of finitely large natural numbers, where any finite k — ponder the tape to see why — will not be transfinitely remote, endlessly remote; k* 0.1 inches will be exceeded and bounded by (k+1)*0.1 inches and so forth on a do forever. Any finite k can be arrived at in k finite steps of +1 from 0, then exceeded in the next step, with +1 here going at the rate of 0.1 inches per step. This is the context in which I looked again at what say ordinary mathematical induction actually shows, and what is entailed by the apparent pattern of do forever loops starting in axioms, and the commonplace ellipsis of endlessness.

I give up. You've got some issue that I can't discern which is throwing up a roadblock. Please feel free to stand in opposition to well established mathematics. Because you are not a research mathematician it probably doesn't matter anyway. If you're teaching students then I do worry but I can't do anything about it. ellazimm

Again, you repeat something we agree with: Where beyond any arbitrary finite k, however large (I picked 10^150 and 300, the square of that, to give and idea of what I am saying), there will be endlessly more rows. That is, for any arbitrary finite k, there are an infinite number of further natural numbers greater than k. WE AGREE WITH THIS!!! Do you get that!!! WHY DO YOU KEEP REPEATING THIS??? If all you mean by "remote zone" is this fact, that there will always be an infinite number of further numbers, then you are not saying anything that we don't all know. But what you are NOT doing is responding to a simple argument: 1. The set of natural numbers N is an infinite set. 2. Every specific natural number k is finite. 3. So either, by force of logic, every one of the infinite number of natural numbers in N is finite (our position), or there are numbers in N which are not finite (which seems to be your position.) Which is it, then: is every natural number of finite, or are there numbers in N that are not finite. Aleta

Aleta, the issue is the tape, always the tape. If we cannot satisfactorily model something as simple as the thought exercise of an endless punch paper tape, we do not genuinely understand yet. This includes that we must be able to speak to the zone that is far away receding endlessly from us, with punched holes in it. Where beyond any arbitrary finite k, however large (I picked 10^150 and 300, the square of that, to give and idea of what I am saying), there will be endlessly more rows. Such that we may pull in k, and do so k times and yet still there is going to be endless tape remaining yet ahead such that the remainder may be matched 1:1 with the un-pulled tape next to it. And pardon me but the term I used is not meant to suggest hidden agendas and ideological threats or stratagems, only that terms are freighted -- is that less suggestive? -- with perceptions and contexts. The issue is I think there is a paradigms issue here. KF PS: Note my concern is pivoting around the claim there is an infinite number of finitely large natural numbers, where any finite k -- ponder the tape to see why -- will not be transfinitely remote, endlessly remote; k* 0.1 inches will be exceeded and bounded by (k+1)*0.1 inches and so forth on a do forever. Any finite k can be arrived at in k finite steps of +1 from 0, then exceeded in the next step, with +1 here going at the rate of 0.1 inches per step. This is the context in which I looked again at what say ordinary mathematical induction actually shows, and what is entailed by the apparent pattern of do forever loops starting in axioms, and the commonplace ellipsis of endlessness. kairosfocus

#480 KF You forgot to mention Newton and Liebniz. Aside from the 18th century disagreement I am not familiar with, the rest of your examples have been vigorously argued over and discussed but no one was persecuted or ostracised with the possible exception of Cantor. I would argue that Cantor had other problems which made it harder for him to deal with the academic animosity his ideas created. Make no mistake, what Cantor proposed was incredibly radical and such ideas have to be tested in the fires of scrutiny. As they should. He made an extra-ordinary claim which required extra-ordinary proof and some time to sink in. Now his ideas are not controversial. And I think you've erroneously thrown in Godel's incompleteness theorem which is not the mathematical equivalent of Heisenberg's uncertainty principle. Of course there are some gaps and controversies but these days a) they are worked out in a collegiate fashion and b) what we are discussing with you is not controversial any more. Just listing some of the past 'controversies' does not prove your point that issues are 'loaded'. It just means that people disagree usually for very good reasons. In mathematics the 'battleground' is now purely intellectual and academic. The only 'loading' is egotistical. No one is marginalising others, no one is being forced out of academic positions, no one is being stifled or bullied. My point is that using the term 'loaded' is inaccurate. Our disagreement with you is purely mathematical. There's no call to add a layer of manipulation or menace. ellazimm

so, kf, you agree with this statement (which is an attempt to put into more precise mathematical language whta you are saying:) “there exists a number X (or numbers) in the set of natural numbers such that for every natural number k, X is greater than k. In such case, X would then be a number in the “transfinitely remote zone”, and would be an example of a natural number that is not finite.” Aleta

EZ, if you think that there are not loaded issues in Math then you know little of the relevant history. Was it 20 years ago a suit from C18 was settled between families of two mathematicians? In this field cf Hilbert et al vs Cantor, and the issues Cantor had with others also. In the mix put Russell's paradox and the import of the setting up of ZFC. Toss in Godel on incompleteness for good measure. What I am saying is there are some concept gaps and that is why I use the thought exercise of punched tape to focus issues concretely. And it is why I put up an algorithm at 217. KF kairosfocus

Aleta, further to this, the conditions set up that there are endlessly remote cells in a zone beyond any finitely remote k no matter how large. If we set up a scheme that cannot accept and comfortably digest this primary sense of the infinite, something is deeply in need of rethinking. Especially as we can show the significance of k, k+1 etc by putting the blue tape onward from row k in 1:1 correspondence endlessly with the unmoved pink tape from 0, 1, 2 etc. This helps make my concerns concrete. KF kairosfocus

Yes, we agree on this: for any natural number k there is an infinite number of natural numbers greater than k. That is what it means to say the set is infinite. "Simply pointing" to this is just a restatement of something we all agree on. I don't think you need to keep repeating this. What is not clear is your beliefs about points 4 and 5 in post 471: Are all natural numbers finite? You claim this is not true. Or do you believe, as 5 says, that "there exists a number X (or numbers) in the set of natural numbers such that for every natural number k, X is greater than k. In such case, X would then be a number in the “transfinitely remote zone”, and would be an example of a natural number that is not finite." If all natural numbers are not finite, you seem to be claiming that there are natural numbers that are something other than finite. Please explain that in more precise language. Aleta

Aleta, I simply point to the two tapes, with rows endlessly beyond any row that is finitely beyond the near end. Infinity, primary sense. At least, a break from tax day here. KF kairosfocus

KF,

DS, My point is that there are endlessly more onward members than any specific finite value as proved not merely asserted.

The question was not whether this statement is proved or assumed. The question was which of my two statements in #419 you were making. Finally it appears that you are clearly stating #1, which comes as a surprise to me. Just a couple of days ago, I said I was 80% sure you were making statement #2.

And in a context where symbols are loaded, answering y/n to a loaded question is not sensible.

Well, as you have now clarified that it's 1 and not 2, it appears that it was/is sensible in this case to ask for yes/no answers.

If you cannot see why there are endlessly remote rows of the sequence beyond any finite k no matter how large on the primary sense of infinite, then there is a problem.

Pardon, but the problem was your lack of clarity, not my understanding. And despite your slipping back into ambiguity, I will interpret this sentence as again affirming 1 and not 2. *** Now that we have settled that, let's observe that statement 1 is consistent with the proposition that all natural numbers are finite. And of course that each cell C in the infinite Turing Machine tape is finitely many steps from cell 0. daveS

473 Aleta

kf accepts that N is an infinite set, and that w and aleph null are names for the transfinite ordinal and cardinal numbers associated with N. He also accepts that w is not a number within N, but rather a number about N: the number of natural numbers within N. By accepting w, he obviously accepts that there are an infinite number of natural numbers.

Are you sure he accepts that? Because he seems to think he can all of a sudden take another step and get to the infinites. I think he's mixed up about what well ordered means. Anyway, we're not going to change his mind so it's probably time to quit. ellazimm

#470 KF

And in a context where symbols are loaded, answering y/n to a loaded question is not sensible. The difference in context has to be explained. And that is in part why I am looking to the concrete case to illustrate many features of the problem.

It's mathematics, symbols aren't 'loaded'. This isn't an ideological disagreement. You're just being asked a question which you can give a yes or no answer to. 472 KF Yes, I know what ordinal numbers are! You can be very, very patronising at times. You don't get to the first ordinal number by counting up from 0 in steps of one!! Just because the set of ordinals is well ordered doesn't mean you can get from the finites to the infinites in a step-wise fashion!! There are an infinite number of whole numbers before you get to omega so you can't get there by counting! Neither can you get there via getting step-wise smaller and smaller. Again: omega is larger than any particular whole number but you can't climb the staircase of whole numbers and suddenly step onto an infinite step. It doesn't work that way. Every whole number has another whole number 1 bigger than it. Every step up lands you on another finite step and you CAN count how many steps it took to get there. This is not context driven or 'loaded'. Either you get it or you don't. Not everyone gets it and there's no shame in that. I don't 'get' Donald Trump or Kim Kardashian, they're both just so much gobbly-gook to me. ellazimm

Hi EZ. This sequence has very little to do with the issues about the natural numbers. kf accepts that N is an infinite set, and that w and aleph null are names for the transfinite ordinal and cardinal numbers associated with N. He also accepts that w is not a number within N, but rather a number about N: the number of natural numbers within N. By accepting w, he obviously accepts that there are an infinite number of natural numbers. That's about all you need to know from previous posts in respect to the current discussion about the natural numbers. Aleta

EZ, I am actually busy, but will say this much, it would be wise to read the thread above before jumping in to comment. If you do, you will see the point of surprise when the Wolfram listing of the succession of ordinals appears; I set apart the list and bold it:

http://mathworld.wolfram.com/OrdinalNumber.html In formal set theory, an ordinal number (sometimes simply called an "ordinal" for short) is one of the numbers in Georg Cantor's extension of the whole numbers. An ordinal number is defined as the order type of a well ordered set (Dauben 1990, p. 199; Moore 1982, p. 52; Suppes 1972, p. 129). Finite ordinal numbers are commonly denoted using arabic numerals, while transfinite ordinals are denoted using lower case Greek letters. It is easy to see that every finite totally ordered set is well ordered. Any two totally ordered sets with k elements (for k a nonnegative integer) are order isomorphic, and therefore have the same order type (which is also an ordinal number). The ordinals for finite sets are denoted 0, 1, 2, 3, ..., i.e., the integers one less than the corresponding nonnegative integers. The first transfinite ordinal, denoted omega, is the order type of the set of nonnegative integers (Dauben 1990, p. 152; Moore 1982, p. viii; Rubin 1967, pp. 86 and 177; Suppes 1972, p. 128). This is the "smallest" of Cantor's transfinite numbers, defined to be the smallest ordinal number greater than the ordinal number of the whole numbers. Conway and Guy (1996) denote it with the notation omega={0,1,...|}. From the definition of ordinal comparison, it follows that the ordinal numbers are a well ordered set. In order of increasing size, the ordinal numbers are 0, 1, 2, ..., omega, omega+1, omega+2, ..., omega+omega, omega+omega+1, .... The notation of ordinal numbers can be a bit counterintuitive, e.g., even though 1+omega=omega, omega+1>omega. The cardinal number of the set of countable ordinal numbers is denoted aleph_1 (aleph-1).

I trust this will be enough to give some pause in the rush to dismissive judgement. KF kairosfocus

In kf's long repeat of things said many times before, and of things we agree about, such as the endless nature of the natural numbers, he says,

So, ordinary induction shows that we can chain a conclusion in a do forever, but always finite loop. It will be reliable for any finite value, but to point across the infinite endless ellipsis and conclude all natural numbers are finite is tantamount to saying that the endless tapes are endless but have only finitely remote points. But beyond ANY finite value no matter how high, there is an endless continuation. That endlessness does not vanish into finitude, it is there, and by force of logic there is a remote zone beyond any arbitrarily large but finite row number. One that we can in effect secondarily model as transfinitely remote.

This encapsulates the confusion. We all agree that there are are an infinite, endless number of further natural numbers past any arbitrarily large specific natural number k. However, I'm thinking the concrete metaphor of "endless tape" is perhaps confusing things, because there could be no real endless anything. I think we all understand well enough to couch things in strictly mathematical terms. We all agree, I think, that

1. The set of natural numbers is infinite (the tape is "endless"), the primary reason being that it can be put in a 1:1 correspondence with proper subsets of itself. 2. For any natural number k, there are an infinite number of further natural numbers greater than k. ("beyond ANY finite value no matter how high, there is an endless continuation") 3. Any particular natural number k is finite.

Here's where we disagree: kf says, that to conclude that "all natural numbers are finite is tantamount to saying that the endless tapes are endless but have only finitely remote points", and he rejects this conclusion. However, this is the conclusion we hold. Adding to statements 1, 2, and 3, above, we add

4. All natural numbers are finite.

Instead, kf says

by force of logic there is a remote zone beyond any arbitrarily large but finite row number. One that we can in effect secondarily model as transfinitely remote.

Now one can interpret this in two ways. If he means that for every k there are an infinite number of further natural numbers greater than k, then he is merely repeating point 2 above. However, he seems to mean something more. In Dave's language (minus the tape metaphor) kf seems to be asserting that 5. There exists a number X (or numbers) in the set of natural numbers such that for every natural number k, X is greater than k. X would then be a number in the "transfinitely remote zone", and would be an example of a natural number that is not finite. Given that kf says his conclusion follows by "force of logic", it would be appropriate to focus on simple statements such as I have presented in order to follow his logic. So, simple question to kf. Does statement 5 adequately represent, in mathematical language, what you mean when you say "there is a remote zone beyond any arbitrarily large but finite row number. One that we can in effect secondarily model as transfinitely remote." Aleta

DS, My point is that there are endlessly more onward members than any specific finite value as proved not merely asserted. Just one more is not enough. And in a context where symbols are loaded, answering y/n to a loaded question is not sensible. The difference in context has to be explained. And that is in part why I am looking to the concrete case to illustrate many features of the problem. If you cannot see why there are endlessly remote rows of the sequence beyond any finite k no matter how large on the primary sense of infinite, then there is a problem. Long before we parse: for all n there exists . . . and get into debates on the existential import of all vs there is at least one etc. Which goes all the way back to the issue that, suitably understood, there is validity yet to the classic square of opposition, cf the discussion at SEP. KF kairosfocus

466 KF This

0,1, 2 . . . k, k+1, . . . [Ellipsis of endlessness] . . . w, w+1, w+2 . . . w+g . . . [ mount on up to epsilon-zero etc]

is just non-sensical. You don't cross a line and get infinite values when counting up naturals one at a time. "mount on up to epsilon-zero, etc"? What? Followed by

where the interval (0,1) — open — can for contemplation be catapulted in to fill in between w and w+1 etc using mild enough infinitesimals and the 1/x hyp function, at least as an exploratory model. This seems to allow unification of the transfinite zone, at least as a suggestion to be looked at.

makes no sense either.

A key issue is the nature of ordinary mathematical induction which sets up a case 0 or 1 then hangs the chaining implication C-k => C-k+1, and infers therefrom to all cases in succession. Or sometimes the all in succession is presented as simply all cases. What actually is entailed operationally is a do forever successively incremented loop with finite stage increments. The implication with a running range stepping k to k+1 and hanging on a first case entails that. So, at some stage we have an ellipsis of endlessness and we point across what we cannot actually span in steps.

See, you have this notion that all of a sudden you're going to traipse into the infinite when incrementing step-by-step. And that just doesn't happen. As you've been told over and over.

In this context, when I hear complaints oh you are vague, I see that as such is given in the face of specific cases, explanations and terms, we are dealing with conceptual gaps that reflect a break between paradigms.

It would help if you used the accepted mathematical paradigm instead of interpreting it in your own way!!

What we have is that in the near, infinitesimal neighbourhood of 0, there is a cloud of values that by using y = 1/x as a hyperbolic catapult, can be projected to a transfinite, hyper real zone, including mile posts at whole number values. And by simple addition, such an infinitesimal cloud can be shifted to the neighbourhood of any particular value we please.

What? I'm sorry but your use of terms, your misinterpretations of common, accepted mathematical concepts, constructs and procedures and your inability to answer daveS's question after repeatedly being asked to do so makes this discussion extremely frustrating. I get that you think that either gradually getting bigger or gradually getting smaller eventually 'catapults' you into the 'transfinite' but that is just not true. Sets can be infinite, values arrived at by stepwise increments are not. If you want to deal with hyper-real numbers then you'd best do so properly and using standard arguments and notation. ellazimm

KF, All that typing, even including a PS on logical matters, but you still refuse to tell us which of:

1) ∀ n ∃ C P(C, n) 2) ∃ C ∀ n P(C, n)

you subscribe to! I was going to address some of your claims in #466, but it's so full of misconceptions, that's an overwhelming task. Sorry KF, it really is. Maybe I'll chime in later, but for now I'll leave it for others to respond to. daveS

Captcha has gone to images now! kairosfocus

EZ & Aleta: (& DS, attn HRUN . . . who needs to learn what has been pointed out several times but studiously ignored: that Mathematics sometimes advances by challenging the consensus so appeal to authority rather than the logic of structure and quantity, fails . . .), It seems I need to explain my perspective, providing my own summary of why I have concerns with the way the transfinite [Cantor's term of choice] has been discussed and operationally used. As a preliminary, please read 215 - 217 above . . . esp 217, and then . . . First, it is clear that this thread has long since established the main point in the OP, that there is a major problem in positing an endless past leading up to the present. Traversing the endless and completing such a traverse in finite stage steps is futile. Appealing to what is tantamount to it, is a fallacy. That's Spitzer's point in a nutshell. He is right, to end the endless is a self contradiction on the level of a square circle. The criteria for the one cannot be met while meeting the criteria for the other. And, the pink vs blue punch paper tape examples with rows of 5 +3 bit cells at 0.1 inch pitch make this issue concrete. Once the number of rows is endless, being punched into the tape all along its run, we can never advance to traverse the endless in finite stages. Run along the sprocket-holes sufficiently to get to ANY finite k, however large, and we face the problem that thereafter -- exactly because the tape runs on endlessly to the right hand side for convenience -- rows k, k+1 etc can be put into 1:1 correspondence with the un-moved but equally endless pink tape from rows 0, 1 etc. Endlessness is pivotal, and it provides an operational definition of what it means for the ordinal sequence of counting sets or numbers to run on without end and be transfinite. Let me illustrate for tapes: |0, 1, 2 === . . . k, k+1 [finite values] . . . ===> . . . |k, k+1 [finite values] . . . ===> . . . (matching 1:1) as well as for the set: {0,1, 2 . . . k, k+1, . . . } with w etc as successor in the transfinite zone: {0,1, 2 . . . k, k+1, . . . } --> w, w+1, w+2 . . . w+g . . . [ mount on up to epsilon-zero etc] [I quietly note on the surprise well above when the legitimacy of that continuation was pointed out: 0,1, 2 . . . k, k+1, . . . [Ellipsis of endlessness] . . . w, w+1, w+2 . . . w+g . . . [ mount on up to epsilon-zero etc] where the interval (0,1) -- open -- can for contemplation be catapulted in to fill in between w and w+1 etc using mild enough infinitesimals and the 1/x hyp function, at least as an exploratory model. This seems to allow unification of the transfinite zone, at least as a suggestion to be looked at. To see what this implies for descending from an endless past, simply reverse the tape. By logic, the same span now runs off to the LHS, and if the span cannot be traversed in 0.1 inch steps one way, it cannot be traversed the other way either. There is a major problem with worldviews that either have to pull a world out of non-being or else have to pull a world out of an endless, transfinite past to get to the present. In the course of such an issue being on the table, questions on the natural numbers and the claim that their span is transfinite but every particular natural number is finite and bounded came up. This has seemed at minimum paradoxical to me and much of the thread has circulated around this matter. A key issue is the nature of ordinary mathematical induction which sets up a case 0 or 1 then hangs the chaining implication C-k => C-k+1, and infers therefrom to all cases in succession. Or sometimes the all in succession is presented as simply all cases. What actually is entailed operationally is a do forever successively incremented loop with finite stage increments. The implication with a running range stepping k to k+1 and hanging on a first case entails that. So, at some stage we have an ellipsis of endlessness and we point across what we cannot actually span in steps. So, a lot hangs on the ellipsis of endlessness and the sub axiom of (often implicitly) pointing across it even though we may not span it in finite increment steps. And BTW, strictly, a sequence converging to a finite limit that is infinite is never actually completed absent "case infinity," it just converges closer and closer so it is useful to recognise that this never actually completes an endless process either. The moreso if the trend to the infinitesimal steps is such that the relevant series diverges, i.e. the set -- sequence -- of successive partial sums will at some stage exceed any arbitrarily large but finite value and thereafter will be forever beyond it, or else will oscillate without converging as does the sequence [-1]^n. Pointing across an ellipsis of endlessness is pervasive in modern mathematical praxis. So, long since it has been pointed out that there is a major difference between a sequence that is convergent on going to infinitesimal increments that beyond some member will always be within a delta neighbourhood of a limit, and one that diverges by increasing in finite stages, stepwise without limit so that it goes to endlessly large values. Zeno's paradoxes and kin have been off the table from the beginning. And it is relevant that the place value notation system is a disguised power series that goes on to endlessness, whether the focus is the fractional part or the whole number part. In this context, when I hear complaints oh you are vague, I see that as such is given in the face of specific cases, explanations and terms, we are dealing with conceptual gaps that reflect a break between paradigms. I was raised mathematically in a world of the primary infinite, where one points to the RHS or the LHS of the line of reals on a graph paper with arrow heads to indicate ranging on endlessly. I was raised on curve sketching where asymptotes approach a limit line and value endlessly but never touch. I was raised on sequences of partial sums that converge within delta neighbourhoods as they move to a limit. I was raised on differentiation from first principles and the limit approach, finding that the nonstandard analysis makes sense of infinitesimals. Except for some odd sounding claims on hyper reals and infinitesimals as in effect beyond the real range. In that context the infinite as what goes on endlessly is a primitive, a first point of reference. And, whole numbers, counting numbers, come up as uniformly separated mileposts on the real line, often marked in graphs with hash lines. We can go back and model the succession of sets per von Neumann, from {} --> 0 to {0} --> 1 etc, and go to rationals, reals and a complex plane, as models that go from [co-ordinate] geometry to algebra in effect. We may systematise and deduce, but when the algebraic transfinite clashes with the infinite in the primary sense, some warning flags will trip. And I see the adroitness in speaking of hyper reals as beyond reals: we have a separate model that works around the problems. Never mind, [0,1] is a CLOSED interval on the line of reals, going back to good old Allendoerfer and Oakley. So, any value, any point in the interval will be a real, filled in by using the power series endlessness of fractional place value notation. What we have is that in the near, infinitesimal neighbourhood of 0, there is a cloud of values that by using y = 1/x as a hyperbolic catapult, can be projected to a transfinite, hyper real zone, including mile posts at whole number values. And by simple addition, such an infinitesimal cloud can be shifted to the neighbourhood of any particular value we please. That is the context in which I spoke of a mild infinitesimal m being catapulted to a mile marker A in the trans finite zone across a sahara of the ellipsis of endlessness. Then, I applied a milepost by milepost down count that brings to bear the challenge of spanning the endless to reach a finitely near neighbourhood of zero. The span the endless in finite stage steps challenge kills that. For me at least, this gives some teeth to the claim that one cannot span an infinite actual past to arrive at the present. Of curse such was challenged, as all naturals are finite. That is the context in which the onward span to w, w+1 etc came in and A was identified as w + g, g a large finite value. Take it as a model that seeks at minimum to find a what if unification of what is patently a divergent cluster of models on the transfinite. Hyper reals beyond the reals, all naturals are finite but the set as a whole is transfinite and whatnot. The problem pivots on the case of the naturals. That is where pink punch paper tape vs blue comes in. By definition, endless and punched every 1/10 inch. From the near end off to an endless RHS. Think, endless cycles of 1 to 255. By the logic of endlessness, there are rows in succession all along the tape and some will be in an endlessly remote zone off to the RHS. That is, for any arbitrarily large but finite k, there will be endlessly more onward rows, receding into a zone of the endlessly remote. So, if we pull in blue k rows, k, k+1 etc can be put into 1:1 correspondence with the un-moved pink tape, endlessly. And we can do the same on a do forever loop without changing the result. That is the operational, primary meaning of infinite. On that logic, there is a transfinitely remote/distant zone of the two tapes in which that endlessness is found, an endlessness that cannot be traversed, as it has no upper END, it is utterly unbounded. Zone is vague, but it is better to be roughly right than to be exactly wrong. That's Kelvin IIRC. As to what it means for there to be endlessly more rows beyond any finite k, that put k on in 1:1 correspondence with the pink tape suffices. And no, it is not just that k has k+1 beyond it, the endlessness represented by that innocuous seeming three dot ellipsis is pivotal. And, we are forever implicitly pointing across it, implying do forever loops that cannot arrive at an actual completion at the transfinite. So, ordinary induction shows that we can chain a conclusion in a do forever, but always finite loop. It will be reliable for any finite value, but to point across the infinite endless ellipsis and conclude all natural numbers are finite is tantamount to saying that the endless tapes are endless but have only finitely remote points. But beyond ANY finite value no matter how high, there is an endless continuation. That endlessness does not vanish into finitude, it is there, and by force of logic there is a remote zone beyond any arbitrarily large but finite row number. One that we can in effect secondarily model as transfinitely remote. Use a hyperbolic function wormhole to catapult from the infinitesimals near the row 0 point to leap to it if we would. As opposed to walking there in steps. This is the root of my concerns, and there is nothing in the thread above that would lead me to conclude that I am being hyper-concerned on something that is not significant. Just the opposite. KF PS: I should note that when I spoke of an implicit premise is doing heavy lifting I took time to explain. I use analogy of the modal ontological argument, in which one premise determines the outcome and stands by itself as a result. That is if an argument is of form p1, p2, p3 . . . pn + ph => c1, where c1 crucially depends on accepting ph not just the other premises, ph is the one doing the heavy lifting to reach c1. Which is a reasonable way of speaking. So the debate shifts to, why accept ph. The heavy lifter premise. This then may lead to a [quasi-] worldview level discussion on alternative clusters of premises or in effect explanatory models. In the relevant cases, we are forever pointing across acknowledged or implicit ellipses of endlessness and implying associated do forever loops of succession. These appear right there in the axiomatic framework and so it is proper to highlight the point. Indeed, this is apparent in ordinary mathematical induction and it is even implicit in the transfinite form once we see the oh the thing is so up to this threshold and from that it will follow it is true on the successor case, filling up set A. But by now I suppose I am simply speaking for record. kairosfocus

It could be that I'm too cynical for the web, but to me it is exceedingly clear why KF resorts to such vague language and why he refuses to answer clear yes/no questions. Were he clear, it would be apparent to many, maybe even to him, that he is wrong. However, this can't be since: "KF is right and DS is wrong. And if math agrees with DS, then math is wrong, too." hrun0815

Optimism is good. :-) One of the reasons I participate in discussions like this is for the exercise of honing the clarity and specificity of my own understanding, and from learning from others who perhaps believe as I do but have different ways of expressing themself, or who bring up points that I haven't thought of or didn't know about. From that point of view, this has been an instructive thread. Aleta

That's a nice summary, Aleta. This might be wishful thinking, but I'm holding out hope that the endless loop of this thread might turn out to be an endless spiral, where even though we keep cycling through the exact same questions over and over, we get a little closer to the truth and commit fewer errors each time. daveS

This thread appears to be endless, but unfortunately not because it is progressing. (Although I welcome ellazimm and his/her? succinct and clear points.) Rather then k, k + 1, k + 2, ... we appear to have k, k + 1, k, k + 1, ... Therefore a summary might be in order, in order to bring the discussion to an end. There are two areas to summarize: A. the mathematical issues themselves, for which we need to distinguish the statements which all parties agree upon from those that there is either clearcut disagreement, or, more commonly, confusion about what exactly is the issue at hand. B. the features of the discussion that are causing it to be stuck in an endless loop rather than making progress. So here we go. First, some of the reasons we aren't getting anyplace. B1.1 I would like to indicate points we agree on, and points where there is disagreement. However, this is hard to do because we can't figure out exactly and specifically exactly what point kf is making. Some reasons: B1.2 kf uses a number of informal and undefined terms, such as "past the ellipsis", "far or remote zone", "infinitely or endlessly remote", "heavy lifting", etc. Since he doesn't explicitly define these, either in words and especially not in mathematical language, we don't exactly know what he means. Trying to become clear on exactly what specific mathematical point he objects to and/or is offering has been one of the main themes of this discussion B1.3 But when asked to answer specific questions about what he means, or if he agrees or disagrees with specific mathematical statements, he refuses, calling such "inquisitorial y/n" questions. In fact, he says, "The endlessness is primary, the algebra and definitions etc around it are secondary. That is, he continually repeats his vague and unspecified "concerns" about endlessness, but dismisses attempts to define terms and make specific mathematical claims as "secondary." B1.4 kf continually repeats points that we have agreed upon with many times, as if they were points of contention. He doesn't seem to be able to remember and/or acknowledge such points (see part A for specifics). Among other things, this adds to the length and repetitiveness of his posts, and contributes to the sense of not being able to figure out exactly what he disagrees with us on. Mathematical issues A1.1 The natural numbers start with zero, and are such that for every natural number k, k + 1 is also a natural number. Dave as stated this in formal language as "For every natural number n, there exists a number [cell C] beyond n (using kf's concrete example of a tape to represent stepping through the natural numbers.) A1.2 This definition ensures that all are natural numbers are finite. I'm sure we all agree about A1.1 and A1.2 A1.3 The set of natural numbers is infinite. I'm pretty sure that kf agrees with this for two reasons. A1.3a He often refers to the fact that the natural numbers N can be put in a 1:1 correspondence with a proper subset of itself A1.3b He often references w and aleph null as transfinite numbers which represent the order of infinity associated with the natural numbers, and that w > the ordinal for any natural number. He accepts that N is an infinite set. A1.4 However, kf seems to object to the statement "There are an infinite number of natural numbers", although that seems to me to be exactly what A1.3 says. What exactly does kf seems to believe? He seems to believe that there is a "far or remote zone" "past the ellipsis" that contains "cells" that are "remotely distant from zero". That is, he seems to think that there is a part of the set of natural numbers that is forever beyond the reach of the finite natural numbers. Dave has expressed this as, "There exists a cell C such that for every natural number n, cell C is beyond cell n." Dave has asked kf to state whether this represents his position, but kf refuses to answer, seeing it as one those inquistorial "gotcha" questions. :-) But as far as I can tell, this is what kf believes. But this makes no sense to us It seems to say that there are numbers in the set of natural numbers that are not natural numbers, although it is not clear whether kf's "far zone" actually has numbers in it. It's just not clear what he thinks, frankly. But, in conclusion, given kf's unwillingness and/or lack of ability to be mathematically specific, in conjunction with the other points listed in section B above, I don't believe there is any chance of us getting any more clarity and specificity on the subject that we have gotten. Aleta

#460 KF Yes, I know what the definition of infinity is (please don't be patronising) and I know how mathematicians found a way to deal with it. But you're not specifying how you discern 'endlessness' from infinity. And you've not indicated what your mathematical background is. And you've not (apparently) put your ideas forward for review by other mathematicians. We're not some novices that are just going to accept your statements without question if we don't understand how you're using terms. Science and mathematics progress via a process of proposals, scrutiny, revision, acceptance, repeat. What scrutiny have you put your proposals to?

Above that property of being matched with a proper subset 1:1 is indicated, and it shows how infiniteness and endlessness beyond any arbitrarily large but finite value are inextricably interconnected.

So, endlessness and infinity are the same to you? But then how do you rectify the idea of an ENDLESS sequence converging to a finite value? This is why we're trying to figure out how you're using the terms. For example: 1.1, 1.01, 1.001, 1.0001, 1.00001 . . . is an endless sequence which approaches a finite value. At no point do the terms of the sequence achieve a transfinite value. We might say the limit of a-sub-n (a-sub-n being the nth term) as n goes to infinity is 1. I think this example is pretty clear. But . . . likewise . . . 1, 2, 3, 4 . . . is an endless sequence. It diverges to infinity meaning the individual terms will eventually 'beat' any limit you specify. But, again, each term in the sequence is finite. And we would say: the limit of a-sub-n = infinity even though no term is infinite. We can work with infinite series instead of sequences if you like. Part of my reason for asking after your mathematical background was so I could pick more meaningful examples. A couple of infinite series examples: 1 + 1/2 + 1/3 + 1/4 + 1/5 + 1/6 + . . . . diverges (becomes infinite, does not 'level off' to a finite value, will continue to grow without bound EVEN THOUGH the individual terms converge to zero) but 1 + 1/2 + 1/4 + 1/8 + 1/16 + . . . converges (approaches a finite value, gets closer and closer to 2 (from below) the more terms you add on). It never exceeds 2 even though you can add 'endless' terms together. All of this is standard, first year Calculus stuff. I learned it when i was 18 years old. And it works. It's useable. Just look at Fourier transforms (infinite series), something used by engineers every day. There's no great mystery or magic about it. Non-controversial, bread-and-butter, applied mathematics. And there's infinities and 'endless sequences and series everywhere. With no problems. ellazimm

EZ, I have already cited, but will repeat for convenience, here AmHD:

in·fi·nite (?n?f?-n?t) adj. 1. Having no boundaries or limits; impossible to measure or calculate. See Synonyms at incalculable. 2. Immeasurably great or large; boundless: infinite patience; a discovery of infinite importance. 3. Mathematics a. Existing beyond or being greater than any arbitrarily large value. b. Unlimited in spatial extent: a line of infinite length. c. Of or relating to a set capable of being put into one-to-one correspondence with a proper subset of itself. n. Something infinite. [Middle English infinit, from Old French, from Latin ?nf?n?tus : in-, not; see in-1 + f?n?tus, finite, from past participle of f?n?re, to limit; see finite.] in?fi·nite·ly adv. in?fi·nite·ness n.

KF PS: Above that property of being matched with a proper subset 1:1 is indicated, and it shows how infiniteness and endlessness beyond any arbitrarily large but finite value are inextricably interconnected. kairosfocus

#456 KF

EZ, the problem is endlessness, which is flat contrary to finite. KF

What is the different between 'endlessness' and 'infinity'? What is your mathematical definition of 'endlessness'? Why is 'endlessness' a problem? Since Cantor much work has been done dealing with these issues and the vast majority of mathematicians have come to accept the Cantor view; how does your approach differ from his? Just out of curiosity, what mathematical courses have you taken? Have you run your ideas past some other mathematicians? Like all sciences mathematics is tricky and complicated and even those who are good at it make sure their ideas make sense by checking with colleagues and fellow researchers. Again, if you initiate a counting procedure you cross many finite steps but you never get to the transfinite/infinite. There is no boundary or edge. And this situation has been researched and dealt with. ellazimm

KF,

I have already stated and showed that on endlessness, for any finite K, there will be endlessly many more rows than the row k, onwards. I have now even illustrated:

Yes. That corresponds to statement 1 in my post #455.

So, in the far zone included by the ellipsis of endlessness, there will be holed rows, endlessly remote from 0 and k etc.

Now this is ambiguous again, depending on what "endlessly remote" means. If by this you mean "at arbitrarily large finite distances" yes. That is consistent with the first quote I clipped, and is statement 1 from #455. If you mean "at infinite distance", no. That's statement 2 from #455. Am I right in assuming you mean "at arbitrarily large finite distances"? daveS

DS, I have already stated and showed that on endlessness, for any finite K, there will be endlessly many more rows than the row k, onwards. I have now even illustrated: 0 ===//===| k ===> . . . EoE . . . Where the blue tape from k on can be matched 1:1 with the pink one from 0, precisely because of endlessness: SNIP, MATCH: | k ===> . . . EoE . . . | 0 ===> . . . EoE . . . Where, once a subset can be matched to the full set, the original set is transfinite. Indeed, by going out k', we can cut and match again showing k on is transfinite. And so on arbitrarily many times. Where per composition of the tape the rows are loaded with holes, at 0.1 in pitch. So, in the far zone included by the ellipsis of endlessness, there will be holed rows, endlessly remote from 0 and k etc. By the logic of the tape's composition and endlessness. Which is an ordered, counting succession. This means, the issue raises points on how we describe and define our sets. The endlessness is primary, the algebra and definitions etc around it are secondary. So I have reason to be concerned, including when ordinary mathematical induction is brought in, as has already been highlighted. Even, when transfinite induction is brought in -- as was briefly noted on relation between A and the ordered sequence of counting sets. If that does not suffice to focus the concern, then something is seriously wrong with your argument. KF kairosfocus

EZ, the problem is endlessness, which is flat contrary to finite. KF kairosfocus

KF, PS to my post #454: You spend quite a bit of time here speaking of the importance of logic, the rules of right reason, and so on. I also think it's important to be clear about precise logical structure of statements one makes. All Aleta and I are asking you to do in #419 and following is to tell us which of these (if either) statements you are making: 1) ∀ n ∃ C P(C, n) 2) ∃ C ∀ n P(C, n) where P(C, n) means "cell C is beyond cell n". In other words, to translate your own statement into one of these forms (or perhaps something else, if necessary). daveS

KF,

DS, I have already repeatedly pointed out the significance of endlessness, which means that there will be any number of rows in the far right zone (8 bits per row in 5+3 tape . . . ) which will be beyond any finite value k.

For any natural number k, there are infinitely many rows in the tape beyond row k. If that's what you're saying, yes. There are no rows in the tape beyond every row k. If you're asserting that there are, no. If you want to have an actual discussion about this, then you're going to have to take a clear position on this issue.

Endlessness means just what it says and is the operational sense of infinite.

So why not just say "infinite"? The tapes are infinite because the cells can be put into 1-1 correspondence with (some) proper subsets of the cells.

That seems to be close to the core issue: infinite is not a synonym for finite. So when — as repeatedly pointed out — the blue is pulled in k rows, 0 to k – 1, from k on there will be an endless 1:1 correspondence with the pink tape, k -> 0, k+1 -> 1, etc.

And I have repeatedly agreed with this.

And, the pull-in can then be repeated any number of times you please, to the same effect, rather like the put existing guests in even rooms and put endless guests in the odd ones with Hilbert’s hotel.

Yes, repeatedly agreed to already.

And, that this point is so hard to see underscores the conceptual issue that makes a simplistic yes/no answer meaningless.

I hope this trend doesn't catch on at UD. It gets criticized quite a bit, but I think most people here accept the responsibility to respond to questions in a debate. Especially one tagged as "Darwinist rhetorical tactics". There is no reason you can't answer my post #419.

Endless means endless, and the pull in k and align in 1:1 correspondence shoes the remaining onward rows — punched with sprocket holes and up to 3 _ 5 holes at 1/10 in pitch all the way — will be an infinite, ordered set.

Yes, yes, agreed to once again.

Which means, due to endlessness, there will always be onward endlessly many values than any finite k.

For any particular natural number k. There are no particular values beyond every natural number k. *** So, your post should end with something like, "therefore cell C in the blue tape will never end up next to or to the left of cell 0 of the pink tape, regardless of the value of the natural number k". If you have to resort to a nonconstructive proof, that's ok with me also. daveS

#452 KF

Which means, due to endlessness, there will always be onward endlessly many values than any finite k. Not just one more, endlessness is pivotal.

Each of those values though is finite. Counting up one at time never gets you to an infinite value in a finite number of iterations. You don't all of sudden traipse into the 'transfinite'. You will eventually get to any specified value and you should even be able to predict when you get to it. But you won't get to 'infinity'. ellazimm

DS, I have already repeatedly pointed out the significance of endlessness, which means that there will be any number of rows in the far right zone (8 bits per row in 5+3 tape . . . ) which will be beyond any finite value k. Let me "sketch" the blue, with the cutoff: 0 ===//===| k ===> . . . EoE . . . Endlessness means just what it says and is the operational sense of infinite. That seems to be close to the core issue: infinite is not a synonym for finite. So when -- as repeatedly pointed out -- the blue is pulled in k rows, 0 to k - 1, from k on there will be an endless 1:1 correspondence with the pink tape, k -> 0, k+1 -> 1, etc. And, the pull-in can then be repeated any number of times you please, to the same effect, rather like the put existing guests in even rooms and put endless guests in the odd ones with Hilbert's hotel. That is bound up in the meaning of endlessness. And, that this point is so hard to see underscores the conceptual issue that makes a simplistic yes/no answer meaningless. Endless means endless, and the pull in k and align in 1:1 correspondence shoes the remaining onward rows -- punched with sprocket holes and up to 3 _ 5 holes at 1/10 in pitch all the way -- will be an infinite, ordered set. Which means, due to endlessness, there will always be onward endlessly many values than any finite k. Not just one more, endlessness is pivotal. Operationally, that is set up by the 1:1 match after pulling in. KF kairosfocus

Addendum to the last sentence of my post #450: That’s going to be impossible in view of the facts that the cells of each tape are in 1-1 correspondence with the natural numbers, and cell k + 1 is adjacent to cell k, for each natural number k. daveS

KF, Well, I can't force you to answer this key question. Anyway, to support your position (as I understand it), here's what you need to do: Start with the pink and blue tapes having their cells 0 aligned initially on the left. Both tapes extend infinitely far to the right. Consider finite leftward shifts of the blue tape by k cells, where k is a natural number, so that cell k of the blue tape ends up next to cell 0 of the pink tape. You need to show that there is a cell C in the blue tape which will never end up next to or to the left of cell 0 of the pink tape, regardless of which k was chosen. That's going to be impossible in view of the fact that the cells of each tape are in 1-1 correspondence with the natural numbers, but let us know what you come up with. daveS

DS, the point is, that for any finite step by step procedure -- and as even place value notation is a power series in disguise that is caught up -- there will be endlessly more rows beyond it, so that there is what I have called a far zone beyond the reach of any finitely bound procedure; often indicated by an ellipsis of endlessness . . . which is doing a lot of often unrecognaised heavy lifting. That is what I have been pointing to as a fundamental phenomenon of endlessness. Analysis of systems and structures with endlessness in them must address that. This includes that something is inherently limited in ordinary mathematical induction, and when one jumps to transfinite, it is by no means clear that set A which is reachable by finite processes -- cf Wolfram as cited above -- is capturing the full set of successively larger counting sets aka counting numbers and/or that of the relevant ordinals. KF kairosfocus

KF,

DS, if there are endlessly many rows at 0.1 inch per row, they are endlessly remote in distance, a proxy for scale. KF

It is not the case that there exists a particular row such that for all natural numbers n, this row is greater than n inches from row 0. It is the case that for every natural number n, there exists a particular row which is more than n inches from row 0. Right? daveS

So, you're saying that there are rows that one could never get no matter how long one let the tape run. True? Aleta

DS, if there are endlessly many rows at 0.1 inch per row, they are endlessly remote in distance, a proxy for scale. KF kairosfocus

KF,

DS, in a for a moment brief, again, finite and infinite are not synonyms;

Of course not. The set {1, 2, 3} cannot be put into 1-1 correspondence with any of its proper subsets. N can. {1, 2, 3} is a finite set, while N is not.

if the tapes by their nature are punched at every 1/10 in in rows, and they run on endlessly, by logic they will have endlessly remote rows;

You certainly haven't demonstrated the existence of any of these "endlessly remote" rows. There are cells arbitrarily many steps from cell 0, but they are all finitely distant. As to it being a matter of logic, you are quite literally the only person I have ever heard/read make such claims, that I recall anyway. Have you noticed that no one here has weighed in on your side on this matter? I defy you to find any support for your position anywhere on the internet outside of 4chan. All you have shown with you blue/pink tape illustration is that the cells on one tape can be put into 1-1 correspondence with the cells numbered k and up on the other tape, for any finite k you please. That just means the tape is infinite.

I note also that for a given string length n, the number of possible bit combinations is 2^n which for finite n will be finite; from which we can easily infer that the total of possible strings of length 0 up to length k will be finite, and k+1 will also be finite and so forth. If you remove the finitude of n, you will imply that there are endlessly many strings of up to endless length, but that is not the point you were trying to make and it was never in dispute.

Again, the way you've phrased this leaves me with questions. "Of up to endless length"? I don't know what that means. So: Do you agree that the set of all bit strings of finite length has cardinality aleph-null? To be clear, I'm referring to the language normally denoted {0, 1}^*, and there are no "infinite" bit strings included. daveS

kf writes,

endlessness will mean that from any finitely remote row k from the origin at the near end of the tapes, there will be yet endless onward rows

We all agree with this. This is equivalent to Dave's statement 1 at 419.

1) For every natural number n, there exists a cell C beyond cell n.

Since this is true, no matter what finite number n you are at, there is still an endless progression ahead of you. There is no end to the natural numbers. Therefore, there is no largest natural number. Therefore, there are an infinite number of natural numbers. Don't we all agree with these things? What do we disagree about? Aleta

DS, in a for a moment brief, again, finite and infinite are not synonyms; if the tapes by their nature are punched at every 1/10 in in rows, and they run on endlessly, by logic they will have endlessly remote rows; where as was already highlighted endlessness will mean that from any finitely remote row k from the origin at the near end of the tapes, there will be yet endless onward rows. That is how the blue tape can be pulled in k rows and rows k, k+1 etc set in 1:1 correspondence with row 0,1 etc of the pink tape. I note also that for a given string length n, the number of possible bit combinations is 2^n which for finite n will be finite; from which we can easily infer that the total of possible strings of length 0 up to length k will be finite, and k+1 will also be finite and so forth. For some k, we simply count up from 000 . . . 0 [k digits] to 111 . . . 1. If you remove the finitude of n, you will imply that there are endlessly many strings of up to endless length, but that is not the point you were trying to make and it was never in dispute. KF kairosfocus

KF, Incidentally, have you studied formal languages? For example, the set of all bit strings, each of which is a finite sequence of 0's and 1's. Examples: 0, 101001, and 1111. Each bit string has finite length, but there are infinitely many of them. Erm, right? In fact, each bit string (except for the empty string) corresponds to a (finite) natural number by considering it as a binary numeral. So we have an obvious mapping from the set of these bit strings to N, which is onto (or surjective), which means the set is at least as large as N. (In fact, the set of these bit strings has the same cardinality as N). [Edit: Likewise, any language over an at most countable alphabet is also countably infinite]. This is just one more of a huge number of examples of infinite sets, each element of which is finite in some sense. These things are common as dirt in mathematics. daveS

KF,

Their successive rows correspond to natural numbers, starting from 0 at the near end. For any finite row k, a further row k+1 will exist as a bound that is succeeded by k+2 etc. For the blue tape to be endless, truncating it at k and putting k, k+1 etc in match with the pink one at 0, 1, etc will still preserve a 1:1 match. If they are not endless, then we will not have such a match of proper subset with the original set. As a direct consequence, for ANY finite k, there will be an endless onward tape — something you saw quite well when you argued that at any given finitely remote past time there were onward values of time on an infinite past view. If there is such an endless — infinite — onward run of tape for any particular finite k we please, then the span of the tape beyond must recede endlessly, there is no upper finite limit to its length.

Yes, I agree. (Notice how I am willing to precisely state my position so as to facilitate our communication.)

As rows exist every 1/10 inch, there will be endlessly remote onward rows that no finite, stepwise count process can span. It is reasonable to say those rows are infinitely beyond.

No, that is not a reasonable thing to say. This is in essence equivalent to my statement 2. You are saying that there exists at least one row/cell such that this cell is beyond cell n, for all finite natural numbers, which is not the case.

Now, we may wish to proceed thusly, and define a set A that takes in all we can potentially count to stepwise in finite stages, caveat being that ability to exceed any k implies all in A are finite. Is A another label for N, the set of successive counting sets as labelled?

Yes, I believe that is correct.

Indeed, the way w succeeds is such that it is said not to have a specific, finite predecessor, z –> w, z being finite and the last natural number. That would have opposite effect to the intent. Instead w succeeds the endlessness and represents order type of the whole.

Ok, if you're saying that ω is greater than any natural number, yes, that's true.

And in my mind if it is to be taken seriously it involves endlessness in the set N, which is beyond any count zone A reachable in finite steps.

The set is endless according to your definition above (in fact it coincides with the definition of "infinite"). How that leads to some zone unreachable in finite steps, I have no idea. In fact I'm certain it doesn't. Consider the infinite Turing Machine tape. There would have to be a leftmost cell not reachable in finitely many steps from cell 0. Then the cell immediately to its left would be reachable in finitely many steps from cell 0. Do you think that is possible? daveS

Aleta, As just noted to DS, the issue pivots on for any FINITE k, there will be onward cells or rows k+1 etc. The point in doubt is whether N -- said to be endless -- is exhausted by any large enough k. I hold, not on grounds that once k is finite we have k+1 etc. So, to use n instead of pointedly finite k is problematic. KF kairosfocus

DS, we go in circles, needlessly. As I have already had occasion to point out, the inquisitorial y/n demand when there is an obvious conceptual difference in play is worse than useless. Again, the pivotal concern is what is endlessness, and the pink and blue punch tapes make it concrete. Their successive rows correspond to natural numbers, starting from 0 at the near end. For any -- repeat, any -- finite row k, a further row k+1 will exist as a bound that is succeeded by k+2 etc. For the blue tape to be endless, truncating it at k and putting k, k+1 etc in match with the pink one at 0, 1, etc will still preserve a 1:1 match. If they are not endless, then we will not have such a match of proper subset with the original set. As a direct consequence, for ANY finite k, there will be an endless onward tape k + 1, k+2 etc -- something you saw quite well when you argued that at any given finitely remote past time there were onward values of time on an infinite past view. If there is such an endless -- infinite -- onward run of tape for any particular finite k we please, then the span of the tape beyond must recede endlessly, there is no upper finite limit to its length. As rows exist every 1/10 inch, there will be endlessly remote onward rows that no finite, stepwise count process can span. It is reasonable to say those rows are infinitely beyond. Now, we may wish to proceed thusly, and define a set A that takes in all we can potentially count to stepwise in finite stages, caveat being that ability to exceed any k implies all in A are finite. We can then identify A as indefinitely large or at least extensible. Potentially infinite. But to go on to the ideal extension of that potential by closing off the set is to point across an ellipsis of endlessness. Is A another label for N, the set of successive counting sets as labelled? The argument put on the table answers yes, per how ordinary mathematical induction is applied. I have concerns on doing this, as N is defined to include the ellipsis of endlessness: {0,1,2 . . . k, k+1, . . . } Indeed, the way w succeeds is such that it is said not to have a specific, finite predecessor, z --> w, z being finite and the last natural number. That would have opposite effect to the intent. Instead w succeeds the endlessness and represents order type of the whole. The ellipsis of endlessness comes into play crucially. And in my mind if it is to be taken seriously it involves endlessness in the set N, which is beyond any count zone A reachable in finite steps. Hence my concerns tied to the concept of an infinite succession of finite numbers. For as the counting sets mount up to endlessness, that points to endlessness in successive sets, making them in effect tend towards being copies of the whole. KF kairosfocus

Reminder: "2) There exists a cell C such that for every natural number n, cell C is beyond cell n" True or false? Aleta

KF, I'm about 80% confident that you believe statement 2 is correct (and necessarily 1 as well, it being strictly weaker than 2). Am I correct? It would be helpful to us in understanding your position if you would simply say "yes" or "no". daveS

DS, see the just above, KF kairosfocus

Aleta, again and again, if something is endlessly beyond ANY finite value k then there is a problem with an argument that entails that all counting sets denoted as natural numbers -- that is what legitimate counting numbers are -- will be finite but there is an infinite supply of same; esp when that argument rests on ordinary mathematical induction which is closely tied to finite stepwise succession. At minimum, paradox. Or else, use of finite and infinite in ways that run perilously close to infinite and finite are two ways of saying the same, rather than that they denote alternatives . . . something suspiciously close to A AND ~A, thence ex falso quodlibet. In terms of the paper tape, if there is a 0.1 inch pitch, then for any finite value k, the distance from the near end will be k * 0.1 in inches. A finite value exceeded by the k + 1th row. If all possible k are finite, the tape will be finitely long not endless as length to k is k* 0.1. Maybe something so concrete as this may help clarify the concerns to you. KF kairosfocus

KF,

DS, endlessness is not a synonym for finiteness.

I agree. Which of my statements from post #419 are true of the infinite Turing Machine tape, if any? Why won't you answer this simple question? daveS

DS, endlessness is not a synonym for finiteness. There is where my concerns lie, again. KF kairosfocus

kf writes,

a definition of endlessness, which means there are legitimate values endlessly — adverb — beyond any given k that is finite.

Yes, Dave, kf's statement still doesn't distinguish between your two statements, because it doesn't clearly state what "legitimate" values mean. Yes, there are always an endless number of further finite values beyond any given k, and surely such values are "legitimate." That is what your statement 1 says. Statement 2, however, says that there is at least one "legitimate" value that is greater than any possible k. Does kf believe this is the case? That is the question. kf, in the interest of mathematical clarity, should respond to your questions with yes or no answers so we can know what he means by "legitimate". Your questions are stated with mathematical clarity, not with words whose meanings are not necessarily clear, so addressing them would help us understand what his words mean. Aleta

KF,

Second so far as I can see, saying that for any given k, followed by k+1 etc, the sequence from k on can be put in 1:1 correspondence with that from 0,1, on is a definition of endlessness.

Ok, thanks. But that definition of an endless Turing Machine tape is consistent with both of my statements 1 and 2, so it doesn't tell me which you hold to. So again, which is correct, 1 or 2 (or neither)? daveS

DS, First the term is not mine, it is longstanding -- cf the ubiquitous ellipsis; it is time to lose the rhetorical hints of dismissive idiosyncrasy. Second so far as I can see, saying that for any given k, followed by k+1 etc, the sequence from k on can be put in 1:1 correspondence with that from 0,1, on is a definition of endlessness, which means there are legitimate values endlessly -- adverb -- beyond any given k that is finite. For if there were a finite run length taking away k would leave some of the original unmatched. So thirdly, I have repeatedly defined what I understand by endless, as based on a standard definition of the transfinite since Cantor. When I say endlessness is endlessness (and not endedness), I am in effect appealing to the three classic laws of thought, with A is A leading. Once world W = {A|~A} then A = A and A != ~A with A x-or A, will obtain. KF kairosfocus

KF,

DS, if the tape is endless does that not mean that it is endless beyond any given k, no matter how large, where k is followed by k+1 etc? If not, then what specifically does endlessness mean? KF

I don't think we have a proper mathematical definition of "endless" yet. [Edit] I believe you introduced the term, so it's your job to give a rigorous definition (preferably in terms of the Turning Machine tape). Do either of statements 1 or 2 in my post #419 capture the meaning?

PS: Your question in its various forms has been answered any number of times. Endless means endless, just as the just above discusses and shows in the form of defining infinity on 1:1 match of a set and a proper subset, here from k on..

[Edit] Is statement 1 or 2 correct, in your view? Just say "1 is correct", "2 is correct", or perhaps "neither is correct", whatever the case may be. Saying "endless means endless" is not helpful without a clear definition to begin with. daveS

DS, if the tape is endless does that not mean that it is endless beyond any given k, no matter how large, where k is followed by k+1 etc? If not, then what specifically does endlessness mean? KF PS: Your question in its various forms has been answered any number of times. Endless means endless, just as the just above discusses and shows in the form of defining infinity on 1:1 match of a set and a proper subset, here from k on.. kairosfocus

KF, Would you please answer the question I posed in #419? I will say, as I did previously, that the Turing Machine tape is not endless by the definition you are using if that means some of its cells must be infinitely many steps from cell 0. daveS

F/N: Wolfram on transfinite induction, for anchoring reference: >>Transfinite Induction Transfinite induction, like regular induction, is used to show a property P(n) holds for all numbers n. The essential difference is that regular induction is restricted to the natural numbers Z^*, which are precisely the finite ordinal numbers. [--> notice, tantamount to: the chaining in ordinary induction is inherently finite] The normal inductive step of deriving P(n+1) from P(n) can fail due to limit ordinals. [--> which have no specific, particular predecessor, due to ellipsis of endlessness, e.g. w] Let A be a well ordered set and let P(x) be a proposition with domain A. A proof by transfinite induction uses the following steps (Gleason 1991, Hajnal 1999): 1. Demonstrate P(0) is true. 2. Assume P(b) is true for all b less than a. 3. Prove P(a), using the assumption in (2). [--> that is, chain the implication, where 2 gets around the lack of specific predecessor by saying for all b less than a ] 4. Then P(a) is true for all a in A. To prove various results in point-set topology, Cantor developed the first transfinite induction methods in the 1880s. Zermelo (1904) extended Cantor's method with a "proof that every set can be well-ordered," which became the axiom of choice or Zorn's Lemma (Johnstone 1987). Transfinite induction and Zorn's lemma are often used interchangeably (Reid 1995), or are strongly linked (Beachy 1999). Hausdorff (1906) was the first to explicitly name transfinite induction (Grattan-Guinness 2001). >> I have commented on points. KF kairosfocus

PPPPS: Aleta, I would suggest that there are many applications of logic to quantities and structures above, which is the essence of mathematics. Further, though simple, the application of endlessness and the pointing out of limitations on do forever chaining do have some relevant force. Where the algorithm presented at 217 above coming on two weeks past shows the main concern adequately; and highlights the effective embedding of a copy of the set of successive counting sets as a whole in its LHS listing in succession, i.e. if the set as a whole that collects successive counting sets grows to endlessness perforce so will its members in the upper zone represented by ellipsis of endlessness. I have no interest in playing out schoolbook exercises that readily go off on endless tangents. kairosfocus

PPPS: And again, if the tape is endless, it is endlessly beyond any arbitrarily large k we can succeed by k+1 etc. And if it has rows all along it by definition, some will be endlessly remote. Or else endless does not in reality mean endless and the proper subset in correspondence with the original set approach, fails. Can the blue tape be pulled in from r_0 to r-k-1 and treated as though k, k+1 on were 0, 1, on, still matching 1:1 with the pink? If yes, endlessness obtains. If not, endlessness does not mean endlessness. kairosfocus

PPS: For convenience, I use Wiki on Peano: >>1] 0 is a natural number. 6] For every natural number n, S(n) is a natural number. [S being, successor] . . . because[citation needed] 0 is the additive identity in arithmetic, most modern formulations of the Peano axioms start from 0. Axioms 1 and 6 define a unary representation of the natural numbers: the number 1 can be defined as S(0), 2 as S(S(0)) (which is also S(1)), and, in general, any natural number n as the result of n-fold application of S to 0, denoted as Sn(0). The next two axioms define the properties of this representation. 7] For all natural numbers m and n, m = n if and only if S(m) = S(n). That is, S is an injection. 8] For every natural number n, S(n) = 0 is false. That is, there is no natural number whose successor is 0. Axioms 1, 6, 7 and 8 imply that the set of natural numbers contains the distinct elements 0, S(0), S(S(0)), and furthermore that {0, S(0), S(S(0)), . . . } [are subsets up to] N.[citation needed] This shows that the set of natural numbers is infinite. However, to show that N = {0, S(0), S(S(0)), . . . }, it must be shown that N [are subsets up to] {0, S(0), S(S(0)), …}; i.e., it must be shown that every natural number is included in {0, S(0), S(S(0)), . . . }. To do this however requires an additional axiom, which is sometimes called the axiom of induction. This axiom provides a method for reasoning about the set of all natural numbers.[citation needed] 9] If K is a set such that: 0 is in K, and for every natural number n, if n is in K, then S(n) is in K, then K contains every natural number.>> Once successive patterns and stepwise progress are introduces as seen, the do forever loop, potential as opposed to completed infinite, ellipsis of endlessness and pointing across the loop are necessarily present also. And, pervade the onward work that builds on such. Where of course post Godel,an entity complex enough to enfold arithmetic will not be complete and coherent and we cannot constructively show it coherent though limited. kairosfocus

Aleta & DS (attn HRUN): First, per the cited, infinite means endlessly beyond arbitrarily large but bounded thus finite quantities, values or numbers. Thus the significance of the ellipsis of endlessness. As I have explicitly cited a second time, yesterday. So, DS, kindly stop ascribing idiosyncrasies to me in the face of understandings sufficiently commonplace to have made it into standard dictionaries. Please, Aleta, look again at endlessness. That which is represented by the ellipsis of endlessness. Then compare the implications of the way in which the set of counting functions is established and how ordinary mathematical induction is set up by chaining. Induction is the key example. Case C-0 or sometimes C-1, and C-k => Ck+1, thence for all cases that we can chain to or denumerate using say decimal place value numbers (which imply power series representations). A potentially infinite is set up, and an ellipsis of endlessness is posed. In the case of the natural, counting sets assigned to the chain of usual symbols for numbers: {0,1,2, . . . } {} –> 0 {0} –> 1 {0,1} –> 2 . . . All of this has been pointed out already. Consistently, there is what I have called a sub axiom, pointing across an ellipsis of continuation to an endless zone of continuation beyond any given arbitrarily large stated counting number. Or better, at any large k we may succeed by k+1 and then set up a substitution as though we were starting over at 0, 1, 2 . . . i.e. we have the ability to exploit endlessness by setting the proper subset fromk on in 1:1 correspondence with the original set and it will match endlessly. Which is the operational meaning of the infinite. This is the context of my having spoken above of the pink and blue punched paper tapes with blue pulled in 10^150 rows and again setting it in matched order with the pink. Endlessness is pivotal and the ellipsis is carrying the heavy load. If there are no rows in the ordered succession that are not endlessly remote, beyond any arbitrarily large but bounded specific value we care to name, k, then the pull in 10^144 miles and restart the count which will match 1:1 still, would fail. So, does endlessness mean endlessness, or does it in reality mean finite but very large? If the latter, then there is a problem of implying ending the endless. I do not for the moment care as to how definitions of sets are set up, the issue is the succession to endlessness of rows which are tantamount to counting, ordinal numbers. If there are endlessly many rows at 0.1 inch pitch, there are endlessly many rows. And endlessly many numbers in succession beyond our ability to count or represent without resort to the ellipsis of endlessness. Where, such endlessness means there is a far zone that is endlessly far -- infinitely far -- away. And by that force, there will be ordinal values that are endlessly remote, often denoted by me as w, w+1 and so forth; w stands in for omega. But that does not introduce something that was not there on the LHS: {0,1,2, . . . k, k+1, k+2 . . . EoE . . . } --> w So also: 0,1,2, . . . k, k+1, k+2 . . . EoE . . . w, w+1, . . . EoE . . . Now, we may denote that w is the first transfinite ordinal, and then make an assignment that the representable ordinals in succession to the EoE beyond any arbitrarily large but specific k etc will be the natural numbers. Then we may make an argument that per ordinary mathematical induction any such number we may specifically represent by k is finite as bound by k+1 etc. However, that still has not eliminated the ellipsis of endlessness and the implied do forever loop on the LHS. The blue tape, less k rows from row 0 on to k-1, is still endless beyond k and k can be relabelled as 0 freely and set in perfect 1:1 correspondence to the un-pulled, untrimmed pink tape. Endlessness is decisive and points to a zone of endlessly remote ordinals. So, however we may group or label, such endless continuation is there on the LHS. Setting up w as assigned first transfinite does not change that. Thus the concerns I have expressed, which seem to me to boil down to turning the natural succession of counting sets into in effect a finite. If ALL successive counting sets are finite, are finitely remote on our punched tape models, how can there be endlessness? I find, to my mind something suspiciously like the race loop between unstable opposed states in the statement: this statement is false. If true, it must be false, if false, it must be true, it is self referentially incoherent. What has seemed so far reasonable to me, is to argue that we identify the potentially infinite and point across an ellipsis of endlessness. Then, accept that mathematical induction in the ordinary sense is of this character and can only, strictly, apply to a finite chain of values. For any value we can reach or specify that can be exceeded by another finite -- note the implied do forever that cannot be completed in actuality -- the general case will apply. But when endlessness is brought to bear, it must be reckoned with in its own right. As to speaking of a far zone, yes the term is fuzzy; as fuzzy as endlessness is and as fuzzy as an ellipsis of endlessness is. Let me spell it out as the zone denoted by endless continuation of the potentially infinite. In the case of the one sided endlessness of the punched paper tapes, if they are endless then as there is for all spans of the tapes a pattern of rows every 0.1 inches, there will be endlessly remote rows. And that applies for all cases to a potentially infinite succession idealised as complete. However we manage to reckon with it, endlessness must be taken seriously and must not in effect be reduced to finitude. KF PS: DS, you are reverting to things that were already correctively addressed above. I have no time just now to go into do forever loops. kairosfocus

One more thought: kf has consistently used vague and undefined phrases such as "going past the ellipsis" into the "far zone." In doing so, he seems to imply statement 2. It would help add some mathematical specificity and clarity to his position if he would affirm or deny that statement 2 is, or is a part of, what he means by "going past the ellipsis" into the "far zone." Aleta

Dave writes,

I think this can be interpreted in two very different ways: 1) For every natural number n, there exists a cell C beyond cell n. That is correct. 2) There exists a cell C such that for every natural number n, cell C is beyond cell n. That is incorrect.

Very good, Dave. I think kf is asserting that 2 is true. I would like to see him clearly affirm or deny statement 2. Aleta

KF, Reading this more carefully:

PS: Put up the two tapes, pink and blue, both being endless from a row 0. Endless implies that there are rows beyond any arbitrarily high specific value we can count to or write down.

I think this can be interpreted in two very different ways: 1) For every natural number n, there exists a cell C beyond cell n. That is correct. 2) There exists a cell C such that for every natural number n, cell C is beyond cell n. That is incorrect. Are we agreed on that? daveS

KF,

Aleta & DS (attn HRUN), please look again. Several axioms do embed an implied iterative endless loop that creates successors, then a point past the ellipsis of endlessness to bridge to the whole.

No looping is implied. As Aleta stated, the Axiom of Infinity essentially creates the set N all at once. The set is abstract. Why do we need to resort to looping when the set can be created in one fell swoop?

PS: Put up the two tapes, pink and blue, both being endless from a row 0. Endless implies that there are rows beyond any arbitrarily high specific value we can count to or write down.

You might be using your own peculiar definition of "endless" here, but I merely stated that the tape was infinite. It is true that you can repeatedly shift the blue tape 10^150 cells and realign it with the pink tape, but you haven't demonstrated the existence of any cells infinitely far from cell 0 in either tape. All you've shown is that the natural numbers can be put into one-to-one correspondence with the natural numbers greater than or equal to any multiple of 10^150. That's consistent with every cell in either tape being a finite distance from cell 0. Regarding the dictionary definitions, they are all consistent with every natural number being finite and all the cells on the tape having finite distance from cell 0.

In that context, I long since put up the two punch tape reels that go on endlessly in a one-sided infinity, and I again point to the implications of endlessness of such a tape. The issue seems, is endlessness really endless or not? If not, it is finite.

It has infinitely many cells. Here's the illustration I have been using. We can number the cells using von Neumann ordinals. The leftmost cell is cell ∅ The next one, its "successor", if you will, is cell {∅} After that, {∅, {∅}}. If I point to any cell in the tape, and tell you its number/ordinal, then you can use a purely mechanical process to find the number of its successor. There is no rightmost cell in the tape, because it's infinite. However, each cell is labeled with a finite ordinal. There is no bound to the distances between cells and cell ∅. Given any arbitrarily large finite ordinal n, there is a cell n in the tape. The set of cells can be put into 1-1 correspondence with proper subsets of itself, which is what your pink/blue tape illustration shows. That summarizes my understanding of the infinite Turing Machine tape. daveS

PS: Notice, I am speaking to a framework and its context, not oh every conceivable point is this and if it is not my concern falls to the ground. That scattershot rhetorical strategy is irrelevant. It is clear there is a step of completing a potential infinite by taking endless loop steps and pointing onward, and it comes up over and over again. In that context, I long since put up the two punch tape reels that go on endlessly in a one-sided infinity, and I again point to the implications of endlessness of such a tape. The issue seems, is endlessness really endless or not? If not, it is finite. kairosfocus

CED: >>finite (?fa?na?t) adj 1. (Mathematics) bounded in magnitude or spatial or temporal extent: a finite difference. 2. (Mathematics) maths logic having a number of elements that is a natural number; able to be counted using the natural numbers less than some natural number. Compare denumerable, infinite4 3. a. limited or restricted in nature: human existence is finite. b. (as noun): the finite. 4. (Grammar) denoting any form or occurrence of a verb inflected for grammatical features such as person, number, and tense [C15: from Latin f?n?tus limited, from f?n?re to limit, end] ?finitely adv ?finiteness n>> I take sense 2 to speak of specific number, and that the definitions are tantamount to saying that the set of naturals is a restriction to the finite, but the succession is unlimited. Once we have an unlimited, endless succession, the issue is there. KF kairosfocus

F/N: Collins Eng Dict >>infinite (??nf?n?t) adj 1. a. having no limits or boundaries in time, space, extent, or magnitude b. (as noun; preceded by the): the infinite. 2. extremely or immeasurably great or numerous: infinite wealth. 3. all-embracing, absolute, or total: God's infinite wisdom. 4. (Mathematics) maths a. having an unlimited number of digits, factors, terms, members, etc: an infinite series. b. (of a set) able to be put in a one-to-one correspondence with part of itself c. (of an integral) having infinity as one or both limits of integration. Compare finite2 ?infinitely adv ?infiniteness n>> KF kairosfocus

Aleta & DS (attn HRUN), please look again. Several axioms do embed an implied iterative endless loop that creates successors, then a point past the ellipsis of endlessness to bridge to the whole. And it is not any novelty to point to the difference between potential and actual infinities. The very way the set of whole counting numbers is listed and how it is often explained often shows this: {0,1,2, . . . } {} --> 0 {0} --> 1 {0,1} --> 2 . . . KF PS: Put up the two tapes, pink and blue, both being endless from a row 0. Endless implies that there are rows beyond any arbitrarily high specific value we can count to or write down. Where to write down in place value notation, we are resorting to a disguised power series with the same underlying issue. Pull blue in 10^150 rows, 10^144 miles at 1/10 inch per row. It is still endless beyond. Do, again and again, same result. Same match 1:1 to the pink again and again,just promote the k, k+1 kairosfocus

KF, Anyway, after this detour into the Axioms of Induction and Infinity, do you still stay that the statement "All natural numbers are finite" is not provable in ZFC? (And by "all natural numbers", I mean every single one, not just all natural numbers that have been generated so far, or something along those lines). More concretely, do you still say that the infinite, one-ended Turing Machine tape must have cells infinitely many steps from cell 0? daveS

hrun0815,

daveS, I am pretty certain that this argument carries zero weight here at UD. :)

Heh. Yeah, I guess somebody had to discover this problem. daveS

That's right, Aleta. I will qualify my #408 by saying again that there are a few mathematicians who don't accept the Axiom of Infinity, and for them, this discussion is moot. I don't think KF claims to reject the AoI though. daveS

Re #408:

Do you recognize that you’re claiming to have discovered a disastrous flaw in elementary set theory that has gone undetected for 100+ years?

daveS, I am pretty certain that this argument carries zero weight here at UD. :) hrun0815

The definition essentially creates the whole infinite set all at one time: it doesn't have to be created one element at a time through an infinite number of steps. I think that perhaps is the key confusion. Aleta

KF,

Succession follows and looping. As is embedded in several elements of the set-up.

This is false. The axiom states that there exists a set I such that ∅ ∈ I and for all x ∈ I, x ∪ {x} ∈ I. End of story, with no looping. Do you recognize that you're claiming to have discovered a disastrous flaw in elementary set theory that has gone undetected for 100+ years? daveS

DS, briefly the ax of inf is tied to the von Neumann construction, whereby the successor of x is defined as x union {x}. If x is a set, then it follows from the other axioms of set theory that this successor is also a uniquely defined set, thence the frequently shown train of counting sets:

there is a set I (the set which is postulated to be infinite), such that the empty set is in I and such that whenever any x is a member of I, the set formed by taking the union of x with its singleton {x} is also a member of I. Such a set is sometimes called an inductive set.

Succession follows and looping. As is embedded in several elements of the set-up. KF kairosfocus

Aleta, Thanks for the compliment. Your posts have improved my understanding of the issues a great deal. One thing that has become more clear to me is that the usual domino analogy for induction can be quite misleading. It seems to suggest (to me, anyway) that proofs by induction really amount to applying modus ponens over and over again, ad infinitum, when that's absolutely not the case. And I think it's a root cause of the difficulty we're having here. daveS

Yes, I see. You'll notice I've dropped out of the conversation - I reached some interesting understandings for myself, but gave up on kf. On the other hand, I was thinking that seeing some actual mathematics in this thread might be nice. One of our points is that kf doesn't formulate any actual math to support his intuitions and concerns, nor does he respond to any proofs. In fact, I thought this was a great paragraph from you:

If these do forever loops that you refer to actually existed, it would mean that the so-called “proofs” in which they were embedded were not really proofs at all, which would be quite problematic. I don’t think it’s plausible this monumental oversight could persist for on the order of a century until finally being revealed on an ID blog.

Aleta

Aleta, And I was highly motivated to avoid induction, for obvious reasons! daveS

Oh duh - what you explained is so much simpler. However, when I tested some numbers, like P(3), P(4), and P(5) I noticed that each result grew by a number that was a multiple of 6, and I had proof by induction on my mind, so I went the way I did. Aleta

KF, Further to my post #400, see this pdf which describes how the Axiom of Infinity can be used to prove the existence of the set N, with no do forever loops, of course. daveS

Aleta, Very nice proof. That's essentially what I had in mind, although I think you can carry it out without using induction, as long as you accept some basic number theory facts. The basic idea is that, as you pointed out, in the factorization n(n + 1)(n + 2), at least one of the factors is even and exactly one is divisible by 3, so this is definitely a multiple of 6. daveS

KF,

DS, the do forever looping is there, right in the definitions, constructions of the counting numbers and axioms.

Have you read up on the Axiom of Infinity? From the wikipedia page:

This construction forms the natural numbers. However, the other axioms are insufficient to prove the existence of the set of all natural numbers. Therefore its existence is taken as an axiom—the axiom of infinity. This axiom asserts that there is a set I that contains 0 and is closed under the operation of taking the successor; that is, for each element of I, the successor of that element is also in I.

That takes care of the existence of the set N in one step, no infinite loops involved. Did you find any do forever loops in my proof above or that of the divisibility-by-6 statement? If not, I don't think we actually have any examples of such things on the table. As I mentioned above, mathematical proofs are typically presented in the context of a first-order theory. Proofs in these formal systems consist of a finite number of steps. From the wikipedia page on first-order logic, with some bolding added:

A deductive system is used to demonstrate, on a purely syntactic basis, that one formula is a logical consequence of another formula. There are many such systems for first-order logic, including Hilbert-style deductive systems, natural deduction, the sequent calculus, the tableaux method, and resolution. These share the common property that a deduction is a finite syntactic object; the format of this object, and the way it is constructed, vary widely. These finite deductions themselves are often called derivations in proof theory. They are also often called proofs, but are completely formalized unlike natural-language mathematical proofs.

If these do forever loops that you refer to actually existed, it would mean that the so-called "proofs" in which they were embedded were not really proofs at all, which would be quite problematic. I don't think it's plausible this monumental oversight could persist for on the order of a century until finally being revealed on an ID blog. daveS

Hi Dave. I've been thinking about this, and here is a fairly formal proof I came up with. To prove: P(n) = n^3 + 3n^2 + 2n is divisible by 6. Lemma: 3(n + 1)(n + 2) is divisible by 6 Proof of Lemma: either (n + 1) or (n + 2) must be even, because every other natural number is even. Assume n + 1 is even, so that n + 1 = 2m, for some m. (If n + 2 is even, just use it instead of n + 1) Then 3(n + 1)(n + 2) = 3•2m•(n + 2) = 6m(n + 2), which is obviously divisible by 6. Proof of main proposition: First note that P(n) = n(n + 1)(n + 2), by factoring. P(0) = 0, which is divisible by 6. Now, assume P(k) for some k is divisible by 6, and then consider P(k + 1): P(k + 1) = (k + 1)(k + 1 + 1)(k + 1 + 2) = (k + 1)(k + 2)(k + 3). Now consider the difference D between P(k + 1) and P(k): D = (k + 1)(k + 2)(k + 3) - k(k + 1)(k + 2) = (k + 1)(k + 2)(k + 3 - k) = 3(k + 1)(k + 2), which is the expression in the lemma, and is divisible by 6. Therefore, for all k, if P(k) is divisible by 6, P(k + 1) is greater then P(k) by some number divisible by 6, and therefore P(k + 1) is also divisible by 6. (This argument could easily be written out more formally, but I won't bother.) Therefore, since P(0) is divisible by 6, and for every k, if P(k) is divisible by 6 so is P(k + 1), by induction P(n) is divisible by 6 for all n. Q.E.D. Any other straightforward proof? Aleta

DS, the do forever looping is there, right in the definitions, constructions of the counting numbers and axioms. Leaving such implicit by rephrasing or redirecting attention does not change that. The issue is endlessness and what it entails, which leads to my concerns. Onwards, it is quite clear no endlessly stepwise finite stage process can actually traverse the endless. Getting to the potentially infinite and pointing across the ellipsis of endlessness needs to reckon with whether that has a relevant and perhaps unexpected impact -- esp. if we have a divergent sequence. KF kairosfocus

KF, One more question about these claims of do forever loops. It concerns a matter different from finitude, but I think it will be clarifying. Let P be the predicate defined on the set of all integers by:

P(n) = True iff n^3 + 3n^2 + 2n is divisible by 6.

Do you believe that every proof of the fact that P(n) = True for all integers n must contain a do forever loop? daveS

KF,

2) Show that for all natural numbers n, if P(n) = True, then P(n + 1) = True. [–> here comes the do forever represented by an endless loop]

No, no looping involved:

Let n be an arbitrary natural number. P(n) = True implies the ordinal n is a finite set. But then n + 1 = n ∪ {n}, also a finite set. Therefore P(n + 1) = True.

This simultaneously proves P(n) = True implies P(n + 1) = True, for all natural numbers n. If you still maintain there is a do forever loop in that proof, kindly write out the loop explicitly.

Induction Axiom The fifth of Peano’s axioms, which states: If a set S of numbers contains zero and also the successor of every number in S [–> do forever, represented by ellipsis of endlessness], then every number is in S.

Let's be clear: Are you saying that proving a nonempty set of natural numbers is closed under the successor operation always requires a do forever loop? daveS

DS: Again, notice the implied succession:

1) Show that P(0) = True. 2) Show that for all natural numbers n, if P(n) = True, then P(n + 1) = True. [--> here comes the do forever represented by an endless loop] 3) Conclude that for all n in N, P(n) is True [--> as in point across the ellipsis of endlessness], by the Axiom of Induction.

Where, on Axiom of induction, per Wolfram, we see the same pattern of reasoning:

Induction Axiom The fifth of Peano's axioms, which states: If a set S of numbers contains zero and also the successor of every number in S [--> do forever, represented by ellipsis of endlessness], then every number is in S.

I have no problem with defining a set by endless succession, save that we need to recognise what that is doing and that it may have subtleties when we move to the far zone implicit in going across an endless span. As pointed out earlier, the stepwise succession of counting sets if we go do forever to endlessness will imply that successive elements in the far zone move to being embedded copies of the endless set. Something we can see by setting up a 1:1 match. We may impose some sort of point across the ellipsis, close the double bracket and say order type is w, transfinite, of cardinality first degree endlessness i.e. aleph null, but the heavy lifting is in the ellipsis on the LHS: {} --> 0 {0} --> 1 {0,1} --> 2 . . . { 1, 2 . . . } --> ? . . . or, as 217 above illustrated a week ago: {0, 1, 2 . . . { 1, 2 . . . } . . . ) --> w (BTW, in turn we see subnesting of the same push to endlessness in members of the far zone.) And, S has in it every number in an endless context of do forever is suggestive . . . Again, paradoxes and concerns. KF kairosfocus

KF,

Notice, a telling little phrase in 391: “and so forth” . . . i.e. a signature of a do forever loop.

Yes, but as I stated, that's not the real proof of the finitude of all natural numbers. If you're still thinking that the proof consists of:

P(0) = True If P(0) = True then P(1) = True, therefore P(1) = True If P(1) = True then P(2) = True, therefore P(2) = True

and continuing on in an infinite loop, that's incorrect. See the three steps in the second blockquote for the steps in the real proof. daveS

DS, please read 217 above to see how the endless loops you keep putting up critically depend on pointing across an ellipsis of endlessness to move to the idealised concept of a completed infinite; always involving endless iterative loops starting with constructing the set of counting sets itself. Notice, a telling little phrase in 391: "and so forth" . . . i.e. a signature of a do forever loop. To suggest an actual end of the endless via finite stage steps, is a fallacy. We can get to a potential infinite but we cannot actually complete it. In the case of cumulative creation of counting sets, at each stage we extend one level in succession. It is reasonable to infer from this that if the process is endlessly repeated the accumulation inside the sets will also become that. Endless, a synonym for transfinite. The answer to which is, we never actually complete such a process, indeed to end the endless would be a contradiction, so we project an ideal. But also that means that the proof by ordinary induction has a gap between what is actually shown and the conclusion that goes beyond that. Yes, if C-0 holds and C-k => C-k+1 then we may do forever, but that cannot actually be completed, only envisioned. At any k, k+1 pair we may proceed to put in parallel with the original and start the count over again [exploiting that property of the transfinite which is of defining character], never getting closer to ending the endless. What we show is the cumulative process will always be finite and bounded as the next step is a bounding cap-off of where we actually reached so far. That is an opposite character to endlessness. Going further, we show that as far as we can reach or represent with place value numbers [which involve power series also] the general claim particularised as so for case 0 will obtain. We then apply a sub axiom of pointing across the ellipsis of endlessness and often conclude to for ALL cases. Often that works as the pattern does not rely on the cumulative effect of endlessness. But in the case of the counting numbers themselves, every step extends so if they are extended endlessly, perforce the counting sets at some zone should be just that, endless. We may workaround by imposing a general successor to the endless set and stipulate that w is the first transfinite, but the simple accumulation of successive counting sets points to if extended endlessly, individual members should tend to become endless, in effect copies of the set as a whole. If on the other hand the members are all determined to be finite, the set as a whole, which reflects the progress of its members, should remain finite also. Do forever cannot actually be completed though it may be continued unendingly. Note the difference and the stress on continuation, pointing to a gap between the potential and the actual infinite. Pointing across the ellipsis of endlessness is doing the heavy lifting, and is in this case pointing to a paradox. Hence, my concern. I think we have gone a bridge too far. KF kairosfocus

KF,

DS, do you recognise that algorithms or implied ones based on do forever loops cannot actually be extended forever, and so we are forever pointing across ellipses of endlessness to draw idealised conclusions? KF

Well, I'm not sure. Why couldn't a "do forever" loop be extended forever? It wouldn't be taking place in space and time, so I don't know what the barrier would be. On the other hand, that's emphatically not what is happening in the proof that all natural numbers are finite. The Axiom of Induction takes care of that. daveS

KF, I get the "infinite loop" aspect of inductive proofs, but I think you're not taking into account the fact that we can apply the Axiom of Induction. To illustrate, let P be the predicate "is finite", defined on N.

Then P(0) = True of course. But P(0) = True implies that P(1) = True, so P(1) = True. P(1) = True implies P(2) = True, so P(2) = True.

and so forth. If I proceed in that manner, I will be executing an infinite loop, and at every step, I will have shown only that a finite number of natural numbers are finite. Since a proof is supposed to consist of finitely many steps, this won't work to prove all natural numbers are finite. That's not how the real proof goes, however. It has these parts:

1) Show that P(0) = True. 2) Show that for all natural numbers n, if P(n) = True, then P(n + 1) = True. 3) Conclude that for all n in N, P(n) is True, by the Axiom of Induction.

#1 and #2 can be proved in a finite number of steps, as I showed above. Incidentally, in this case #2 is proved without induction, but there would be nothing wrong with having to do a second round of induction at this stage. daveS

PS: Note . . . http://whatis.techtarget.com/definition/infinite-loop-endless-loop >>An infinite loop (sometimes called an endless loop ) is a piece of coding that lacks a functional exit so that it repeats indefinitely. In computer programming, a loop is a sequence of instruction s that is continually repeated until a certain condition is reached. Typically, a certain process is done, such as getting an item of data and changing it, and then some condition is checked, such as whether a counter has reached a prescribed number. If the presence of the specified condition cannot be ascertained, the next instruction in the sequence tells the program to return to the first instruction and repeat the sequence, which typically goes on until the program terminates automatically after a certain duration of time, or the operating system terminates the program with an error. Usually, an infinite loop results from a programming error - for example, where the conditions for exit are incorrectly written. Intentional uses for infinite loops include programs that are supposed to run continuously, such as product demo s or in programming for embedded system s. A pseudo-infinite loop is one that looks as if it will be infinite, but that will actually stop at some point.>> Wiki: >>Looping is repeating a set of instructions until a specific condition is met. An infinite loop occurs when the condition will never be met, due to some inherent characteristic of the loop. Intentional looping There are a few situations when this is desired behavior. For example, the games on cartridge-based game consoles typically have no exit condition in their main loop, as there is no operating system for the program to exit to; the loop runs until the console is powered off. Antique punch card-reading unit record equipment would literally halt once a card processing task was completed, since there was no need for the hardware to continue operating, until a new stack of program cards were loaded. By contrast, modern interactive computers require that the computer constantly be monitoring for user input or device activity, so at some fundamental level there is an infinite processing idle loop that must continue until the device is turned off or reset. In the Apollo Guidance Computer, for example, this outer loop was contained in the Exec program, and if the computer had absolutely no other work to do it would loop run a dummy job that would simply turn off the "computer activity" indicator light. Modern computers also typically do not halt the processor or motherboard circuit-driving clocks when they crash. Instead they fall back to an error condition displaying messages to the operator, and enter an infinite loop waiting for the user to either respond to a prompt to continue, or to reset the device>> In many systems such loops are used in the main subroutine that then branches on inspected conditions or interrupts. Power down is an interrupt of highest priority and should trigger safe shutdown routines. Actually completing an endless process is a fallacy. KF kairosfocus

DS, do you recognise that algorithms or implied ones based on do forever loops cannot actually be extended forever, and so we are forever pointing across ellipses of endlessness to draw idealised conclusions? KF kairosfocus

VC 358, yes, the transfinite as we study it is based on do forever loops that we cannot actually complete but point beyond. KF kairosfocus

DS, What has been of secondary concern to me is the logic of the system of numbers, how it is operationally defined by step by step succession, and the issue of claiming a finite stepwise process based on stages that are finite, creates a system in which all members are finite but the whole is infinite. That is at minimum paradoxical. The primary context has been the claim being made or implied, of an endless spatio-temporal causal succession coming down to now, which interfaces with the mathematics. However, as mathematics is in effect the logical study of structure and quantity, logical considerations clearly obtain. One of these is that to claim to have traversed the infinite by cumulative, finite stage steps or to imply such, is to assert a contradiction. The endless is not ended by such a stepwise proces. Such processes based on unlimited looping of steps are indeed capable of pointing to endlessness, but are themselves finite, only potentially infinite. Hence the use of ellipses of endlessness. But it is easy to persuade ourselves that the sub axiom of pointing across the ellipsis of endlessness and drawing a conclusion on the whole has settled a matter. The first concern is, doing so unexamined. The second, is that an implicit step (as it so often is) should be viewed with caution when it is carrying a LOT of weight. Third, in the case of inferring that all counting sets in endless succession are finite but the whole is infinite, there is at minimum a paradox. In the case of ordinary induction, the problem is as outlined in 217 above and as was repeatedly pointed out. When one sets out a claim say C-j then hangs it on case 0 or 1, then adds that C-k => c_k+1, one is going in an open-ended loop, applying an endless loop algorithm to create a potential infinite then pointing across an ellipsis of endlessness. What is actually established is that we have a claim that will succeed as far as we can reach or enumerate specifically, but we cannot ever actually end the endless. This is where the problem comes out when this procedure is used to infer that say all counting sets built up in succession and continued endlessly are nonetheless finite. In fact the implication of endless building up of successive sets -- notice the recursion and do forever loops -- is that there is a zone where the sets have in them an ellipsis of endlessness. That is the succession process points to endlessness within individual sets even as the overall collection is extended without limit across its own ellipsis of endlessness. Follow the logic to see how that happens. Endlessness appears in the successive members as entangles with endlessness of the whole based on the potential infinity of the successor process based on do forever. We cannot actually complete, but we look beyond to the idealised: {0,1,2 . . .} --> w The ellipsis of endlessness carries a LOT of weight. We also come full circle to that evolutionary materialist cosmologies face the unhappy choice between pulling being out of a non-existent hat, non-being; or else, ending the endless. That is on top of self referential, self falsifying incoherence as regards the capability of mind, which undermines the whole scheme of thought. KF kairosfocus

KF, It's possible that we're just not interested in the same things then. I'm focusing on what can be proved in a particular axiom system, as well as the issue of "beginninglessness", as WLC describes it, illustrated by the reverse HH tour and the eternal ticking clock. I haven't said much about "ending the endless", and I don't think that occurs in mathematical induction. At least so far as I can understand without a rigorous definition. daveS

DS, that in a stepwise succession pattern n being finite entails n +1 finite is not the same as addressing endlessness; a stepwise iterative, cumulative, finite stage process will not span the endless. And it is the transition to endlessness which is where my concerns lie as has been stressed over and over. Ending the endless, explicitly or implicitly, is an error. KF kairosfocus

KF, Well, the correct analog to "the successor of an even will be an odd" is "if n is finite, then n + 1 is finite". Both of which I accept of course. Both seem equally trivial to me. I'm interested in what we can prove. You have stated that we cannot prove that all natural numbers are finite (assuming the Peano axiom system, say). Correct? On the other hand, you say we can prove that if S is a finite subset of N, all the elements of S are finite. Again, correct? daveS

DS, I am pointing out that the inference to the scale of Z is based on stepwise, endless loop inference which is then extended through an endless ellipsis. And that the successor of an even will be an odd is very different from the import of in an endless set of successive counting sets, all the sets will be finite. KF kairosfocus

KF, So does the following summarize your position on this question? My proof shows that for any finite subset S of Z, if n ∈ S is even, then n + 1 is odd. It does not show that for all n ∈ Z, if n is even, then n + 1 is odd. daveS

DS, you are using a process which rests on a looping process reflected in simply the n itself. I am not saying that this skips over integers, but that it is inherently based on endless looping with what that entails for stepwise processes addressing the endless. KF kairosfocus

KF, Here's the proof:

Let n be an even integer, so n = 2k for some integer k. Then n + 1 = 2k + 1, which is odd.

Can you name the first five even integers I'm looping over? daveS

DS, the loop is there. And the pointing onward across the ellipsis of endlessness is also there. I add, including in the axiom of induction. Wolfram: " If a set S of numbers contains zero and also the successor of every number in S, then every number is in S." KF kairosfocus

KF, Regarding your post #376:

all we can count to or actually represent ... will be finite.

Let K be the set of all natural numbers we can count to. Clearly 0 is an element of K, and if n is in K, so is n + 1. Therefore by the Axiom of Induction, K = N. That is, every natural number is a number we can count to, so every natural number is finite. daveS

KF,

DS, it seems to me the endless loop is right there in “for ALL . . . ” esp. if you see how the set is built up from {} by succession. As in how do you get TO evens plural much less an endless span of them. KF

If there were any kind of loop in the proof, I would have to start with some particular even integer n, show that n + 1 is odd, then move to another even integer and repeat. None of that appears in the proof. I dealt with all even integers simultaneously. daveS

F/N: Over at TSZ, KS tries a clincher:

If you accept that the naturals are constructed upward from 0 (or 1), like this… 0 is a natural number. If n is a natural number, then n+1 is a natural number. …and if you accept the following premise… If n is finite, then n+1 is finite. …then it follows that every natural number is finite. It’s that simple. If you disagree, then where does the argument go wrong?

The proof of course is familiar, and my concern with it is the same. Ending the endless, and perhaps even making the transfinite mean the finite. The general process is: {} --> 0 {0} --> 1 {0,1} --> 2 . . . {0,1,2 . . . (k-1)} --> k {0,1,2 . . . k} --> k +1 . . . The sub axiom of the ellipsis of endlessness appears in its usual ghostly three dot garb, and we move from a step by step loop that inherently cannot actually complete the endless to inferring to the completed endless. Cannot actually complete? Yes, at a given n = k, then k+1, we are in effect able to cut off what has gone before and start over 0, 1, 2 . . . so that at no finite k are we ever close to completing the endless. Which means, no finite number is endless, and no span of finite numbers will be endless. Go back to pink and blue punch tapes, starting here and going on endlessly. Pull in the blue k steps, say 10^150, i.e. ~ 10^144 miles. There are still endlessly many rows ahead. For any finite k, the span of tape is 0.1 inch x k, an inherently finite value. So if all the values of n are finite, then the tape is finitely long at any k. For ALL values of k. Which is problematic if one is claiming actual endlessness. This is the sort of context in which I am concerned with claims of an infinite, actually endless succession of counting numbers, n. What I suggest is, we set up endless loop processes that point to the potentially transfinite, though in themselves they are finite. Always. The finite is not the transfinite. Endlessness is pivotal and the ellipsis of endlessness is key. This also extends to ordinary mathematical induction. For it endlessly chains from a claim, case 0 or 1. C-0 or C-1 and C-k => C-k+1, then go cases 2,3 . . . and there we see the ellipsis of endlessness that cannot be spanned in steps. In these cases what we are doing is we take the implicit step of achieving an endless loop based potential infinite then infer completion of the endless as an ideal concept. So, we go: {0,1,2 . . . EoE . . . } --> w and so forth. And those are where my concerns lie on claiming that

all n in the set just shown are finite,

as opposed to,

all we can count to or actually represent (say as in place value notation decimal or binary form, which are disguised power series of form: . . . p*b^k+1 + q*b^k . . . *b^1 +s*b^0 + t*b^-1 + u*b^-2 + . . . --> note the chained, successive subscripts in the whole number and fractional parts) will be finite.

KF kairosfocus

VC, I should footnote on your two counters, one counting s the other every 2nd s. These both go to potential infinity, but indeed one is slower. Think of the two punch tapes, pink and blue. Now add a third in that ugly beige we all remember from IBM punch cards. This one, however has an oddity, rows are 0.2 inches apart. If all three are endless, does this have as many holes as the other two? The answer being, the numbers are endless. And if the blue is pulled in 10^150 holes and the ~10^144 miles of tape is cut off, all three remain endless. Aleph null stands in for first degree endlessness that can be matched 1:1 endlessly (note, process not completion) with the natural numbers. But in any finite equal length beige will have about half the number of rows as pink and blue. The issue is endlessness. KF kairosfocus

DS, it seems to me the endless loop is right there in "for ALL . . . " esp. if you see how the set is built up from {} by succession. As in how do you get TO evens plural much less an endless span of them. KF kairosfocus

KF, Well, in any case, are we agreed that the above proof of the statement "for all integers n, if n is even, then n + 1 is odd" contains no infinite loops or repetition? daveS

DS, I see we can define numbers in a way like von Neumann, and from the succession so established, point to potential infinity and accept the set as a whole as endless. That then leads to cardinality of first degree endlessness and order type w. From N, Q, from these R, thence C thence ijk vectors and structures etc. KF kairosfocus

F/N: Decided to glance back at TSZ, just to see. I was not disappointed: 1: Note to KS: The context is there (let me add by way of emphasis: regrettably), on much backstory by you and ilk. With Dawkins' atrocious sneering remark about ignorant, stupid, insane or wicked ever lurking. I also add: there is need to focus the issue. And the infinite turns out to be far more subtle of an issue than appears. 2: Note to Dazz:

keiths: The natural numbers truly can be exhausted by a stepwise process. It just takes an infinite number of steps. [Dazz] That’s what I’ve always understood too.

An infinite or endless process is of course exactly what cannot be completed in finite stage cumulative steps. Fallacy of ending the endless. After every k, k+1 steps we can throw away what has gone before promote the subscripts to full counts, and act as though this is the beginning, and be no closer to ending the endless, and that can be done in an endless loop to the same effect. Above I set k = 10^150 then its square 10^300. Makes no difference. What we can do is do something enough to show a potential infinity then point onward with an ellipsis and act on that ideal, that vision, that mental abstraction, that proposition. And maybe that is the problem, do you accept the difference between the contemplative mind and the rock that can have no dreams? KF kairosfocus

KF, Of course, the set of natural numbers is defined inductively. That's why I wonder how you make sense of the entire "completed" set N in the first place. However, the proofs of "for all natural numbers n, if n is finite, then n + 1 is finite", and "for all integers n, if n is even, then n + 1 is odd" are not recursive or inductive. Edit: Your post above illustrates what I said above. I don't think you can speak of a "completed" set N. daveS

DS, if we start from 0 is in N then say for each n in N S(n) its successor is in N, that is recursive. And the successive process will lead to a finite set of bounded numbers -- which by being exceeded in turn will be finite [and notice how the looping emerges as the successor has its own etc] -- but cannot exhaust the full set which is endless. It points to it as a potential but not completed infinity of process. Cf the von Neumann type establishment from {} -->0, {0} --> 1, {0,1} --> 2 etc. This shows a potential infinity and as per usual, goes to the fulness of the set with that ellipsis. KF kairosfocus

KF, No, there is no recursion or endless looping in the proof of the statement "for all natural numbers n, if n is finite, then n + 1 is finite". Here's a simple example that may be less confusing: * (for every n) if n is an even integer, then n + 1 is an odd integer. To prove this, let n be an even integer, so n = 2k for some integer k. Then n + 1 = 2k + 1, which is odd. This proves statement *, with no recursiveness or endless looping. I agree with the wikipedia quote, by the way. daveS

DS, you don't see the recursiveness involved, aka endless looping? KF PS: Wiki on Peano: "Axioms 1, 6, 7 and 8 imply that the set of natural numbers contains the distinct elements 0, S(0) [successor to 0], S(S(0)), and furthermore that {0, S(0), S(S(0)), …} [subset or equal to] N" kairosfocus

KF, No, the relevant part of my proof above consists of 3 sentences, with no "looping" construction or repetition. daveS

DS, n to n +1, repeat. KF kairosfocus

KF,

DS: Do you see the sub-axiom at work? *** The point here is that what we can properly do is case 0 or case 1 depending, and the chaining claim c-k => c-k+1, which then chains in an endless loop. That is unlimited but it cannot exhaust endlessness and looks at taking the leap to the end of the rainbow.

No, there is no endless loop in the proof of "if n is finite, then n + 1 is finite". Take an arbitrary natural number n > 0. Then n = {k ∈ N | k < n}, which is a finite set, so no "EoE" here. BTW, I'm using the von Neumann definition of ordinals here, as you have throughout this discussion; the finite ordinals coincide with N. But then n + 1 = n ∪ {n}, another finite set, so n + 1 is finite.

And for every n begs the question, what is n and how do we get there.

n is a natural number. It is either 0 or the successor of a natural number. The axioms describe exactly what they are and how we "got there". daveS

VC, that is a heart of the issue, there is no stepwise, finite stages, cumulative attainment of an actually completed infinite. We point to the potential and sweep across an ellipsis of endlessness. KF kairosfocus

Aleta, Beyond means taking the set as a whole in one step and in context of the ordinal sequence putting up w as successor. KF PS: When I look at the vases faces gestalt image I can see a superposition of the two interpretations, especially when colours other than B/W are used, and I can switch mode to rapid alternation of the two views too. Long time ago now, a pastor used to talk of how when John used an ambiguous word strategically he often means both senses as a subtle wordplay of superposition and mutual mirroring to send a richer yet sense -- double meanings on steroids I suppose. Q-bits anyone? kairosfocus

DS: Do you see the sub-axiom at work?

If K is a set such that: * 0 is in K, and * for every natural number n, if n is in K, then S(n) [--> the successor to n] is in K, then K contains every natural number.

The point here is that what we can properly do is case 0 or case 1 depending, and the chaining claim c-k => c-k+1, which then chains in an endless loop. That is unlimited but it cannot exhaust endlessness and looks at taking the leap to the end of the rainbow. The sub-axiom is carrying the heavy weight, again. And for every n begs the question, what is n and how do we get there. KF kairosfocus

For clarity, here's a better-formatted version of the axiom of induction:

If K is a set such that:

* 0 is in K and * for every natural number n, if n is in K, then S(n) is in K

then K contains every natural number.

daveS

KF, Just out of curiousity, have you read the wikipedia page on the Peano Axioms carefully? If you haven't, I think it would answer quite a few of your questions, for example why an infinite Turing Machine tape need not have any cells infinitely many steps from the single end. (Not that this is inconceivable, but it's not necessary and is certainly not how people typically think of these things). Here's part of the section on the Axiom of Induction, which reads:

To do this however requires an additional axiom, which is sometimes called the axiom of induction. This axiom provides a method for reasoning about the set of all natural numbers. If K is a set such that: * 0 is in K, and * for every natural number n, if n is in K, then S(n) is in K, then K contains every natural number.

The simple proof of the finitude of all natural numbers that Tao wrote has K = the set of all finite natural numbers, and because K satisfies both starred hypotheses, K is all of N. Hence every natural number is finite. You've expressed doubts about whether mathematical induction can accomplish such a thing, but the fact that it can is actually an axiom. And if you're going to discuss N, then that axiom is in the "rule book", so to speak. daveS

kairosfocus:

VC, KS may be expressing phenomena tied to Hilbert’s Grand Hotel Infinity. Endlessness cannot be traversed in finite steps, and at any particular point the stepwise process will have only attained a finite extent, ever pointing onwards to the potentially infinite — as opposed to the actually completed infinite.

There isn't any such thing as "the actually completed infinite". Infinity is a journey, a never-ending journey. Virgil Cain

I have to go to work today, (I'm mostly self-employed), but I'll say this: You write,

in looking at the chain of counting sets as laid out in a von Neumann type construction, and in applying ordinary mathematical induction to this, we have only really addressed what an endless loop algorithm can do. That is, we have an in principle endless procession of cumulative finite stage steps. This is utterly distinct from claiming to have exhausted, or actually completed or ended the endless. Instead, we must recognise the ambiguity, and we must reckon that anything reachable by a stepwise finite stage process will by definition be finite and bounded by a successor. However such a loop process cannot exhaust endlessness. Thus, we are forced to make a conceptual leap — by way of implicit sub axiom — to an ideal view of a completion we cannot attain stepwise, and we then proceed beyond the ellipsis of endlessness.

More or less agree, if you take "beyond the ellipsis of endlessness" to be a metaphor for contemplating the set as a whole in the manner of Cantor. However, if "beyond the ellipsis of endlessness" means that within the natural numbers there is some "far zone" that is beyond the reach of the finite numbers created by k > k + 1, then no. Unless such "far zone" can be defined with some mathematical precision, and I don't believe it can, I think your feelings about it are really about the mystery of trying to intuit an infinitely large set. And since we really can't intuit the infinite, the thing to do is fall back on what mathematics tells us, as per Cantor and transfinite mathematics. Aleta

F/N: I only very rarely look at TSZ, but just did so on a Feb 1 KS post that of course sneers at the benighted fundies that cannot get their heads around how a set with all members finite and separated by finite stages can be transfinite or endless. Evidently, there is a failure to see that finitude inherently speaks to boundedness and the infinite to boundlessness or endlessness. I suggest to KS, there is an issue of the ellipsis of endlessness and there is a difference between a process that being stepwise and cumulative on finite stages can only ever be bounded -- For k has k +1 to follow -- and the endlessness it points to. That is there is a difference between the potentially and actually infinite and even an endless loop that takes finite steps cannot span the ellipsis of endlessness. We are forced to take a sub axiom of completing the span by pointing, and address the emergent phenomenon of endlessness in its own terms. That is w succeeds the ellipsis, not any particular finite member of the set that collects successive counting sets aka the naturals. It is a limit ordinal, as Wolfram reminds and as was mentioned above. KF PS: SalC, pardon my taking up your argument as it aptly illustrates my point about the sub axiom being implicitly used:

Let n = 1, then n is finite since there exist a number which is greater than n, namely n+1. By induction we show all natural numbers are finite since there exists for every n, a natural number greater than n, namely n + 1. For there to be a natural number n+1 for every n in the naturals implies the set of naturals is infinite.

This first chains, not recognising that chaining in steps in an unlimited loop will only progress in steps. So, at any pair n, n+1 we reset by promoting the subscripts and it is as though we have only just begun. We are chasing the end of the rainbow which is always unreachably far ahead of us. Ordinary mathematical induction is inherently dependent on finite step, stepwise cumulative chaining and does not in itself bridge the endless, as say we see in 217 above. So, what is done is to implicitly bring in the ellipsis of endlessness and span it in one step. The Reddit discussion has the same pattern, jumping from n to n+1 then spanning endlessness in one onward leap. Yes, the set that collects successive, cumulative counting sets is inherently endless. That is the point. And inferring from the inherent finitude of cumulative steps that the endlessness as a whole only contains the finite as members becomes paradoxical. The sub axiom of the long jump across the endless is carrying the weight of the conclusion. And when one premise carries all the weight, that is a point that should give us pause. Circularity beckons. So does the problem of ending the endless in one swooping conceptual leap. Hence, my concern. PPS: I see the point that there is a reasonable bridge between information and entropy is still a problem. (Cf April 10 2015 thread here.) I simply note that again, and observe there is a paradigm shift. Please see Harry S Robertson on Statistical Thermophysics. I point to the discussion in Thaxton et al, TMLO chs 7 - 9 and to the observation that there is a difference between clumping from scattered state and functional organisation on configuration to specific plan. One may speak of work to clump and onward work to configure, and to relevant entropy reductions, which as this is a state function can be done in principle all at once. The point remains since 1984 that it is maximally implausible for such ordering and organising to functionally specific pattern to occur by blind watchmaker forces. And, as a personal note on tone, I have no need to prove to you re my qualifications, which you know to be legitimately acquired. kairosfocus

PS: This then opens up the issue of the closed interval [0,1], the infinitesimals next door to 0, and the catapult hyperbolic function 1/x that pushes such infinitesimals out to the transfinite zone, starting with the Hyper Reals and Hyper Integers. The issue then begs for an answer, how are such related to the naturals and reals, ordinals and transfinites as we have explored. Above, I have played with some speculative models of exploration and they suggest that if we define mild infinitesimals m, we can project to the transfinite zone and create a continuum there between w +k and w+ (k+1) etc, where the ordinals by direct analogy to the real number line and the naturals, will be like milestones. Hard infinitesimals h, we can then project onwards out to the zone of the continuum cardinality, whether that be aleph 1 or some successor or whatever. But this is little more than playing with ideas, it is part and parcel of stirring the pot, an explicit theme of this thread of discussion. If this is feasible and coherent on serious analysis, I cannot say, but I can say that the playing around in a sandbox for a few moments is interesting -- as it was interesting for me as a child with a real sandbox. And it suggests the further point that we need to bring together the various models of the transfinite zone and clarify their relationships. kairosfocus

Aleta There is some closeness here. In 217 I laid out an endless loop algorithm that shows the stepwise process of advance which cannot exceed the potentially infinite. Not least, that at any k, k+1 pair, the whole can be started again as though it were 0. Just promote the subscripts. Loop after loop as an unending unlimited process short of pulling the plug. This immediately implies that ordinary mathematical induction is unable to transit to the actually exhausted transfinite. It can show that we have a potential infinite and that to any actual value we can attain stepwise or write down

[which is tantamount to the same; as, the place value number writing system . . . p*b^k+1 + q*b^k . . . *b^1 +s*b^0 + t*b^-1 + u*b^-2 + . . . (b, the base in use -- often 10 but sometimes 2, 12, 20 or 16 or 8 or 60 etc ) . . . is a finite in fact potentially infinite power series, note its own ellipses of endlessness]

it will hold by chaining: that Claim-X hanging on Claim-X, case 0 or 1 by successive implication also holds. However, that is in itself a limitation of the potential infinite. The ellipsis carries a lot of weight, and there is the implicit resort to a conceptual step across the transfinite span of the ellipsis, what I have called a sub axiom that is carrying a lot of weight. Contemplating the ideal, completed set that we cannot actually exhaust by stepwise process, we then assign it an order type w and a cardinality of endlessness in the first degree, aleph null. Through the ordinals, we revert to the same over and over again, and when we reach an uncountably large . . . not even countable in principle . . . one w1, we assign this the cardinality aleph 1, generally found to be the power set of aleph null. Then we continue again. The result of all this is there is a serious problem in how we tend to think about the naturals. The process of counting and pointing to the potential endlessness does not exhaust the endless, it only points to it. Then, when we go to ordinary mathematical induction, we go: here is claim C-0 or C-1, and here is a proof that for any pair k, k+1 C-k => C-k+1. Then we play the magic step of the ellipsis of endlessness and voila we say this pervades the endless. Process is imagined complete and the whole is said to have been swept in just one further conclusive step. This relies on what I have called an implicit sub-axiom. That is, the spanning of the ellipsis of endlessness by pointing. This carries a lot of weight and is ambiguous between unending process and endlessness. I can see the reason for the deprecation, but I wonder how ever so many things in mathematics, science and engineering can get on without the ellipsis in maybe a tamed form. What this leads me to hold as a plausibly reasonable view for the moment . . . yes, I am emphasising provisionality . . . is that:

in looking at the chain of counting sets as laid out in a von Neumann type construction, and in applying ordinary mathematical induction to this, we have only really addressed what an endless loop algorithm can do. That is, we have an in principle endless procession of cumulative finite stage steps. This is utterly distinct from claiming to have exhausted, or actually completed or ended the endless. Instead, we must recognise the ambiguity, and we must reckon that anything reachable by a stepwise finite stage process will by definition be finite and bounded by a successor. However such a loop process cannot exhaust endlessness. Thus, we are forced to make a conceptual leap -- by way of implicit sub axiom -- to an ideal view of a completion we cannot attain stepwise, and we then proceed beyond the ellipsis of endlessness. In this case, we look at how, on conceptually traversing the ellipsis of endlessness (often implicitly), we contemplate the ideal set of counting numbers as a whole that we cannot actually exhaust; we assign this whole the order type w and the cardinality of first degree endlessness, aleph null. Where, the endlessness is in the LHS: {} –>0, {0} –>1, {0,1} –> 2, . . . {0,1,2 . . . k, k+1, . . . EoE . . .} –> w

What this says to me, is that we are dealing with a gap that is unbridgeable by ordinary stepwise processes. This means to me that we have no right to say that all potential counting sets in succession of actual endlessness are of finite scale, but we can freely say that all counting sets actually reachable by processes based on the stepwise approach will be finite. Finite, because we can always show them bound by going on one more step in some fashion. Once we move to the inherently abstract contemplation of the potential endlessness, we then can assign the whole ideal process of attaining the end of the rainbow an order type omega and a cardinality, the first degree of endlessness, aleph null. It seems that we are finite and bounded in ways we cannot even readily imagine. But at the same time, we can contemplate the ideal world, here we can dare say, the form of the endless and transfinite. The ghost of Plato is laughing. Coming back, we see that there is always a problem when one claims or implies traversing the endless in a stepwise, inherently finite process. Which, to my view, would include claims about an actually endless and now completed to present, causal chain . . . EoE . . . Ck+1 --> Ck --> . . . --> Cn, now. Ending the endless through a stepwise, inherently finite process of successive, cumulative chaining is a fallacy. As an endless cycling of the wheels on a vehicle gripping a road can only ever attain a finite distance -- as, one can always drive on a bit further -- so also, stepwise, finite stage cumulative processes cannot span the transfinite. Which can be shown by cycle counting an endless loop algorithm. Cycle k always leads to cycle k+1 and we can promote the ellipsis and in effect start over again, no closer to exhausting endlessness than we were before. There is a verse in the grand old revival hymn, Amazing Grace:

When we've been there ten thousand years... bright shining as the sun. We've no less days to sing God's praise... than when we've first begun.

Strikes me, there's some'at in that. KF kairosfocus

Hi kf. I've had some further thoughts that clarify some things for me. The central idea is that the ellipsis itself is an ambiguous symbol that can be interpreted two ways, and that the tension caused by this ambiguity is possibly the source of some of your cognitive dissonance and sense of paradox. Building on the distinction I made in 352 between process and product, I see now that possibly the ellipsis itself can be interpreted to mean either process or product. (In fact, Wikepedia says, "The use of ellipses in mathematical proofs is often discouraged because of the potential for ambiguity. For this reason, and because the ellipsis supports no systematic rules for symbolic calculation, in recent years some authors have recommended avoiding its use in mathematics altogether.") So here is my idea: I can think of two ways to interpret the ellipsis, and this corresponds to the distinction I made in 352. You can think of the ellipsis as standing for the rule that creates the natural numbers: given any k, there is a k + 1. This is what I mean in saying that the ellipsis stands for the process. It means "keep on going, following the pattern." However, and occurred to me after writing 352, instead one could think of the ellipsis as standing for all the remaining members of the set. That is, it could represent the entire set of numbers not hitherto enumerated. With this interpretation, the ellipsis would stand for the entire infinite result of the process and not the process itself. It may be that this ambiguity is part of what is confusing. The ellipsis as process only produces finite numbers, and at any moment only a finite number of them. The ellipsis as product interpretation includes the entire infinite set. So like the Gestalt faces/vase I referenced in a earlier post, flipping back and forth between the two ways to interprete the ellipsis might be the source of your cognitive dissonance. With one view, you only see a finite number of elements, and with another view you see an infinite number. However, because the process/product distinction isn't clear, your attempt to see both meanings at once, with an emphasis on the product interpretation, leads to your sense that there must be something more, something infinite, in addition to the finite number produced by the step-wise process. Aleta

re 351: interesting and useful comments. You write,

My thought is, on endlessness there SHOULD be transfinitely remote rows in an endless tape, or equivalently that the endless succession of incrementing counting sets should at the remote zone attain to the transfinite

Although "remote zone" is left undefined, it seems that this formulation says that the natural numbers, as defined by N = {0, 1, 2, 3, ...} contains both finite numbers, which can be reached by steps, and, by virtue of the ellipsis, also transfinite numbers which cannot be reached by steps, but nevertheless exist out of reach. Your argument for this is in the next paragraph,

And if all such rows or successive counting sets in sequence are in fact finite, then it would seem that the extent must be finite.

That is, there can't be an infinite set of numbers all of which are finite. I don't believe this formulation is mathematically viable in that it could not be rigorously defined. I believe this formulation is trying to grasp a real and important notion, endlessness, but that concepts such as "beyond the ellipsis" and "remote zone" are more metaphors for the result of endlessness than they are mathematical ideas that could ever be properly formulated. The part that you quote after "I have a suggestion" may help me explain further, and may lead to some common understanding. You write,

stepwise processes point to the endless and manifest the potentially infinite. This includes ordinary mathematical induction as well as counting set chains and processes that are tied to such. On conceptually traversing the ellipsis of endlessness (often implicitly), we contemplate the ideal set of counting numbers as a whole we cannot actually exhaust; we assign this whole the order type w and the cardinality of first degree endlessness, aleph null.

I think the part I bolded is a key. To help explain, I want to distinguish between the process of endlessness and the result. In respect to the natural numbers, the ellipsis refers to the unending nature of the process: we can always take a next step. This is concrete and can be formulated mathematically with precision. However, when we try to conceptually grasp the result of that unending process, we go beyond what we can mathematically formulate within the framework of the natural numbers themselves: when we, to use your nice phrase, "contemplate the ideal set of counting numbers as a whole we cannot actually exhaust," we are stepping "up a level", so to speak, in our conceptualizing. Even though mathematicians and others have been contemplating the unending infinite for a long time, Cantor formalized it in the way you state: "we assign this whole the order type w and the cardinality of first degree endlessness, aleph null." That is, we take the concept of the result of unendingness and give it a name: as I described in a post on the history of math, we create a new kind of number, starting with aleph null, and from there build a whole new branch of mathematics concerning transfinite numbers. So here is one way to think about resolving the issues you have brought up: a way that doesn't involve "traversing the ellipsis" nor any "remote zone". We can look at either endlessness as process or we can look at the result of endlessness as the concept of an infinite set. Endlessness as a process is what the ellipsis inside the natural numbers means. When we write {1, 2, 3, ...}, the ellipsis refers to the process by which this set can be built endlessly. The ellipsis does not, however, refer to the result of the process. The result of the process, the "ideal set of counting numbers as a whole we cannot actually exhaust" is described with a number (not an ellipsis) that is not in the natural numbers. Aleph null, stands above, so to speak, the natural numbers, and formalizes our concept of an ideal set - one which is infinite. It is aleph null which contains the resolution of your concern by encapsulating the infinite nature of the result of the unending process expressed by the ellipsis. This distinction helps me, at least, understand how to resolve the sense that you describe that there has to be something else "out there", remotely and transfinitely beyond the finite naturals that can be reached in steps. The "remotely out thereness" of the set of natural numbers - there infinite nature, is dealt with by the mathematics of transfinite numbers, but it doesn't include anything inside the set of natural numbers. All there is in the set of natural numbers are finite numbers, and an unending process. The result of that process - an infinite set - is captured by the transfinite number aleph null. Probably this explanation will not allay your concerns. However, I am convinced that the intuitions you have about what is "beyond the ellipsis" could never be mathematically formulated. And to summarize, I think you are trying to squeeze concepts into the natural numbers that don't need to be there, and are adequately resolved by the created of the transfinite numbers to symbolize and work with the "ideal set of counting numbers as a whole." Aleta

Aleta, My thought is, on endlessness there SHOULD be transfinitely remote rows in an endless tape, or equivalently that the endless succession of incrementing counting sets should at the remote zone attain to the transfinite. I use zone to emphasise endlessness and nonspecificity. The ellipsis of endlessness is again pivotal. And if all such rows or successive counting sets in sequence are in fact finite, then it would seem that the extent must be finite. I have a suggestion (now with a spot of adjustment for further specificity):

unlimited cumulative stepwise processes based on finite stages point to the endless and manifest the potentially infinite. This includes ordinary mathematical induction as well as counting set chains and processes that are tied to such. On conceptually traversing the ellipsis of endlessness (often implicitly), we contemplate the ideal set of counting numbers as a whole we cannot actually exhaust; we assign this whole the order type w and the cardinality of first degree endlessness, aleph null. Where, the endlessness is in the LHS: {} -->0, {0} -->1, {0,1} --> 2, . . . {0,1,2 . . . k, k+1, . . . EoE . . .} --> w

Could this be a way forward? It seems to capture my thought and points to my concern. Notice, this implies a distinction between open-ended chaining of induction and actually exhausting the ellipsis of endlessness. KF kairosfocus

re: 348. I am trying to understand the concern. However, it is confusing to me when you make replies that don't clarify the questions I've asked. Obviously, all the rows that can be reached by steps are finite - we've agreed to that. What I am asking is this: are there actual numbers that are "endlessly distant"? In 345, you said, "If there is endlessly remote tape there will be rows of appropriate rank, and that raises the point they should be beyond any finite scale away." Assuming the pronoun "they" refers to "rows", this seems to say that some rows will be "beyond any finite scale away", which I assume means they would be an infinite scale away. So I am not sure whether you are saying that there are, or that there are not, numbers an infinite (endless) distance from the starting point. Therefore, the question: Are there numbers an infinite distance from the starting point I understand you have a concern. Answering this question will help clarify the concern. Aleta

VC, KS may be expressing phenomena tied to Hilbert's Grand Hotel Infinity. Endlessness cannot be traversed in finite steps, and at any particular point the stepwise process will have only attained a finite extent, ever pointing onwards to the potentially infinite -- as opposed to the actually completed infinite. I am suggesting that if that is his meaning it would be much as the case in 217 above. KF PS: I have seen someone point out that the eschatological kingdom would be of that character, potentially infinite in the mathematical sense but enduring ever after unto ages of ages without end. Indeed, here is Dan 2: "44 And in the days of those kings the God of heaven will set up a kingdom that shall never be destroyed, nor shall the kingdom be left to another people." Note, endlessness. And of course all of this started with claims about an actually infinite spatio-temporal past for the physical cosmos we inhabit and its antecedents. I again suggest if the endless cannot be traversed in steps one way, it cannot the other way either. So the most plausible view is a finite past to our world. And yes that points to ultimate beginning and to cause. kairosfocus

Aleta, if the rows are all finitely distant, it would appear that they cannot at the same time be endlessly -- infinitely or better, transfinitely -- distant. Thus, the concern. And again that one step through the ellipsis of endlessness seems to be carrying a lot of weight. KF kairosfocus

The funniest part of this thread is taking place over on TSZ where keiths said there could be a finite set that keeps growing and growing forever that wouldn't be infinite. Seriously, he said that. Virgil Cain

Hi kf. First, I agree with you when you write, "the endlessness is pivotally important." The nature, meaning, and consequences of endlessness is what I'd like to discuss. You write,

If there is endlessly remote tape there will be rows of appropriate rank, and that raises the point they should be beyond any finite scale away

Question: Does the phrase "they should be beyond any finite scale away" answer my question in the affirmative: yes, there are numbers that are infinitely far away? That is, you answer Yes to the question "are there numbers in the set that are infinitely far away from the starting point?" Am I correct that you answer yes to this question? Aleta

Aleta, Observe how a step by step chain of counting or implication at any finite stage k --> k+1 can readily be started afresh, and will be just as far from the exhaustion of the ellipsis of endlessness as though we were starting from 0; indeed the 1:1 correspondence technique applies to the fresh labels, just go k -->0, k+1 --> 1 etc. But, routinely, such are extended through the ellipsis as though that were a single step that sweeps the board. Such seems to be typically a sub axiom, often implicit. As what bridges the ellipsis, it is doing the heavy lifting and is a focus for concern. Again, the endlessness is pivotally important. KF PS: Go to the tapes with 0.1 inch pitch for concreteness. If there is endlessly remote tape there will be rows of appropriate rank, and that raises the point they should be beyond any finite scale away. As, finite is tantamount to not endlessly remote. Thus my concerns. kairosfocus

KF,

DS, I exactly meant each term n to add up to n exploiting 1^i = 1. Now, what of the term n when n goes up without limit, what used to appear as the infinity symbol sitting on top of the sigma? KF

Well, as I stated above, the sequence a_n = n diverges. I don't know what this is supposed to tell me, however. daveS

Bumping 335: From 335: You’ve mention the sub axiom of the ellipsis of endlessness (EoE) several times, and also that of a far zone: it is these ideas that I don’t understand. It seems to me that you are saying that there are numbers in the set that are infinitely far away from the starting point as well as the numbers that are finitely far away. Question1 : Is this accurate? Is this what you are saying? Also, I've been thinking about what "far zone" might mean. Question 2: Is the far zone a region that contains numbers? Aleta

DS, I exactly meant each term n to add up to n exploiting 1^i = 1. Now, what of the term n when n goes up without limit, what used to appear as the infinity symbol sitting on top of the sigma? KF kairosfocus

Well, that's not terribly helpful. Here's how I interpret #336:

Term n = SUM (1^i) from i = 1 to n,

1^i = 1 for all integers 1, so we have:

SUM(1) from i = 1 to n

which is simply n of course. So Term n = n for all positive integers, and this sequence diverges. Something tells me you don't mean to add up a bunch of expressions of the form 1^i, however; why put a useless exponent on the 1? Would you please tell me what the sum is, exactly? daveS

336 kairosfocus

See my edit to #337. What's the sum again? daveS

DS, pls cf 336. KF kairosfocus

KF, The sequence of partial sums for the original sequence a_n = 1/n diverges, of course. Edit: Have to go for now, but I'm not sure what your sum actually is in #336. I thought you were talking about summing 1/1 + 1/2 + 1/3 ..., but it's not clear now. I don't know what you mean by the "span of the natural numbers", but of course the set of positive integers contains no largest member. To reply to your post #333 again,

DS, the set of positive integers is by definition endless. Endlessness counts, as I have pointed out. KF

If a necessary condition for a set to be "endless" is that it contains infinite members, then no, the set of positive integers is not "endless" in this sense. daveS

DS, Let us take the finite series terms: Term n = SUM (1^i) from i = 1 to n, Then, let n increase without limit, colloquially, increase endlessly, go to infinity. What happens to term n? What does this tell us about the span of the naturals? KF kairosfocus

Thanks kf: 1. I seem to understood correctly concerning the issue of "throwing everything away so far. 2. I also assume that we agree that both S1 and S2 in my example are infinite sets, because S2, a proper subset of S1, can be put in 1:1 correspondence. 3. You write in 332, and I agree. We can consider this a settled point.

A number reached or reachable by step by step finite stage counting processes will be finite, but an endless set of numbers cannot be exhausted by such counting processes. The counting process will only be potentially infinite.

4. You then write, and this is where I'd like to start today,

At some stage, the sub axiom of pointing to and filling out the ellipsis of endlessness in one step of generalisation will be called in. In the case of N, it is with a divergent sequence that is endless. ... If the tape is endless, how can its far zone only be finitely far away from the near end in 0.1 inch steps?

You've mention the sub axiom of the ellipsis of endlessness (EoE) several times, and also that of a far zone: it is these ideas that I don't understand. It seems to me that you are saying that there are numbers in the set that are infinitely far away from the starting point as well as the numbers that are finitely far away. Question: Is this accurate? Is this what you are saying? Aleta

KF,

DS, the set of positive integers is by definition endless. Endlessness counts, as I have pointed out. KF

I'm not saying that the set of positive integers has an "end", i.e., a last or greatest element. I am saying that in the sequence I defined, the differences between consecutive terms is always positive and never "infinitesimal". Likewise, 1/n is positive and not "infinitesimal" for all positive integers n. Edit: Wait, I just read #332. Are you saying that the set of positive integers, being "endless", therefore has infinitely large members?? daveS

DS, the set of positive integers is by definition endless. Endlessness counts, as I have pointed out. KF kairosfocus

Aleta, In the blue and pink tape examples, I set k = 10^150, and noted that a k, k+1, . . . onward sequence would match 1:1 with the original from 0, 1, 2 . . . (never mind discarding 10^144 miles of blue tape) due to endlessness. So, if k = 8 much the same would follow. KF PS: A number reached or reachable by step by step finite stage counting processes will be finite, but an endless set of numbers cannot be exhausted by such counting processes. The counting process will only be potentially infinite. The endlessness will exceed count processes and linked chaining processes such as inference case k => case k+1. At some stage, the sub axiom of pointing to and filling out the ellipsis of endlessness in one step of generalisation will be called in. In the case of N, it is with a divergent sequence that is endless. Where as the paper tape illustration shows, endlessness has significance. If the tape is endless, how can its far zone only be finitely far away from the near end in 0.1 inch steps? (And, does not the claim, all counting numbers are finite but the set of such as a whole is endless not then pose at minimum a paradox?) kairosfocus

You write, "[the issue] is that having hit k, k + 1 etc, we can throw everything away so far and put the onward count in 1:1 correspondence with the original count precisely because the onward count is endless." I'm not sure I understand this, so let me offer an example and you can tell me whether I am correct or not. Consider the set S1 = {1, 2, 3, 4, 5, ...} Now we "throw away everything so far" and consider the "onward count" S2 = {6, 7, 8, 9, ...} S1 and S2 can be put in a 1:1 correspondence because both sets are infinite, since both counts are endless. Is this an example of what you mean? If not could you give an example? Aleta

Good, kf, you combined the two statements into one, which I think could be stated as "A number can be reached by counting if and only if it is finite" That is, all numbers reachable by counting are finite, and any finite number is reachable by counting. I'm pretty sure that is all in agreement with what you wrote: "Aleta, a number REACHED by stepwise counting is finite and if finite it can be reached by a long enough count chain. " So this is progress. Now I'm going to think about your next sentence in 328, about what the issue is. And I really appreciate your willingness to take this step-by-step. Aleta

KF,

DS, your remark is tantamount to you stay in a finite band of n. That is exactly what the limit is not. KF

I defined the sequence as a_n = 1/n for each positive integer. Each positive integer is finite. The sequence does not contain any terms 1/n where n is non-finite. Yet it converges to 0. All this is completely standard. daveS

Aleta, a number REACHED by stepwise counting is finite and if finite it can be reached by a long enough count chain. The issue is not the finite neighbourhood of 0 out to some arbitrarily large k, k + 1 succession. No, it is that having hit k, k + 1 etc, we can throw everything away so far and put the onward count in 1:1 correspondence with the original count precisely because the onward count is endless. KF kairosfocus

DS, your remark is tantamount to you stay in a finite band of n. That is exactly what the limit is not. KF kairosfocus

KF, No, it doesn't go to "infinitesimal levels", ever. 1/n - 1/(n + 1) is always a positive real number. I assume we both know what a convergent sequence is, so maybe we should leave this issue for now and concentrate on N. daveS

Ok, next: 320 c, which we agreed on, says "No matter how far we count, we will never be infinitely far from zero. We will always be a finite distance from zero." Q1 for this post: Could we rewrite that in conditional form: if a number can be reached by step-wise counting, it is finite"? Q2: Is the converse true: if a number is finite, it can be reached by step-wise counting? So, is Q1 an acceptable rewrite of a point we have agreed on, and do you think the converse in Q2 is true, or not? Aleta

DS, did the force of the epsilon delta relationship in the neighbourhood of 0 as n increases endlessly make my point clear? The gap between 1/n and 1/(n + 1) goes to infinitesimal levels as n increases without limit. Note, that use of endlessness. 1/10 vs 1/11 is about 10% different 1/1,000 to 1/1,001 is 1/10 of 1% different already, and it goes on from there. think about the difference between 1(10^300) and 1/(1 + 10^300), then go onward without limit. KF kairosfocus

KF, The limit is zero, but all pairs of consecutive numbers in the sequence are a positive distance from each other and from zero. That's not a controversial statement at all. daveS

Aleta, I believe Q1 is yes, Q2 is it depends as there may be concept gaps, I won't go all the way to paradigm shift but that is related. KF kairosfocus

DS, what is the limit of the sequence {1/n} as n increases without limit, i.e. endlessly . . . and notice this routine use of endlessness in Math. I suggest to you that for any arbitrarily small delta neighbourhood of 0, the error [1/n - 0] = epsilon will be below delta for all SEQUENCE terms beyond some k, the particular k being dependent on how small delta is. Effectively k ~ 1/delta, actually the next whole number beyond it. That is the limit is zero and the size of 1/n diminishes without limit other than zero as n becomes endlessly large. KF kairosfocus

Good - this is progress. Summary: we agree about the following in respect to counting in step-wise fashion: a. We can never complete the endless. b. Claiming or implying ending or spanning or traversing the endless in stepwise succession is a fallacy. c. No matter how far we count, we will never be infinitely far from zero. We will always be a finite distance from zero. Good. d. The next step is to consider the statement whether there are numbers infinitely far from zero: I, Aleta, say "There are no numbers which are infinitely far from zero. Kf says "NO, THIS DOES NOT FOLLOW. NOT IN A WORLD OF ELLIPSES OF ENDLESSNESS WITHIN SETS THAT CONTAIN THE COUNTING SET SUCCESSIONS." So, two new questions: Q1: Do you agree that we have reached some clarity about what we agree on, and that we have an issue, d above, to address? Q2: Also, are you willing to continue to try to take things one or two statements at a time, continuing to search for agreement when we can? Aleta

KF,

The steps of extension are not finite all the way.

Well, the steps are actually positive all the way. 1/n - 1/(n + 1) = 1/(n*(n + 1)) is never 0 nor infinitesimal. In any case, I don't think there is any issue of redefining infinite to mean finite in the context of the natural numbers. daveS

M62, unfortunately, this is obviously not so simple. And I am acutely aware I am swimming upstream of conventional wisdom, due to concerns that point to at minimum paradoxes. This stuff is also freighted with pretty heavy potential worldview implications tied to the infinite past some claim, infinitesimals and calculus, the nature of numbers and more. KF kairosfocus

DS, Yes, the set 1/n is transfinite, it is a successive chain of rationals in the interval [0,1] i.e, an approach to the infinitesimals next to 0. The steps of extension are not finite all the way -- another use for infinitesimals. This is the same issue Zeno faced, and obviously this set is of same cardinality as n; and [0,1] is itself transfinite of order beyond aleph null. But with the counting sets the succession to endlessness is automatically enfolded in successive members and the increments are finite and divergent not convergent, there is no delta neighbourhood of a limit where beyond some point for any delta range all onward elements will be within delta of the limit. Where, we cannot actually span the endlessnes but we point to it. KF kairosfocus

Aleta: d. Infinite means “beyond any even arbitrarily large but finite value”. No matter how far we count, we will never be infinitely far from zero. We will always be a finite distance from zero. --> AGREED, IN CONTEXT OF COUNTING AS A STEPWISE PROCEDURE OR THE CHAIN OF SUCCESSIVE IMPLICATIONS IN ORDINARY MATHEMATICAL INDUCTION, ETC. c. There are no numbers which are infinitely far from zero. --> NO, THIS DOES NOT FOLLOW. NOT IN A WORLD OF ELLIPSES OF ENDLESSNESS WITHIN SETS THAT CONTAIN THE COUNTING SET SUCCESSIONS. KF kairosfocus

By definition, one cannot instantiate an infinite set. Therefore there cannot be an infinite number of past seconds (or any time interval you choose.) Is this really so difficult? mike1962

I was writing 312 when you posted 311, and am interested in narrowing things down to very precise statements, one at a time. You write, "That our counts or chains of implication taken in steps etc will always be finitely remote from a start point ." So we agree that as we count, we will always be a finite distance from our starting point. I agree with that statement. Do you agree with that statement? Aleta

KF,

I am beginning to think there is an implicit redefining of infinite to mean finite in the context of the naturals.

The set of natural numbers is infinite. It is not finite because it can be put in 1-1 correspondence with a proper subset of itself. There are many infinite sets all of whose elements are finite. Take the set of all 1/n where n is a positive integer. Every single element in this set is less than or equal to 1 and greater than 0. There are finite sets with only infinite elements. {ω, ω + 1, ω + 2}, for example. Edit: The cardinality of a set is independent of the magnitudes of its elements. daveS

Can you explain the conflict between c and d. Lets see if we can work together to come up with some language we agree upon. Do you agree with c and not d, or vice versa, and could you word either c and/or d in ways that you could agree on? Let's focus on what we do agree on. Aleta

Aleta:

c. There are no numbers which are infinitely far from zero. d. Infinite means “beyond any even arbitrarily large but finite value”. No matter how far we count, we will never be infinitely far from zero. We will always be a finite distance from zero.

That our counts or chains of implication taken in steps etc will always be finitely remote from a start point does not in my view imply that the set of counting numbers, as endless, will not go endlessly beyond any arbitrarily large but finite value. I am saying we cannot span the set in steps but can point to its endlessness by showing a typical pattern and pointing onward through ellipsis of endlessness. I think the two things I just said are consistent with each other, and do not entail that all in-principle counting sets are of finite cardinality. Endlessness of the succession implies or at least strongly suggests to my mind at least that some counting sets in succession will themselves be endless. Those, we cannot reach to by a finite span of steps of extension of the typical counting set that starts from {} --> 0, {0} --> 1, {0,1} --> 2 etc. That would seem to be required to get to endlessness [in principle], per the sort of issues in 217 above. KF kairosfocus

I agreed with two of your main points in 308. I also made two statements which I think are consistent with your position, and asked if you agree with them. Do you agree with c. and d. in 308? I know there are large issues, but perhaps we could make progress if we figured out what we agree upon. Aleta

Aleta, please see how I have cleaned up and highlighted. I think there is a significant conceptual issue. I am beginning to think there is an implicit redefining of infinite to mean finite in the context of the naturals. If they are endless, how do we say they are ALL finite apart from taking induction a bridge too far, from open ended reliability to traversing the endless? KF PS: Just above c seems jarring and in conflict with d in context. kairosfocus

You write,

[It] points to the potentially infinite but does not actually complete the endless. Claiming or implying ending or spanning or traversing the endless in stepwise succession — even of logical steps of inference — is a fallacy.

I agree with you. a. We can never complete the endless - I agree with this. b. Claiming or implying ending or spanning or traversing the endless in stepwise succession — even of logical steps of inference - is a fallacy - I agree with this also. We are in agreement. I wrote some similar statements: c. There are no numbers which are infinitely far from zero. d. Infinite means “beyond any even arbitrarily large but finite value”. No matter how far we count, we will never be infinitely far from zero. We will always be a finite distance from zero. Do you agree with my statements? They seem to be saying the same things that you are, so do you agree with my statements? Aleta

Aleta (& DS), I think the core issue is that something has gone wrong with the meaning assigned to infinite. So, there is a gap of concept at work -- which makes simplistic y/n answers meaningless; and, it is one where infinite in certain contexts seems to have been implicitly redefined to mean finite. Endless beyond any finitely, arbitrarily large value has been effectively erased, it seems when it comes to the Naturals. As at now, it seems to me that the way it has been done is based on a use of induction that is open to challenge. As I have I believe reasonably shown from 217 on, no inductive stepwise chain of extension of counting numbers can span the endless. Indeed when it reaches to any finite value k then k + 1 as immediate successor, we may truncate the so far and start afresh and still be at the beginning, indeed putting the onward chain in 1:1 correspondence with the original one. That is what the discussion on pink and blue punch tapes was about. Instead mathematical induction hanging from an initial value and succession logic or steps shows open-ended reliability and points to the potentially infinite but does not actually complete the endless. Claiming or implying ending or spanning or traversing the endless in stepwise succession -- even of logical steps of inference -- is a fallacy. We have implicitly imposed a sub axiom that pointing onwards suffices. In this case, the succession of counting sets incrementing step by step endlessly, actual endlessness seems to be material. KF kairosfocus

KF,

It comes to a point that if after that degree of emphasis has been put up, inquisitorial yes/no answers are repeatedly demanded, that is a sign that something is very wrong. And not with what I have said.

When Aleta and I ask for yes/no answers, that's exactly what we mean. We would like you to literally type "Y-E-S" or "N-O" in your reply, because we have such a hard time figuring out what you are saying. At this point, I'm still not clear what your position is. If you would actually answer yes or no, then it would save us a lot of guesswork. daveS

Aleta,

I’m sorry to have to interrupted Dave’s conversation with you (sorry, Dave), but it is not clear what your answer is because of all the confusion about what you think endless and infinite mean.

No problem at all! daveS

"Inquisitorial yes/no" questions!? OK, here is what I think your answer is. There are no cells (numbers) which are infinitely far from the end of the tape (that is infinitely far from zero). Infinite means "beyond any even arbitrarily large but finite value". No matter how long the tape runs (no matter how far we count), we will never be infinitely far from zero. We will always be a finite distance from zero. I would agree with both of those propositions. Have I stated them in a way that you could agree with? If we knew we agreed with each other on this, then maybe it would clear up some confusion. Aleta

KF,

See where oh the set is infinite but every number in it is only finitely large becomes of significant concern?

Erm, no, I don't understand the concern, tbh.

Indeed, meaning 3c above exploits that, as the reason a certain proper subset can be matched 1:1 with the original transfinite set is that both are endless. And with the punched tape illustration, every successive row is a standard 0.1 inches further along. So endless values in succession implies endless distance, giving punch to the meaning. If it is not REALLY that, go get your own words, infinite is already occupied.

But it is. It's trivial to see that the cells in the infinite tape can be put into 1-1 correspondence with a proper subset of its cells. We've already been over that. Associate each cell to its neighbor on its right (for the tape in the picture). I have yet to see a yes-no answer to my question. My best guess is that now you are saying that the thing I've been calling an "infinite Turing Machine tape" is not actually infinite?? daveS

Aleta (attn HRUN), I have been crystal clear and consistent, from laid out sequences of ordinals to dictionaries to concrete examples and on to asking pointed questions in that light. If infinite does not mean "endlessly beyond any even arbitrarily large but finite value or things tantamount to that," then it has been turned into a synonym for finite. It comes to a point that if after that degree of emphasis has been put up, inquisitorial yes/no answers are repeatedly demanded, that is a sign that something is very wrong. And not with what I have said. Where, it is precisely because the infinite as far as I can reasonably gather means as I have again summarised, that I find something jarring in the claim that per induction the set of naturals has only finite members in it although the set as a whole is transfinite in cardinality. Let me add: In terms of the punch tape example, if the endless extension of the tape does NOT have in it rows that are endlessly far from the originating end, something is wrong. So far, that we can take away any arbitrarily large but finite initial range from the tape and it would still be endless beyond. In that context I have repeatedly pointed to the importance of the ellipsis of endlessness, and have further noted that the EoE is in the LHS of the assignment of ordinal value: {0, 1, 2 . . . } --> w. (I have even gone so far as to examine the difference between unlimited extension of a chain of inferences per implication from case k to case k +1 in steps from an initial value and spanning the endless. In effect, there seems to be an often unstated but implicit sub axiom of spanning the endless through pointing onwards from a potentially transfinite chain, that is doing a lot of work and carrying a heavy load.) KF kairosfocus

So your answer is "Yes"??? Or is it "No" Please, answering the question with a paragraph with lots of rhetorical questions isn't useful. Just answer, with one word, Yes or No. Are you asserting that the infinite Turing Machine tape pictured here has cells which are infinitely far from the end? Aleta

Must. Not. Ever. Answer. Simple. Question! hrun0815

Aleta, I have actually gone back to ensure that the opposite is clearly intended. Let me put the just adjusted up again:

if infinite does not mean endlessly remote beyond any finite but arbitrarily large value, what does it mean? And, if it does not mean that any actually finite value is not endlessly remote beyond any arbitrarily large finite value — here at 0.1 inch per row, what does it mean? Where, too, if it does not mean that one may repeatedly — an arbitrary number of times, even with an endless loop algorithm — pull in any arbitrarily large but finite range (I picked 10^150 and its square to draw out the point) endlessly but have no effect on the remaining endlessness, what does it mean?

If your conception of the infinite is so radically diverse, why use the same terms? KF PS: I add that this includes that if one claims an infinite past of the observed cosmos and its physical predecessors, then one claims a past that is endlessly remote and spanning beyond any arbitrarily large but finite time of the past, e.g. 10^150 s or its square or its square of 10^300 s taken any number of times in succession without scratching the surface of the endlessness, etc. kairosfocus

Then your answer is No: there are no cells which are infinitely far from the end. Is this correct? Aleta

Aleta, if infinite does not mean endlessly remote beyond any finite but arbitrarily large value, what does it mean? And, if it does not mean that any actually finite value is not endlessly remote beyond any arbitrarily large finite value -- here at 0.1 inch per row, what does it mean? Where, too, if it does not mean that one may repeatedly -- an arbitrary number of times, even with an endless loop algorithm -- pull in any arbitrarily large but finite range (I picked 10^150 and its square to draw out the point) endlessly but have no effect on the remaining endlessness, what does it mean? KF kairosfocus

No, you haven't "given and emphatically underscored" an answer. You've repeated your concerns, but I can't tell whether your answer is yes or no. I'm sorry to have to interrupted Dave's conversation with you (sorry, Dave), but it is not clear what your answer is because of all the confusion about what you think endless and infinite mean. So Dave's question is trying to get to some specifics that clarify the concepts: Are you asserting that the infinite Turing Machine tape pictured here has cells which are infinitely far from the end? Yes or No Aleta

Aleta, already given and emphatically underscored. If not actually infinitely -- endlessly -- remote in the far left zone, then finite and not infinite. With the tape going at 0.1 inch per row leftwards. Hence, my conceptual concerns. KF kairosfocus

We know all this. What is your answer to dave's question? Aleta

F/N: Collins ED is even better:

infinite (??nf?n?t) adj 1. a. having no limits or boundaries in time, space, extent, or magnitude b. (as noun; preceded by the): the infinite. 2. extremely or immeasurably great or numerous: infinite wealth. 3. all-embracing, absolute, or total: God's infinite wisdom. 4. (Mathematics) maths a. having an unlimited number of digits, factors, terms, members, etc: an infinite series. b. (of a set) able to be put in a one-to-one correspondence with part of itself c. (of an integral) having infinity as one or both limits of integration. Compare finite2

KF kairosfocus

DS: AmHD:

in·fi·nite (?n?f?-n?t) adj. 1. Having no boundaries or limits; impossible to measure or calculate. See Synonyms at incalculable. 2. Immeasurably great or large; boundless: infinite patience; a discovery of infinite importance. 3. Mathematics a. Existing beyond or being greater than any arbitrarily large value. b. Unlimited in spatial extent: a line of infinite length. c. Of or relating to a set capable of being put into one-to-one correspondence with a proper subset of itself.

If it is not endless it is not infinite. If the far zone is such that every row of holes is finitely many times 0.1 inch away, it is not infinite. Begin to see where some of my concerns lie? See where oh the set is infinite but every number in it is only finitely large becomes of significant concern? See where issues of concept arise? Infinite implies boundless, beyond ending, not finite. Indeed, meaning 3c above exploits that, as the reason a certain proper subset can be matched 1:1 with the original transfinite set is that both are endless. And with the punched tape illustration, every successive row is a standard 0.1 inches further along. So endless values in succession implies endless distance, giving punch to the meaning. If it is not REALLY that, go get your own words, infinite is already occupied. KF PS: For meaning 3c, try starting the count over from k = 10^150, recognising that this is simply a finite subset capable of being put into 1:1 correspondence with the original set. Think, a pink and a blue tape, only you pull in the blue 10^150 holes (~10^144 miles) and then match it against the pink tape's 0 end. Endlessness is endlessness, it makes no difference. PPS: After you do that, pull in to the 10^300th hole, 10^150 times the first distance . . . use the first pull as a yardstick and do it 10^150 times over. Then put the blue tape in match with the pink -- conveniently, holes can be optically lined up. There is still no difference. PPPS: Do it over and over again with no end (use an endless loop algorithm), no difference. Endlessness is endlessness. P^4S: the observed cosmos is about 5 * 10^23 mi across. kairosfocus

Gotta run now, but is that a "yes"? daveS

DS, endlessness is endlessness, it cannot be finite. There is no LH end and the remote zone is infinitely far away, with endless holes 0.1 inch apart all the way. KF kairosfocus

KF, I guess you're talking about an infinite Turing Machine tape with an end on the right but no end on the left? Like in the picture, but with directions reversed? If so, that's what I have in mind. [Edit: To be clear, my tape consists of just a single row of cells.] My question (for the third time) is:

Ok let’s be very clear. Are you asserting that the infinite Turing Machine tape pictured here has cells which are infinitely far from the end? This is a yes/no question.

daveS

DS: Okie, let us compare, showing end to RHS and endlessness to LHS: Counting No's N: . . . EoE . . . k+1, k, . . . 2, 1, 0 Tape Rows: T: . . . EoE . . . R_k+1, R_k, . . . R_2, R_1, R_0 All at 0.1 inch pitch, per standard. The relevant part in both cases is. . . . EoE . . . Endlessness to LHS means for the tape unending rows at 0.1 in pitch. Set k = 10^150 and it would be 1.58*10^144 miles from the start with no end of onward rows to come, indeed, you could start the count from k (just use the subscripts) and it would make no difference to what is to the L. An actual infinite tape would have to be endless to the L, and an actual endless timeline of causal events and entities would be the same, only in time. KF kairosfocus

KF, By an infinite Turing Machine tape, I mean one in which the cells are in 1-1 correspondence with the set of natural numbers. In the picture I linked to, the leftmost cell is cell 0, the first one to its right is cell 1. Cell n is n steps to the right from cell 0, for any natural n. I don't know what you mean by "remote zone" here, but I will say that if you took two of these tapes and cut off the first 10^150 cells of one of them, they would remain indistinguishable (assuming no symbols had been written in the cells). And obviously I can't draw a picture of the entire tape. Nevertheless, we have been talking about an infinite Hilbert Hotel without any pictures. So again, are there any cells in this tape infinitely many steps from cell 0? Edit:

The tape, so far as I can understand, must be endless to be infinite. KF

Well, in the picture, there is no right-hand end to the tape. Each cell has an adjacent neighbor to its right. daveS

DS, you tell me what infinity means to you, please. Then, let us see an actual picture or drawing without ellipses or open ended lines or perspectival tapering to a point at the horizon or other vanishing point, of what an actual 0.1 inch pitch 8-wide paper tape would look like. Row 10^150 would be 10^149 inches off or 1.58*10^144 miles from the start with no end of onward rows to come -- row k here would be formally equivalently far from the remote zone as row 0. The tape, so far as I can understand, must be endless to be infinite. KF kairosfocus

KF,

In rejecting that by claiming every past point is finitely remote, that is tantamount to a finite past. If every “milestone marker” to the left — pastwards direction — is finitely remote the total increment of necessity will be finite. KF PS: Same, for a paper tape

Ok let's be very clear. Are you asserting that the infinite Turing Machine tape pictured here has cells which are infinitely far from the end? This is a yes/no question. daveS

Aleta & DS, Don't you see that you agree with me by implication? Take the model: // . . . H:k+1, k, . . . 2, 1, 0. At every finitely remote k + 1, k, the H shows that was once the present. But the subscripts allow us to lop off the tail and go: // . . . H:k+1, k | Obviously this is formally equivalent to (using primes for the new onward k's): // . . . k'+1, k', . . . 2, H:1, 0 | which is just as remote from any infinite past to the left beyond the "break" marks. The claim of an infinite past looks to be meaningless, it is reducing to claims of a finite past (of whatever extent) but with an endlessness tacked on that cannot be represented or accepted. If there were an infinite causal, temporal past succession of events and entities, the past would have to stretch off leftwards like the negative x axis with an arrow pointing to infinity in the past or off to the left. In rejecting that by claiming every past point is finitely remote, that is tantamount to a finite past. If every "milestone marker" to the left -- pastwards direction -- is finitely remote the total increment of necessity will be finite. KF PS: Same, for a paper tape kairosfocus

KF,

DS, Let us look at two managers, one who starts at the far zone of the hotel infinity and inspects rooms, one from the near zone. Both set out at one room per second and have to inspect all rooms. Will either ever complete, why? KF

Aleta is right, there is no such "far zone". Also, the manager we have been talking about, who is just finishing the tour now, never "set out". If you had simply asked whether a second manager, starting now at the front desk and working backward would ever finish, the answer is no. But again, the situation is not symmetric; one manager began at a specific point, the other one was on a beginningless tour. Now, can you answer my simple yes/no question: Are any cells on the infinite Turing Machine Tape infinitely far from the end? You can explain all you want, but I'm requesting that you first respond with either "Yes" or "No". daveS

You can't start in the "far zone". There is no "place" at negative infinity to start. You can inductively move towards infinity, so to speak (an informal way of saying going on endlessly), but you can't move from infinity back to zero. It makes no sense to speak of "starting in the far zone." If you want to start someplace a long ways before zero, you still have to start at some finite number. So, meaningless question. Aleta

DS, Let us look at two managers, one who starts at the far zone of the hotel infinity and inspects rooms, one from the near zone. Both set out at one room per second and have to inspect all rooms. Will either ever complete, why? KF PS: I add, an endless paper tape has rows of dots, as follows: r0, r1, r2 . . . . EoE . . . Whichever way you pass it through a read/write head -- say it is the way clean/dirty rooms are recorded -- it is the same, and to have been going from the infinite past and have reached a finitely remote k from 0 is like: . . . EoE . . . H:k+1, k, . . . 2, 1, 0. But to get to k, first you have to do: . . . EoE . . . H:p+1, p, . . . EoE . . . k+1, k, . . . 2, 1, 0 You cannot traverse either of the two EoEs in steps. PPS: Any 0, k, or p will be infinitely far from the far zone of the tape, which is endless. And p will be transfinitely remote from both the far zone and the 0 end. In short you cannot have your cake and eat it. My point is, no transfinitely long tape or tape r/w process proceeding in steps will be actualisable. A tape may loop in a finite span or run finitely in a line but it will not be open ended and transfinite. Or, loop and be transfinite. PPPS: Let me symbolise a transfinite loop, the :0* being plugged into the ^0 to loop. ^0 . . . EoE . . . H:k+1, k, . . . 2, 1, 0* kairosfocus

KF, An infinite Turing Machine tape with a single end is a good model for the HH, with each cell representing a single room, and the "last" cell representing the front desk. Given such a tape, how many cells are infinitely many steps from the last cell? None, right? Edit: Here's a picture. I am thinking of the tape oriented in the opposite direction so that the last cell is on the right (so the manager moves from left to right), but of course that makes no essential difference. Which cell is infinitely far from the end? daveS

KF, I'm going to insist on no rephrasings here. If you have a critique, please use the same language I am using. What I'm saying is that the manager completes a tour of the HH presently, according to the schedule I laid out. The process is beginningless, it is true. Edit:

Where if infinite past means anything at all, it means that at some point in the causal succession there was an endless span of steps to be bridged to reach here.

No, that's not what I understand it to mean. We've been over this repeatedly, but the manager was never more than finitely many rooms away from the front desk. daveS

DS, And so you are trying to span the endless in steps from the suggested infinite past. But, you do not even have a first step, just a claimed forever continuation. Where if infinite past means anything at all, it means that at some point in the causal succession there was an endless span of steps to be bridged to reach here. This is a contradiction in terms and in concept as well as a failure of the sequence to span in steps. If we cannot ascend to the endless and the transfinite, apply the mirror reflection, we cannot descend from it either. And in HGHI, the manager cannot inspect the rooms in toto in steps for the same reason. KF kairosfocus

kf, we agree: "No step by step unlimited process can exhaust the endless", given that is what "endless" means. Going on endlessly doesn't "span" anything - it just goes on and on and on ..." Aleta

KF, Since this process is beginningless, it cannot be described by an algorithm. I have already given all relevant details of the manager's tour: He was in room number -n, n seconds ago, for every natural number n. Clearly no rooms were missed, and the tour ends at the present. Note that there is no analog to the "ellipses of endlessness" in the HH. Edit: No ω's either. daveS

Aleta, I have pointed out the concern and how it comes out given the implicit sub axiom of ellipsis of endlessness. Notice, I have shown that no step by step unlimited process can exhaust the endless [at any k, k+1 etc the process starts over again from effective start point and cannot span], so there is an implicit axiom that does the work. KF kairosfocus

DS, set up the algorithm and show it. KF kairosfocus

kf writes, "Just a refocus on context." No, just a rehash of things already said multiple times, without addressing my main points in 253: a simple proof that all numbers in N are finite, which fails only if there is some third kind of number in N (not finite but not transfinite) that "reflects transfinite nature" and is somehow "beyond the ellipsis" yet still in N. However, kf doesn't address the issue of trying to mathematically supply some specifics about these numbers, or any other part of what he thinks exists if all natural numbers aren't finite. So, kf has a intuitive concern about something ("ending endlessness?"), but isn't able to specifically or mathematically give it any coherence. I've tried pretty hard to understand his perspective, but that's my summary of the situation. Since it doesn't look like there will be any further progress, I believe (again) that this is the end of the discussion. Aleta

KF,

We need to live with a world that manifests an inherently finite past succession to date.

However, assuming an infinite past, the manager of the Hilbert Hotel could, proceeding at a rate of one room per second, complete the inspection of every room today. Recall that this is a beginningless tour, not an endless tour. daveS

F/N: all of this points to the issue of claimed or implied actual completion of the endless, which is where we started. Viewing the cosmos as causal succession: . . . C_k --> C_k+1 --> . . . C_n, now we see that a causal succession embeds a succession of states. Is the LHS ellipsis a completed EoE so that we are in the zone w + g i.e. the past was transfinite? Nope, as EoE cannot be bridged or traversed in finite steps. Language alone is already trying to warn us. A finitely remote initial point is indicated, as was discussed already. This is just a contextual reminder. Nor does it work to say at any p in the past we are only finitely remote onwards from k and we can repeat endlessly: . . . C_p --> C_p+1 --> . . . C_k --> C_k+1 --> . . . C_n, now No, the ellipsis on the LHS is still there and would still be endless. Yet worse is the case where one implies an endless causal succession in the past to the present, which if it means anything means that for some p': . . . EoE . . . C_p' --> C_p'+1 --> . . . EoE . . . C_k --> C_k+1 --> . . . C_n, now Ending the endless is a fallacy. If you doubt this, kindly show such an actual step by step completion or algorithm that can bridge the implied transfinite span in steps. We need to live with a world that manifests an inherently finite past succession to date. A world that strongly points to a beginning, where -- let's augment -- a Root R gives rise to the beginning B, from which temporal-spatial causal succession proceeds: R:B –-> . . . C_k –> C_k+1 –> . . . C_n, now Where, further augmenting, R is a necessary being root. Just a refocus on context. KF kairosfocus

Aleta: I have pointed out in 217 above, two days back, how an inductive proof simply postpones the point of making the ellipsis of endlessness, so that it is unlimited but does not span the endless. Such a proof is good enough for showing that for any particular n we please, some C(n) will be true as it rests on C(0) or C(1) and shows that C(k) => C(k+1), but an endless loop that advances in steps is still incapable of actually spanning the transfinite. Indeed, take some arbitrary k of very high value, then proceed to k+1 etc. Then, put in correspondence with the beginning of the sequence count C(0), C(1) etc. That is, we have a proof that after k we have not made any material progress towards the transfinite zone. Instead, we rely on the ellipsis of endlessness and say the potentially infinite transfers to the set of all n. That is an imposition, in fact what was shown was that for an unlimited range C(n) will hold, but not that it has spanned the transfinite. Normally, that is of no consequence, we in effect have an axiom -- or a sub-axiom -- imposed similar to the parallel lines one in classical Euclidean Geometry. However, in the particular case, we are dealing with the set of counting numbers itself. It is this set that we rely on to count and to take in all possible counts, and which the ellipsis of endlessness (note my repeated emphatic use of this full description and abbreviation EoE*) shows must continue endlessly. That endlessness is where the transfinite nature of its cardinality comes from. As already, repeatedly, pointed out, we then follow the pattern of the finite and assign a novel number w as the successor to the endless succession: {0,1,2 . . . EoE . . .} --> w does not pop transfinite-ness out of thin air, it is already present in the LHS, in the EoE. Indeed, that is what the successor operation repeatedly shows, e.g. (as was actually used above) we see how {0,1,2,3,4} --> 5 by way of: {} --> 0 {0} --> 1 {0,1} --> 2 etc. does not pop five-ness out of thin air on the RHS but labels a phenomenon inextricably present on the LHS. But, again, the set with the EoE is the set we use to count, and it is its successive members that create its span, right through the ellipsis. If all of its members are finite per the imposition of the axiom of completion of the EoE (and I know I am giving a novel, descriptive label), then we have a paradox at best, that a string of inherently finite incrementing counting sets is transfinite. But,

if . . .

p1: the string is created by finitely steps to have in it a finite value so far,

then . . .

c1: there is not endlessness.

While, if . . .

p2: the string has gone to endlessness,

then . . .

c2: the endless degree of steps must find itself reflected in the substance of the counting sets in it.

where also . . .

c3: the counting sets so far are all always collected on the LHS

That is one thing that 217 showed, by showing the presence of a copy of the set so far at any given count in the LHS list of successive counting sets and their numeral representations. Allow me to copy that discussion, clipping 217:

START –> 1] Initiating Feed: Initial condition: {} –> 0 ===> LOGIC MACHINE, LM Initialise LM space for storing current counting set list { . . . }, here, initially to empty set then on increment to immediately following successors to go through 1, 2, . . . EoE . . . Initialise LM space for storing current assigned numeral for current counting set, here, the empty set Initialise printer, confirm ready Go on to fetch, decode, execute . . . 2] LM-0: Set LM counter –> 0 Print “{“, print list from counting sequence to date, comma separated values, print “} –>”, print [counter contents]// gives counting set assignment and states the successor Increment printer output sheet for next line. Go on to fetch, decode, execute . . . 3] LM-next case: Increment LM counter value using standard, place value notation as stored in the machine Extend LM space for storing current counting set list { . . . }, to include newly incremented counter value // extends the counting set for the onward successor Print “{“, print just extended list from counting sequence to date, comma separated values, print “} –>”, print [current counter contents] // prints the result with the new counting set, preparatory to the onward successor Increment printer output sheet for next line. Go on to fetch, decode, execute . . . 4] Continue: Go on to fetch, decode, execute code block 3 just above.

This process is unlimited but inevitably is finite and however rapidly executed CANNOT exhaust and end the endless. Step 4 guarantees that, by imposing an endless loop. Endless loops are great for the main machine process in a computer, but these by definition are open ended and incomplete up to imposing a close down interrupt by shutting down the system or yanking the plug etc. And, this is in effect a proof by induction on initial case plus chaining logic plus standard result process at each step, here an algorithm rather than churning out the result of a formula etc. Which, we must recognise as unlimited but not ending the endless. And as an internal loop were it to do so the “final” printed set would be the whole endless set, nested. We RELIABLY produce instead an unending chain of finite counting sets but we do not have ability to exhaust the set as a whole. We revert to ellipsis of endlessness and collect the whole in a set we term the natural numbers big-N, giving its successor the finite symbolic numeral omega, then we start over again at transfinite level and proceed. Indeed the above exercise (it is patently code-able, save for the implications for storage) can be modified to execute that and to terminate at a suitable point after listing the ordinals in the compressed way say Wolfram did. That is a terminating, finite, exhaustively computable process that exploits the ellipsis of endlessness.

As you can see, the axiom of the EoE is being used to decide the matter, carrying the whole weight of the conclusion that the counting sets are all finite but their span is transfinite. That is a big weight for a single -- and often implicit -- premise to carry. I suggest that what is shown is that there is an unlimited succession of incrementally lengthening counting sets which cannot be completed by a succession of actual successive steps, but we use a symbol, the EoE, to represent that there is a potentially infinite process here. Often we then have to address things like partial sums and error terms, showing that beyond a given point the onward difference to endlessness would be within a certain error band. That again uses EoE. It also implies that onward terms taper into infinitesimals trending to 0 such that the onward sum is within error bands. Or, in epsilon delta terms, the sequence of partial sums will be within some delta neighbourhood of the limit as pushed forward. Infinitesimals lurk, even when we find ways to avoid talking about them: he who must not be named and all of that. We need it, but we should be aware that we are tickling a dragon's tail. On the case in view, we do not have a sequence of partial sums approaching a limit, we have a limitless expansion, indeed this ordered set gives us the metric for endlessness. For us to go to the RHS and assign w, the endlessness has to appear in successive subsets hidden under the EoE; especially as w is not the successor to any one given value, it is a recognised successor to the process as a whole. That is why I am uncomfortable with the idea of concluding that all subsets collected in succession are finite, to endless extent. A more direct conclusion is that to any degree we can complete the count succession, it will be finite, but the process is endless. And we posit a symbol and successor for that endless collection, w. When we term w the first transfinite ordinal and assign it as beyond the natural counting numbers, that is a definition that has to face the paradox above. We have to live with it, but should recognise it. Let me highlight, a summary of what I am comfortable with:

Finite counting numbers extend without limit, we cannot count out and list the set that collects such numbers [i.e. it is a fallacy to assert or imply ending the endless in successive steps], the set as a whole can be symbolised by using EoE, and has cardinality first degree of endlessness. That first degree endlessness is symbolised as aleph null, and we collect the sets in succession as a whole from 0 and assign a fresh number that succeeds, w -- which we explicitly recognise as transfinite. I think we should be cautious, then in using ordinary mathematical induction and the axiom of EoE to then say all naturals are finite and yet the set as a whole -- composed by incremental succession such that the counting sets lurking under the symbols stretch out with the scale of the whole -- is transfinite. At minimum, the implicit premise of EoE should be explained and the weight it carries should be disclosed.

Of course, here is the axiom of infinity in its usual simple form:

There is a set I that contains{} --> 0 as an element, and for each a (an element in I), the set a UNION {a} is also in I.

That is, starting from {} --> 0, we collect in succession the preceding sets and extend endlessly. Such crucially depends on EoE to propagate to the full set. A set that as we see is inherently not completed by stepwise succession. So the [sub-]axiom of the ellipsis of endlessness is carrying a lot of weight. Which, we should duly note. And in turn that allows us to answer VC's concern: N: 0, 1, 2, . . . n . . . EoE . . . Multiply each element by 2: E: 0, 2, 4, . . . 2n . . . EoE . . . That is this is a disguised form of the whole set thanks to EoE. Likewise, transform each n in N to 2n + 1: O: 1, 3, 5 . . . 2n + 1 . . . EoE . . . Again, a disguised form thanks to EoE. So, the three sets are in mutual 1:1 match. Likewise, shift k: N: 0, 1, 2 . . . EoE . . . s_K: k (= k + 0), k + 1, k + 2 . . . EoE . . . This is just a k-shifted transform of the same fundamental set. The symbols have changed but the sets are all countable and transfinite per EoE. They are fundamentally the same. There is self-similarity of sub-sets, a sort of fractal self-repeating in the smaller pattern in the loose sense. And so, when Cantor et al took the paradox and said, okay when a proper subset can be matched 1:1 with the set of counting numbers that is a way to recognise its transfinite nature, it opened up a new world. Of course, VC's counters A and B with an underlying 1-second clock feed are extensions of the algorithm clipped from 217 above with one (say B) at a half-rate count, in effect there is an inner loop that sets up a 2-count then transfer to the counting register. With a common start B will run at more or less half the count of A to unlimited extent. Both are endless processes and show that a stepwise succession cannot complete endlessness. It also applies the [sub-]axiom of EoE and concludes that for any clock tick k, counter A will read k and counter B roughly or exactly half of k. But both are headed to the same transfinite zone. Just, B is the proverbial slow boat to China. Where at any given time, we will always be pointing onwards to a potential infinity. EoE is important. KF *PS: I think I should quietly note: your highlighting as if typical of an obvious typo in such a context above (pardon, I will sometimes make such errors and fail to spot/correct them), per fair comment, does not help the discussion. That is like the verbal slip of speaking of a far end rather than zone; also highlighted. Sorry for slips and typos, but they are no more than that. Just yesterday I found myself saying how decisions are *maken,* an inadvertent blend of made and taken. Oopsie, but worth a chuckle. kairosfocus

Why do my detractors think that just repeating what I am refuting refutes me? Talk about being mental midgets... Virgil Cain

Aleta, You are just a blind parrot blowhard. I know what Cantor said. I also know that what I said refutes him. And I know that what you said about set subtraction of infinite sets is total BS. These represent two countably infinite sets: Two counters- one counts every second and the other counts every other second. The first counter will always have a higher count (double or close to it) than the second- always and forever. You lose. Virgil Cain

Virgil, I'm afraid you don't know what you are talking about. Try reading here: https://en.wikipedia.org/wiki/Countable_set. I quote,

For example, there are infinitely many odd integers, infinitely many even integers, and (hence) infinitely many integers overall. However, it turns out that the number of even integers, which is the same as the number of odd integers, is also the same as the number of integers overall.

That's it for me with you. Aleta

Aleta, You don't have an argument. Just saying "You can’t use “standard set subtraction” on infinite sets", is meaningless. You actually have to make a case and you cannot. ALSO- Two counters- one counts every second and the other counts every other second. The first counter will always have a higher count (double or close to it) than the second- always and forever. That is just another proof of my case. Virgil Cain

Virgil, your logic in 261 is wrong. You can't use "standard set subtraction" on infinite sets. There are just as many positive evens {2, 4,6, ...) as there are positive integers [1, 2, 3, ...]. This is about as foundational of a universally accepted fact about infinite sets as there is. Sets A, B, and C in your example all have the same cardinality - aleph null, the first transfinite number, the first type of level or infinity. Aleta

Two counters- one counts every second and the other counts every other second. The first counter will always have a higher count (double or close to it) than the second- always and forever. Virgil Cain

Hi Aleta- First please respond to my post with something of substance and then I will get to your question. Virgil Cain

Hi Virgil. Every other whole number is even. Does that mean there are twice as many whole numbers as evens? What do you think? Aleta

Aleta:

Can you at least entertain the possibility that your intuition is wrong, and that Cantor et al are right?

Cantor leads to logical inconsistencies. For example Cantor said that all countably infinite sets have the same cardinality, ie the same number of elements. Yet standard set subtraction proves that is not so: Let set A = {0,1,2,3,4,5,...} Let set B = {1,3,5,7,9,11,...} Let set C = {0.2.4.6.8.10,...} A - B = C, proving that all countably infinite sets do not have the same cardinality, ie the same number of elements. And only contrived mental gymnastics can get around that fact. Virgil Cain

kf writes,

Aleta, the naturals span to endlessness. Yes, we conceive the endlessness whole and see this as expressing what we sum up as a first transfinite, but that character is in the set of whole counting numbers.

I don't believe this addresses either of my questions: what is wrong with my proof that all naturals are finite, and if you think otherwise, can you be specific about the nature of these non-finite natural numbers that are "past the ellipse." Saying that set of the counting numbers has a transfinite character does not say anything specific about the particular numbers in the set. If they all aren't finite, what are they? Also, I don't know why you addressed the continuum - that doesn't bear on the topic of the naturals. Aleta

KF,

DS, passing by a moment, the law of the excluded middle is one of the three pivotal principles connected to distinct identity that are rightly termed laws of thought or first principles of right reason. That’s why I will also have to fish around to see if there is not a distinct identity in some relevant sense. KF

Well, as you stated, this smooth infinitesimal analysis is regarded as just as rigorous as "standard" analysis. It appears this example shows that we need not restrict ourselves to classical logic only when doing mathematics. I assume there are many other such examples. [Edit: In fact I know there are, but I haven't looked into this much.] If you can point out a real mathematical issue, that is, an instance where this approach yields incorrect results, then I'd like to hear it. Otherwise, I see no problems. daveS

Aleta, the naturals span to endlessness. Yes, we conceive the endlessness whole and see this as expressing what we sum up as a first transfinite, but that character is in the set of whole counting numbers. As for continuum, I suggest the point is that for any arbitrary pair of close members of R there will always be more between. That will include say 1/pi in the relevant interval and in fact 1/pi^n where n is a whole number, all of which are not rationals. Rationals are reals but not all reals are rationals. KF PS: I spoke of LEM st aside for smooth infinitesimal analysis, cf Bell et al. That's a third approach. kairosfocus

DS, passing by a moment, the law of the excluded middle is one of the three pivotal principles connected to distinct identity that are rightly termed laws of thought or first principles of right reason. That's why I will also have to fish around to see if there is not a distinct identity in some relevant sense. KF kairosfocus

KF, Thanks for the reference. And yes, I stand corrected, the wikipedia entry on smooth infinitesimal analysis does say it is based on logic without the law of the excluded middle. I wouldn't characterize that as a "red flag", however. daveS

What is the concern? You keep saying that, but have no specifics. If every milepost isn't finite, then what is the nature of a non-finite natural number? I ask the following: 1. Address my proof in 253 above - how is it invalid? 2. If every milepost isn't finite, then what is the nature of a non-finite natural number? Be specific about that. 3. Answer the bolded question. Can you even entertain the possibility that your intuitive concern is wrong, and that established mathematics is right? [I see that you later answered this question in a P.S., so you can ignore this.] [edited to more clearly state three questions.] Aleta

Aleta, please note the ellipsis of endlessness is on the LHS of the definition of w as successor. That is it is embedded in the set. That is where my concern is. W exists as summarising the order type of the endlessness, it is not popping that into existence out of thin air. If the set were not of transfinite span, w would not be of first order transfinite cardinality. And being or transfinite span with every mile post being finite is at minimum a concern. KF PS: The fact that I am not asserting contradiction but instead concern suffices to show I am aware that my concern may be wrong, but needs good reason to see why. And, in this general context Cantor was also wrong on key matters, hence the issue of naive set theory vs ZFC. (In short, no authority is better than his/her facts and reasoning backed up by underlying assumptions; I here reveal my Protestant heritage.) kairosfocus

kf, you write,

For, the range of counting numbers as a whole is said to be endless and for that to be it seems “intuitively” that it should have in it members that reflect transfinite nature in themselves.

You're intuition is wrong, I think. You've already said that w, the first transfinite number, is not in N. Now you say your intuition says that there should be members of N that "reflect transfinite nature" (whatever that might mean.) That's a contradiction right there. In math, proofs and precise steps of argument are needed - intuition doesn't override proof. I've offered the following proof, and asked you why you don't think it is valid 1. Either all natural numbers are finite, or there are transfinite numbers in N. 2. w (or the corresponding aleph null) is the first transfinite numbers: w is the ordinal successor of the natural numbers 3. w is not in N 4. Therefore, there are no transfinite numbers in N 5. Therefore, all natural numbers are finite. Your intuition tells you there needs to be some kind of other number between finite and w, something that "reflects transfinite nature", that is in N, but you can offer no specifics about what that might mean. If you could provide mathematical justification for this notion (as opposed to vague concerns about "ending the endless"), you would re-write mathematics. So here's a question: Can you at least entertain the possibility that your intuition is wrong, and that Cantor et al are right? Aleta

DS, Bell's approach is not the rough and ready survival of the C17-18 approach that still sometimes surfaces, but another approach that addresses the issue of a point array and smoothness with nilpotent infinitesimals, etc. As one illustration, an infinitesimal is viewed as such that its square will be zero, an extension of the concept that was classically put as, the higher order terms are vanishingly small relative to first order infinitesimals, dx >> [dx]^2. Where obviously [10^-300]^2 = 10^-600, which is vanishingly small for most practical purposes relative to the original scale, though obviously this is a finite example; the point is the number of orders of mag down on unity will double on squaring. It is said to be just as rigorous as the other approaches, save that there is a workaround on LEM, which on what I gather would typically obtain WRT a phenomenon if there is some fuzziness or superposition in it so that distinct contrasts of W = {A | ~A} do not obtain. That is, there are now at least three significant schools of thought that provide alternative perspectives on Calculus foundations. KF kairosfocus

Aleta, forgive mis-stating, I used a spatial metaphor and meant to refer to the far "zone" where the ellipsis of endlessness would have to be traversed if a step by step process wee employed. Perilously close to contradiction is relative to the relationship between paradox and contradiction. Paradoxes routinely run close and may seem incongruous, but sometimes they do go over into contradiction, and one cannot be sure on an initial glance, or even after much close study. I have said it in many ways, that if all naturals are finite, that runs close to contradiction by way of ending the endless. For, the range of counting numbers as a whole is said to be endless and for that to be it seems "intuitively" that it should have in it members that reflect transfinite nature in themselves. Think, innate mile markers on a road built by a programed step by step machine [or maybe a machine capable of simultaneously creating the road from the origin to the far zone], here an endless linear one in a flat space. If the road is endless, will the markers ALL be at finite distances from the origin at say the famous Kingston Parish Church point of departure? If so, is that not inherently a limitation, an implicit finite terminus? Or, is there a way to say the roadbuilding machine runs out of steam but the road picks up at the far zone at "mile marker" w and so forth? If not, how can we have every marker at finitely remote distance AND at the same time, the road with the markers is endless? KF kairosfocus

KF,

DS, it gets worse, do points “touch” — thus no gaps — and where is the continuum.

I don't know what points "touching" would mean. I also believe that the hyperreals do form a linear continuum, just as R does.

Smooth Infinitesimal analysis, at price of workarounds to the LEM, puts in in effect crudely pico segments of infinitesimal scale.

If you're talking about the "sloppy calculus" that is sometimes taught using infinitesimals, it is a bit of a cheat, but I suppose it's useful in some situations. I was never taught calculus that way, so I don't have much to say about it. On the other hand, the version based on nonstandard analysis is absolutely rigorous, with no logical problems. daveS

There is no "far end". I give up! (But I've said that before, and then have come back, so we'll see.) And, what does perilously close to a contradiction mean? What contradiction? Why can't you be more precise. This is math. What is the contradiction? Aleta

Aleta, the issue is perilous closeness to a contradiction between everybody finite -- including the "far end" of the succession of counting sets, and the set is transfinite as the EoE shows. This is a way to try to put it. The connexion to timeline of cosmos is through the series so the math can be looked at on its own, implications lie where they fly. KF kairosfocus

DS, it gets worse, do points "touch" -- thus no gaps -- and where is the continuum. The definition of continuum I learned way back was, effectively, between distinct neighbour points, you can always insert an intervening one, which strictly implies pico gaps at the bottom; oh boy. (one oddity, cynically suggest continuum is a myth and accept the infinitesimals as fitting the "final" gap when reduction goes to EoE, a monad or its kissing cousin.) Not nice. Smooth Infinitesimal analysis, at price of workarounds to the LEM, puts in in effect crudely pico segments of infinitesimal scale. They get us to at that scale curves are concatenations of straight segments. KF kairosfocus

Yes I understand there is a wider context, but in the narrower context, what problem do you see with all natural numbers being finite, and the set of naturals having an infinite number of members? I understand there are issues with the broader context, but you have continually seemed to argue there are issues with the narrower context of the naturals. It seems to me it would be useful for you to clearly, more clearly than you have, explain in perhaps more precise mathematical language, what the issue with the naturals are. Issues with w, or an infinite past, or infinitesimals, are interesting, but bringing them up as a larger context doesn't actually address the smaller one. If the smaller issue (the naturals) were actually being addressed, then the larger context might be interesting, but it looks to me like your continually returning to larger issues (w, infinite past, infinitesimals) is a way of avoiding the arguments about the naturals. Every time the discussion tries to narrow down on the naturals, you fall back on "but there are other issues." So, I repeat,

Could you separate the assertion that all naturals are finite, and that the set of naturals is infinite, from the issue of an infinite past? And, if you separate the two issues, is there anyone claiming that there is a problem with “ending the endless” if we look at just the naturals, or is the only concern you have with the other issue concerning the past?

Aleta

KF,

DS, Maybe you do not have a problem, but I do. LNC problem: numbers next to 0 but below the reals where there is supposedly a continuum [thus no gaps or breaks etc], is inherently questionable and needs some reasonable resolution.

I think I see what you're saying, but remember that the infinitesimals are "infinitely close" to 0, so it's not as if they are sitting in some "gap" in the reals, which would contradict the definition of a continuum. Anyway, the hyperreals were constructed almost 70 years ago, so I think any serious outstanding issues would be resolved by now. Granted, it's a strange set. But there certainly is no violation of the law of the excluded middle here. daveS

Seeing how you KF are still into physics I thought I should mention that the model I have finds two of possible four requirements for intelligence in the behavior of matter, with no need to "guess" (anymore?) and "confidence" that normally sets constants that would be the part consciously felt by what you can call God if you want. I have no solid evidence that the universe is this way, but from what I have for theory is possible. This illustration shows what I have, for modeling the behavior of matter as though it's fine tuned by intelligence even though that is not necessarily the case. In either event it's a novel scientific model to experiment with: https://sites.google.com/site/intelligenceprograms/Home/Causation.png GaryGaulin

Aleta, form the very first I welcomed that you agreed with me on that one. However, I am not sure that that is a generally acknowledged point, given what we see Durston et al pointing to and as we saw Spitzer remark on earlier. And the discussion has to bear in mind that wider context. KF kairosfocus

DS, Maybe you do not have a problem, but I do. LNC problem: numbers next to 0 but below the reals where there is supposedly a continuum [thus no gaps or breaks etc], is inherently questionable and needs some reasonable resolution. So far, I see, artifice, a useful fiction that works around a ticklish situation. KF kairosfocus

kf, you write,

I am surprised to still see questioning the issue of ending the endless as that has been a root issue behind several UD threads recently. As in, the proposal of an actually infinite past of the physical cosmos entails an actually completed infinite succession of causal stages that can be labelled in one way or another that translates pretty directly into completing the endless. You may not support that, and that has been acknowledged from the beginning when you said such. But the matter lurks.

I'm glad you acknowledge that I've not defended nor discussed the infinite past issue. But that is different than the issue of the naturals. The difference in the two situations is this: that in creating the naturals we build each number from its predecessor, endlessly, moving "upwards", towards infinity. In the example of the past, one is claiming that somehow one could move up from negative infinity, which makes no sense. So, could you separate the assertion that all naturals are finite, and that the set of naturals is infinite, from the issue of an infinite past? And, if you separate the two issues, is there anyone claiming that there is a problem with "ending the endless" if we look at just the naturals, or is the only concern you have with the other issue concerning the past? Aleta

KF,

DS, do you not see the problem that [0,1] is by all accounts a continuum, and putting up numbers next to 0 that are not reals?

No, I don't think there is a problem with this construction.

I can see an artifice of argument set up as scaffolding that says well infinitesimals are smaller than any real; but there is an apparent price being paid here: is [0,1] a continuum or not . . . and does this not mean that between two close neighbours that are distinct we can insert another point, basically by averaging the first place in the deep decimals where there is a difference or the like?

No, that's not what a continuum is [at least in reference to subsets of R]. Otherwise, the rational numbers would be a continuum, which they're not.

Red flag is reserved for the alternative that talks in terms of sacrificing excluded middle. Maybe, working premise, an infinitesimal is smaller than any finitely large real, but not quite zero. That’s more or less the rule of thumb view I have seen used for decades, lurking behind the limit approach, which is obviously now the standard one. And it has historical roots. It seems some serious artifices had to be brought in to look at them again. KF

But where exactly is the law of the excluded middle being set aside? I'm just guessing here that you are saying something about numbers either being 0 or not 0? I don't know. Edit:

PS: attempting the down-count beyond w is exactly my point, it hits the ellipsis of endlessness and cannot break the cardinality of first magnitude endlessness. Stepwise process is inherently finite and cannot traverse the EoE to reach a finite neighbourhood of 0.

That has been acknowledged all along, though. Counting down from ω to 0 is not involved in the Hilbert Hotel inspection tour. daveS

DS, do you not see the problem that [0,1] is by all accounts a continuum, and putting up numbers next to 0 that are not reals? I can see an artifice of argument set up as scaffolding that says well infinitesimals are smaller than any real; but there is an apparent price being paid here: is [0,1] a continuum or not . . . and does this not mean that between two close neighbours that are distinct we can insert another point, basically by averaging the first place in the deep decimals where there is a difference or the like? Orange flag. Red flag is reserved for the alternative that talks in terms of sacrificing excluded middle. Maybe, working premise, an infinitesimal is smaller than any finitely large real, but not quite zero. That's more or less the rule of thumb view I have seen used for decades, lurking behind the limit approach, which is obviously now the standard one. And it has historical roots. It seems some serious artifices had to be brought in to look at them again. KF PS: attempting the down-count beyond w is exactly my point, it hits the ellipsis of endlessness and cannot break the cardinality of first magnitude endlessness. Stepwise process is inherently finite and cannot traverse the EoE to reach a finite neighbourhood of 0. PPS: Look at smooth infinitesimal analysis for walkaway from LEM. kairosfocus

KF, If I may address some of your points to Aleta,

Last I checked the reals are a continuum, and [0,1] is a real continuum, and yet infinitesimals are being discussed close to 0 as neighbours that are smaller than any real number. Orange flag at minimum.

What exactly is the orange flag here? As we've stated several times, there are no real infinitesimals, although they exist in the hyperreals.

On another approach, the law of the excluded middle is being set aside. Red flag!

?? Where did this happen?

What about to taking some transfinite ordinal, say w + g and down-counting in stepwise succession? Again, things start to get delicate. Orange flag again.

Well, say you attempt to count down from ω. There's nowhere to go, unless you skip almost all of N. Is that a problem somehow? daveS

Aleta, Passing by a moment again. The survey on numbers is useful. I am surprised to still see questioning the issue of ending the endless as that has been a root issue behind several UD threads recently. As in, the proposal of an actually infinite past of the physical cosmos entails an actually completed infinite succession of causal stages that can be labelled in one way or another that translates pretty directly into completing the endless. You may not support that, and that has been acknowledged from the beginning when you said such. But the matter lurks. Scroll up to the OP, where Durston cites a case. In this or an earlier thread there was talk of infinite past oscillating universes. You may not be interested in the cosmology but it is material context and brings up the math on secondary issues. That math is of significance, and is worth discussing; but it is in fact incidental though connected to the logical and conceptual issues. It is not the existence of w and/or aleph null that are the issue, it is when things are affirmed or implied that point to stepwise traversal of the infinite. And that connects to concerns I have over how we think of induction. That is why in part I spent time looking at the logical Machine generating the stepwise succession. A result is, it goes on limitlessly, but still cannot traverse the transfinite in steps. Where, in looking at {0, 1, 2 . . . } --> w, the endlessness is there in the LHS. The RHS does not pop it out of thin air. That's why I have stressed EoE. Succeeding k to k +1 does not span the endless, it points to the potential infinite, and indeed we can put k, k+1 etc in correspondence with the overall set, underscoring the endlessness. And I find myself further uncomfortable with the proposition that on an ordinary inductive proof it is shown that an endless set that counts up has in it only finite members. That runs very close to an outright statement of ending the endless. I find myself needing to look very closely at that and related matters. When I do so, I find further that a lot of scaffolding artifices are popping up surrounding infinitesimals, hyper reals, super reals and whatnot. Last I checked the reals are a continuum, and [0,1] is a real continuum, and yet infinitesimals are being discussed close to 0 as neighbours that are smaller than any real number. Orange flag at minimum. On another approach, the law of the excluded middle is being set aside. Red flag! Put in multiplicative inverses and I would see a catapult to the transfinite zone. But then the links between hyper or super reals and reals and established transfinites held to extend the counting numbers -- which supposedly are a subset of the reals -- look murky. Orange flag again. What about to taking some transfinite ordinal, say w + g and down-counting in stepwise succession? Again, things start to get delicate. Orange flag again. At minimum, there is caution, proceed with extreme caution. Okay, for now, exploratory modelling that tries out things to explore. Red-amber flags waving, we explore hoping to spot the quicksand patches before we tumble in. I think it is worth taking reals as continuous in [0,1] seriously and regarding infinitesimals as all but 0, not finitely different from 0. That cries out for multiplicative inverses that are transfinite and as I see a perfectly good sequence from w up, why not a mild one, m, that drops us to say w + g when catapulted through y = 1/x? Where would that take us for our purposes , , , in say the lines of thought explored by Euler? Of course, I called that A, long ago and saw that it would get us to a down count through w + (g -1) --> A~1, etc. As well continuity in [0,1] would by catapulting neighbours, allow filling in say w to w +1 etc, i.e. the exploratory, naive approach suggests that the transfinite ordinals can be looked at as mileposts on a transfinite continuum that extends from w on, with an EoE leading up from, 0, 1, 2 etc and conceptually traversed by w being successor to the counting set with the EoE. Interesting, though not a mathematical proof from first principles by lock-down steps. Next, attempting a downcount in steps to reach a finite neighbourhood of 0 would try to traverse the endless. A, A~1, etc will go in correspondence with the 0, 1, 2 etc and we are back to stepwise traversal of an ellipsis of endlessness. Maybe that lends some conceptual support to the idea of such a traversal running into the gap between unlimited succession and traversing the endless that the algorithm from this morning shows at was it 217. https://uncommondescent.com/atheism/durston-and-craig-on-an-infinite-temporal-past/#comment-597338 Meanwhile, it looks like Euler was thinking in not very dissimilar but much more sophisticated ways that someone is trying to rehabilitate through hyper real thinking: http://www.maa.org/sites/default/files/images/upload_library/22/Allendoerfer/2002/0025570x.di021222.02p0075s.pdf So, let us see how we can connect some dots into a coherent whole, if that is possible. The firmest thing so far is it is futile to try to cumulatively traverse the endless in finite steps. KF kairosfocus

Here are some thoughts about the bigger picture in this discussion. At the end of this post, I'll describe how I think this applies to our discussion about infinity. A major theme in the history of mathematics is that of extending the notion of number. I used to have an exploratory discussion day with my pre-calculus class about this. Here's a brief summary, off the top of my head: 1. Counting numbers starting with one, and rationals came first. There is pre-historical evidence of this understanding. 2. Irrationals came next: the story of the proof that sqrt(2) is irrational is famous. 3. Zero came next, introduced from the Hindu's about 1000 AD, and introduced first as a placeholder in the decimal number system. Later, when the numbers came to be visualized on the number line, the counting numbers were backed down to zero rather than starting at one. Note that there was resistance to accepting zero as a number in this sense, because you can't have zero things. Overcoming this resistance involved extending the concept of what numbers mean, moving them away from just associated with counting or measuring concrete objects. 4. Interesting enough, negative numbers were next, and they didn't get accepted as numbers in the Western world until the 1700's: the argument being how can you have less than nothing? Here we see a pattern that will be repeated a. A number is impossible, often in respect to an equation: x + 5 = 3 has no solution because you can't add a number that makes it less. b. Someone says lets invent a symbol for this "impossible" number, pretend that it exists, and see what happens: hence, –2. c. Mathematicians explore the possible rules for the new number, and it's implications d. Mathematicians discover that there are no inconsistencies, and the new number fits well into the existing numbers system once understand how it works. e. Mathematicians find ways to both visually the new number and apply it to real-world situtaions f. The new number is fully integrated into mathematics, and our notions of number have been extended and have grown. 5. Imaginary and complex numbers came next, not long after negatives, and the steps above were repeated. The equation x^2 = –1 has no solution, as a consequence of the rules for multiplying negative numbers, so let's make up a number i = sqrt(-1) and see what happens. And, lo and behold, all sorts of stuff happens that works, fits i with the rest of the number system, and leads to all sorts of powerful applications and extremely counter-intuitive results such as the Mandelbrot set. 6. So this brings us to infinity. The beginning idea is that of endlessness: a process that can always be continued. Building the natural numbers from each numbers successor is an example of an endless process. We say that, therefore, there are an infinite number of natural numbers. However, infinity isn't a number at the end of the naturals, it isn't a place to be reached, etc. However, Cantor decided to play the same game as above: let's "pretend" that infinity is a number, let's give it a name and symbol, let's explore how and works, and see what we get. And again, we got new, consistent (for the most part) mathematics that introduced a new type of number, the transfinites. The transfinites extend the meaning of number. Just as negatives extended number past counting numbers, but did not change the nature of the naturals, and imaginary numbers extended the reals, but did not change them, the transfinites extended the concept of number to include infinity, but it did change or undo the basic nature of the other numbers. So aleph null is the name of the infinite number of natural numbers. That doesn't change the fact that the naturals are defined by the successor rule, so that each and every natural is finite. Cantor's extension of number to include aleph null and other transfinites doesn't add a mystery to the naturals that wasn't there before. Just because Cantor was able to successfully to invent new mathematics involving transfinites doesn't mean that the infinite set of naturals has been or could be completed. kf continues to claim that "there are those who are explicitly claiming actual completion of an infinite stepwise succession," and I have asked him to cite someone who believes this. Perhaps, and I offer this as a hypothesis, kf feels that way because he feels that the existence of aleph null implies a completion of the infinite. But it doesn't. If this is not the source of kf's claim/feelings, then his feelings come from elsewhere. If so, I again ask for an example of someone who claims the infinite can be completed. Aleta

George Gamow writes:

The sequence of numbers (including the infinite ones!) now runs: 1. 2. 3. 4. 5. ...... &aleph;1 &aleph;2 &aleph;3 ...... and we say "there are &aleph;1 points on a line" or "there are &aleph;2 different curves" ...

Is this a finite sequence? eta: weird. in the preview those came out as the Hebrew character א but not when saved. Mung

kf, you write,

there are those who are explicitly claiming actual completion of an infinite stepwise succession.

I've asked before: who is someone who is explicitly making this claim? Fundamental accepted mathematics does not make this claim, and I don't know anyone who does. Is it possible that you are arguing against a position that in fact no one holds? Can you cite a source of someone " claiming actual completion of an infinite stepwise succession"? Aleta

KF,

DS, My first concern is centred on the assertion rooted in an ordinary inductive proof/argument that natural, counting numbers [to which we may assign the succession of ordered counting sets starting from {} as discussed above] form an endless succession of finite values which are all finite but cumulatively belong to a transfinitely large set. KF

I just don't see any problem with this. The individual finite natural numbers are very different from the entire collection. daveS

Aleta, 223, thanks for the thought. I wish I did not see a point of concern much as you summarised by clipping. But, the concern is there -- much like a theological doubt. Once there it has to be reasonably worked through. KF kairosfocus

DS, My first concern is centred on the assertion rooted in an ordinary inductive proof/argument that natural, counting numbers [to which we may assign the succession of ordered counting sets starting from {} as discussed above] form an endless succession of finite values which are all finite but cumulatively belong to a transfinitely large set. KF kairosfocus

Aleta, it seems to me that in a relevant context there are those who are explicitly claiming actual completion of an infinite stepwise succession. That context is surrounded by cases where issues and assertions may imply just such ending the endless. In those contexts issues on the meaning of the transfinite, ordinal succession to that zone, the nature of mathematical induction and of the set {0, 1, 2 . . . EoE* . . . } arises, joined to the onward reals, continuum and the interval [0,1]. In context we then see the transfinite ordinals from w and what may be connected therewith. KF *PS: I speak explicitly of ellipsis of endlessness as this seems critical. Notice, the ordinary form of mathematical induction uses step by step sequencing hung upon an initial value in a sequence of steps. Such a sequence extends without limit, but inherently cannot exhaust or end the endless. kairosfocus

F/N: Some reading going back to and upgrading Euler: http://www.maa.org/sites/default/files/images/upload_library/22/Allendoerfer/2002/0025570x.di021222.02p0075s.pdf KF kairosfocus

KF,

DS, If I am going to accept a paradox that runs brushingly close to a contradiction, you had better believe I am going to look at it very closely indeed to ensure that what I acknowledge is not in fact incoherent.

Could you state in precise mathematical terms what this alleged "paradox" is?

DS, my problem with suggesting non real infinitesimal hyper reals — other than as a model building artifice to create a system, then be checked to see if the scaffolding can thereafter be removed — is that [0,1] is a continuum of reals. 0 is a real, and numbers in its very near neighbourhood should also be reals, per continuum. So, on the face of it, there is plenty room at the bottom near 0 to catapult infinitesimals that are all but zero. And of course, similarly proposing hyper reals beyond the reals should fit in with this. KF

You can carry out any construction you want, as long as you do it correctly. I'm just saying that 1/m = ω + g is impossible under any scheme you have suggested so far, so you'll have to try something else. I think all the info in the quote you posted concerning the hyperreals is already on the table, btw. daveS

But no one is claiming to end the endless. Why you think that is the case is what I don't understand. Aleta

DS, my problem with suggesting non real infinitesimal hyper reals -- other than as a model building artifice to create a system, then be checked to see if the scaffolding can thereafter be removed -- is that [0,1] is a continuum of reals. 0 is a real, and numbers in its very near neighbourhood should also be reals, per continuum. So, on the face of it, there is plenty room at the bottom near 0 to catapult infinitesimals that are all but zero. And of course, similarly proposing hyper reals beyond the reals should fit in with this. KF PS: Let me clip a discussion that brings out points where concerns pop up: http://2000clicks.com/mathhelp/BasicNumsys51Hyperreal.aspx

Any of a colossal set of numbers, also known as nonstandard reals, that includes not only all the real numbers but also certain classes of infinitely large (see infinity) and infinitesimal numbers as well. Hyperreals emerged in the 1960s from the work of Abraham Robinson who showed how infinitely large and infinitesimal numbers can be rigorously defined and developed in what is called nonstandard analysis. Because hyperreals represent an extension of the real numbers, R, they are usually denoted by *R. Hyperreals include all the reals (in the technical sense that they form an ordered field containing the reals as a subfield) and they also contain infinitely many other numbers that are either infinitely large (numbers whose absolute value is greater than any positive real number) or infinitely small (numbers whose absolute value is less than any positive real number). No infinitely large number exists in the real number system and the only real infinitesimal is zero. But in the hyperreal system, it turns out that that each real number is surrounded by a cloud of hyperreals that are infinitely close to it; the cloud around zero consists of the infinitesimals themselves. Conversely, every (finite) hyperreal number x is infinitely close to exactly one real number, which is called its standard part, st(x). In other words, there exists one and only one real number st(x) such that x – st(x) is infinitesimal

kairosfocus

Aleta, the issue of a transfinite number of finites [successively arrived at -- cf my use of a thought exercise logic machine earlier today], esp where counting sets extend without limit is right at the heart of my concern. Unlimited extension is one thing, ending the endless is another. KF kairosfocus

DS, If I am going to accept a paradox that runs brushingly close to a contradiction, you had better believe I am going to look at it very closely indeed to ensure that what I acknowledge is not in fact incoherent. That is for instance why you will sometimes hear me speaking of the deep nature of the problem of the one and the many. In theology the triune concept of God is another similar case. KF kairosfocus

Hi kf. I appreciate that you are genuinely working to communicate some perhaps ineffable issues concerning the infinite nature of the natural numbers. You write,

I long ago learned to respect my sense of cognitive dissonance, of logical incongruity. Remember, as primarily a physicist I had to swallow the transition from the classical to quantum and relativity.

Recognizing cognitive dissonance is important, because it is better to acknowledge two competing views than it is to deny one in order to relieve the uncertainty and conflict. However, as has been the experience for many trying to grasp some of the results of quantum physics and relativity, sometimes the truth is that one has to accept both perspectives in order to really understand the larger picture. I think the same is true of the infinity of the natural numbers. Each natural number is finite and there is an infinite number of them seems, perhaps, to set up an either/or cognitive conflict. You, I think, are trying to resolve the conflict by somehow denying one half of the and statement about rather then transcending the conflict and accepting the bigger picture. Like many Gestalt-ish issues, focusing too hard on one half of the picture makes it impossible to see the other half, but standing back and relaxing the vision allows one to see that there is a whole that encompasses the two different perspectives. With that said, throughout your long post you return often to the issue that I think is most bothering you. From multiple places:

The claims being made come too close to ending the endless. The claim that finitude spreads through the whole chain by succession seems to me to suggest a claim to exhaust, or end the endless by an algorithm that can only ever be actually finite. Induction shows an unlimited, reliable logical chain that will work for any particular n you please, which by being specified becomes inevitably finite. But it cannot exhaust the endless. If it did so, it would indeed confer finitude upon all members, but to do that it has to end the endless. If every counting number in succession is finite, how then can we consistently claim the set as a whole is transfinite, endless? Pointing to, but not completing, in a context where completing is the requisite. This process is unlimited but inevitably is finite and however rapidly executed CANNOT exhaust and end the endless.

Those are just some of the lines that you wrote that summarize your concern: that somehow claiming that every natural number is finite brings an end that contradicts the endlessness - the infinitude - of the set. I don't believe this is a contradiction. I cant say anything more than I've already said to relieve you of you concern other than I think you thinking there is an issue here when in fact there is isn't. No, you can't exhaust or end the endless, but claiming that each step is finite doesn't imply that you can. I think it is good and constructive that the discussion has finally, in my opinion, clearly delineated what the issue is, and where we have a difference. I see no conflict or contradiction where you do. I really think this is a Gestalt issue. Like the famous picture of the two faces/vase, when you see the finite nature of each step, you can't see the endlessness, and when you think about the endlessness, you can't see how all the components can be finite. Infinity is not a topic that our minds can natively comprehend, any more that is wave/particle duality, or non-simultaneity. But that is the beauty of mathematics - we can logically create systems that bring us to understandings that go beyond what we can intuitively grasp. Cantor et al, in formalizing notions of infinity, made us accept many ideas that are counter-intuitive, or in conflict with other notions that seem clear to us. But accept them we must, because the math shows us that they are as they are. So asserting that every natural number is finite, and that the set of all such numbers is infinite, does not claim, or imply, that we have brought an end to endlessness. Rather, it tells us something about the nature of endlessness. Aleta

DS, I have no problem with endlessness of counting numbers, and I have no problem with inductions being of unlimited extent, such that for any concrete substitution case it will hold. The issue at first level is completing the endless in that way. In that context w emerges as the assigned successor to the endless succession. And the issue is just what is the set of counting numbers starting from zero, and what are their attributes. The outlined stepwise process above distinguishes between being unlimited in successive extension and completing the set, nesting that to complete one would have to produce an endless copy of the set, which by definition is infinite and endless. Cannot be done. Analytically. Also, the endlessness is within the set itself, w does not add endlessness to it. Further as the way the set progresses is through collecting more and more successors, it will in process be finite but points beyond to endlessness. That whole context leaves me very wary when an inherently finite and potentially infinite only proof process is held to entail an endless actual number of finite numbers. There is a contradiction there or else something too close to be comfortable. KF kairosfocus

KF, In your notation, m must be a non-real hyperreal infinitesimal. I don't have any idea how these things are graded as "mild" or not, so I will set that aside. In that case, 1/m = A is an infinite hyperreal, and is thus not equal to ω + g for any nonnegative integer g. daveS

DS, other numbers are drawn out of the ordinals. And as discussed I spoke to a mild infinitesimal taken through 1/m to get to A, which per an exploratory model I substituted as w + g. KF kairosfocus

KF,

Continue to endlessness and w emerges as supremum: {0, 1, 2, . . . EoE . . . } –> w

In fact, {0, 1, 2, ...} = ω is how this is usually expressed. I will ask again: If you have problems with an induction proof actually "finishing", what sense does it make to you to think of N as being a "completed" set in the first place? The set itself is generated by induction, after all. And no Turing machine can generate and list all the members of N in a finite number of steps. I think a more consistent position for you would be to deny the existence of N (in the sense that Aleta and I think of it) and just say one can work with finite subsets of N only. That would sidestep this issue of mathematical induction we are discussing. This is quite an unorthodox position, of course, but you wouldn't be the only adherent. Edit: Further to my #218: One way to see a difference between ordinals and hyperintegers is this: There is no smallest infinite hyperinteger, while ω is the smallest infinite ordinal. daveS

KF,

DS, the same “catapult” is used routinely in non standard analysis, as has been pointed out to you already.

What I'm saying is that:

1/m = A, gets you to w + g

is an impossibility. It's like saying 2 + 2 = 5. The infinite hyperreals are not ordinal numbers. I would urge that you exercise the same caution here with the "catapult" that you do when discussing mathematical induction. daveS

PS: Let's represent that algorithm and logic machine:

START --> 1] Initiating Feed: Initial condition: {} --> 0 ===> LOGIC MACHINE, LM Initialise LM space for storing current counting set list { . . . }, here, initially to empty set then on increment to immediately following successors to go through 1, 2, . . . EoE . . . Initialise LM space for storing current assigned numeral for current counting set, here, the empty set Initialise printer, confirm ready Go on to fetch, decode, execute . . . 2] LM-0: Set LM counter --> 0 Print "{", print list from counting sequence to date, comma separated values, print "} -->", print [counter contents]// gives counting set assignment and states the successor Increment printer output sheet for next line. Go on to fetch, decode, execute . . . 3] LM-next case: Increment LM counter value using standard, place value notation as stored in the machine Extend LM space for storing current counting set list { . . . }, to include newly incremented counter value // extends the counting set for the onward successor Print "{", print just extended list from counting sequence to date, comma separated values, print "} -->", print [current counter contents] // prints the result with the new counting set, preparatory to the onward successor Increment printer output sheet for next line. Go on to fetch, decode, execute . . . 4] Continue: Go on to fetch, decode, execute code block 3 just above.

This process is unlimited but inevitably is finite and however rapidly executed CANNOT exhaust and end the endless. Step 4 guarantees that, by imposing an endless loop. Endless loops are great for the main machine process in a computer, but these by definition are open ended and incomplete up to imposing a close down interrupt by shutting down the system or yanking the plug etc. And, this is in effect a proof by induction on initial case plus chaining logic plus standard result process at each step, here an algorithm rather than churning out the result of a formula etc. Which, we must recognise as unlimited but not ending the endless. And as an internal loop were it to do so the "final" printed set would be the whole endless set, nested. We RELIABLY produce instead an unending chain of finite counting sets but we do not have ability to exhaust the set as a whole. We revert to ellipsis of endlessness and collect the whole in a set we term the natural numbers big-N, giving its successor the finite symbolic numeral omega, then we start over again at transfinite level and proceed. Indeed the above exercise (it is patently code-able, save for the implications for storage) can be modified to execute that and to terminate at a suitable point after listing the ordinals in the compressed way say Wolfram did. That is a terminating, finite, exhaustively computable process that exploits the ellipsis of endlessness. BTW, thus the place for catapults that are not step by step incrementing processes. Using 1/x, 1 --> 1, 1/10 --> 10 [two orders of mag . . think in terms of place value steps], 1/100 --> 100 [4 orders], 10^-300 --> 10^300, [600 orders of mag], and then go on to the infinitesimal zone and catapult to the transfinite. Catapulting like that gives me a structural, quantitative connexion -- which seems logically coherent -- so that I can see the links from a bound and limited zone, [0,1] that is well within the finite set of ordinals and the transfinite that is beyond stepwise reach though steps point there. kairosfocus

zxc _____ Aleta & DS: Aleta, 196: >>back to 192: if all known transfinite numbers (cardinal and ordinal) are not actually members of N, then does it not follow that all numbers in N are finite? What alternaives are there? Either all natural numbers are finite, or there are transfinite numbers in N. If we have eliminated the second possibility, the first statement is true. “Jarring” concerns about an endless number of finite numbers may express a natural (which is sort of a double entendre, I guess) sense of the mystery of infinity, one which Cantor et al plumbed for us. But unless you can actually establish something mathematical (which my post at 192 highlights), your sense of being jarred is waiting for you to come to terms with that mystery.>> I long ago learned to respect my sense of cognitive dissonance, of logical incongruity. Remember, as primarily a physicist I had to swallow the transition from the classical to quantum and relativity. In this case, it is not that logical chaining from initial values and an assertion C-n for case n that then entails C-n+1 that is a problem. Yes, it chains on, unlimited. But it cannot exhaust, it is stepwise and subject to the ellipsis of endlessness. With what is on the table here being the very counting set that serves as first yardstick of endlessness in the first degree, Aleph null. The claims being made come too close to ending the endless. I elaborate a bit more in . . . DS, 197: >>It seems to me if you reject the inductive proof that all natural numbers are finite, then you reject the validity of mathematical induction in general. And since N itself is generally defined inductively/recursively, I don’t see how you make sense of the existence of N as a set itself . . . . Every natural number is finite, but no one is saying that N is in any way finite.>> I took a careful look at what the usual proof by induction I have used since 6th form days actually establishes. It finds a case 0 or 1, then establishes -- on a framework for case-n (C-n) that C-k => C-k+1. This hangs a logical chain on the first fact and proceeds to do so STEPWISE. This establishes unlimited extension indeed but again we cannot end the endless through a chaining of successive finite steps. We can only append a pointing ellipsis of endlessness. The issue is thus endlessness as the heart of the transfinite nature of the successive counting numbers. Which can be pointed to but not exhausted. Now, look at the set {0, 1, 2, . . . EoE . . . } This is, endless. It is also the sequence of counting sets per the von Neumann type assignment {} --> 0, {0} --> 1, {0,1} --> 2 . . . EoE . . . such that any value such as 5 emerges as the order type of its predecessors collected: {0,1,2,3,4} --> 5 This means that the counting, 1:1 match etc properties of the successor and its cardinality are established by what is on the LHS of the assignment. It can be shown that this example is WLOG. Continue to endlessness and w emerges as supremum: {0, 1, 2, . . . EoE . . . } --> w The endlessness is in the LHS, the set defined as the natural numbers. Endlessness is the heart of being transfinite and we need to face it. Where, our process of counting here must be endless on the LHS. By definition, ordinary mathematical induction points to but cannot exhaust endlessness. The claim that all naturals are finite hangs from finitude of the first and an endless succession that can only be pointed to. But in looking at k and k+1 for instance, the endless chain begins again any number of times and points to onward endlessness that can be put in 1:1 correspondence with the set starting from 0, 1 etc. The set is transfinite, on the LHS. Does finitude then chain to and exhaust the members? By mere force of instant logical extension to the whole? Thus entailing, all counting sets in the succession are finite, never mind the endless chain of such counting sets that scale ever upwards in succession, a process which must -- at least, it seems it must -- in the far zone go on to endlessness in the sets? [Or, the successive count has not become transfinite, so far as I can see to date. How do we get a transfinite collection of ever-mounting distinct counting sets where each and every one is finite, including at the far zone of endlessness? To my mind so far, I can see that we have a stepwise incremental algorithm of chaining, that is in an endless loop that it cannot exhaust. It spits out a step per loop, and points on to endlessness but is in itself inevitably finite, it can only step forward a finite, countable number of times. It points to potential infinity, it does not actually exhaust it. It also establishes that at each step we have the next successive number as label for the set that collects sets thus far, and only if the counting sets in the far zone scale to the transfinite within their internal membership lists can we have an overall set that is endless and transfinite. In short, there is nesting of the emerging transfinite character of the whole. At least, that is what I am seeing.] The problem is, ending the endless. Finitude implies ending, chaining in steps is inherently finite but points to the endless succession. And w is the limit ordinal that summarises that endlessness and is successor to the endless chain. There is no finite k such that k + 1 = w. Instead, I suggest a more modest interpretation: induction shows an unlimited, reliable logical chain that will work for any particular n you please, which by being specified becomes inevitably finite. But it cannot exhaust the endless. Just as w cannot simply succeed any particular k. Just as, the successive counting set looping algorithm can only ever stepwise attain to the finite and in so doing ever extends the scale of the sets, but points to the endless succession. The claim that finitude spreads through the whole chain by succession seems to me to suggest a claim to exhaust, or end the endless by an algorithm that can only ever be actually finite. For the moment, I think it safer to say, that finitude propagates down the chain, without limit as our algorithm loop counter increments and labels progress since case 0 so far. But that is very different from claiming it can exhaust the set as a whole. If it did so, it would indeed confer finitude upon all members, but to do that it has to end the endless, which by its very nature it cannot, it ever invites another clock-tick and step. Further to this, we are counting using this particular set [here, I envision the loop counter and a printer spitting out the assignment endlessly on Mr Turing's paper strip or a modern update thereto], and a finite number has the character, it is ended and surpassed even. If every counting number in succession is finite, how then can we consistently claim the set as a whole is transfinite, endless? So, I put my qualms on the table, I asterisk the claim. I do not dismiss it as absurd -- but I am concerned as to its coherence given the inherent issue that the counting numbers in succession are inherently endless. I do not know if we are able to bridge to mutual understanding as to why my concern. But maybe the idealised processor chugging away endlessly at a counting and printing loop algorithm but utterly unable to exhaust the set as a whole, stamping the final member as finite -- whoops there goes another clock tick -- can help. Where, I am confident that such is a reasonable mathematical exercise of induction from the particular to a succession rule to the chaining to unlimited extent. Howbeit, the chaining inherently cannot exhaust the whole. And that whole must be transfinite and to do so it looks a lot like the far zone we cannot reach has to have a fractal-like, nested copy of the whole in it. And, w is not somehow of distinct quality and characteristics from what lies on the LHS of the assignment of identity and labelling as ordinal successor that sums up and holds the cardinality of what it now tags: {0, 1, 2, . . . EoE . . . } --> w DS, 201: >>do you accept that the standard inductive proof given by Tao does indeed show that all natural numbers are finite? Your phrasing above suggests not.>> Please see the thought exercise of a counting loop algorithm implementing machine to see how I think unlimited reliable succession is not equal to ending the endless. Notice the need to embed a copy of the whole to end the process. Potential, but not actualised. Pointing to, but not completing, in a context where completing is the requisite. In short, I fear we are overclaiming what induction per se delivers. Aleta, 203: >>The definition of the naturals as being created by the statement that every natural number k has a successor k + 1 is an axiom, but it is not an arbitrary axiom – it is a universally accepted, I think, part of the foundational definition of natural numbers. But when you write that you are “fishing for the inherent, apt description of the essential meaning of a phenomenon, i.e. I am feeling for the innate nature of these number …”, I think you are talking about a psychological issue, not a mathematical one.>> Not psychological, but conceptual, philosophical, logical and mathematical by virtue of that discipline being the logical, abstract study of structure and quantity. Coherence is the chief test and guardian in such an exercise, but in this case there must also be congruence with the natural experiential root of whole counting numbers. Here, the issue seems to in part turn on unlimited though at any achieved stage finite succession of incrementing counting sets and ending the endless. Which by extension extends to causal succession from a claimed unlimited extension of antecedents [algorithmic process bridges readily to machine implementation] and to attempted decrementing from the transfinite just as much as incrementing to attempt attainment of the transfinite. Aleta, 209: >> we having been using “natural number” in the mathematical sense, not in some informal sense as including all sorts of different types of other numbers. As Dave said, let’s keep our eye on the ball: N = {1, 2, 3, …} is the topic.>> The mathematical sense of natural numbers builds on and must not violate what has been established through human experience of the phenomenon of matched counting sets and unmatched ones leading to counting, the concept of counting numbers that label particular standard sets -- which are then made abstract -- and so forth. The formal builds on and systematises the informal. It then leads to extensions: rationals, reals, complex numbers etc. So, onward links are relevant. Especially given the context set in the OP. DS, 211: >>How can mirrors be real if our eyes aren’t real?>> Mirrors and eyes are both real. And my first look into an abstract, virtual half-infinite in principle world was when I looked in a mirror and learned that images can be physically located behind it by parallax. P* ---> |: + + + > * Im (same distance behind, on line of norm) I recall once setting as a 6th form exercise, doing the pins and mirrors expt they did in 4th form, then challenging to ponder the virtual half-universe. Next step, set up two mirrors in parallel: endless, receding mutual reflections, in an endless in principle loop of light. In praxis, fading off as the reflections are not perfect. Applicable to laser cavities and creation of coherent radiation -- and the place of half silvered mirrors leading to spiking thence q-switching by various means to get controlled, much stronger pulses. Mathematical, idealised extension: endless loops pointing to the infinite. I recall, looking into the recession as the two little mirror strips were put in parallel was quite a shock that opened up the vista of the infinite. Even, though it could not actually attain it physically. A crucial distinction between physics and mathematics. Which brings us back to our ever looping incrementing algorithm, which logically is unlimited but is in principle strictly forbidden from claiming to have ended the endless. Aleta, 212: >>Why is this argument not valid?>> Please see the algorithm loop based illustration of the distinction between unlimited extendability and ending the endless. I am concerned that we may have gone a bridge too far. KF PS: White screen of captcha death, I have to go back and do the copy, cut out, nonsense phrase and insert real post on edit trick. kairosfocus

DS, the same "catapult" is used routinely in non standard analysis, as has been pointed out to you already. Used, to bridge the all but zero and the transfinitely large. In particular, infinitesimals and their multiplicative inverses the hyper reals. This last includes hyper integers. Hyper reals have to be continuous and the continuity of [0,1] makes for that when I looked at what I have called mild infinitesimals. This BTW fits in with the use of that interval in looking at the continuum and its degree of endlessness as distinct from that of counting numbers. Calculus and infinitesimals, I first saw in 4th form. Seeing the Newton-Leibniz approach reborn through non standard analysis opens up vistas. There is good reason to be confident that the use of 1/x ad multiplicative inverses bridges the v large and the v small. I am just suggesting what if a mild infinitesimal m through 1/m = A, gets you to w + g, g a large but finite number that is a successor to w, w + 1 . . . w + g . . . EoE . . . KF kairosfocus

Wow - I had forgotten about that book, but it was one of the first to get me really interested in math. I also really liked Isaac Asimov's books on science - I still have a whole set of his books. These were formative in my early teen years. Aleta

N = {1, 2, 3, …} is the topic.

Reminds me of this book: One Two Three . . . Infinity: Facts and Speculations of Science Mung

The OP was about "step by step causal succession" and "counting to infinity." Step-by-step and counting are done with the natural numbers (or the integers if you count backwards.) The focus of the OP is the natural numbers, not other types of numbers. So I ask you to address this simple argument directly, rather then just saying "it's not so simple".

if w (or the corresponding aleph null) are the first transfinite numbers, and they are not in N, then that proves that all natural numbers are finite. Q.E.D.

and, changing the wording to be declarative,

If all transfinite numbers (cardinal and ordinal) are not actually members of N, then it follows that all numbers in N are finite. Either all natural numbers are finite, or there are transfinite numbers in N. If we have eliminated the second possibility (which you agree we have), the first statement is true.

Why is this argument not valid? Aleta

KF,

DS, passed by a moment, a quick point. If a model being explored may have an interesting, possibly useful property it is worth noting. Catapulting and implications in this exploratory sandbox “space” are interesting — and they connect to, just how SHOULD we understand naturals, reals and the two infinities — big and small. Notice, endlesness is IN the naturals, that is how we get to w, and the real continuum between 0 and 1 opens up catapult phenomena that bridge to the transfinite once infinitesimals are on the table too. KF

Exploration is fine, but I do find it somewhat odd that while you have serious doubts about something so straightforward as mathematical induction, you nevertheless seem quite confident in this "catapult" idea, which is not exactly rigorous, to say the least. Your idea of filling in between ordinals can be made rigorous, I think (see the long line for something similar) but I don't know how it's going to shed any light on N.

PS: Just for now, I toss in, how do we get to endlessness if the nature of the finite is to be ended?

How can mirrors be real if our eyes aren't real? j/k. Seriously, though, I have no idea what this question is asking. At least if we stick to N, we can rely on standard definitions that, hopefully, we all agree on. daveS

Aleta, I note, the issue of what the naturals properly are is pivotal to their extent and to the issue of ending the endless, up-ways or down-ways. As for the focus of the thread as a whole, this is just one facet. The OP sets the focus, in the end. KF kairosfocus

kf, I am absolutely sure you are aware that we having been using "natural number" in the mathematical sense, not in some informal sense as including all sorts of different types of other numbers. As Dave said, let's keep our eye on the ball: N = {1, 2, 3, ...} is the topic. Aleta

PS: Just for now, I toss in, how do we get to endlessness if the nature of the finite is to be ended? kairosfocus

Aleta, I am looking at numbers that naturally appear, hence their name. From these we go to rationals, mixed numbers, place value/power series systems [think, decimals], reals, complex, then structures such as vectors, matrices etc. So, if they are natural, what is that nature? As opposed to one sets up arbitrary clusters of axioms and explores in a sort of super crossword puzzle game. Pardon, still mainly attending to local affairs -- and, e.g. the spin games to make pseudo consultations sound like the real deal are "interesting." KF kairosfocus

DS, passed by a moment, a quick point. If a model being explored may have an interesting, possibly useful property it is worth noting. Catapulting and implications in this exploratory sandbox "space" are interesting -- and they connect to, just how SHOULD we understand naturals, reals and the two infinities -- big and small. Notice, endlesness is IN the naturals, that is how we get to w, and the real continuum between 0 and 1 opens up catapult phenomena that bridge to the transfinite once infinitesimals are on the table too. KF kairosfocus

KF @193:

And the continuum of [0,1] would then allow filling in the gap between w + g and W + (g + 1) by suitable extension of the number system model, however informally I have argued. That is, I can see the reals or hyper reals if you will filling in between the transfinite ordinals endlessly too; there is plenty of room at the bottom near 0 as between any two neighbouring values m and n down there, there will be another, say p.

Wha?? We're having a hard enough time dealing with N here. I suggest we keep our eyes on the ball and not indulge in any such fanciful constructions for the time being. daveS

It would appear that the infinite must be simple and cannot be composed of parts or anything that can be counted. Mung

kf, you write,

The naturals are those counting set numbers in principle reachable by stepwise sucession from {} –> 0, {0} –> 1, {0,1} –> 2 etc, noting that they are endless in succession. And here I am using definition in a conceptual, even philosophical sense, fishing for the inherent, apt description of the essential meaning of a phenomenon, i.e. I am feeling for the innate nature of these numbers not imposing an arbitrary axiom that then controls what the meaning is. That endlessness in the definition — amplified from the ellipsis — implies that no stepwise process can exhaust them

I agree with the non-bolded parts above. However, the part I bolded doesn't make sense to me. What "arbitrary axiom" are you referring to? The definition of the naturals as being created by the statement that every natural number k has a successor k + 1 is an axiom, but it is not an arbitrary axiom - it is a universally accepted, I think, part of the foundational definition of natural numbers. But when you write that you are "fishing for the inherent, apt description of the essential meaning of a phenomenon, i.e. I am feeling for the innate nature of these number ...", I think you are talking about a psychological issue, not a mathematical one. The mathematical issue is clear, as stated (mostly) in the non-bolded part above: the psychological issue - what I referred to in an early post as the mystery of the infinite, is what you are grappling with and fishing for. I understand, I think, both as a math teacher and as someone who has tackled various mathematical problems myself, this issue of searching for a sense of "really understanding." In teaching calculus, I have often seem students who learn to do the math correctly, but who don't really grasp what it is about. The math itself is what it is, but a sense of comprehending what it is really all about is a feeling that for some students is always vague, and for others develops, sometimes suddenly like a light bulb. Aleta

Aleta, passed by for a moment, cf 195 above. Bolded, in context. KF kairosfocus

KF,

DS, I think if you look carefully, you will see that I am saying something a bit more precise about just what an induction that chains from a finite initial case C_0 or C_1 etc means.

Well, do you accept that the standard inductive proof given by Tao does indeed show that all natural numbers are finite? Your phrasing above suggests not.

And notice the issue just put up of limit ordinals with w the first precisely as it is successor to endlessness. KF

I have mentioned limit ordinals/cardinals several times already, so it's not exactly new to the conversation. I would also be cautious of calling a limit ordinal the "successor" to anything, either "endlessness" or "an endless set", since it by definition is not a successor ordinal. daveS

"Please note my fishing for what are the naturals. KF" What does that mean? Aleta

Aleta, I believe per fair comment that my answer was given by way of pondering what is involved in induction from the sort of initial finite case C-0 or C-1 means. Unlimited succession, which brings back in the very issue at stake. Okay, I have spent much time here, the evolving local situation calls for my attention as the clock ticks on. Please note my fishing for what are the naturals. KF kairosfocus

DS, I think if you look carefully, you will see that I am saying something a bit more precise about just what an induction that chains from a finite initial case C_0 or C_1 etc means. And notice the issue just put up of limit ordinals with w the first precisely as it is successor to endlessness. KF kairosfocus

KF,

Mathematical induction establishes unlimited reliability and endlessness, it does not stamp finitude into the set of counting numbers.

It seems to me if you reject the inductive proof that all natural numbers are finite, then you reject the validity of mathematical induction in general. And since N itself is generally defined inductively/recursively, I don't see how you make sense of the existence of N as a set itself.

Yes, any particular, specific counting set value we may assign k can be exceeded k + 1, but it is looking a lot like a fallacy of composition to use that inherently finite point to bind the set as a whole when its essence is endlessness.

I don't think there's any fallacy of composition going on here. Every natural number is finite, but no one is saying that N is in any way finite. daveS

All more of the same, kf, without anything but vague concerns and without addressing, among other things, my simple point in 192. You write, I add: once the set of counting sets is endless it has in it members that cannot be reached by a finite successive process, i.e. it is actually endless and beyond step by step exhaustion, on pain of not being endless. We can look on and point to the endlessness but cannot reach it and no k so k + 1 — inherently finite — will reach the extreme zone. ... And the notion that we have an endless number of FINITE values exhausting (in principle?) the succession of counting sets — what we use to count and to show endlessness itself — is very, very jarring here. Yes, the set is infinite, and no amount of steps can get to the end of it, because there is no end. But at each step you are at a finite number - there are just an infinite number of finite numbers. You keep using phrases which betray a deep misunderstanding - you can't "reach" endlessness, and there is no "extreme zone" within the natural numbers. It's "inherently futile" to think about "reaching the extreme zone" because the idea itself is erroneous. So back to 192: if all known transfinite numbers (cardinal and ordinal) are not actually members of N, then does it not follow that all numbers in N are finite? What alternaives are there? Either all natural numbers are finite, or there are transfinite numbers in N. If we have eliminated the second possibility, the first statement is true. "Jarring" concerns about an endless number of finite numbers may express a natural (which is sort of a double entendre, I guess) sense of the mystery of infinity, one which Cantor et al plumbed for us. But unless you can actually establish something mathematical (which my post at 192 highlights), your sense of being jarred is waiting for you to come to terms with that mystery. Aleta

F/N: Wolfram on transfinite induction:

Transfinite induction, like regular induction, is used to show a property P(n) holds for all numbers n. The essential difference is that regular induction is restricted to the natural numbers Z^*, which are precisely the finite ordinal numbers. The normal inductive step of deriving P(n+1) from P(n) can fail due to limit ordinals. Let A be a well ordered set and let P(x) be a proposition with domain A. A proof by transfinite induction uses the following steps (Gleason 1991, Hajnal 1999): 1. Demonstrate P(0) is true. 2. Assume P(b) is true for all b<a. 3. Prove P(a), using the assumption in (2). 4. Then P(a) is true for all a in A. To prove various results in point-set topology, Cantor developed the first transfinite induction methods in the 1880s. Zermelo (1904) extended Cantor's method with a "proof that every set can be well-ordered," which became the axiom of choice or Zorn's Lemma (Johnstone 1987). Transfinite induction and Zorn's lemma are often used interchangeably (Reid 1995), or are strongly linked (Beachy 1999). Hausdorff (1906) was the first to explicitly name transfinite induction (Grattan-Guinness 2001).

Where also:

Principle of Weak Induction Let D be a subset of the nonnegative integers Z^* with the properties that (1) the integer 0 is in D and (2) any time that n is in D, one can show that n+1 is also in D. Under these conditions, D=Z^*.

These first point to limit ordinals, where w is the first, as posing a logical barrier necessitating going beyond finite chaining exactly because of the EoE effect. So, indeed, we can define the counting numbers as those in principle reachable by successive logical chaining from 0 or 1. Then we can point to the endlessness involved. But, but, but we see here that the naturals are viewed as finite. I suggest, rather, we see the distinction between reachable in principle and endlessness. The number w is a systemic succession not a particular value in a chain, succeeding from some value k such that k +1 = w, it is a limit ordinal. Endlessness of succession is embedded in its meaning. I again point to the need to take that endlessness seriously. I would modify the above accordingly. The naturals are those counting set numbers in principle reachable by stepwise sucession from {} --> 0, {0} --> 1, {0,1} --> 2 etc, noting that they are endless in succession. And here I am using definition in a conceptual, even philosophical sense, fishing for the inherent, apt description of the essential meaning of a phenomenon, i.e. I am feeling for the innate nature of these numbers not imposing an arbitrary axiom that then controls what the meaning is. That endlessness in the definition -- amplified from the ellipsis -- implies that no stepwise process can exhaust them. Finite stage stepwise induction from initial case C_0 and C_k => C_k + 1 will point to but cannot stepwise exhaust the endless set. Where such a proof then hangs an unlimited reliable chain from a first demonstrated mathematical fact. That seems to capture what the set of successive counting sets or natural numbers is about, at least as I can see it just now. Then w succeeds, not by increment of unity k + 1 *=* w . . . NOT, but by being defined as successor to the endless set. Where also, it seems reasonable to use mild infinitesimals near 0 in the continuum [0,1] to catapult to the transfinite zone by the use of y = 1/x. From this, it further seems that between w and w + 1 etc, one may catapult a continuous zone thus filling in a line we may suggest as a trans-real line by analogy with the hyper reals. And implicit in this would be model assumptions and a sort of chaining by inductive succession. The question is, would such be reasonable as giving a finer ordering? There is a lower bound w [a limit ordinal], and there is a catapult mechanism that exploits the [0,1] continuum in the all but 0 lower end, and as if m >n, 1/m < 1/n, we can assign succession and we can also see that there is always a p between in the [0,1] continuum, so it seems reasonable. So, maybe here is a zone worth expanding on. And of course I am here using the definition that mathematics is logical reasoning about structure and quantity (which implies inter alia, sets). KF kairosfocus

F/N: Wolfram on limit ordinals:

Limit Ordinal An ordinal number alpha>0 is called a limit ordinal iff it has no immediate predecessor, i.e., if there is no ordinal number beta such that beta+1=alpha (Ciesielski 1997, p. 46; Moore 1982, p. 60; Rubin 1967, p. 182; Suppes 1972, p. 196). The first limit ordinal is omega.

KF kairosfocus

Aleta, I wish it were that simple, and I am fully aware that in this mix is the mathematical proof by induction that I first learned to use in 6th form math a long time ago now. The matters at stake here go to not only mathematics but meta issues, phil of math issues, nature of sets etc. The key point is, we are dealing with counting sets and the meaning of numbers, e.g.: {} --> 0, {0} --> 1 . . . {0, 1, 2, 3, 4} --> 5 Indeed many would dispense with arrows of assignment and simply use equality of definition. I add: the collection, assignment process is what we effectively mean when we say 5 is successor to 4. And cardinality of 5 emerges as being an equivalence class, i.e. the set is a five-set and can be put in 1:1 correspondence with any other such. That is, we use an example that in this respect is WLOG. Onward, sets of countable transfinite cardinality will be such that proper, limited subsets can be put in 1:1 match with the unlimited succession of counting numbers; famously the evens and the odds. . . . {0, 1, 2, . . . EoE . . . |} --> w That is, w as successor is inextricably entangled with what has gone before. The ellipsis of endlessness is INSIDE the set of all counting numbers, it is "just" an assignment that this counting set is termed w. We cannot cleave w apart from what has gone before, it is entangled into what w means. And, obviously, to go, 1 + 1 + . . . 1 k times --> k and then one more to exceed it as k + 1 showing k is bound and finite, does not remove the significance of the EoE. Ellipsis of endlessness. Counting is not separable from the succession of counting sets. The endless list of such sets. Let me add: we are counting (in principle) with these sets and that requires an endless chain of endlessly increasing members. So, we see that we have a potentially infinite succession, a limitless process of counting sets, and when we consider that endlessness as a whole-- one, that we may imagine but cannot complete in steps on pain of trying to end the endless -- we say the successor is w. For induction, setting claim C is so for initial value C_0 or C_1 and it chains as C_k => C_k+1 simply embeds that potential infinity, the "it is so without limit," the subscripts imply the presence of the endless succession of counting sets. To then say, voila, QED, all counting sets in that endless succession are inherently finite runs into, the endlessness. We are open ended, unlimited and endless thus not bounded at the upper end, so to claim or imply that all counting sets are finite runs into trouble. The unlimited by definition cannot be limited. You cannot end the endless. So, I think there is need to rethink. At least, for me. This is close to the heart of my discomforts, my sense of cognitive dissonance. I think the chaining, the linked axiom of infinity or whatever (and yes I know the independence issue obtains as with the axiom of choice and whether c = aleph 1) are telling us something that needs to be hedged around carefully. The EoE puts endlessness into the chain of counting sets, tantamount to the ordered succession of natural numbers. On an induction argument, what is proved -- strictly -- is, this succession of results is endless and reliable. It is an endless chain of stepwise logical transfer with good links hanging from an initial demonstrated mathematical fact. But for it to be valid itself, it cannot be bound, it must succeed itself in an unlimited chain as the subscript goes on forever increasing. Chain out in k steps to k and you can go on to k + 1, for any value you please. Which means, the set of successive counting sets has to be open to limitless extension. To assure that very reliability. The very opposite of finiteness. Yes, any particular, specific counting set value we may assign k can be exceeded k + 1, but it is looking a lot like a fallacy of composition to use that inherently finite point to bind the set as a whole when its essence is endlessness. So, the endlessness is in the set, not in w as designated successor, as w is composed from, emerges from, is inextricably entangled with that endlessness of succession WITHIN the set. Indeed w MEANS that. That entanglement is the root of my concern. I am comfortable in accepting chaining as inherently unlimited, but that simply further underscores the point. I add: once the set of counting sets is endless it has in it members that cannot be reached by a finite successive process, i.e. it is actually endless and beyond step by step exhaustion, on pain of not being endless. We can look on and point to the endlessness but cannot reach it and no k so k + 1 -- inherently finite -- will reach the extreme zone. Yes, by appending yet another EoE to the k, k +1 succession (notice how neatly we embed yet another endless counting chain on a proper subset by in effect using a start count from k and proceed to match k --> 0, k + 1 --> 1 etc . . . showing the transfinite nature here by 1:1 correspondence with the original, full set; and in fact we could make endlessly many match-able copies like that . . . ), we may POINT to the endlessness, but we do not actually attain it, and if we did it would no longer be endless, a contradiction would have occurred: ending the endless. I have spoken of an impassably vast Sahara and how we need to catapult past it using something like y = 1/x as we approach 0 in the [0,1] interval, using continuity and appealing to infinitesimals. At least that is how I am thinking. Where, further adding: yes, shifting to reals, I am also looking at the all but zero small, the infinitely small. I find no reason to reject that a mild infinitesimal, m can catapult us into a zone finitely near w, even as we may speak of hard ones that catapult us into hyper-reals beyond all reals as it is roughly suggested. And the continuum of [0,1] would then allow filling in the gap between w + g and W + (g + 1) by suitable extension of the number system model, however informally I have argued. That is, I can see the reals or hyper reals if you will filling in between the transfinite ordinals endlessly too; there is plenty of room at the bottom near 0 as between any two neighbouring values m and n down there, there will be another, say p. So, we can catapult the [0, 1] continuum between any two successors. I see endlessness of particular values at the bottom among the reals in a limited range continuum, and endlessness at the top too including endless fitting in of the continuum by such a catapult process, between successive transfinite ordinal values say w + r, w + (r + 1). Mathematical induction establishes unlimited reliability and endlessness, it does not stamp finitude into the set of counting numbers. On pain of undermining its own reliability. I add: And the notion that we have an endless number of FINITE values exhausting (in principle?) the succession of counting sets -- what we use to count and to show endlessness itself -- is very, very jarring here. Where, endlessness cannot be severed from the members, a set being, roughly, a definable collection. This is now beginning to bring out more of the force of my concern. KF kairosfocus

In fact, kf, if w (or the corresponding aleph null) are the first transfinite numbers, and they are not in N, then that proves that all natural numbers are finite. Q.E.D. Aleta

Cleanup on aisle ... EoE ... k + 1 please! Mung

... I ... can't ... seem ... to ... stop ... counting ... Mr. Escher, we have a problem. Mung

OK, that is clear: w is the ordinal successor to the natural numbers, but is not a natural number. Then what is wrong with saying every natural number is finite? Aleta

Aleta this is an endless loop, I have repeatedly answered the question, in the negative. However the further material point, is that endlessness is in the set of whole counting numbers itself and w is in effect its successor as a whole, a value assigned to the first degree of endlessness as an ordinal. So, w is not an arbitrary, unrelated imposition which is exactly why the sequence shows it as successor to the whole counting numbers as they amount to endlessness. That is there is an organic connexion and a phenomenon of emergence to be recognised, endlessness. Endlessness that is within the set of counting numbers, where succession is such that, e.g. 5 --> {0, 1,2,3,4} and so forth, i.e. counting sets if you please have successors. We can then reasonably ask, go to the point of endlessness and ask, what is the onward successor, and that is assigned w. KF kairosfocus

I don't get it, kf. I don't see the problem. I don't see that you have answered my question, either. Is w in the set of natural numbers or not? Saying "w is the successor to the naturals" doesn't answer the question - is it a successor in the naturals, after the ellipsis, or is it a successor to the naturals - beyond but not in the naturals. Which is it? Why won't you/can't you say? Aleta

Aleta, I already gave the answer: w is successor to the naturals, which has a meaning in ordinal context that reflects taking in what is before then capping it. Elsewhere, I spoke of the issue that the endlessness is already in the naturals, expressed in the EoE. But that's the problem/point right there, the endlessness is in the naturals. KF kairosfocus

There is nothing ambiguous about the .... All it means it that for any k, k + 1 is also a natural number. That is all it means.

N = {1, 2, 3, …} N does not equal {1, 2, 3, … w, …} In the interest of clarity: Do you agree that N does not contain w? Yes or No?

Aleta

Aleta, First the ellipsis is ambiguous. Second w is successor to the naturals, per the usual understanding. The issue is on the subject, endlessness is within the naturals. KF kairosfocus

You writem "Of course, we have the succession conveniently provided by Wolfram," The "the succession conveniently provided by Wolfram" is not all within the natural numbers: N = {1, 2, 3, ...} N does not equal {1, 2, 3, ... w, ...} In the interest of clarity: Do you agree that N does not contain w? Yes or No? Aleta

The ... already means endless continuation. What do you gain by adding another symbol EoE to also mean endless continuation? It all means the same thing - there is always another finite integer. Aleta

Ok, I don't think I'm seeing the problem, however. daveS

DS, look at the set itself: the counting numbers, which is by definition endless and would contain all numbers ordered from 0, 1, 2 . . . EoE . . . I am looking instead at a definition, N is the least inductive set (set of successors to 0, 1 etc in effect). KF kairosfocus

KF,

And, to assert all naturals by succession and induction are finite, is to imply spanning the transfinite. I am thinking, we modify that any completed span will be finite. We may only actually point conceptually to the whole. Which is valid as mathematics is a conceptual exercise in the first place.

Most mathematicians don't think of the natural numbers as a being in a partial state of completion. Rather, the set N is already "completed", if you will. Can you give a good reason for not going ahead and flatly stating that all natural numbers are finite, period? Is it possible that we will at some point discover an exception? daveS

kf. I appreciate your characterization of this discussion as an exploration: I think that is what good constructive dialog ought to be. However, I'm finished with my part of the discussion: trying to address and make sense of the many points you bring up, many of which I've already said I'm not interested in, would not be a good use of my own time and energy. You may be uncomfortable with "the claim that all naturals are finite but the set of naturals is transfinite," but I'm not, so I'm ready to let he discussion come to an end. Aleta

F/N: I see we are in the high hit for the past month club here now. Any new participants, please understand this is an exploration, live, messy, incomplete, patently vulnerable. I am uncomfortable with two things, claiming an infinite down-count that gets to a finite neighbourhood of 0, and the claim that all naturals are finite but the set of naturals is transfinite. As at 174, I am coming to a point of comfort by introducing an explicit ellipsis of endlessness and holding that it is INSIDE the definition of the set of naturals. So, ruling that w etc are not naturals is not relevant to the main concerns. And, I am seeing that we can suggest a catapult -- the function y = 1/x -- to get us from [0, 1] the closed and continuous real interval, to the zone by way of a process at least conceptually comparable to how discussion of hyper-reals and infinitesimals is entertained in non standard analysis. All of this then extends tot he issue of infinite stepwise succession on finite stages, and to the claim or implication that here is an actual infinite past to the physical, matter-energy space-time cosmos and extensions thereof in some form or other. Finite successive causally connected stages would be on the table an these can be labelled in succession . . . C2, c1, c0 | . . . singularity | C1*, C2*, . . . Cn* Where Cn* is now. The math is directly logically connected. I argue that claiming or implying completion of an endless successive process of finite stages is a futility, a supertask and so the best conclusion is our cosmos etc are of finite temporal span, had a beginning at some finite time, including whatever physical may lurk behind the singularity of what 13.75 BYA on the usual timeline. And to pop a physical world out of a nonexistent hat of non-being at some point is even more of an absurdity. Mix in ontological issues on necessary being foundational tot he actual existence of any world, and we are staring eternity -- as opposed to time -- in the face, folks. At least, that is how it looks to me. So, if you have thoughts, welcome. KF PS: Those who wish to cynically dismiss me as having fixed and unalterable ideas, this thread is in part a demonstration of the opposite, it is of exploratory character in the context of an intuitive sense of discomfort with common claims. Why that discomfort, apart from there is some incoherence somewhere, there is some circle of begged questions or both, or, what? I want to be at a point of comfort or at least lessened discomfort due to having had a serious open exploration of the issue. PPS: If you thing the ordinal chaining borrowed from Wolfram for convenience and extended as well as issues of down counting etc tied to such not to mention catapulting from [0,1] to a transfinite range are all wet, kindly, show why. kairosfocus

MT, I hear your concerns. I guess this is the thread for concerns -- I have long meant to add stir the pot as a category, I will do so in a moment. KF kairosfocus

DS, Endless extension in actual space is just as problematic as endless extension in time. KF kairosfocus

Aleta, I just woke up with the infinite on mind, and thought to look here. I think a contrasting case will help. The interval [0,1] as a continuum has in it transfinitely many real numbers, and to complete the process of say travelling across one metre traverses a transfinite succession of such a continuum in a finite time. For this, there is no problem, these are processes within finite limits. And of course a translation can then extend any continuum between [0,1] to any span in stepwise succession, so the notion of a continuous line, then plane then space then hyperspace is no problem. Now, we go to endlessness, and to the issue of assigning the value aleph null as cardinality to an endless succession of counting numbers considered as a set. First order of magnitude endlessness, and then one may assign onward values by a succession of power sets. Further, one may define w as the successor to the process as imagined to continue endlessly, and go on from there to w + 1 etc, on to epsilon nought etc. In context, a prime issue is mathematical induction, seen as chaining onwards, where if X is so for initial member i and the logic of succession is that if X(K) then X(K+1) this chains onwards in ordinal succession endlessly. As opposed to as a complete in fact process. And, I confess to getting just a tad concerned when there seems to be a hestitation to look at coming back down once one looks at the transfinite range of ordinals and cardinals. If simply changing direction of succession and start-point can be so sensitive, that is not a healthy sign. Beyond, it is clear that one cannot actually complete an endless stepwise process, the stepwise process is inevitably potentially but not actually infinite. So, to premise a completed process is already to move to the world of what is potential and conceptual, not physically actualised, as a general rule. Going back to the span [0,1] I am seeing that again the traversal is conceptual, we do not actually work out the endless succession to arrive at a given point, say 1/pi in that succession, or any one of the endless chain 1/ (pi^n) which we can conceptually catapult into the zone, we note that we can conceive of the continuum, and use it to model the actual world. Between any two neighbouring but distinct values, we may in principle define a third, most easily by an averaging process. (BTW, I can sympathise with Mapou in his discarding of the infinite, though I think there is a legitimacy to the conceptual space and to its mapping of the actual world.) Now, let us look at your onward remarks. Let us see what I spoke to in your first clip from me in 169:

ascending count from 0 or a finite neighbourhood of that in an attempt to attain w etc is inherently futile, w is in effect an emergent value once endlessness of succession is in play.

In short, in the first part, I am saying the completion of endlessness is a futility, a supertask. I am not envisioning this as actually done. And, I am seeing w as the concetualised successor to that process, and as projected once endlessness of succession of steps is in process. Likewise, the point of endlessness is it implies a spanning of a transfinite range at least as a concept, and further entails that such is impossible as a result of a stepwise finite process. To span, we must catapult across the range conceptually, we need a mathematical wormhole. That seems to be in part what the use of y = 1/x to discuss infinitesimals and hyper reals is about. As you recall, I have discussed what I can now say is a "mild" infinitesimal m, that catapults you [conceptually . . . ] into the range of w, at w + g, g finite. Where m in my view is part of [0,1] so I have no reason to hold it not a valid conception, and I accept the existence of hard transfinites h -- now, that is a happy coincidence that goes to the classic first principles of differentiation: f'(x) = lim as h --> 0 of {[f(x +h) - f(x)]/h} -- in said range and close neighbourhood of 0. Forgive the sci fi terminology. H'mm, let me add to this. As between any two values in [0,1] we may define a third, we see that we can identify that if m and n are neighbouring mild infinitesimals, then their catapult values will be just as near, A, B, i.e. we see that there can be a line of continuum defined in between successive ordinals w +g and w +h, say. (I here use h in a different sense, sorry.) Where of course between m and n we can interpose an intervening neighbour and catapult that too. That sure looks like, transfinite continuum. Which would also perforce extend tot he hard infinitesimals, so the hyper reals would be continuous, of course involving hyper integer values among them. And, I see that once non standard analysis is on the table, infinitesimals are back in business. So, it makes sense to speak of mild ones. And to apply a function to transform x-value at input to y-value at output is a reasonable process. Here, in the very near neighbourhood of 0 for x. Coming back to the next series of your remarks:

No, there is no “spanning of the transfinite” in counting up. Nothing is ever spanned, the ellipsis is never passed. As I said above, the transfinite is about the whole set of natural numbers, but not about some place “beyond the ellipsis” within the natural numbers. And since there is no transfinite spanning counting up, there is no transfinite spanning “counting down”. “Counting down from infinity” is impossible not because a transfinite span must be completed, but because there is no such place as “infinity” to start counting down from. Wherever you started counting down from will be a finite number, and you could always start counting down from a higher number.

yes, we agree no stepwise finite step process will span a transfinite zone. Hence my starting from the idea of a catapult via 1/x from what I would now term a mild infinitesimal, m. And, numbers inherently are a conceptual space that has a conceptual span, though obviously a transfinite one. I would suggest that once we have the zone, w, w +1, w +2 . . . w +g . . . w + w . . ., we can and do have up/down successions in a transfinite band. So, it makes reasonable sense to do a down count from some w +g, g finite and ask, what happens if we keep on endlessly? To which the answer is, we cannot escape the transfinite zone by stepwise succession downwards that actually attains the finite neighbourhood of 0, the cardinality is still of order aleph null. At least, that seems reasonable so far. And no, it seems to me that a succession upwards or downwards in a transfinite range of numbers is reasonable as they can be laid out in order of ascent and simple request, what, sir is your predecessor and a pointer to the left of one step will succeed. Until one hits a transfinite ellipsis of endlessness. w + g, w + (g - 1), . . . or, w +g [= A], A ~1, A ~2, . . . [Read, A less one, etc] Where such are obviously very powerful symbols in this business we are attempting here. Let me add to the set of symbols, to symbolise endless continuation with: . . . EoE . . . Adapting Wolfram:

From the definition of ordinal comparison, it follows that the ordinal numbers are a well ordered set. In order of increasing size, the ordinal numbers are 0, 1, 2,. . . EoE . . . , omega, omega+1, omega+2, . . . EoE . . ., omega+omega, omega+omega+1, . . . EoE . . . [then full stop]. The notation of ordinal numbers can be a bit counterintuitive, e.g., even though 1+omega=omega, omega+1>omega. The cardinal number of the set of countable ordinal numbers is denoted aleph_1 (aleph-1) [and, it corresponds to w1].

Symbolising, it seems we are looking at: . . . EoE . . . w+g [= A], A ~1, A ~2, . . . w . . . EoE . . . r, (r-1) . . . 2, 1, 0. [r defining a convenient finite neighbourhood of 0] Now, we can say, the EoE cannot be spanned in steps. And any stepwise process will be finitely remote from its start point at any actually completed stages k, k +1 and so forth, repeat. In this context I can see holding, EoE is a roadblock to finite process, or rather an un-span-able Sahara. You run out of resources long before you can span it in steps. Now you speak of how " . . . the transfinite is about the whole set of natural numbers, but not about some place “beyond the ellipsis” within the natural numbers." Of course, we have the succession conveniently provided by Wolfram, and the implication of successive steps being that what we can actually count to will be finite. But there is endlessness so the span of the whole, as the potential and abstract endless process is transfinite. An emergent conceptual property of the whole. Fine so far. Howbeit, at a price. Endlessness within the counting succession is involved inside the set, via the ellipsis again: { 0, 1, 2 . . . EoE . . . } And, we are here dealing with the very set used to count. Its span MUST be endless, transfinite. So, while any actual succession of actual steps must be finite, the span of the whole as we may abstract from taking steps and applying succession, is transfinite. Where, too, it matters not that we define w as NOT a "natural" as the EoE is inside the set of naturals, I have just made that span explicit. The naturals keep going on and on ENDLESSLY. We can only attain to finite degree but the EoE says, onwards forever. And endlessness is the very stuff of the transfinite in mathematics. So, further, we see that the claim to complete a downwards succession within that EoE to a finite neighbourhood of 0 is a futility. And, to assert all naturals by succession and induction are finite, is to imply spanning the transfinite. I am thinking, we modify that any completed span will be finite. We may only actually point conceptually to the whole. Which is valid as mathematics is a conceptual exercise in the first place. So, yes any actual count that attains a finite neighbourhood of 0 in the downwards direction will be finite. Which is the same as saying, the actual succession will be finite in cumulative span, the EoE cannot be bridged in actually completed steps. Which for my interest, has direct relevance to a claimed past transfinite causal succession, or at any rate, one that has to face EoE. And yes, the three little dots do point to something awesome and mysterious. Onwards, with the explicit acknowledgement of the EoE in the set of counting numbers -- which identifies where counting can potentially but not actually range to -- I can see that any natural or counting number we can attain is finite, but the set as a whole has EoE in it, and that gives it transfinite character. And yes there is a distinction I make there, that points to the concern I have on asserting all natural numbers are finite. All values or members we can attain to by a stepwise successive process are finite, but the whole set contains EoE so is of inherently transfinite character. And we may proceed to define a successor to that EoE, w, and then succeed it w + 1, etc, within a range that starts in the transfinite and extends the concepts. That, I am comfortable with. KF kairosfocus

FWIW, one late correction to my post #104: The ordinals do not form a set, but rather a proper class. daveS

I don't agree with the concept of minus infinity to positive infinity. It leads to stupid results. For Eg, Most particles have a lifetime of microsecond. If they start moving near speed of light, their lifetime increases.In '0 to negative infinity' time belt,if they start moving, their lifetime will decrease! In fact, because lifetimes are in microseconds for most particles, in the '0 to negative infinite' time belt, particles will cease to exist if they move! Me_Think

KF, Suppose the universe were spatially infinite, which I assume you agree is at least conceivable. Would that then mean that there must exist points in the universe infinitely far from Earth? daveS

Thanks, kf. I will limit my comments those pertaining to the natural numbers. Tu write,

Perhaps, I am being overly scrupulous or needlessly concerned but it will not shake.

Yes, I think you are. The key to what I see as your confusion, and the source of your concern, is contained here:

I think the best we can see so far is that ascending count from 0 or a finite neighbourhood of that in an attempt to attain w etc is inherently futile, w is in effect an emergent value once endlessness of succession is in play.

An ascending count is not an "an attempt to attain w." w could be considered an emergent value associated with N, being the ordinal number associated wth aleph null, the transfinite number defined as the order of infinity represented by the natural numbers. But an ascending count doesn't "attain" anything: it just goes on and on because there is nothing to ever cause it to stop. Every k is followed by k + 1. It's not trying to get to some other level of number w, so there is no futility involved. w is a number about N, but it is not a destination of some kind within N. And then you write, We can only actually ascend in steps to a finite point, but the issue of endlessness is real. It then gives rise tot he issue that if there is an implied endlessness of descent, it will be challenged to complete in a finite neighbourhood of 0. It seems to me the two issues of going up or down are entangled, as the spanning of the transfinite in steps is implied in both. No, there is no "spanning of the transfinite" in counting up. Nothing is ever spanned, the ellipsis is never passed. As I said above, the transfinite is about the whole set of natural numbers, but not about some place "beyond the ellipsis" within the natural numbers. And since there is no transfinite spanning counting up, there is no transfinite spanning "counting down". "Counting down from infinity" is impossible not because a transfinite span must be completed, but because there is no such place as "infinity" to start counting down from. Wherever you started counting down from will be a finite number, and you could always start counting down from a higher number. So, this is the heart of the matter, I think. Thanks for the response. I'm pretty sure this is all I have to say: I don't think there is anything more I could say. I think you have intuitive concerns about the nature of infinity - it's a baffling subject, but I do think you have an erroneous concern about there being some unresolved mystery connected with those three little dots ... Aleta

Aleta: Having addressed a local issue, pardon my having had to be basically offline, I will pick up from 159: 1: >> I am wondering who is making this claim? [claimed stepwise actual completion of the endless]>> Asa I briefly noted, that is one of the implications of claiming an infinite past, which has not only been asserted out there, but in thread, DS has gone on to say, 160: "To me, the existence of an infinite past just means that given any natural number n, the universe already existed n seconds ago. [edited] This is consistent with every instant in the past being a finite number of seconds away from the present." So, it seems to me the claim is at minimum implied and is converted into an attempt to say that any particular past moment will be finitely remote so there is no descent from the transfinitely remote past. And, by extension of causal succession, there is no transfinitely remote distant past just at any given point, finitely remote values, which correspond to numbers. I believe this claim is patently false, if a transfinite past is claimed, a transfinite causal succession is claimed and an achieved completion of the endless is claimed. Which is so obviously problematic that here is an attempt to suggest that everything within the series, n, is finite but the whole is transfinite. A transfinite past succession and an endless past train of steps thus in principle numbers to go with it, is there. And, on fair comment, it does fall under the stricture of trying to claim or imply completion of the endless. You are not making such a claim (as we both acknowledged long since), but others have or strongly seem to me to imply such. 2: >>I have not been discussing a “descending order to a finite neighbourhood of 0.” We have, I think, been discussing counting up from 0, in discrete steps, and in discussing the nature of the endlessness that entails, but I have not been discussing “counting down” from infinity to a “finite neighbourhood of 0.” This is essentially the same point as a made in 1.>> Again you may not have, but the issue is there in context, given what has been at stake. My concern in part has been, how can we represent such a claim symbolically, on the way to understanding it. I think the best we can see so far is that ascending count from 0 or a finite neighbourhood of that in an attempt to attain w etc is inherently futile, w is in effect an emergent value once endlessness of succession is in play. We can only actually ascend in steps to a finite point, but the issue of endlessness is real. It then gives rise tot he issue that if there is an implied endlessness of descent, it will be challenged to complete in a finite neighbourhood of 0. It seems to me the two issues of going up or down are entangled, as the spanning of the transfinite in steps is implied in both. 3: >>My position is that the natural numbers N = {0, 1, 2, … k, k + 1, …} · a. are represented by the first order of transfinite cardinality aleph null, the number of numbers in the set N, and that w represents the corresponding first infinite ordinal. Thus aleph null and w are transfinite ideas associated with N. · b. further transfinite orders of cardinality and ordinality are about other sets, not N.>> My concern remains, that N -- which contains the counting numbers as extended in order endlessly -- as a set has transfinite cardinality, and the weight of that should not in effect be left to a three dot ellipsis. I am even uncomfortable with the argument If k is finite and k + 1 is its successor, then any pair k, k + 1 will be finite, and 1 is finite so all numbers in succession thereafter are finite. The problem being, the matter in view to discuss successions is exactly dependent on finite succession when the ellipsis points to endlessness. I think we are here close to begging a question or two, uncomfortably close for me. How do I put it. Something like, a finite increment to a finite is a finite indeed, however we are arguing to the endless and in a context where an endlessness is transfinite. So, a transfinite number of finites where the very numbers themselves are what is in view to attain to cardinalities, sits uneasily for me. Perhaps, I am being overly scrupulous or needlessly concerned but it will not shake. 4: >>The rest of your post is again about counting down from infinity, and about the possibility of an endless past.>> Yes, that seems entangled. KF PS: White screen of death again. kairosfocus

Still busy, later. kairosfocus

KF,

DS, in saying at any n in the past there was a world is implying just such an endless past. 1, 2, . . . n . . . rinse and repeat.

Clarification: What I am saying is that an infinite past does not entail the existence of any points in time infinitely far in the past. daveS

When you have more time, I hope you can look specifically at 159 and respond to my points so as to keep them separate from other points. Aleta

Aleta, passing by again a moment. There are people out there claiming an endless past; which I have been representing as before singularity at 0 -- note OP " some naturalists such as Sean Carroll suggest that all we need to do is build a successful mathematical model of the universe where time t runs from minus infinity to positive infinity". DS, in saying at any n in the past there was a world is implying just such an endless past. 1, 2, . . . n . . . rinse and repeat. That is where my concern on traversing the transfinite in steps comes from. KF kairosfocus

I wasn't under the impression that our universe having an infinite past was ever the issue. I think everyone here, including kf, Spitzer, etc. accept that our universe started 14 billion years or so ago., so that time within our universe definitely has a finite past. My impression has been that we have been assuming that time in some universal Cartesian sense stretches back before this universe - the very first post in this series of threads mentions a series of universes. And Spitzer's original arguments are about an abstract, mathematical infinite past, not past as embedded in this universe. So, to kf, I want to make it clear that my post at 159 has nothing to do with the issue of the age of the universe, or the existence of other universes, or anything related to that. So my hope is that you would make at least one response to 159 without getting these other issues involved. Aleta

KF, Eh? I'm not sure what you're saying there. [Edit: If you're saying (to summarize my statement above) that 13.75 billion years ago, the universe already existed, and 10^500 years ago, the universe already existed, and likewise for any finite number of years ago, then that is correct.] All the ellipsis means in this context is that the set is closed under the successor operation. When we write {0, 1, 2, ...}, we're saying that the set has 0 (and 1 and 2) as elements along with the successor of any element. It's nothing terribly deep. daveS

DS, so, 13.75 bn ya, the observed cosmos was, and 10^500 y past and . . . [that transfinite ellipsis again]. KF PS: For the moment I have to have focal effort elsewhere, so overnight. kairosfocus

Dave: That’s not what I am assuming. To me, the existence of an infinite past just means that given any natural number n, the universe already existed n seconds ago. [edited] This is consistent with every instant in the past being a finite number of seconds away from the present. I think KF has it backwards. You don't move from the past to the present , every moment in the past is the" present " relative to that moment. You are always at ( 0 ) on the line. It is the configurations of space that are the points on the line. In that sense, a possible infinite number of configurations makes the configuration that we term the present not impossible but probable. velikovskys

KF,

Surely, if the past is endlessly remote, at some point it must have been transfinitely remote if such is so.

That's not what I am assuming. To me, the existence of an infinite past just means that given any natural number n, the universe already existed n seconds ago. [edited] This is consistent with every instant in the past being a finite number of seconds away from the present. Mung: Thanks. daveS

Thanks for the reasonably succinct response, kf. I would like to respond to a few points. I'm going to try to keep each point on a specific question or comment in order to help separate the issues I have a favor to ask: would you be willing to respond to each point separately also? Perhaps we can sort out what the real issues are, and see if we can separate the common ground from the points of difference between us. I have bolded major questions that I would particularly like a short answer to. I am speaking for myself here, although I am pretty sure Dave and I are in agreement on the issues I'll mention. Also, I am going to model the idea of responding clearly to each point by responding to each of your paragraphs. Anyway, I'll try. Here it goes. 1. You write,

The focal issue comes back to, it seems there is a fallacy to be addressed, claimed stepwise actual completion of the endless.

I am wondering who is making this claim? a) I am not claiming this is possible. b) the people making this claim, I think, are the people Spitzer et al are responding to: those who believe time has gone on endlessly from the past, with no beginning. But again, I am not making, nor defending, that claim. So are we clear that I, and I believe no one in this thread, has said a "stepwise actual completion of the endless" is possible. It seems to me we are all in agreement on this point. Do you agree that we are in agreement on the point that "a stepwise actual completion of the endless is impossible"? 2. You write,

In looking at linked mathematics themes, the questions have come up on what it means to have a transfinite succession, and particularly what it means to have such in descending order to a finite neighbourhood of 0.

I have not been discussing a "descending order to a finite neighbourhood of 0." We have, I think, been discussing counting up from 0, in discrete steps, and in discussing the nature of the endlessness that entails, but I have not been discussing "counting down" from infinity to a "finite neighbourhood of 0." This is essentially the same point as a made in 1. Could we agree, then, a. that counting "down from infinity" is not a topic of discussion between you and me, and b. that the issue we are going to discuss, if we do continue to discuss, is the issue of counting up from 0, and thus the nature of infinity as it applies to the succession of natural numbers. If a is what you want to discuss, and not b, then it will be clear that we don't have a common topic of interest, and so we can consider the discussion done. 3. You write,

I am not satisfied that pointing out that successive addition attains to natural number k then k + 1 adequately addresses the endless succession to arrive at transfinite cardinality.

This seems to be a common point of interest. My position is that the natural numbers N = {0, 1, 2, ... k, k + 1, ...} a. are represented by the first order of transfinite cardinality aleph null, the number of numbers in the set N, and that w represents the corresponding first infinite ordinal. Thus aleph null and w are transfinite ideas associated with N. b. further transfinite orders of cardinality and ordinality are about other sets, not N. First, do you agree with 3a?. Second, do you agree with 3b? c. More specifically, in response to your statement of concern, can you describe what you mean by "the endless succession to arrive at transfinite cardinality.", and specifically, what does "arrive at" mean. Can you flesh out your perception of what the issue is as we create the set of natural numbers by endlessly taking the step to the enxt natural numbers? 4. The rest of your post is again about counting down from infinity, and about the possibility of an endless past. If your response to 3a and 3b above is that you want to continue to discuss counting down from infinity, and not the nature of the natural numbers as we traverse them going up from 0, then it is clear that we are not interested in the same topic. Being clear on that will be useful. However, if you are willing to accept that I agree counting down from infinity is impossible (see 1 above), and you still would like to discuss your concern about the natural numbers (see 3c above), then we can continue. I look forward to your response. Aleta

Folks I have a few moments. >>>>>>>>>>>>> Alicia & DS: Thanks for comments across the thread, and general tone is appreciated; as Mung has noted. The focal issue comes back to, it seems there is a fallacy to be addressed, claimed stepwise actual completion of the endless. That comes up in Spitzer, Durston and Craig, and from many other directions. Language itself is seemingly trying to tell us something here: finitude --> endedness, infinity --> end - LESS - ness. To claim completion of endlessness seems to reflect a category confusion. In looking at linked mathematics themes, the questions have come up on what it means to have a transfinite succession, and particularly what it means to have such in descending order to a finite neighbourhood of 0. I am not satisfied that pointing out that successive addition attains to natural number k then k + 1 adequately addresses the endless succession to arrive at transfinite cardinality. Something is missing. Something, tied to endlessness. Something, that then applies to claimed completion of a stepwise endless process such as the inspection of HGHI's rooms from the far, transfinite span inwards to the reception area viewed as room 0. Where also, a reasonable symbolism and sequence model i/l/o the ordinality of the numbers that captures the transfinite span to be traversed is a significant issue. The line of successive ordinals is where that will have to be resolved, somehow. That is why I have sought to identify some ordinal of countably transfinite cardinality and address the issue of stepwise succession onwards down towards 0. Surely, if the past is endlessly remote, at some point it must have been transfinitely remote if such is so. So, what is a reasonable representation, and what does that tell us about stepwise traversal of the transfinite? And no, such a remote point (say even the much objected to A = w +g above) would not be a beginning of events, just a startpoint for counting downwards. (I sometimes got the impression above that there was an objection to the notion of carrying out a count that runs from the remote past; but such was once the present and at any present time we can start to count a progression: 1, 2, . . . and keep going. Obviously such will always run k, k + 1, etc, but that is the point. An inherently finite succession of steps seeking to span the endless seems inevitably futile. The misleadingly simple three dot ellipsis is covering a major process that implies a qualitative shift due to endlessness. The closest I have come is to suggest endlessness leads to an emergent phenomenon, the transfinite that comes in degrees, starting with the famed aleph null. And the interface with the ordinal succession to w and beyond is also significant. From this the issue of claiming of implying actual stepwise completion of the endless arises. For concrete example 1 + 1 + . . . 1 = k is a completed and finite process. 1, 2, . . . is not.) This has direct relevance to an underlying concern from OP on, on the claimed endless past of the cosmos and linked causal succession of stages to now. >>>>>>>>>>>> HRUN Pardon, but I must advert to earlier notes to you. It is clear that you have never registered that this area is the one where there was a major back-tracking on what is now termed naive set theory, that there are significant differences in thought among relevant professionals about actualised infinities and other themes. I suggest in future that you re-think projecting closed mindedness to others. >>>>>>>>>>>>>> Mung: Entertaining as ever. >>>>>>>>>>>>> Q: A good one. _____________ Gotta run. KF kairosfocus

Hilbert's hotel reminds me of Ira's Flophouse. Since it was pretty cold outside, three vagrants entered the derelict hotel. "How much for a room?" they asked the night manager. Removing the dead cigar stump from his mouth, the night manager said "30 bucks for all night." Each of them coughed up $10. After they went off to their grimy but warm room, the manager came in. "How much did you charge them?" he asked. "30 bucks," said the night manager. "Nah, I know those guys and promised them a room for only $25. Give them a $5 refund." So as the night manager went to their room, he tried to figure out how to divide $5 three ways. He solved the problem by tipping himself $2 and refunding each of the vagrants $1. So, each of them had paid $9 for the room. Lessee. 3 x 9 = 27 plus the $2 that the night manager tipped himself comes to $29. What happened to the other dollar? -Q Querius

Thanks, Mung. Aleta

I'd just like to say how pleasant daveS and Aleta have been compared to what we often see here at UD and to thank them. Interesting discussion. Mung

I see - you didn't like the "Kairosfocus can't focus" comment. Yes, as the author of the OP you have the right to say that is what you want to discuss. In fact, anyone has the right to say what they do and do not want to discuss, as I did. However real discussions seldom stay on the original topic, and as a discussion evolves, the most important consideration to me is whether the people in the discussion are actually creating a constructive dialogue. One of the characteristics of a constructive dialogue is that people respond clearly and specifically to the other person's points and answer the other person questions. In so doing, the topics and the participants's respective positions gains clarity. This is what I mean by focus: staying clear about the course of the thread of a conversation, and participating in ways that create some clarity about the respective positions of the participants. This is what I was saying you were not doing. Of course you had the right to return the OP, and the notion of past time, if you wished. But given that you knew, or should have known, that the other participants in the current discussion were solely interested in the natural numbers and the analogical hotel, not time, perhaps you could have acknowledged that you were not in fact furthering the discussion with us. As a matter of general philosophy, having the right to do something and having it be a useful thing to do can be two different things. If you want to help create constructive discussions - ones in which all parties have a chance to both clarify their positions and gain greater understanding of the other positions, you should learn to focus, I think. Aleta

Aleta, the OP sets the focus for the thread. Your suggestions above that were personalised by use of my handle were inappropriate given the OP. KF kairosfocus

Why? I've read them, several times. I HAVE NEVER BEEN DISCUSSING THE ARGUMENTS ABOUT THE NATURE OF TIME. I HAVE AGREED THAT "COUNTING UP" FROM NEGATIVE INFINITY IS IMPOSSIBLE. I HAVE JUST BEEN INTERESTED IN DISCUSSING THE NATURE OF THE NATURAL NUMBERS. Pardon my shouting, but why don't you get those three points? I have repeated them a number of times. Aleta

Aleta, kindly read the original post, observing the two cites in it, thanks. KF kairosfocus

??? What do you mean? Do you mean that you want to talk about the "can't get here from the infinite past" issue even though no one who is in the current conversation is interested? If so, fine, but then don't bother to address me at the start of your post. Also, thread owner or not, very seldom does a 150 comment thread stay focused on the OP - usually one sub-issue, or a related issue, becomes the focus. Aleta

Aleta, I note to you that there is a substantial focus issue and that is what I have chosen to speak to as thread owner. KF kairosfocus

But you have to go through the twilight ... oops, transfinite, zone to get there! :-) Aleta

Which room has the best view? The one at the top, of course! :D mike1962

Each room is finite, but the hotel itself does not consist of a finite number of rooms. We can claim that each room has a room number, but who did the numbering, and when? Does the hotel have a 13th floor? Each floor has an infinite number of rooms, there are an infinite number of floors, and an infinite number of steps between each floor. Which room has the best view? Mung

To write a paper that clarified his thoughts and share it with mathematicians would be a way of getting feedback about whether his “facts and reasoning were sound.”

You keep forgetting the primary fact: 'KF is right and DS (and Aleta) is wrong. If math agrees with DS (and Aleta) then math is wrong, too.' That clearly tells you why writing a paper and getting it evaluated by a journal or other competent mathematicians is a completely irrelevant waste of time. Unless they agree whith KF (which they won't), they are simply wrong as well. hrun0815

I find it ironic that Kairosfocus, despite his name, appears to be unable to focus on a discussion. Here are 2300 more words saying, again, what he has said before, and that continue to address points his fellow discussants are NOT making while failing to address points that we are. kf writes,

That is, there is a claim on the table of an infinite past that has somehow arrived at today.

No. Neither dave or I have made that claim, or expressed interest in the topic of time. We have made it clear we are interested in the pure mathematics of the nature of infinity in respect to the natural numbers. I've even said you are right about the infinite past not being able to arrive at today. But you don't seem to be able to grasp what is and isn't on the table as a topic, and are thus unable to narrow the focus of your thoughts. kf writes,

It is highly significant, in that context, to see the resistance and even dismissiveness in the thread above to the ordering pattern put up from 0, 1, 2, . . . k, k +1 . . . w, w + 1, . . .

No, Dave and I (after some explanation from Dave and further reading) have fully acknowledged the existence of the above sequence of ordinals. But that sequence is not a counting sequence relevant to the natural numbers: the above sequence is about something different. N = {0, 1, 2, . . . k, k +1 . . .} only. Again, kf keeps talking about something that goes beyond the topic kf writes,

And, as there has been so much of foreclosing discussion by appealing to the finitude of “all” naturals, I have felt it wise to back away and go to the first principles of counting numbers and constructing ordinal sets instead. That is not evasion of focal issues, but instead trying to address them in a way that does not needlessly run into perceptual barriers.

First principles are that every natural number k has a successor k + 1. Simple as that. For natural numbers, the cardinal value and the ordinal values are the same. Constructing ordinal sets as a first principle doesn't help, because once you include w and its successors, you aren't talking about the natural numbers any more. [Oops - I'd told myself I wasn't going to counter-point anymore. Third and last point: kf continually makes points and uses terms that he doesn't clearly explain: "going past the ellipsis" into "the transfinite zone" where "w kicks in" and "endlessness begins". When we ask what these concepts mean and how they could apply to the natural numbers, there is no answer. As Dave said, and I agree with everything else Dave said also (I like the phrase "wrestling with fog"), kf should try writing up his ideas about the above vague notions in a way that a trained mathematician or journal could evaluate. He is claiming that a fundamentally accepted fact in number theory, that "all natural numbers are finite", is wrong. If he could establish that in the world of mathematics, he would have some renown. I see that kf has added this:

And no, I have no interest in the journals game. That effectively substitutes appeal to authority for fact and logic in the context where no authority will be better than facts and reasoning.

That's revealing. Who is to evaluate "facts and reasoning", if not a body of people capable of understanding the arguments in the context of what is already known? To write a paper that clarified his thoughts and share it with mathematicians would be a way of getting feedback about whether his "facts and reasoning were sound." In general, without such feedback, one can invent ideas in a vacuum and go on thinking one is right forever without accepting the challenge of convincing the larger world. Aleta

KF,

DS, just to begin your manager would have to traverse a transfinite interval to reach a finite neighbourhood of 0.

I would phrase it like this: given any natural number n, n seconds ago, the manager had already visited all but finitely many of the rooms. You're not going to refute that using cardinal/ordinal arguments. daveS

DS, just to begin your manager would have to traverse a transfinite interval to reach a finite neighbourhood of 0. That is the core issue of the ellipsis which you have consistently not addressed, and this requires completing the endless. Going beyond, what you almost brush aside sets out the context of meaning for what follows. And no, I have no interest in the journals game. That effectively substitutes appeal to authority for fact and logic in the context where no authority will be better than facts and reasoning. The above is an elaboration on the challenge: claiming to have completed an inherently endless stepwise process. Fallacy name: I just completed the endless. Ooooooops. KF kairosfocus

KF, That's ... a lot of words. Let me try and address some of the substance.

The first challenge is that this will confront the mathematics of the transfinite in order to be coherent, thus in the end, the ordinals. It is highly significant, in that context, to see the resistance and even dismissiveness in the thread above to the ordering pattern put up from 0, 1, 2, . . . k, k +1 . . . ω, ω + 1, . . . at least, until there was citation from Wolfram, on which there has been mostly a silence rather than a response.

Well, the ω's are never traversed by the hotel manager, so I don't know what we are required to say about the entire sequence. I acknowledge that it exists. The relevant sequence here is 0, 1, 2, ..., or counting down, ..., 2, 1, 0. These (or their opposites) are the rooms visited by the manager. I have to tell you when he was in room -n for each natural number n, which I have done. What more do you need?

This by no means implies that it is good enough to in effect say as every k is therefore finite there is nothing more to discuss; all “natural numbers” are finite even though the set as a whole is not; and just go away with — pardon, I here suggest a rhetorical effect not an inferred, intended persuasive effect — your confused notions.

Uh-oh. Scare quotes around the term natural numbers? Our confused notions?? Aleta and I are using the standard definition of N. You've been given at least two proofs showing that every element of N is finite. One written by arguably the greatest living mathematician. IIRC, it was about 3 sentences long. Both were utterly elementary and no errors were pointed out by you. So yes, I take the finitude of every natural number to be settled. And I thought I just saw you acknowledge that this could be true somewhere in this post, but I can't find it now. So that we both understand each other, is it true that every natural number is finite? Yes/No?

I therefore say, we must look at the sequence of the transfinite ordinals, w, w + 1 as being involved with endlessness of counting numbers, etc.

"involved with" is not a very specific claim, to say the least. The rest of your statements are so vague, there's really nothing I can say. It's like wrestling with fog. So, I suggest that as you have now sketched out your ideas, write this up more carefully and consult a trained mathematician and/or submit it to a journal! daveS

Aleta & DS, First, I have consistently underscored that Hilbert's Grand Hotel Infinity [HGHI] is exactly that, infinite. I think in that context, there is a clear tendency to so focus on the finite step by step sequence of natural numbers in looking at it that sight of that premise or context may be lost. So, it needs to be emphasised, it is HGHI henceforth. Second, that means, the number of rooms is endless and that it manifests, as a countable, ordered setting, the phenomena of w and of aleph null. While no particular room may be so labelled, the pattern of endless rooms makes such to be present. This further means that when one goes from 0 to 1 to k to k + 1 etc, there will be an ever extending onward path, yes. Now also, what is further very relevant is the issue of a transfinite down count. That is, there is a claim on the table of an infinite past that has somehow arrived at today. That is not going away as an issue, however personalities or concerns as expressed may be perceived or however arguments may be counter-pointed or may be dismissed. The focal issue is, that down count as the manager of HGHI supposedly has been endlessly inspecting rooms at the rate of one per second forever past and is claimed to now be say at room -r, a finitely remote neighbourhood of room 1. Say: . . . M --> -r . . . -2, -1, 0. Room 0 is the reception area etc. That down count must pass from a transfinitely remote zone to the current situation -- if the infinity of new guests can be brought in by switching current ones to even rooms and putting the new ones in odd rooms, the HGHI must be such that there are endless rooms. If the countdown is real (or at least model-real), it must be complete to the current situation. That puts focus on the left hand ellipsis that leads the reversed sequence. So the reasonable question arises, how can the proposed state be? How can one traverse a transfinite span in steps to reach a finite neighbourhood of 0? Or, can one? Linked, what does an infinite actual past of the observed physical cosmos and/or its causal antecedents considered as strictly physical/material entities -- as is being claimed by some -- mean? Is it coherent, what would be its evidence, what would we find that can test such a hypothesis, etc? The first challenge is that this will confront the mathematics of the transfinite in order to be coherent, thus in the end, the ordinals. It is highly significant, in that context, to see the resistance and even dismissiveness in the thread above to the ordering pattern put up from 0, 1, 2, . . . k, k +1 . . . w, w + 1, . . . at least, until there was citation from Wolfram, on which there has been mostly a silence rather than a response. If that transfinite ordering of numbers is valid (formerly doubted and dismissed above, now implicitly conceded), of course its opposite or reverse will also be valid: . . . w + 1, w, . . . k + 1, k, . . . 2, 1, 0 (All that has here changed is the direction of the ordering. The fist two ellipses are transfinite in span indicated and the last one is finite.) Now, there was a second issue, in effect what does the succession mean, especially given the joint claims that all natural numbers in the set {0, 1, 2, . . . } are finite yet the set as a whole is of transfinite cardinality aleph null, which on the ordinal side is that of was first transfinite ordinal. In that context, there is a significant issue of identifying finite k as 1 + 1 + 1 + . . . + 1 k times, which implies that the ellipsis is addressing a finite span. This by no means implies that it is good enough to in effect say as every k is therefore finite there is nothing more to discuss; all "natural numbers" are finite even though the set as a whole is not; and just go away with -- pardon, I here suggest a rhetorical effect not an inferred, intended persuasive effect -- your confused notions. (I ask, beyond a loaded ellipsis, how is the transfinite character manifest in the ordered sequence 0, 1, 2 etc as it mounts up to be the set of naturals? How does the weight of w affect the whole? How do we express that beyond an ellipsis that invites, oh, it just goes on? How does the difference between finite and infinite manifest? Is saying all naturals are finite anywhere near an adequate statement in context? Is oh the set as a whole is transfinite notwithstanding capture the "what more" that needs to be said and appreciated?) I think, at minimum, there is something that needs to be made clear and shown coherent. Here, the issue is, we are looking at something that is a suggested model of the succession of causal chains that are claimed to be a consequence to date of a transfinite process. And the sort of ordinal line model is patently relevant, indeed, we can see that by simply suggesting that successive causal entities in the chain C be subscripted, C_k, etc. That is they are to be identified as in a succession that is held to go: . . . C_k +1, C_k, . . . C_2, C_1, C_0, C_1*, C_2*, . . . C_n* Where, C_n* denotes the current situation. But the natural question is, what does the leftmost ellipsis mean relative to a line that we could "expect" to have been something like:

. . . C_w+1, C_w . . . [transfinite onward span, i.e. endlessness] . . . C_k +1, C_k, . . . C_2, C_1, C_0, C_1*, C_2*, . . . C_n*

But in the wider pattern, we have two sets of ellipses that are addressing transfinite spans. The last two are relatively unproblematic, they are finite. From the discussions and context, it seems that the best so far conceptual understanding is that as the sequence of counting numbers increases without limit -- and that is a qualitative change from oh individual numbers we represent as a finite chain of increments from 0, k, are finite -- that leads to aleph null as in effect the emergent property, the first order of magnitude of limitlessness. So, once endlessness is involved, w and friends are present, even if there is no explicit symbolisation. I therefore say, we must look at the sequence of the transfinite ordinals, w, w + 1 as being involved with endlessness of counting numbers, etc. Where, Wolfram sums up:

The first transfinite ordinal, denoted omega [--> I have used w for convenience], is the order type [--> in effect the "length" from 0 of the set of counting numbers so far] of the set of nonnegative integers (Dauben 1990, p. 152; Moore 1982, p. viii; Rubin 1967, pp. 86 and 177; Suppes 1972, p. 128). This is the "smallest" of Cantor's transfinite numbers, defined to be the smallest ordinal number greater than the ordinal number of the whole numbers. Conway and Guy (1996) denote it with the notation omega={0,1,...|}.

That is the succession of sets from {} --> 0, {0}--> 1, {0,1} --> 2 that incrementally increases without limit at that point is at the successor value w, which some folks represent {0,1,...|}. From w we may proceed at the transfinite succession to E_0 and so forth. Now, we can see that endlessness is the pivotal contrast to finitude. Often, expressed by a transfinite span ellipsis. I think we need to take endlessness quite seriously and at the force of its full meaning: having no completion, no terminus. With w present as a direct systemic result. So, instantly, there is an issue that if the chain of order does go to the transfinite in ascending mode, it must also be of the same order in descending mode. Therefore, it seems that a fair conclusion is that a transfinite span cannot be spanned or traversed in step by step finite, finitely incremented stages. So, it is not good enough to blandly assert that manager M of HGHI has been ticking off rooms like a clock forever, or that there has been a transfinitely successive causal chain of the physical cosmos that leads to now. At least, without serious explanation of the bridging of the transfinite, the completion of an endless succession. That has all the marks of a contradictory claim, especially for the physical world. Endlessness completed is not endlessness. It is ended. Spitzer is right to raise a red flag. But, this also points to the issue, how would that appear in our symbolism, and the answer is, there is a transfinite ellipsis that cannot be bridged in stepwise increments of unit size. To my mind this also means that claimed proofs of the naturals all being spanned by finite unit increments, and exceeded by the next in succession are running into the issue of the transfinite span. The potentially endless but not actualisable span. I think therefore that it is not credibly feasible for M to have spanned the transfinite in steps and thus have reached k -- a finite range from 0. Likewise, it is not credible for the observed cosmos to have had an actual past transfinite succession of finite causal entities and causal transitions to the next stage, down to the present. Instead, it is credible that at some finitely remote k, there was an initiatory terminus. Matters not if that is 10^17 or 10^25 or 10^1700 s past, or whatever. Credibly, k is there. Of course, on the current understanding of the observed cosmos, there is such a beginning point,the singularity. There is speculation on a wider multiverse and on an endless past, though there is not a solid answer to observability or to the issue of ever rising entropy, which leads to the increasing non-availability of energy concentrations that can drive causal processes relevant to the world we observe around us. This is the concept sometimes termed heat death -- at least, it is comparable to it. Now, too, I find it interesting to see the way there is an attempt to rule a datum line against the use of the catapulting effect of the hyperbolic function y = 1/x near 0, to span to the transfinite, by direct comparison to the approach taken in nonstandard analysis with the hyper reals and hyper integers as one manifestation. But in a world of calculus praxis, that is a very reasonable consideration. [0,1] is a closed interval, and is continuous. So it is reasonable to look at infinitesimals, m of mild enough character that they would catapult us to a range that is transfinite. (I take it from L'Hospital's rule that we accept that infinitesimals can be of diverse order of relative magnitudes.) Yes, there is a debate on the relationship of the continuum to aleph null and successors, etc. The line of successive counting numbers invites filling in by the steps to the reals via rationals and it is notorious that it points onwards endlessly. So, how do we have coherence of the whole? I have suggested the simple step, 1/m = A = w + g, g a finite increment onwards from w. If we deal with truth, the issue of the general coherence of truth is there. And, as there has been so much of foreclosing discussion by appealing to the finitude of "all" naturals, I have felt it wise to back away and go to the first principles of counting numbers and constructing ordinal sets instead. That is not evasion of focal issues, but instead trying to address them in a way that does not needlessly run into perceptual barriers. I assume there is not incoherence in the logic of quantity and structure. But it is apparent that our understanding, individual and collective, is apparently fragmentary and thus incomplete. Notoriously, what is c and how it relates to aleph null, aleph 1 etc have been found to be undecidable. But c is the very stuff of the calculus, and it is tied directly to reals which in turn are traceable to counting numbers and fractions with power series used to give expression to fractional parts that my converge to values not finitely expressible in place value notation, e.g. pi or e etc. Where, place value notation is disguised power series notation. Which in turn clearly makes strong use of ordinals in expressing the sequence of digits, bases and powers. So, all of this connects to very commonplace things, and to all sorts of very real world issues. As I conclude for the moment, I draw attention again to the point that endlessness of succession of ordinals from 0 is important, and that once that endlessness is on the table -- typically by implicitly transfinite ellipsis, once it first appears, we are dealing with the transfinite, however implicitly. That naturals -- counting numbers form 0 to 1 to 2 etc -- range on endlessly entails endlessness and so also the implications of the transfinite. Thence we face the impassable zone (at least for stepwise processes) illustrated by the transfinite ellipsis. And so, causal successive processes will be confronted with the logic of endlessness, whether from a start point ranging onwards, or whether we look at a claimed endless preceding succession that finds terminus in the now. So, whatever back forth exchanges, whatever conceptual struggles, whatever oh no it's not that, then could it be like this then, etc, are important as we look onwards. This is not a cut and dried, settled commonplace only an idiot does not understand the way we do matter, for sure. KF kairosfocus

As the HH hotel manager goes from room to room, does he leave the light on? Mung

KF, One technical point: The infinite hyperintegers are different from the infinite ordinals/cardinals from set theory, so there is no hyperreal infinitesimal m such that 1/m is an infinite ordinal number. daveS

Hi kf. You write,

As for the Hotel Infinity, the procedure for adding infinitely many new guests, moving present ones to the even rooms 2n, n being present room, and adding the infinity of new guests to the odd ones 2n – 1; that can only work if the number of rooms is transfinite. The hotel as a whole expresses w.

You say above "only work[s] if the number of rooms is transfinite." But the number of rooms is infinite, with cardinality aleph null - that is the premise of the whole analogy. The hotel analogy is just about the nature of the natural numbers - no "transfinite zones" needed.

That is, it seems that the relevant point is that w is in effect the numerical designation of the first emergence of endlessness. Thus, it can be viewed as an emergent property of endlessness.

What does the "first emergence of endlessness mean?" I am walking down the number line. At every number I can always take the next step: at k there is always k + 1. Given that there is always a next step, the procession is always endless, starting at my very first step. And I could go ... (endlessly, it seems). But I won't. kf, are you aware that your thoughts on this matter - the nature of infinity in respect to the natural numbers, is not standard mathematics and is not shared by other mathematicians. You have idiosyncratic and confused notions, and further discussion isn't going to change anything. And you don't need your notions to make the point you want to make. You claim that we can't get to infinity, or get here from negative infinity, in a finite number of steps. That is true - that is what infinity, the ellipsis, means. There is no need to talk about "bypassing the ellipsis to get to a transfinite zone" to make that point. So, I am going to stop my role in this discussion at k, recognizing that if I go to k +1 I'll just have to go on to k + 2, and so on (...) without any further progress or enlightenment being made. For what it's worth, I've learned some things (or at least deepened past understandings). I remember first being introduced to these ideas about infinity back in college calculus classes, and of course dealt with the nature of natural and real numbers while teaching calculus for many years. Reading the articles at Wikipedia and Wolframs, as well as the posts by others here and elsewhere, has been interesting. So I've both enjoyed the discussion for it's own sake, as well as for the usual challenge of trying to have a focused conversation with kf. But it's time for me to move on for now. Aleta

KF, Then as Aleta pointed out, you're no longer talking about traversing the HH. The infinitesimals and nonreal hyperintegers have no bearing on that problem. daveS

DS, go to the nonstandard analysis. Infinitesimals are valid near-0 members of the continuous closed interval [0,1] for purposes of logical analysis of structures and quantities. KF PS: If you find a catapult approach unacceptable, try simply A = w + g, g a finite. A is of cardinality aleph null. kairosfocus

KF,

DS, as has been repeatedly put forward across this discussion, m is an infinitesimal of a mild enough degree to land us at w + g through its multiplicative inverse. The point is, [0,1] is a closed, continuous interval so there will be numbers closer to 0 than any epsilon-neighbourhood you can construct, i.e. infinitesimals are there on the continuuum.

This is false. The real number field is Archimedean, which means that for any positive x in R, there exists a natural number n such that 1/n is less than x. In other words, x does not lie in the neighborhood (-1/n, 1/n) of zero. daveS

DS, as has been repeatedly put forward across this discussion, m is an infinitesimal of a mild enough degree to land us at w + g through its multiplicative inverse. The point is, [0,1] is a closed, continuous interval so there will be numbers closer to 0 than any epsilon-neighbourhood you can construct, i.e. infinitesimals are there on the continuuum. Such are real enough to found a whole alternative approach to calculus -- nonstandard analysis. KF PS: step by step traversal of the transfinite is a supertask, and as such the reasonable conclusion is the proposal of an infinite actual past is futile. Concluding an infinite count down to the singularity then upwards a finite count to the present will fail due to the problem of the transfinite spanning ellipsis. Beginning is not the pivotal issue, completion is. Where the point of A, A~1 etc above is to show that continuation step by step to try to access 0 is futile. kairosfocus

KF,

Similar to how Robinson et al defined hyper reals including hyper integers, let us go to some m –> 0 but is not quite 0. An infinitesimal of a sort. Let us extract its multiplicative inverse, further stipulating that it will give us a whole number type result, fractional part uniformly zero. 1/m = A, where A = w + g, a successor to omega where g is some large but finite value.

No matter how small your positive real number m is, then 1/m will not be a successor to ω. It's an impossibility. You will simply get a real number. The multiplicative inverse of any nonzero real m is also real, and not an infinite ordinal. Refer here to the field axioms. This has been pointed out many, many times, so I don't understand why you keep posting this "construction".

And the endlessness involved means we cannot actually complete the ascent to w in successive real world steps. Nor can we carry out a descent from there in that way.

Note that there is no "ascent to ω" in any of these HH puzzles. The guest originally in room 10^150 gets moved to room 2*10^150; one of the new guests is placed in room 2*10^150 - 1. All the room transfers go like this, with each hotel occupant ending up in a room with a finite number.

On this, I think I can accept that any whole number k we can write out or count up to in steps will actually be finite, but that endless succession — which we cannot actualise in fact but only indicate in principle — creates an emergent property, transfinite numbers.

I would more or less agree with this.

That is, as we lay out the number line and continue the ordinal sequence with an ellipsis that goes on to w, there is an implied transfinite span. So also {0, 1, 2, . . . } implies a transfinite span and the whole as a set expresses w.

Well, nothing is "going on to ω here". The statement that the entire set expresses ω sounds reasonable.

And once endless succession lurks in an ellipsis, we will need to face the issue of traversal of a transfinite span and the futility of claimed or intended actual traversal in successive finite steps.

Except perhaps in the case of an eternal process extending through an infinite past, such as a beginningless ticking clock or tour by the manager of the HH. daveS

Aleta (and DS), my first point is that once we have endlessness, there is an emergent state -- the omega point if you will. But that is precisely that, emergent and organically tied to what has gone on to reach that point. The nature of endlessness is that it can never be a completion and termination of a finite step by step process. Which, is directly tied to the focal context for all of this: the naturalistic claim of an actualised real world infinite temporal past as an alternative to the equally naturalistic claim of a world from utter non-being, a genuine nothing. We can create a real world step by step process that continues and for all we see is POTENTIALLY endless but at every stage an actual finite step based process will be finite and have a k steps so far character. By contrast, we may provide a conceptual pattern of ordinal numbers that indicates and provides numerals for the transfinite, ordinal and cardinal. And, BTW, transfinite is Cantor's term to confine discussion to the subject in hand as opposed to all that may be inadvertently dragged in when we use the term infinity. I go to the real world claim. An infinite actual past bridged to the present implies traversing a transfinite span in cumulative discrete finite causal steps that may be enumerated. That is, inter alia the claim is subject to the scrutiny of the logical study of structure and quantity, aka mathematics. I have repeatedly used a mathematical catapult to get us to the transfinite domain, based on the continuum in the closed interval [0, 1]. Similar to how Robinson et al defined hyper reals including hyper integers, let us go to some m --> 0 but is not quite 0. An infinitesimal of a sort. Let us extract its multiplicative inverse, further stipulating that it will give us a whole number type result, fractional part uniformly zero. 1/m = A, where A = w + g, a successor to omega where g is some large but finite value. So, we can represent, with k a finite value:

{} –> 0, to {0} –> 1, to {0,1} –> 2, . . . k, . . . [a transfinite span, as above with counting numbers in succession] . . . w, w + 1, w + 2, . . . w + g [g a large finite value], …, w·2, w·2 + 1, …, w^2, …, w^3, …, w^w, …, w^[w^w], …, E_0, ….

It matters not that many successors to A exist, our interest is its predecessors as in A less one, [w = (g - 1)] etc. Then we may symbolise that as A~1, A~2, etc. Where, the cardinality of A is the same as w, aleph null. The first degree of endlessness. From that, this is what I have done to draw out the issue of having to traverse a transfinite span in a stepwise descent to a finitely remote neighbourhood of 0 followed by descent to 0 and ascent from 0 with intent to assign 0 as the singularity and some n* as now. I clip 77 above from Feb 2:

it seems, we may reasonably list in reverse form: . . . A, A less 1 [i.e. W + (g-1)],. . . w, . . . 2, 1, 0 Thus — without assuming that there is anything but an indefinitely large span beyond A to the left — we can look at down-counting from A, symbolising [w + (g – 1) as A ~1, etc: A, A ~ 1, A ~ 2, . . . w + 1, w, . . . r, . . . 2, 1, 0 0#, 1#, 2# . . . Now, g is finite but very large, this allows us to establish an ordering down to w. My key concern is that the ellipsis beyond w is endless, so the stepwise down count sequence that begins at A will go on forever without bridging it to r, a finite neighbourhood of 0. Indeed, it seems that once the secondary count started at A hits w at g steps later, and goes on, we are in the position of trying to count across an endless span. Thus, a stepwise count process will not reach r, much less the interval [0,1]. To me, this seems to give some substance to the remark that an inherently finite stepwise counting process will not bridge a transfinite span, will not traverse a transfinite range. This is as distinct from that we may set in order a succession that as a set will define a transfinite span of ordered succession. Countable in principle, inexhaustible in practice. The gap between the potentially infinite process and the actually completed infinite process. To span the transfinite, it seems to me we need the sort of “catapult” that the multiplicative inverse acting on an infinitesimal will give. Applying to the cosmic space-time domain, we have a pattern of causal and temporal succession in finite stpes that are in principle countable. They come from the remote past of origins, and reach to the present. From, say, the singularity as 0 at 13.7 BYA or whatever, we have a finite span to the present, here n*. The issue is then beyond that horizon, where some claim completion of an actually infinite succession: . . . A, A ~ 1, A ~ 2, . . . r, . . . 2, 1, 0, 1*, 2*, . . . n* But the issue already identified is instantly applicable. The finite succession is complete-able, the transfinite is endless by definition, of different orders, aleph null being applied to counting numbers. And so, if we can already see that we have a problem bridging from A to r, there will be a problem bridging to A from the endless values beyond it. It seems to me that the best answer is, that there is some r a finite distance from 0, which is the terminus of the space time domain, i.e. it is inherently finite.

As for the Hotel Infinity, the procedure for adding infinitely many new guests, moving present ones to the even rooms 2n, n being present room, and adding the infinity of new guests to the odd ones 2n - 1; that can only work if the number of rooms is transfinite. The hotel as a whole expresses w. That is, it seems that the relevant point is that w is in effect the numerical designation of the first emergence of endlessness. Thus, it can be viewed as an emergent property of endlessness. So, yes, any counting number k we can write down will be finite as product of 1 + 1 + . . . 1 k times over, but once we have an endless succession, it seems to me that an emergent effect is that the endless succession as a whole manifests w, the first transfinite ordinal. From that we may proceed in the transfinite zone. And the endlessness involved means we cannot actually complete the ascent to w in successive real world steps. Nor can we carry out a descent from there in that way. The transfinite span ellipsis is highly significant. On this, I think I can accept that any whole number k we can write out or count up to in steps will actually be finite, but that endless succession -- which we cannot actualise in fact but only indicate in principle -- creates an emergent property, transfinite numbers. That is, as we lay out the number line and continue the ordinal sequence with an ellipsis that goes on to w, there is an implied transfinite span. So also {0, 1, 2, . . . } implies a transfinite span and the whole as a set expresses w. And once endless succession lurks in an ellipsis, we will need to face the issue of traversal of a transfinite span and the futility of claimed or intended actual traversal in successive finite steps. KF kairosfocus

KF, I think you have just explained it. Nowhere in the re-rooming scheme did you mention any ω's or otherwise transfinite numbers. The original occupants are moved to the even-numbered rooms, and the new guests are interleaved among them in the odd-numbered rooms. We're talking about even and odd natural numbers, which are all finite. Did you think they would run out of room? That's not a problem with an infinite hotel. daveS

kf writes,

Let this be seen to happen where the number of rooms is not transfinite — i.e. endless — attaining to at least w in the sequence as would be in effect painted on the doors. w is the first transfinite ordinal, of cardinality aleph null. Kindly explain. KF

First a question, kf: are you using transfinite to just mean infinite in the common mathematical sense? Or does it have some more and/or other meaning to you? Second, are you saying that if the room numbers were painted on the doors, there would be a door someplace with w written on it? You write: "w is the first transfinite ordinal, of cardinality aleph null." - true. However w is not a number, or a division point, or anything on the number line. There is no place in the infinite hotel that corresponds to w. w says something about the size of of the hotel, but it does not describe any place in the hotel. Aleta

kf, Cardinality aleph null doesn't "kick in", and you don't ever attain "w in the ordinal succession". Aleph null is a name for the size of an infinite set equivalent to the natural numbers. It is not a place or quality that you aren't at for a while and then you are. You, the person taking the steps, can never achieve transfiniteness, even though the set you are traversing is infinite. Each natural number has also an ordinal position equivalent to its cardinal value, but there is no place within the natural numbers where the ordinal value w is reached. This is a number line, kf. You can walk forever, and you're still on the number line. That's all. There is no "transfinite zone" on the number line. Aleta

DS, kindly start with the full hotel. Infinitely many new guests pull up. Our manager shifts current guests in rooms n to 2n, and puts the new ones in 2n - 1; none of the old guests are roomless and the new ones are also now in rooms though the hotel was formerly full. Let this be seen to happen where the number of rooms is not transfinite -- i.e. endless -- attaining to at least w in the sequence as would be in effect painted on the doors. w is the first transfinite ordinal, of cardinality aleph null. Kindly explain. KF kairosfocus

Aleta, for each finite k, the room count will be just that, finite, which will iterate for k + 1. Kindly now continue that essential finiteness of successive steps and show us how you obtain cumulative transfiniteness of the count [the type order, I believe is the technical term] without attaining to at least w in the ordinal succession, which is where cardinality aleph null kicks in. Where, w is the first transfinite ordinal. KF kairosfocus

KF, I didn't read this carefully:

As the put in infinitely many fresh guests by putting current room n occupant to 2n and new ones to 2n – 1 shows, the whole matches the evens.

Yes, this is another proof that the set of rooms finitely distant to the front desk is infinite. daveS

Yes, kf, the natural numbers are endless. However, they don't pass the ellipsis into the transfinite zone", whatever that means. They are defined by the fact that for every natural number k, k + 1 is also a natural number. Each k is a finite number, and there are an infinite number of them. Those are really the only two points I've been trying to discuss with you. Aleta

kj, Hilbert's Hotel is about " a hypothetical hotel with a countably infinite number of rooms" (wikipedia and Wolframs'), and "countably infinite means having the same cardinality as the natural numbers. Therefore, if you aren't discussing natural numbers, you are not discussing Hilbert's Hotel. Aleta

KF,

Also, I would think that a lagged count of the set will not be a proper subset.

Eh? The function I defined gives a 1-1 correspondence between A = {..., -2, -1, 0} and B = {..., -3, -2, -1} = A - {0} (set difference). B is a proper subset of A. Therefore A is infinite. Note also that A is the set of room numbers for rooms finitely distant from the front desk (counting the front desk as a room). daveS

DS, the problem is not that the whole numbers form an endless continuation, it is that finitude at given k on this particular set will mean that the span to k is finite not transfinite. For the span to be transfinite it has to be just that, limitless. Also, I would think that a lagged count of the set will not be a proper subset. As the put in infinitely many fresh guests by putting current room n occupant to 2n and new ones to 2n - 1 shows, the whole matches the evens. And no finite span of rooms will be such that transfer of the full house guests from n to 2n will accommodate all existing guests. It has to be endless. KF kairosfocus

kf says,

Aleta, I have been deliberately staying away from debating the naturals.

I've noticed that. However it is the natural numbers that are relevant to the hotel example, and it is the natural numbers that are relevant to the discrete steps of a "step by step causal succession" n time. The model here is the number line, with the natural numbers (or the integers if you wish) as the things we are talking about, and with the number line there is no "bridge to the transfinite" involved. The sequence of ordinals is not relevant to either the infinite hotel nor the idea of time passing in a step-by-step causal way. So you have been deliberately staying away from exactly the topic that is relevant. Aleta

KF,

DS, as I already noted above per standard results a set will be transfinite when it can be placed in 1:1 correspondence with a proper subset. KF

So the set of finite nonpositive integers is infinite because we have a 1-1 correspondence between it and one of its proper subsets. f(n) = n - 1 is one such correspondence. If you agree with that, then this also gives a 1-1 correspondence between the set of room numbers for rooms at finite distance from the front desk and one of its proper subsets. Therefore the set of rooms finitely distant from the front desk is infinite. daveS

Aleta, I have been deliberately staying away from debating the naturals and have addressed the ordinals starting from von Neumann's construction on {} up and have above discussed ordinals across a transfinite span indicated by an ellipsis. With the Wolfram discussion and direct parallel to my earlier remarks in play in answer to doubts and dismissals that may be inspected above. At no point in our current discussion have I said w and on are natural numbers, but I have said they form an ordinal scheme extending from 0, 1, 2 etc on. Whether or not the natural numbers terminate before that level and whether or not all natural numbers are finite [but have an overall cardinality that is transfinite*], the transfinite ordinals w etc are a continuation from 0, 1, 2 . . . as counting numbers. That is all I need for the issue of needing to traverse the transfinite to become a serious question on issues regarding a claimed infinite past. KF *PS: The counting scheme k = 1 + 1 + . . . 1 k times raises interesting questions on what is in that ellipsis in all cases. kairosfocus

DS, as I already noted above per standard results a set will be transfinite when it can be placed in 1:1 correspondence with a proper subset. KF kairosfocus

kf, the sequence of ordinals mentioned in Wolfram, 0, 1, 2, …, omega, omega+1, omega+2, …, etc. is NOT the same as just addressing the set of natural numbers. w, w + 1, etc. are not in the set of natural numbers and are not somehow "beyond the ellipsis". That sequence is not relevant to discussing taking unit steps on a number line, traversing the natural numbers You write,

"Obviously a finite step produced set cannot but be finite. .... I spoke of naturals, k as finite counting sets, and how I could see an endless incremental succession of same. That endlessness of succession is where the issue of transfiniteness enters.

Herein possibly lies the confusion. If we consider the set of numbers K = {1, 2, 3 , ... k}, then indeed that set is finite. If we consider the set of numbers N = {1, 2, 3, ...}, that set is infinite in size even though each member is a finite number. The only place transfiniteness show up in this discussion is that aleph null is the name given to the level of infinity possessed by the naturals, The sequence in Wolfram is NOT about further numbers in N that are in some further "transfinite zone beyond the ellipsis." N = {1, 2 3, ...} does NOT eventually include w.} Aleta

KF, All this leads me to ask, if I describe to you a set, how could you determine that it is in fact infinite? For example, the HH. How could you know it has infinitely many rooms? At any "stage", your counting process has progressed only to a finite number. Consider the set of all numbers 2^k, where k is a natural number. Is this an infinite set? It's in 1-1 correspondence with N of course, so I say yes. But I think you're going to get hung up at the same place that caused you to conclude that the set of rooms in the HH at finite distance from the front desk is finite. I don't think your views on counting allow infinite sets at all. daveS

Aleta, I am responding to something projected unto me in comment 100. KF kairosfocus

Aleta, it seems there are all sorts of gaps of communication at work; I can only pause a moment just now. There is a reason why I have spoken of an ordinal sequence of counting numbers, of counting sets and how such are finite but successively larger following the cardinality k where the kth set has 1 + 1 + . . . + 1 = k, with 1 additive step repeated k times and a finite span ellipsis in the notation. Obviously a finite step produced set cannot but be finite. But the interest is a transfinite set, for which the problem becomes that the ellipsis has to become of more than a finite span. And, ordinals come first, with w being the first transfinite and a successor to the finite ordinals. Let me (in part for HRUN's benefit) clip Wolfram for the moment:

http://mathworld.wolfram.com/OrdinalNumber.html In formal set theory, an ordinal number (sometimes simply called an "ordinal" for short) is one of the numbers in Georg Cantor's extension of the whole numbers. An ordinal number is defined as the order type of a well ordered set (Dauben 1990, p. 199; Moore 1982, p. 52; Suppes 1972, p. 129). Finite ordinal numbers are commonly denoted using arabic numerals, while transfinite ordinals are denoted using lower case Greek letters . . . . The first transfinite ordinal, denoted omega [--> I have been using w], is the order type of the set of nonnegative integers (Dauben 1990, p. 152; Moore 1982, p. viii; Rubin 1967, pp. 86 and 177; Suppes 1972, p. 128). This is the "smallest" of Cantor's transfinite numbers, defined to be the smallest ordinal number greater than the ordinal number of the whole numbers. Conway and Guy (1996) denote it with the notation omega={0,1,...|}. From the definition of ordinal comparison, it follows that the ordinal numbers are a well ordered set. In order of increasing size, the ordinal numbers are 0, 1, 2, ..., omega, omega+1, omega+2, ..., omega+omega, omega+omega+1, .... The notation of ordinal numbers can be a bit counterintuitive, e.g., even though 1+omega=omega, omega+1>omega. [--> in the notation, commutativity is broken] The cardinal number of the set of countable ordinal numbers is denoted aleph_1 (aleph-1). If (A,LT =) is a well ordered set with ordinal number alpha, then the set of all ordinals LT alpha is order isomorphic to A. This provides the motivation to define an ordinal as the set of all ordinals less than itself . . . . There exist ordinal numbers which cannot be constructed from smaller ones by finite additions, multiplications, and exponentiations. These ordinals obey Cantor's equation. The first such ordinal is epsilon_0 [--> I have used E_0] . . . . Ordinal addition, ordinal multiplication, and ordinal exponentiation can all be defined. Although these definitions also work perfectly well for order types, this does not seem to be commonly done. There are two methods commonly used to define operations on the ordinals: one is using sets, and the other is inductively.

Immediately we see an explanation of many concepts and constructs and in particular the presence of an ellipsis of transfinite span: 0, 1, 2, ..., omega, omega+1, omega+2, ... with the finite ordinals in the neighbourhood of 0 succeeded by an ellipsis of transfinite span and this by w, then w + 1 etc, with an onward ellipsis of likewise transfinite span. It is instantly clear that such a transfinite span cannot be traversed and spanned in a succession of finite steps, whether ascending or descending [and hence the use of the general terms level and zone]. Earlier today, I spoke of naturals, k as finite counting sets, and how I could see an endless incremental succession of same. That endlessness of succession is where the issue of transfiniteness enters. Maybe, we can now revisit other points, clarifying along the way? Pardon, I have to run just now. Later. KF kairosfocus

kf, no one says that "hotel infinity", aka, the natural numbers, have a finite number of rooms, aka numbers. They have an infinite number of elements, and that number is aleph null, the lowest order of infinity. But you keep talking about a "transfinite zone" that is "beyond the ellipsis": in reference to the natural numbers, there is no way to get "beyond the ellipsis", and there is no such thing as a "transfinite zone". That is the issue at stake. Besides Dave's posts, please see my 95, 99, 101. and 102. Aleta

DS, just for now, re 100, the hotel infinity cannot have a finite total of rooms. That is a clue as to some of the issues underlying the points at stake. KF kairosfocus

HRUN, you were answered long since. KF kairosfocus

KF: Well, can you clarify how our perceptions of your position are incorrect? daveS

So many comments and we are back at: KF is right and DS is wrong. And if math agrees with DS, then math is wrong, too. hrun0815

DS, I suggest to you that there is a problem of perceptions. KF kairosfocus

Aleta, Yes, I do agree with your other comments. I've been trying to say the same thing I think, specifically that ω is not the successor of any natural number, so there is no way to count up to or down from ω [Edit: from any natural number]. I guess KF believes there is some murky quasi-infinite zone in the natural numbers, but as you have clearly pointed out, the order and magnitude properties of N are not that mysterious or exciting. daveS

OK, that is interesting, although I don't completely understand it. However, would you agree with my other comments that if you restrict yourself to the natural numbers you don't "surpass the ellipsis" and get to the transfinite zone (which I presume means the w, w+1, w+2... sequence. That is, even if {0, 1, 2, …, ?, ? + 1, ? + 2, …, ? + ?, …} does list all the ordinals, the ?, ? + 1, ? + 2, …, ? + ?, … part is not part of the natural numbers? Aleta

Aleta, The ordinals don't make up a sequence that is indexed by the natural numbers as sequences most often are, but the notation 0, 1, 2, ..., ω, ω + 1, ω + 2, ..., ω + ω, ... actually does make sense, in that the ordinals do form a totally ordered set. ω itself is greater than any of the finite ordinals, so it's meaningful to arrange it after all the finite ordinals, after the first ellipsis. See this for more details. daveS

Correction to kf: I misread when you wrote, "Also, you say “This would be as opposed to a finite span 0, 1, 2 . . . k, k + 1 . . . where the first ellipsis would be finite in its span.” Yes, the first ellipsis would be finite. I was thinking of your other sequence "0, 1, 2, . . . w, w +1, w + 2 . . .", which is a sequence that I don't believe exists, and is mathematically not meaningful. Aleta

And kf, you write, "I am specifically interested in spans that go all the way to a transfinite zone and in what happens if one tries to ascend/descend in steps." But there is no "transfinite zone" in the natural numbers. You have created a sequence that includes the natural numbers and then the transfinite numbers as if the second somehow followed the first in an ordered set. But I don't believe such a sequence is mathematically meaningful. Do you have a reference where this sequence is discussed in any mathematical literature? Aleta

Hi kf. You added the following to your previous post:

I do envision that there may be a transfinite span in a case with a two-sided ellipsis, as in say: 0, 1, 2, . . . w, w +1, w + 2 . . . for which the first is two sided and the second open on its RHS. This would be as opposed to a finite span 0, 1, 2 . . . k, k + 1 . . . where the first ellipsis would be finite in its span.

What you envision is NOT the natural numbers. You are envisoning a sequence which includes both natural numbers and transfinite numbers, but they are two different types of things, and I don't believe they can be put in sequence as you are doing. Also, you say "This would be as opposed to a finite span 0, 1, 2 . . . k, k + 1 . . . where the first ellipsis would be finite in its span." If you are meaning to refer to the natural numbers here, that would NOT be a finite span. The ellipsis refers to the never ending process of going to the next natural number, which is an infinite span, not a finite one. Aleta

KF, It seems to me that you want to be a finitist, yet you accept the existence of objects such as π, ω and perhaps even noncomputable numbers. If the total number of rooms in the HH is finite, what is ω? Edit:

PS: making a distinction in successive numbers of unlimited extent that “naturals” are finite and w etc as transfinite are not “naturals” does not to my mind eliminate the ordinal number pattern of unlimited succession. I am specifically interested in spans that go all the way to a transfinite zone and in what happens if one tries to ascend/descend in steps.

That's great, but I'm not that ambitious, for the purposes of this discussion. This is why you're looking at a different problem from mine. You want to investigate traversals of HH(ω) while I am content to stick with HH. daveS

kf, so you are saying that you can surpass the ellipsis "where that is specified as the continuation reaches a specified level." What does that second phrase mean? What "specified level" do you reach that allows you to surpass the ellipsis? I know of no "levels" in the natural numbers, and no place in the continuation of going to the next natural number that the nature of the continuation changes. So can you explain more how the process of going to the next natural number ever reaches a "specified level" where we "surpass the ellipsis." Aleta

DS, if every single room is finitely remote the total of rooms should be finite, finiteness at each step implies a thus far finite neighbourhood of 0. If the total of rooms never completes as a finite count and is actually infinite, it seems to me that it must therefore include a zone that is transfinitely remote from the value 0. That is why I look at an inspection that begins at the remote zone and needs to traverse the span to 0 in steps. KF PS: making a distinction in successive numbers of unlimited extent that "naturals" are finite and w etc as transfinite are not "naturals" does not to my mind eliminate the ordinal number pattern of unlimited succession. I am specifically interested in spans that go all the way to a transfinite zone and in what happens if one tries to ascend/descend in steps. kairosfocus

Aleta, I have not intended any surpassing of an ellipsis, save where that is specified as the continuation reaches a specified level. An open ended ellipsis implies unlimited extension. I do envision that there may be a transfinite span in a case with a two-sided ellipsis, as in say: 0, 1, 2, . . . w, w +1, w + 2 . . . for which the first is two sided and the second open on its RHS. This would be as opposed to a finite span 0, 1, 2 . . . k, k + 1 . . . where the first ellipsis would be finite in its span. Where also, w, for convenience, stands for the transfinite ordinal omega. And the issues at stake pivot on that question of traversing a span that is transfinite. KF kairosfocus

KF, A "zone" transfinitely remote from the finite neighborhood of 0? You will have to give a proper definition of this. Every single room in the HH I am describing is finitely remote from the front desk, so you won't be able to do the above. Let me also address your use of ω. My HH has room numbers consisting of the opposites of the natural numbers only. In effect, you are working with an extended HH, say HH(ω) which has room numbers also including (some? all?) infinite ordinal room numbers (with a minus sign in front, if you will). That's fine, but that's not the HH I am describing a tour of. ω is not a successor ordinal. I cannot use my procedure of "backing up one room" from room -ω to get to an adjacent room closer to the front desk. Hence my procedure does not work to define a tour of HH(ω). But of course I never claimed I could. My tour traverses HH only. daveS

kf, you write, in three different posts, the following:

In effect I read that as, as one moves out in steps from 0, things get into a vast impassable wilderness but the sequence keeps going, and eventually it arrives at w and so forth onwards way out there in numbers Sahara territory.

raises issues of ordinals and of the traversing of a transfinite span when one moves off on the open ellipsis

DS, pardon but I said nothing of a starting point, I spoke to a starting zone. One that is transfinitely remote from the finite neighbourhood of 0. If the inspection arises at the transfinitely remote zone of the hotel,

All of these seem to say that if you examine the natural numbers N = {1, 2, 3 ...}, at some point you get "past the ellipsis" into a "transfinite zone" in which you get to the transfinite numbers and "eventually arrive at w and so forth onwards way out there in numbers" All of these things are not true. If you limit yourself to the natural numbers, you never get "past the ellispsis." The transfinite numbers are a different type of number, but they are not part of the natural numbers. I don't believe there is anything in standard mathematics about the natural numbers that corresponds to what you are calling a transfinite zone. So to say that " as one moves out in steps from 0, things get into a vast impassable wilderness but the sequence keeps going, and eventually it arrives at w" is wrong. If you move in steps out from 0 you just keep getting bigger and bigger natural numbers - you never get to some other "zone" and you never get to w. Aleta

Aleta, analogies are not proofs but are often highly instructive and inductively strong. By analogy, if I see you are evidently a mammal, much can safely be inferred by analogy with type-cases, never mind cases such as whales or platypuses. KF kairosfocus

DS, pardon but I said nothing of a starting point, I spoke to a starting zone. One that is transfinitely remote from the finite neighbourhood of 0. If the inspection arises at the transfinitely remote zone of the hotel, it has to traverse a transfinite span in single, finite steps if it is to reach a finite neighbourhood of 0, and then eventually rooms . . . -2, -1, 0. I chose a point in that zone, A, to begin a down-count of steps as the tour must pass each successive room. As he passes A, I start to count, to show why something based on an inherently finite stepwise incremental and cumulative process will not be able to traverse the intervening span onwards from A to reach a finite neighbourhood of 0. And nope, substituting a finitely remote zone relative to 0 does not answer the point. If you are inspecting an actual infinity of rooms in succession, you must start at the transfinitely remote zone. Such a tour will not complete as a stepwise process and will not ever reach a zone finitely remote from 0 as at every successive room past A the manager will only be a finite distance past A, never mind how that increments on and on. The implications for a claimed actually infinite in the past space-time world that proceeds in cumulative, finite causal steps, will be plain. KF kairosfocus

Hi Querius. You write, "Nevertheless, the clip also demonstrates the futility of using mathematical analogies to make an argument." I agree with you about analogies in general - they are useful in illuminating ideas, sometimes, but don't themselves ever prove anything. However, I don' think the clip is using mathematical analogies - it is just using mathematics that is wrong. I Aleta

KF, Your post #90 echoes this statement you made earlier:

The room inspection tour must start in the transfinite zone and arrive at the finite one in order to inspect all rooms.

In the Hilbert Hotel model, the tour I described has no starting point. The hotel manager has been inspecting the rooms throughout the assumed infinite past. Furthermore, he has never been more than finitely many steps from the front desk. daveS

Aleta, I have had a thought: if the point is, that there are unlimited numbers that can be set in finite counting sets, I can see that . . . just keep going in steps. However, that does not answer to another linked issue, the import of the ellipsis that the ordered sequence is unlimited in character. For that, setting the ordered numbers in line and applying a definition of a "border" as: if it is finite it is natural, and if it is beyond a transfinite span from 0, it is not a natural though it may be an ordinal starting from w, does not resolve the onward point on descent from the infinite past as claimed. Is that a step of progress? KF PS: In effect I read that as, as one moves out in steps from 0, things get into a vast impassable wilderness but the sequence keeps going, and eventually it arrives at w and so forth onwards way out there in numbers Sahara territory. Of course the y = 1/x wormhole near 0 allows one to catapult to that zone in one astonishing step. Once you are at the w zone, the same impassable Sahara faces s/he who would descend in steps to the zone near 0, so again, the catapult must be used. Now, somebody needs to go write a new Flatland. kairosfocus

Q, thanks, indeed the decimal, place value system has two formally equivalent expressions for a whole number, the [n-1] .999 . . . and the [n].000 . . . KF kairosfocus

kairosfocus, Here's one that I figured out in Junior High (as I'm sure lots of other kids did too). Let n = 0.999... (repeating) 10n = 9.999... 10n-n = 9.999... - 0.999... 9n = 9 n = 1 Therefore 0.999... = 1.000.... :-) -Q Querius

Glad you watched the video, Aleta, The odd thing is, that this mathematics is used in quantum mechanics as he pointed out in the textbook! Nevertheless, the clip also demonstrates the futility of using mathematical analogies to make an argument. Analogies are great for explanation, but that's where it ends. -Q Querius

Aleta, I have no objections to or concerns regarding B. My problem, as described and explained, is how A can be compatible with B, given that we are in fact describing the counting numbers and how we get to the cardinality of "counting sets" as I spoke of for convenience. Where it looks to me like the claim that any counting number k is k = 1 + 1 + . . . + 1 k times over, and may be exceeded by k + 1 (showing it to be finite), raises issues of ordinals and of the traversing of a transfinite span when one moves off on the open ellipsis. Decreeing and declaring that oh, transfinite ordinals are not naturals, does not help my concern a lot, when at the same time, it is held that the naturals are endless and can be so arranged that proper subsets are in 1:1 mutually exhausting correspondence with the whole -- the very definition of being transfinite in cardinality. And, I am avoiding the standardised terminology but reverting to first steps as it seems there is a problem of how the standard terms will be understood/defined. KF PS: I have had occasion to complain of poof-magic mathematical hand waving by physicists on occasion; going all the way back to undergrad years. kairosfocus

In his first step, with S = 1 - 1 + 1 -1 + ..., he correctly points out that you get different partial sums depending on the number of terms: 1 for an odd number of terms and 0 for an even number. He then says we should just average the two, and call the sum 1/2. That is balderdash! S oscillates between two sums, so it does not converge, which is the only legitimate sense in which we can say an infinite series has a sum. There is no legitimate mathematical justification for saying the sum is 1/2. Since everything else builds from there, the rest is all wrong also. See here for a longer explanation: https://plus.maths.org/content/infinity-or-just-112, which interesting enough shows a quantum physics use of some very much more advanced mathematics that would imply that S = -1/12. Quantum physics struggles often with quantities which compute as infinite but in fact, obviously in the real world, aren't: Feynman became famous for coming up with a way to get around this problem in certain kinds of situations. But I object to the guy using bad mathematics to make his point. Aleta

nm daveS

Aleta, See what happens to your sets of numbers when a physicist gets hold of it. https://www.youtube.com/watch?v=w-I6XTVZXww First try to explain if and where there's any error other than you might illogically disagree with the conclusion. -Q Querius

On the set N, my concern is the claim every member is finite [thus subject to a finite count out to some k] when joined to the second claim that the cardinality of the whole is transfinite.

But what is your concern? (I am not claiming a completed infinite past, so that is not the current topic.) A: every element of the set of natural numbers N = {0, 1, 2, 3, … } is a finite number. B: the number of of numbers in the set N is a transfinite number aleph null. You are using language that is different than mine, and I can't tell whether we are saying the same thing. I'm saying "B: the number of of numbers in the set N is a transfinite number aleph null." Aleph null is the name of the order of infinity possessed by the natural numbers, and is considered a "transfinite number", which define different classes of numbers. But you write, "the cardinality of the whole is transfinite." By the whole, I assume you mean the set of natural numbers. Yes, the cardinality of the set of natural numbers is the transfinite number aleph null. But if you are saying what I am saying, what is the concern. Are statements A and/or B above wrong, and if so why? Aleta

Aleta, I am not at that time discussing a finite span but the transfinite one implicit in a claimed completed infinite past. On the set N, my concern is the claim every member is finite [thus subject to a finite count out to some k] when joined to the second claim that the cardinality of the whole is transfinite. KF kairosfocus

You have a concern about A: what is it? If we are just looking at the natural numbers, I don't see how "traversing the transfinite" is relevant. You write,

Now, let us go to such a succession that goes on through ellipsis to the zone where we pick up w and its successors, w being omega the number that is the “first” ordinal of cardinality aleph null: {} –> 0, to {0} –> 1, to {0,1} –> 2, . . . k, . . . [a transfinite span, as above with counting numbers in succession] . . . w, w + 1, w + 2, . . .

But in the set of natural numbers one would never "go through the ellipsis to the zone where we pick up w". w is not a number in the set N, so there is no way we could reach it in order to go through it. So, to repeat, every member of the set N is a finite number. Why do you have a concern about that? Aleta

Aleta, on the narrow point, I can see that every number k we can actually complete a count to and make a complete k-set {1, 2 . . . k} will be finite, and will of course have cardinality k. When the indefinite or transfinite traverse ellipsis comes in, that is where my concerns begin; with an endless count, there is not going to be any upper limit count number like that. So, I do have a concern about claim A, especially in connexion with claim B, which I would like to see resolved. Simply listing k = 1 + 1 + . . . 1 k times and there is a successor k + 1 will not help as the ellipsis here is not a transfinite traverse if the claim is k is finite. Beyond, I simply say, the question is interesting but not the end of the story. The onward issue is traversing the transfinite. KF kairosfocus

KF: I'm only interested in part of what you are interested in, but I'm wondering, just to make it clear, if you agree with the two statements I wrote above: A: every element of the set of natural numbers N = {0, 1, 2, 3, … } is a finite number. B: the number of of numbers in the set N is a transfinite number aleph null. notice, I am NOT saying that aleph null is in the set somehow You do say that "notice, I am NOT saying that aleph null is in the set somehow," which does bear on your agreement with either A or B. In fact, I think you are saying that you agree with B, and that aleph null is not a member of N. What about A: every element of the set of natural numbers N = {0, 1, 2, 3, … } is a finite number. Do you agree with that? Aleta

Aleta I have been expressing some concerns and -- given the way there has been back-forth for some time -- it looks like I will need to go to start-points. So, to the construction of (basic sense) counting numbers: {} –> 0, to {0} –> 1, to {0,1} –> 2, . . . k [some finite value], . . . The ellipsis shows, continue to arbitrary length and it keeps going. Now, let us go to what I will for convenience call counting sets: {1}, of cardinality 1 {1, 2} of cardinality 2 . . . {1, 2, . . . k} of cardinality k. The idea being, that when something is to be counted, it can be matched 1:1 perfectly to the appropriate counting set. In general for k finite, the cardinality will implicate the presence of a member of that position, kth, in the stepwise sequence. This may then be exceeded by k + 1, by taking a succeeding step. This goes somewhere interesting and to where my concerns lie:

I note how k is a finite value, and there is an onward ellipsis, such that we then see an exceeding successor, k + 1, then: {} –> 0, then {0} –> 1, then {0,1} –> 2, . . . k, . . .

[a transfinite or endless onward span –> let’s add: for any specific finite k you please you can count on forever in here, k+1, k + 2 . . . and put the onward count in correspondence to 0, 1, 2 . . . or perhaps better 1, 3, 5 . . . having already put everything so far in correspondence with 2, 4, 6 . . . as 1 can here be identified by its being odd as strict successor to all evens (notice, use of the definition of a transfinite set as enfolding an endless strict subset) ]

. . .

So, we see here that the endless version of the ordered counting numbers, {1, 2, 3, . . . } can be such that we put a proper subset in one to one match with it with both being endless. So, to claim that the set is endless and thus of transfinite cardinanlity aleph null -- notice, I am NOT saying that aleph null is in the set somehow -- seems to be in direct irreconcilable conflict with claims that all its members are finite, when they are labelled the natural numbers. Be that as it may, I step aside from the matter. As my real interest lies in descent from the transfinite. We have been dealing with ordered numbers, with a first member and distinct succession, with a ranking/succession rule that is strictly applicable, continuing endlessly. So, let us deal with ordinal numbers as ordinal numbers in succession from 0 or 1 as first depending on interest. I usually start with 0. Now, let us go to such a succession that goes on through ellipsis to the zone where we pick up w and its successors, w being omega the number that is the "first" ordinal of cardinality aleph null:

{} –> 0, to {0} –> 1, to {0,1} –> 2, . . . k, . . . [a transfinite span, as above with counting numbers in succession] . . . w, w + 1, w + 2, . . .

As, from w there is an onward succession: w, w + 1, w + 2, …, w·2, w·2 + 1, …, w^2, …, w^3, …, w^w, …, w^[w^w], …, E_0, …. I then believe I may next reasonably identify one such successor to w that is of interest, w + g , which will be of the same cardinality aleph null, where I am viewing aleph null as in effect an index of order of scale being countably transfinite, with its successors being of higher order of scale and not being countably transfinite; whether the order of scale of the continuum c belongs to the sequence is of course notoriously undecidable: w, w + 1, w + 2, . . . w + g [g a large finite value], …, w·2, w·2 + 1, …, w^2, …, w^3, …, w^w, …, w^[w^w], …, E_0, …. Let us call w + g, A, where also given that [0, 1] is continuous, some infinitesimal m will be its multiplicative inverse: A = 1/m, similar -- note I claim no more than comparability -- to how the nonstandard analysis comes into play elsewhere. Now, given the endless succession from k on, I suggest that in up-counting from a given finite point in the span of numbers, k, we will never reach w in successive finite incremental steps. Likewise, it seems, we may reasonably list in reverse form: . . . A, A less 1 [i.e. W + (g-1)],. . . w, . . . 2, 1, 0 Thus -- without assuming that there is anything but an indefinitely large span beyond A to the left -- we can look at down-counting from A, symbolising [w + (g - 1) as A ~1, etc: A, A ~ 1, A ~ 2, . . . w + 1, w, . . . r, . . . 2, 1, 0 0#, 1#, 2# . . . Now, g is finite but very large, this allows us to establish an ordering down to w. My key concern is that the ellipsis beyond w is endless, so the stepwise down count sequence that begins at A will go on forever without bridging it to r, a finite neighbourhood of 0. Indeed, it seems that once the secondary count started at A hits w at g steps later, and goes on, we are in the position of trying to count across an endless span. Thus, a stepwise count process will not reach r, much less the interval [0,1]. To me, this seems to give some substance to the remark that an inherently finite stepwise counting process will not bridge a transfinite span, will not traverse a transfinite range. This is as distinct from that we may set in order a succession that as a set will define a transfinite span of ordered succession. Countable in principle, inexhaustible in practice. The gap between the potentially infinite process and the actually completed infinite process. To span the transfinite, it seems to me we need the sort of "catapult" that the multiplicative inverse acting on an infinitesimal will give. Applying to the cosmic space-time domain, we have a pattern of causal and temporal succession in finite stpes that are in principle countable. They come from the remote past of origins, and reach to the present. From, say, the singularity as 0 at 13.7 BYA or whatever, we have a finite span to the present, here n*. The issue is then beyond that horizon, where some claim completion of an actually infinite succession: . . . A, A ~ 1, A ~ 2, . . . r, . . . 2, 1, 0, 1*, 2*, . . . n* But the issue already identified is instantly applicable. The finite succession is complete-able, the transfinite is endless by definition, of different orders, aleph null being applied to counting numbers. And so, if we can already see that we have a problem bridging from A to r, there will be a problem bridging to A from the endless values beyond it. It seems to me that the best answer is, that there is some r a finite distance from 0, which is the terminus of the space time domain, i.e. it is inherently finite. As for handy-dandy cookie cutter definitions of sets and members, at this stage I am quite leery, so that is why I have reverted to speaking of ordered succession and counting numbers, with extensions to the zone of transfinite ordinals. Can you address my concerns? I extend appreciation in advance. KF kairosfocus

Hi kf. I agree with you about not being to get here from an infinite past. But I am confused about some other issues under discussion. Would you be able to say you agree or disagree with the following statements, from a purely mathematical point of view. A: every element of the set of natural numbers N = {0, 1, 2, 3, ... } is a finite number. B: the number of of numbers in the set N is a transfinite number aleph null. Aleta

Aleta, I would add that some of the transfinite/infinite numbers KF refers to are hyperreals. daveS

JJ, The issue is, what does it mean to suggest an infinite descent in finite causal steps from an infinite past. And as I am about to discuss further, I have some serious points of concern with what is being given to us. KF kairosfocus

Aleta,

to DaveS: transfinite numbers are not real numbers (or natural numbers). Transfinite numbers, which may be a misleading name, are “numbers” which represent different levels of infinity. The number of natural numbers, which is infinite, is called aleph null. This is the smallest order of infinity. The number of real numbers, aleph one, is also infinite, but a greater order of infinity: there are more reals than natural numbers. These are not numbers in the same sense that the reals are numbers.

Yes, I agree. KF claims to the contrary that the set {0, -1, -2, ... } does have transfinite elements. He has stated that if every element of {0, -1, -2, ... } were finite, then that set would have finite cardinality. daveS

JJ: Not only is it logically impossible to count back an infinite amount past number of natural events prior to this time Seems reasonable, I thought KF's argument was nothing can happen at all if time was infinite, that infinite time was like walking the wrong way on a moving sidewalk, every time you take a step you are further from your destination, the present. which shows that we could never have reached this moment in time if there were an infinite amount of past natural events, When an event occurs it happens in its present, an infinite number of events equal an infinite number of presents but the idea of “infinite finiteness” which the materialist would have to believe in, if he holds to never ending finite natural events, is a tautological oxymoron. An infinite set can be broken up into a infinite number of finite sets. velikovskys

to DaveS: transfinite numbers are not real numbers (or natural numbers). Transfinite numbers, which may be a misleading name, are "numbers" which represent different levels of infinity. The number of natural numbers, which is infinite, is called aleph null. This is the smallest order of infinity. The number of real numbers, aleph one, is also infinite, but a greater order of infinity: there are more reals than natural numbers. These are not numbers in the same sense that the reals are numbers. So Dave is correct when he says "There [are no] transfinite numbers in the set {0, -1, -2, …}. Saying, perhaps, that there is the transfinite number alpha null in the set because the set goes on forever, would be wrong: that would be mixing apples and oranges. The number of numbers in the set is aleph null, but aleph null is not in this set. Is this clear? Does kf agree, or not? Aleta

Not only is it logically impossible to count back an infinite amount past number of natural events prior to this time which shows that we could never have reached this moment in time if there were an infinite amount of past natural events, but the idea of "infinite finiteness" which the materialist would have to believe in, if he holds to never ending finite natural events, is a tautological oxymoron. The Materialist would have to dump logic on both counts in order to hold to that particular idea. Jack Jones

KF, There is no proof there of the existence of any transfinite numbers in the set {0, -1, -2, ...}. daveS

DS Please notice what I did at 63, in context including:

Let me augment the list of ordinals of scale aleph null: w, w + 1, w + 2, . . . w + g [g a large finite value], …, w·2, w·2 + 1, …, w^2, …, w^3, …, w^w, …, w^[w^w], …, E_0, …. where of course, ordinals will go: {} –> 0, to {0} –> 1, to {0,1} –> 2, . . . k, . . . [a transfinite span –> let’s add: for any specific finite k you please you can count on forever in here, k+1, k + 2 . . . and put the onward count in correspondence to 0, 1, 2 . . . or perhaps better 1, 3, 5 . . . having already put everything so far in correspondence with 2, 4, 6 . . . as 1 can here be identified by its being odd as strict successor to all evens (notice, use of the definition of a transfinite set as enfolding an endless strict subset) ] . . . w, w + 1, w + 2, . . . [as above] with reminder: The finite ordinals (and the finite cardinals) are the natural numbers: 0, 1, 2, …, since any two total orderings of a finite set are order isomorphic. The least infinite ordinal is w [–> omega], which is identified with the cardinal number aleph_0. However, in the transfinite case, beyond w, ordinals draw a finer distinction than cardinals on account of their order information. Whereas there is only one countably infinite cardinal, namely aleph_0 itself, there are uncountably many countably infinite ordinals My concern has been that for the finite counting numbers laid out in ordered sequence, 0, 1, 2 . . . , the cardinality of successive ranges will equal the value of the last listed member. So, a stepwise succession to k will hold cardinality k and this is then exceeded by k + 1 of cardinality k + 1. But in every case, the cardinality is therefore just as described, finite. As in not transfinite, not endless, not of order aleph null.

KF kairosfocus

KF,

DS, the highlighted tells a long tale. When a set is presented as “the room numbers are 0, -1, -2, -3, … “ that ellipsis is very important, pointing to the transfinite character of the set. This means that at some scale one is transfinitely far away from the beginning.

Please prove this, including a rigorous definition of the phrase "at some scale". Things you can't do: * Use "real infinitesimals", which do not exist. * Use hyperreal infinitesimals, because their reciprocals are not real numbers. All the numbers in the set {0, -1, -2, -3, ... } are real. daveS

GG, of course you are familiar with the von Neumann type construction which starts at the empty set {} and then goes as I outlined at 63: {} –> 0, to {0} –> 1, to {0,1} –> 2, . . . k, . . . , thus getting to all whole numbers -- in principle. You may find my discussion here on (fairly lengthy because of many stages of issues; pick up after the pic and discussion of the flying spaghetti monster . . . ) how this can move to a virtual world interesting. Then, if you are a mind of adequate cosmos-forming power it's fiat lux and poof, we are in the province of a world of space-time, temporal-causal succession. KF kairosfocus

Q & GG: Or, ponder how a universe spawns from the dreams of a rock [vs Divine, eternal contemplation], following Aristotle . . . on recognising that rocks have no dreams. Nothing, properly denoting non-being. KF kairosfocus

F/N: Wiki on the hotel:

Hilbert's paradox of the Grand Hotel is a thought experiment which illustrates a counterintuitive property of infinite sets. It is demonstrated that a fully occupied hotel with infinitely many rooms may still accommodate additional guests, even infinitely many of them, and that this process may be repeated infinitely often . . . . The paradox Consider a hypothetical hotel with a countably infinite number of rooms, all of which are occupied. One might be tempted to think that the hotel would not be able to accommodate any newly arriving guests, as would be the case with a finite number of rooms, where the pigeonhole principle would apply. Finitely many new guests Suppose a new guest arrives and wishes to be accommodated in the hotel. We can (simultaneously) move the guest currently in room 1 to room 2, the guest currently in room 2 to room 3, and so on, moving every guest from his current room n to room n+1. After this, room 1 is empty and the new guest can be moved into that room. By repeating this procedure, it is possible to make room for any finite number of new guests. Infinitely many new guests It is also possible to accommodate a countably infinite number of new guests: just move the person occupying room 1 to room 2, the guest occupying room 2 to room 4, and, in general, the guest occupying room n to room 2n, and all the odd-numbered rooms (which are countably infinite) will be free for the new guests. Infinitely many coaches with infinitely many guests each For more details on this topic, see Pairing function. It is possible to accommodate countably infinitely many coachloads of countably infinite passengers each, by several different methods. Most methods depend on the seats in the coaches being already numbered (alternatively, the hotel manager must have the axiom of countable choice at his or her disposal). In general any pairing function can be used to solve this problem. For each of these methods, consider a passenger's seat number on a coach to be n, and their coach number to be c, and the numbers n and c are then fed into the two arguments of the pairing function . . . . Analysis Hilbert's paradox is a veridical paradox, it leads to a counter-intuitive result that is provably true. The statements "there is a guest to every room" and "no more guests can be accommodated" are not equivalent when there are infinitely many rooms. An analogous situation is presented in Cantor's diagonal proof.[3] Initially, this state of affairs might seem to be counter-intuitive. The properties of "infinite collections of things" are quite different from those of "finite collections of things". The paradox of Hilbert's Grand Hotel can be understood by using Cantor's theory of transfinite numbers. Thus, while in an ordinary (finite) hotel with more than one room, the number of odd-numbered rooms is obviously smaller than the total number of rooms. However, in Hilbert's aptly named Grand Hotel, the quantity of odd-numbered rooms is not smaller than the total "number" of rooms. In mathematical terms, the cardinality of the subset containing the odd-numbered rooms is the same as the cardinality of the set of all rooms. Indeed, infinite sets are characterized as sets that have proper subsets of the same cardinality. For countable sets (sets with the same cardinality as the natural numbers) this cardinality is aleph_0. Rephrased, for any countably infinite set, there exists a bijective function which maps the countably infinite set to the set of natural numbers, even if the countably infinite set contains the natural numbers. For example, the set of rational numbers—those numbers which can be written as a quotient of integers—contains the natural numbers as a subset, but is no bigger than the set of natural numbers since the rationals are countable: There is a bijection from the naturals to the rationals.

This of course raises many issues. The point being, the power of endlessness. Which requires transfinite character. Where also the situation of having an ordinal immediate successor or immediate predecessor does not mean that a number w + r, r finite, cannot be of transfinite cardinality. From this we see that an inherently finite stepwise cumulative process of in effect counting causal succession will not exhaust the transfinite span. If we hold 0, 1, 2, . . . k, k+1 to be inherently finite to k, the span will not be transfinite. Countable in principle does not mean that one can complete an endless counting process in praxis. As the very word "endless" suggests. If it is thus a supertask to attempt to count up endlessly to arrive at w etc of order of magnitude aleph null, by the same logic it is equally a supertask to try to count down from that scale across an endless span to a finite neighbourhood of 0, of "radius" n. In short there is a difference between in principle and in praxis. Much lurks beneath the ellipsis and we must be very clear as to whether it speaks of a finite and complete-able process or an endless span that cannot be completed by a finite succession of finite steps. Hence the significance of a more powerful process 1/m = A. KF kairosfocus

DS, I notice:

There are infinitely many rooms, but each room number is finite. Please, no more ill-defined expressions such as “of scale little-omega”.

DS, the highlighted tells a long tale. When a set is presented as "the room numbers are 0, -1, -2, -3, … " that ellipsis is very important, pointing to the transfinite character of the set. This means that at some scale one is transfinitely far away from the beginning. That is what gives the problem of completing the stepping down process from the endlessly high value zone to the finite neighbourhood of 0. As for "gibberish," I again point to what I noted at 56 in the previous thread:

Now, the count and successive establishment of counting numbers from {} –> 0, to {0} –> 1, to {0,1} –> 2 etc suggests looking at ordinal numbers as an approach. And such is obviously foundational. Where, for convenience let us refer Wiki (which in this context from my POV is inclined to be seen as testifying against its ideological interests) . . . and where I use w for omega and E for epsilon:

In set theory, an ordinal number, or ordinal, is one generalization of the concept of a natural number that is used to describe a way to arrange a collection of objects in order, one after another. Any finite collection of objects can be put in order just by labelling the objects with distinct whole numbers. Ordinal numbers are thus the “labels” needed to arrange infinite collections of objects in order. Ordinals are distinct from cardinal numbers, which are useful for saying how many objects are in a collection. Although the distinction between ordinals and cardinals is not always apparent in finite sets (one can go from one to the other just by counting labels), different infinite ordinals can describe the same cardinal (see Hilbert’s grand hotel). Ordinals were introduced by Georg Cantor in 1883[1] to accommodate infinite sequences and to classify derived sets, which he had previously introduced in 1872 while studying the uniqueness of trigonometric series.[2] Like other kinds of numbers, ordinals can be added, multiplied, and exponentiated. The finite ordinals (and the finite cardinals) are the natural numbers: 0, 1, 2, …, since any two total orderings of a finite set are order isomorphic. The least infinite ordinal is w [–> omega], which is identified with the cardinal number aleph_0. However, in the transfinite case, beyond w, ordinals draw a finer distinction than cardinals on account of their order information. Whereas there is only one countably infinite cardinal, namely aleph_0 itself, there are uncountably many countably infinite ordinals, namely w, w + 1, w + 2, …, w·2, w·2 + 1, …, w^2, …, w^3, …, w^w, …, w^[w^w], …, E_0, …. Here addition and multiplication are not commutative: in particular 1 + w is w rather than w + 1 and likewise, 2·w is w rather than w·2. The set of all countable ordinals constitutes the first uncountable ordinal w_1, which is identified with the cardinal aleph_1 (next cardinal after aleph_0). Well-ordered cardinals are identified with their initial ordinals, i.e. the smallest ordinal of that cardinality. The cardinality of an ordinal defines a many to one association from ordinals to cardinals . . .

This at least looks promising, as it clearly points to whole numbers of transfinite nature, and distinctly identifies increments by addition to the next ordinal. Where cardinality at transfinite scale is an index of order of magnitude expressed at aleph null level by one to one correspondence. The logical next step is to suggest some finite counting number g, to be added to w, and put up as a further construction of A: 1/m = A (That is A * m = 1, multiplicative inverse. Where, m is an infinitesimal.) A = w + g In this context A less 1 would be w + (g – 1) . . . let us symbolise as A ~ 1, and so forth. Under these circumstances, it seems to me for the moment that A would be a transfinite not actually reachable from 0 by an inherently finite step by step process but is a whole number in an identifiable sequence. Reversing the matter let us now look at: . . . A, A ~ 1, A ~ 2, . . . 2, 1, 0, 1*, 2*, . . . n* A is obviously not a first step, the leading ellipsis takes care of that. For all we know for the moment an indefinitely large descending sequence has arrived at A. At least, we must be open to it. But, now we go beyond A and can make a correspondence of onward steps trying to descend to 0, say to be tagged with the singularity: A, A ~ 1, A ~ 2, . . . 2, 1, 0 . . . n* 0#, 1#, 2# . . . We face an inherently finite state based descent that can only ever be completed to a finite extent. But the span to be traversed to 0 is transfinite.

Let me augment the list of ordinals of scale aleph null:

w, w + 1, w + 2, . . . w + g [g a large finite value], …, w·2, w·2 + 1, …, w^2, …, w^3, …, w^w, …, w^[w^w], …, E_0, …. where of course, ordinals will go: {} –> 0, to {0} –> 1, to {0,1} –> 2, . . . k, . . .

[a transfinite span --> let's add: for any specific finite k you please you can count on forever in here, k+1, k + 2 . . . and put the onward count in correspondence to 0, 1, 2 . . . or perhaps better 1, 3, 5 . . . having already put everything so far in correspondence with 2, 4, 6 . . . as 1 can here be identified by its being odd as strict successor to all evens (notice, use of the definition of a transfinite set as enfolding an endless strict subset) ]

. . . w, w + 1, w + 2, . . . [as above]

with reminder:

The finite ordinals (and the finite cardinals) are the natural numbers: 0, 1, 2, …, since any two total orderings of a finite set are order isomorphic. The least infinite ordinal is w [–> omega], which is identified with the cardinal number aleph_0. However, in the transfinite case, beyond w, ordinals draw a finer distinction than cardinals on account of their order information. Whereas there is only one countably infinite cardinal, namely aleph_0 itself, there are uncountably many countably infinite ordinals

My concern has been that for the finite counting numbers laid out in ordered sequence, 0, 1, 2 . . . , the cardinality of successive ranges will equal the value of the last listed member. So, a stepwise succession to k will hold cardinality k and this is then exceeded by k + 1 of cardinality k + 1. But in every case, the cardinality is therefore just as described, finite. As in not transfinite, not endless, not of order aleph null. But, we then see that the set of numbers -- including of room numbers [how can they be put on the doors?] -- we actually require needs to be of transfinite character, endless. That requires going to transfinite cardinals of order w. The room inspection tour must start in the transfinite zone and arrive at the finite one in order to inspect all rooms. This cannot be completed, no more than it can be completed to increment in steps to the transfinite while being finitely far from the start at each successive, cumulative step. In short, my concern is that the ellipsis does a lot of work, and may be implicitly covering over a supertask not feasible of completion. KF PS: The captcha pops up and goes white screen again. kairosfocus

Aleta, you might want to investigate why, starting with Einstein, physicists refer to something that they call space-time. Gary, the problem that a lot of people have is that they don't understand nothing. Nothing in this context is non-existence. For example, the Easter bunny is non-existent. So, imagine how a universe spawns out of the Easter bunny. -Q Querius

GG, nothingness in this context means non-being. Not matter, not energy, not time, not laws and forces, not mind.

KF, in a computer model like I described all of that including time(steps) have to somehow be coded into it or else absolutely nothing ever exists in the virtual world. The methodology forces everyone to start with a total nothingness (i.e. dimension an empty array to put things like forces into) then supply the coded math/logic that makes a world as close as possible to ours form inside. GaryGaulin

KF, Your quoted construction is gibberish, I'm sorry to say. Regarding your PPS, the room numbers are 0, -1, -2, -3, ... . There are infinitely many rooms, but each room number is finite. Please, no more ill-defined expressions such as "of scale little-omega". There are so many mathematicians involved with ID. Dembski, Sewell, Berlinski, probably quite a few posters here. Have you ever run any of this stuff by any of them? daveS

DS, have you noticed the lead ellipsis in the series? That means the issue is onwards from A, for the sake of the argument. Note 7 above:

what is warranted is that step by step finite succession cannot bridge to the transfinite. This is easiest to see starting at 0 and counting up, but it is patent that bridging the transfinite the other way to appear at the present has to bridge the same span. That is why I went to lengths to identify a reasonable ordered succession 0, 1, 2 . . . [TRANSFINITE SPAN] . . . w, . . . w + g . . . and identify that A = W + g, a transfinite with w the first transfinite ordinal and g some large finite [so still of the scale aleph null] will be such that in a descent . . . A, A~1 [= w + (g – 1)], A ~ 2, . . . 2, 1, 0, 1*, 2* . . . n, n being now, we see A, A~1 [= w + (g – 1)], A ~ 2, . . . 0, 1#, 2#, . . . and so we run into a transfinite bridge and the count down will not reach from A to 0, no more than it can reach up from 0 to A. The causal, finite step by step succession of the past will inherently be finite, strongly grounding the conclusion that the past was finite.

If you cannot get a tansfinite span by incrementa steps after A, it matters not for the argument at this point what may lie beyond A. But then the same logic applies a second time and there is no indefinitely transfinite preceding span for any value. That is the sequence is finite, the past is finite. Time began a finite span ago. KF PS: I used the multiplicative inverse of m and linked mention of the hyper-reals to show how one can get to a transfinite. All it needs is recognising that the interval [0, 1] is continuous, and so there are values arbitrarily, infinitesimally close to 0. Closer than any epsilon neighbourhood of 0. PPS: Without room numbers in the ordered, numbered sequence of rooms that are of scale w [standing in symbolically for omega], of aleph null cardinality, there will not be an actual infinity of rooms. There is a difference between an unspecified large but finite value and an actual infinity, which is what the hotel is supposed to be. kairosfocus

Let me explain why all this hyperreal stuff is moot. The issue is whether the past could be infinite. If the past was infinite, then that would certainly mean that given any natural number n, the universe already existed n seconds ago. IOW, -n seconds is a valid time coordinate for our universe (assuming the origin is set at the present). This does not necessarily mean that given some infinite hyperreal integer A, then the universe already existed A seconds ago. I am not supposing such. If you present me with an infinite hyperreal integer A, I don't know if -A is a valid time coordinate for our universe. That's why you have to stick to arguing against the Hilbert Hotel example where the room numbers all come from N (or their opposites), and where each room is finitely many steps from the front desk. daveS

nm daveS

KF,

DS, you have acknowledged that a step by step process is inherently finite (even citing with approval arguments based on it). The task in hand is to span the transfinite, and at some point the manager would have been transfinitely far from the last room no 1 and the front desk room 0.

I was just at the gym thinking that at least we are not talking about rooms infinitely far from the front desk anymore. Oh well. At no point was the manager at some transfinite distance from room 0. Every room number is finite, hence every room has finite distance to the front desk. Edit: In response to your PS, I am working with a Hilbert Hotel with room numbers equal to the opposites of the natural numbers. No transfinite room numbers allowed. daveS

M62, Your card game example aptly shows the cumulative, causal transition of stages with time and the unidirectional flow. A fresh deck in order is disordered by shuffling and going back spontaneously is a rare event indeed. This reflects the point of trend to increased entropy through moving to config clusters of higher statistical weight. KF kairosfocus

DS, you have acknowledged that a step by step process is inherently finite (even citing with approval arguments based on it). The task in hand is to span the transfinite, and at some point the manager would have been transfinitely far from the last room no 1 and the front desk room 0. Step by step successive descent at that level will never bridge down to a finite range from 0 as moving a finite set of steps away from a transfinite point say room w + g to w + (g - 1), w + (g - 2) etc will still be of the same cardinality aleph null away from the front desk; w being the first transfinite ordinal omega which holds cardinality aleph null. Counting up from 0 in steps will never surpass finite values and likewise trying the same span the other way around will not be any more successful. As, has been pointed out to you as a concern any number of times now. Notice, too, when the new guests come the message is broadcast so changes in rooms are all at once [old guests previously in rooms n to rooms 2n, new ones to 2n-1], i.e. in parallel. That is a clue on how action in successive individual steps would fail. KF PS: Notice how Robinson et al have worked in nonstandard analysis to bridge to the transfinite. They use the power of the hyperbolic function y = 1/x for x --> 0 to move in scale from the v small to the very large. Then put in an infinitesimal, to result with a hyper-real, sometimes a hyper-integer. I suggest a more modest "catapult" from some convenient infinitesimal m to y = 1/m = A = w + g, this being a transfinite whole number value of cardinality aleph null. Then, as the manager descends in order, at some juncture he inspects room A. kairosfocus

KF, You're certainly welcome to show that the manager missed a room under my scheme. daveS

DS, nope; the issue of stepwise traversal of a transfinite span remains. KF kairosfocus

KF, I have told you how the manager traverses the Hilbert Hotel in a step-by-step fashion. That's analogous to my infinite clock example: The manager carries a pocket watch which ticks once per each room he inspects. That's what I said I could do. daveS

DS, you have yet to tell us how a finite step by step process traverses the transfinite span of an actual infinity. KF kairosfocus

Mapou, time is causally connected. KF kairosfocus

There is only the present, the NOW. But there are relational changes amongst the objects of the universe. And some of these objects have memory too, besides brains, such as computers, and decks of cards, that record the uni-directionality of these state changes. For example, take a BlackJack game. The deck of cards going from one relational state progressively to another. The odds of the game change due to these relational state changes. The system has memory, and it is based on a "direction" of the state changes. The flow of these state changes is called "time." Even though consciousness is always in the "now", consciousness can change its state as a result of the perception of the progressing state changes among objects. Close your eyes. Consciousness sees black. Open your eyes. Consciousness sees colors. mike1962

KF:

While time is evidently unidirectional

This, too, is an illusion created by the way the way our brain stores memory as a sequence that can be scanned as such by our consciousness. IOW, it's not even wrong. The idea of a unidirectional arrow of time is pure nonsense. There is only the present, the NOW. I have explained many times on UD why there can be no such thing as changing time or motion in time. It is a self-referential fallacy. I would do it again but I'm afraid it will fall on deaf ears. So this is my last post in this thread. Have fun with your misconceptions. Mapou

KF, No, I have described how the manager could inspect every room in the Hilbert Hotel. If you disagree, name a room that he missed, or otherwise prove that one exists. Please note that every room number is finite. Edit:

PS: You have now added oh try two rooms and infinitely many cycles between the two. This still leaves on the table the issue of finiteness of stepwise process.

Obviously. That's the point. daveS

DS, you have described how the manager could inspect finitely many rooms in an inherently finite process. The problem is the span in question is transfinite and endless in the first degree, of scale aleph null. KF PS: You have now added oh try two rooms and infinitely many cycles between the two. This still leaves on the table the issue of finiteness of stepwise process. kairosfocus

Aleta, the argument on the table -- in now a third current thread -- is in fact that the universe (taking in multiverse proposals etc) is infinitely old. Mathematical considerations are tied to the issue of there being a proposed endless causal stage by stage succession of events to the present. However, inherently a step by step countable process is inherently finite if completed. The span to be addressed is by contrast transfinite. KF kairosfocus

Aleta @41, Yes, just to clarify, I think it's very unlikely that our universe is infinitely old, not that my opinion means anything. I'm not trying to prove it is. I'm simply interested in analyzing KF's argument against an infinite past. While I don't think it succeeds, at least it's new (to me). Ultimately, I suppose we are discussing time in the universe, but we have been mostly focusing on the properties of number systems, the infinite, etc., as you said. daveS

KF, Could you translate your mathematical objection about "spanning the transfinite with the inherently finite" to the Hilbert Hotel? I've described very simply how the manager could inspect each of the infinitely many rooms of the hotel, with each step simply moving to the next room over. What's the mathematical issue? Regarding the physical feasibility of the HH, of course that's true. The point is it's a concrete model which allows us to reason about the abstract more easily. You could make the hotel less spectacularly infeasible by requiring it to have only two rooms, with the manager going back and forth between rooms once per second, with this process having continued into an infinite past. I don't think it's been shown that a physical analog of this process is impossible (see the oscillating universe models which remain unrefuted at this point). But again, I'm interested in the mathematics here, not the physics. daveS

to Q at 33. I don't believe anyone in this discussion is arguing that the universe has existed for an infinite amount of time. They are arguing about the abstract nature of time as it might be stretching back before the start of the universe. If I'm wrong about this, kf and ds, please correct me - you haven't been discussing time within our universe, have you? Aleta

DS, the core issue seems to be conceptual. If we have had an infinite step by step temporally manifested causal succession to now, it has had to span a transfinite domain to reach the present or any finitely remote past point you care to identify. This is problematic given that any step k is succeeded by k + 1, etc, leading to an inherently finite successive pattern of cumulative steps -- something you and the sources you cite appeal to in claiming that all natural numbers are finite.* Substituting inherently finite spans of discrete cumulative steps across the finite past does not succeed in replacing or removing that challenge. You have acknowledged the inherent finitude of stepwise processes and thus by implication the impotence of same to span the transfinite range that is required. In short, the processes you accept do not have the power to address the challenge in hand, spanning the transfinite. KF PS: Hilbert's Hotel shows, spectacularly, why the abstract infinite would be utterly infeasible in the physical world. A full hotel [which means every room is occupied] that by reassigning rooms suddenly can hold a further infinity of guests? A manager able to inspect all the rooms in finite stepwise succession down to the reception hall and desk? [We call that room 0.] Workers able to build and complete it room by room? Where, physical feasibility is a constraint on physical actuality. * I agree that any number we actually reach or exceed by step by step counting is finite, but am concerned that the span of counting numbers is in principle unlimited in range thus transfinite. The ellipsis -- . . . -- may inadvertently disguise that a transfinite range thus a potential transfinite span rather than an actually traversed one, has been put into the discussion. The ordinals gives us a way to discuss this, and that is what I used above and previously. 1/m = A where A is also w + g, beyond the first transfinite ordinal and is of cardinality aleph null arises in that context as a way to put in symbolic terms the issue of concern. kairosfocus

GG, nothingness in this context means non-being. Not matter, not energy, not time, not laws and forces, not mind. We may indeed profitably discuss levels in potential field and conservation but energy in physics is never in itself a negative. As one clue notice how kinetic energy is associated with a velocity squared term, the mass-energy relationship depends on speed of light squared, and in the force-displacement dot product formulation dW = F dot dx work signs do not split into something from nothing but into energy flows from one type to another. Ponder in this context energy conservation. KF Algebra: 0 = R - R, rearranged R = R. This is little more than the RHS restates the same value and kind as the LHS. This does not flash such into physical actuality. An equals sign has no power to create. Especially, something from nothing. (Perhaps, inadvertently, we should see that it is a thought, pointing to a mind reflecting on logical-quantitative and structural relationships. A mind is something creative and in theism God is the ultimate creative Mind!) kairosfocus

Mapou, we are dependent on a past causal succession that has led to the present. While time is evidently unidirectional and so far as we see open ended to the future, we may and do profitably wish to ponder that past by moving backwards in analytical thought. Not least as the weight of that cumulative past informs us about underlying regularities of behaviour, trends and values of key parameters that can guide us in acting now to favourably shape the future. KF kairosfocus

Querius:

the sum allows us to move backward in time

Motion in time is an absurdity. It's not even wrong. Mapou

Let's see what a physicist at the University of Nottingham does with an infinite number series . . . https://www.youtube.com/watch?v=w-I6XTVZXww Then, as you can clearly see from the math (which is used in string theory) that if we assign a billion years for each number, the sum allows us to move backward in time! o.O -Q Querius

Infinity is a religion of cretins. Just saying. Mapou

Uh, no. The part after the second “or” does not follow. You just went from -R to +R with no justification at all.

I admit to not being a math-wiz. And creating two opposites of something from nothing using the equation 0=R-R where (R is not equal to 0) is in a way oversimplifying. But then again in works in math so who knows? If you are good at showing all the possible ways to substitute the equation variables then please show me what you find. At least in computer logic it's the start of a very simple oscillation that (with no forever increasing Time variable) would go forever into infinity, if it were not for power blackouts and computers not being expected to be able to stay going that long. GaryGaulin

Lessee, what would it be like to live in a universe that's infinitely old? - Due to inflation, many stars would be infinitely far apart - There would be an infinite number of dead stars filling up space, blocking out the light from new stars - There would have to be a way that new stars would spontaneously appear, and at a rate consistent with cosmic inflation - The entropy of the universe would be maximized, just below the rate of new stars magically appearing from somewhere - Everything that could have happened happened already - Science would finalize its divorce from reality, and evolve into a system of whose sole purpose is to rationalize observations into a philosophically acceptable narrative for atheists - The Multiverse hypothesis could be abandoned as redundant - A lot of people would have to apologize for arguing that if God exists, who created God. It's turtles, gods, and stars all the way down. -Q Querius

JDH, Would you please point out my mathematical errors then? daveS

daveS At this point in the debate with KF, you have had many people ( some with advanced degrees in math ) try to explain this to you. It is clear you don't understand the concept. It may be an assumption of mine, but I assume you are also a naturalist. You are not helping your cause by showing how dogmatically you can hold a position, even when others can see that your position is not true. JDH

Gary writes,

0=R-R or: -R=0-R or: +R=0–R

Uh, no. The part after the second "or" does not follow. You just went from -R to +R with no justification at all. I have no idea what the point is, but that is wrong. Aleta

KF, I know my thoughts on this are an oversimplification but it makes sense math-wise, and might contain a clue for you to work on. Energy to achieve maximum Radius of universe is mathematically possible from nothing (zero) by separating the nothingness into equal positive and negative halves: 0=R-R or: -R=0-R or: +R=0--R = +R=0+R The phase Angle (one Radian or 0 to 360 degrees each) is analogous to time but only repeats itself in cycles, as opposed to a continuous timeline. In 1D is a sine wave: X=Cos(A)*R Adding Y for 2D makes a circle: Y=Sin(A)*R Adding Z for 3D makes a sphere. Calculate X,Y,Z using your favorite spherical coordinate formula or matrix math. The law of conservation of energy is not violated. Only thing required is that nothingness cannot exist without some wave forming imbalance that we in turn perceive as a universe containing matter and antimatter. GaryGaulin

KF, I have simply been saying that a clock ticking throughout an infinite past up to the present cannot be defeated using simple cardinal arithmetic. That's really in essence identical to this Hilbert Hotel example, which I have just explained. I don't know if that counts as "spanning the transfinite with the inherently finite", but it's all I have been asserting. daveS

DS, how do you span the transfinite with the inherently finite? KF kairosfocus

KF, PA system?? Smart phone?? We don't need to get into that. Obviously this hotel is not physically realizable, but that's not the point. The manager was in room -n n seconds ago, for all natural numbers n. He completed the inspection of every single room just now. I don't know if that's what you call "spanning the transfinite", but it's quite parallel to the clock example. You can't show it's impossible just based on cardinalities. daveS

DS, being in room n, n seconds past does not bridge to reaching the front desk at 0 when we deal with the transfinitely remote rooms; when also the inspection process is a finite step by step process. And that does not get into the problems of managing the suggested actual hotel as a whole that are independent of his inspection tour. Assume he has a smart phone and a PA system that reaches every room, with an assistant at front desk. Infinitely many new guests arrive and he is full but by asking guests in room -n to go to room 2n suddenly he can put the new ones into 2n - 1, and yet will have the same number of guests after such a move. And so forth. KF. kairosfocus

KF, Gotta run. In the scenario I described above, the manager was in room -n n seconds ago, for each natural number n. Given any room in the hotel, I can tell you when he was there. daveS

DS, Yes a manager can span the finite in finite time. But the issue is to span the proposed transfinite with an inherently finite stepwise process. KF kairosfocus

DS, do you not see that a transfinite span to 0 then runs into a problem when it is to be spanned by an inherently finite process? KF kairosfocus

KF,

I point out that what holds a finite value cannot at the same time be a transfinite span from the origin, 0.

Yes, that's something I've been saying all along. Again, put all this together and run it by vjtorley, please. Edit: Re: your HH explanation: If the manager was in room number -100 one hundred seconds ago, he arrives at the desk now. daveS

PPS: More reading, HT Niw: http://www.reasonablefaith.org/god-and-cosmology-the-existence-of-god-in-light-of-contemporary-cosmology kairosfocus

DS, I note to you that if you wish to define "all" integers as finite -which then raises serious concerns on then claiming the cardinality of the set of integers is transfinite if such be applied -- a finite integer must needs be a finite span of "units" or steps from 0 -- that does not remove from the table the span of ordinal whole numbers suitable for counting sequences. That is why I have latterly stayed strictly away from appealing to "natural numbers" and "integers." I point out that what holds a finite value cannot at the same time be a transfinite span from the origin, 0. Likewise, no finite span of steps will be able to traverse the transfinite span. The challenge remains, to traverse the transfinite in a stepwise process that rests on finite stages. Assertions about at a given time it stands done do not answer the issue. Hence my use of A above. KF PS: For HH, simply revert to negatively numbered rooms, so the regression is open ended in the opposite to usual direction: . . . -2, -1, 0. Each room is now a second, say, and the tenant in it the events thereof. Has anything fundamental about the problems of actualising such a hotel changed? Try, the manager inspects each room in turn, and has been doing so forever at a rate of one per second. When does he arrive at the front desk, 0? Or imagine, builders are building the rooms at one per day forever, when will they get to building the front desk? (Can they reach room 0 from room w + g, aka room A, which is transfinitely remote from 0, given that a day by day sequence of room builds is inherently finite? Does building A, A~1, A~2, . . . in sequence [an inherently finite process] arrive at 0 by traversing the transfinite distance to 0? Where the span to 0 is endless?) kairosfocus

See also my UD article: https://uncommondescent.com/?s=%22the+dissolution+of+today%22 niwrad

The HH example involves a customer attempting to enter the full hotel, so there is a starting point. And recall:

And the point that from any moment in the infinite past there is only a finite temporal distance to the present may be dismissed as irrelevant.

WLC affirms that "from any moment in the infinite past there is only a finite temporal distance to the present". As I mentioned in the other thread, I'll step back and let others discuss. If vjtorley is interested in addressing these arguments involving transfinite natural numbers and finite numbers of "order aleph-null", then I for one would like to see it. daveS

DS, nope he has not done so, but made a statement for sake of argument that shuts out a side discussion that we are now having. I repeat, I am quite concerned that any proposed bridging from a transfinitely remote point -- not the beginning of the whole, but a point that is ordinally subsequent (as illustrated) -- to the present that suggests that a finite and completed sequence attains the present is questionable or even contradictory. Is the zone bridged transfinite? If yes, no finite sequence of steps can completely bridge it to 0. Is the zone in question one that has been bridged by a FINITE and now completed sequence to now? If yes to this instead, obviously the bridged span is just as FINITE not transfinite. What looks very much like trying to have the cake and eat it too is to propose that a TRANSFINITE span has been bridged by a FINITE, completed step by step descent. KF kairosfocus

Yes, I read the HH discussion. It presumes a starting point, so it doesn't parallel my clock example, which has none. daveS

KF, First notice this:

And the point that from any moment in the infinite past there is only a finite temporal distance to the present may be dismissed as irrelevant.

That may be irrelevant to their discussion, but is quite central to ours. WLC agrees with me in that any point in the infinite past is only finitely distant temporally to the present.

The question is not how any finite portion of the temporal series can be formed, but how the whole infinite series can be formed.

I assume that a deity who exists outside of time would be able to form such a series. Do you think that even God could not arrange this? daveS

DS, have you actually read the discussion of HH? An infinite number of past seconds occupied in succession by events fits right in. And I have just put up a PS on spanning the transfinite. KF PS: Note, my point of concern has always been, that to count up to or down from infinity the transfinite would have to be spanned in step by step finite succession, leading to an impossibility. kairosfocus

PS: Particularly observe:

Against (2.21), Mackie objects that the argument illicitly assumes an infinitely distant starting point in the past and then pronounces it impossible to travel from that point to today. But there would in an infinite past be no starting point, not even an infinitely distant one. Yet from any given point in the infinite past, there is only a finite distance to the present.[16] Now it seems to me that Mackie's allegation that the argument presupposes an infinitely distant starting point is entirely groundless. The beginningless character of the series only serves to accentuate the difficulty of its being formed by successive addition. The fact that there is no beginning at all, not even an infinitely distant one, makes the problem more, not less, nettlesome. And the point that from any moment in the infinite past there is only a finite temporal distance to the present may be dismissed as irrelevant. The question is not how any finite portion of the temporal series can be formed, but how the whole infinite series can be formed. If Mackie thinks that because every segment of the series can be formed by successive addition therefore the whole series can be so formed, then he is simply committing the fallacy of composition.

kairosfocus

KF, It's not clear to me that he impossibility of the existence of Hilbert's Hotel implies the impossibility of the existence of an infinite past. "Things" is a pretty general term. But, at least WLC's argument is not based on mathematical misunderstandings, I will say. daveS

DS, I suggest you read here http://www.leaderu.com/truth/3truth11.html for an outline of Craig's Kalam argument and for some elaboration of the following skeleton outline, and notice how Hilbert's Hotel is applied:

1. Whatever begins to exist has a cause of its existence. 2. The universe began to exist. 2.1 Argument based on the impossibility of an actual infinite. 2.11 An actual infinite cannot exist. 2.12 An infinite temporal regress of events is an actual infinite. 2.13 Therefore, an infinite temporal regress of events cannot exist. 2.2 Argument based on the impossibility of the formation of an actual infinite by successive addition. 2.21 A collection formed [--> note tense, denoting completion] by successive addition cannot be actually infinite. 2.22 The temporal series of past events is a collection formed by successive addition. 2.23 Therefore, the temporal series of past events cannot be actually infinite. ________________ 3. Therefore, the universe has a cause of its existence.

KF kairosfocus

PS: For further thought, Tim Holt, http://www.philosophyofreligion.info/theistic-proofs/the-cosmological-argument/the-kalam-cosmological-argument/maths-and-the-finitude-of-the-past/ :

three mathematical arguments for the finitude of the past will be outlined. The first argument draws on the idea that actual infinites cannot exist, the second on the idea that actual infinites cannot be created by successive addition, and the third on the idea that actual infinites cannot be traversed. If any of these arguments is successful, then the second premise of the kalam arguments will have been proven. The Impossibility of an Actual Infinite The first mathematical argument for the claim that the universe has a beginning draws on the idea that the existence of an infinite number of anything leads to logical contradictions. If the universe did not have a beginning, then the past would be infinite, i.e. there would be an infinite number of past times. There cannot, however, be an infinite number of anything, and so the past cannot be infinite, and so the universe must have had a beginning. Why think that there cannot be an infinite number of anything? There are two types of infinites, potential infinites and actual infinites. Potential infinites are purely conceptual, and clearly both can and do exist. Mathematicians employ the concept of infinity to solve equations. We can imagine things being infinite. Actual infinites, though, arguably, cannot exist. For an actual infinite to exist it is not sufficient that we can imagine an infinite number of things; for an actual infinite to exist there must be an infinite number of things. This, however, leads to certain logical problems. The most famous problem that arises from the existence of an actual infinite is the Hilbert’s Hotel paradox. Hilbert’s Hotel is a (hypothetical) hotel with an infinite number of rooms, each of which is occupied by a guest. As there are an infinite number of rooms and an infinite number of guests, every room is occupied; the hotel cannot accommodate another guest. However, if a new guest arrives, then it is possible to free up a room for them by moving the guest in room number 1 to room number 2, and the guest in room number 2 to room number 3, and so on. As for every room n there is a room n + 1, every guest can be moved into a different room, thus leaving room number 1 vacant. The new guest, then, can be accommodated after all. This is clearly paradoxical; it is not possible that a hotel both can and cannot accommodate a new guest. Hilbert’s Hotel, therefore, is not possible. A similar paradox arises if the past is infinite. If there exists an infinite past, then if we were to assign a number to each past moment then every [counting] number (i.e. every postive integer) would be assigned to some moment. There would therefore be no unassigned number to be assigned to the present moment as it passes into the past. However, by reassigning the numbers such that moment number one becomes moment number two, and moment number two becomes moment number three, and so on, we could free up moment number one to be assigned to the present. If the past is infinite, therefore, then there both is and is not a free number to be assigned to the present as it passes into the past. [--> notice the link to Hilbert's Hotel] That such a paradox results from the assumption that the past is infinite, it is claimed, demonstrates that it is not possible that that assumption is correct. The past, it seems, cannot be infinite, because it is not possible that there be an infinite number of past moments. If the past cannot be infinite, then the universe must have a beginning. This is the first mathematical argument for the second premise of the kalam cosmological argument. The Impossibility of an Actual Infinite created by Successive Addition The second mathematical argument for the claim that the universe has a beginning draws on the idea that an actual infinite cannot be created by successive addition. If one begins with a number, and repeatedly adds one to it, one will never arrive at infinity. If one has a heap of sand, and repeatedly adds more sand to it, the heap will never become infinitely large. Taking something finite and repeatedly adding finite quantities to it will never make it infinite. Actual infinites cannot be created by successive addition. The past has been created by successive addition. The past continuously grows as one moment after another passes from the future into the present and then into the past. Every moment that is now past was once in the future, but was added to the past by the passage of time. If actual infinites cannot be created by successive addition, and the past was created by successive addition, then the past cannot be an actual infinite. The past must be finite, and the universe must therefore have had a beginning. This is the second mathematical argument for the second premise of the kalam cosmological argument. The Impossibility of an Actual Infinite that has been Traversed The third mathematical argument for the claim that the universe has a beginning draws on the idea that actual infinites cannot be traversed. If I were to set out on a journey to an infinitely distant point in space, it would not just take me a long time to get there; rather, I would never get there. No matter how long I had been walking for, a part of the journey would still remain. I would never arrive at my destination. Infinite space cannot be traversed. Similarly, if I were to start counting to infinity, it would not just take me a long time to get there; rather, I would never get there. No matter how long I had been counting for, I would still only have counted to a finite number. It is impossible to traverse the infinite set of numbers between zero and infinity. This also applies to the past. If the past were infinite, then it would not just take a long time to the present to arrive; rather, the present would never arrive. No matter how much time had passed, we would still be working through the infinite past. It is impossible to traverse an infinite period of time. Clearly, though, the present has arrived, the past has been traversed. The past, therefore, cannot be infinite, but must rather be finite. The universe has a beginning.

More points to ponder. kairosfocus

KF, As I said, I am just noting that I agree with WLC on the issue of an infinite past. He does not claim anywhere in the quote that it is impossible. Certainly not based on cardinality grounds. Regarding your construction, there are no large finite numbers g "of the scale aleph null". I don't have to read any further after that error. Why don't you contact WLC and ask him to review your argument? daveS

DS, no step by step completed process of cause-effect [including a counting succession] can but be finite. It will therefore fail to span the transfinite. For many good reasons, reasons reflected in the assertion of those who form natural, counting succession numbers by incrementing, that all naturals are finite. (My concern is that an ordinal succession can be defined and if it is of transfinite scale -- endless -- not all members can actually be reached by completed counts. As opposed to, we can point out how to reach them in principle.) When Craig states "there never will be an actually infinite number of events, since it is impossible to count to infinity" he has elsewhere specifically identified a succession of seconds as relevant events for this. He is not in disagreement -- but per the Kalam cosmological is famously in agreement -- with Durston when the latter states:

an infinite real past requires a completed infinity, which is a single object and does not describe how history actually unfolds. Second, it is impossible to count down from negative infinity without encountering the problem of a potential infinity that never actually reaches infinity. For the real world, therefore, there must be a first event that occurred a finite amount of time ago in the past . . .

But the issue is not so much who agrees/disagrees but what is warranted. And, what is warranted is that step by step finite succession cannot bridge to the transfinite. This is easiest to see starting at 0 and counting up, but it is patent that bridging the transfinite the other way to appear at the present has to bridge the same span. That is why I went to lengths to identify a reasonable ordered succession 0, 1, 2 . . . [TRANSFINITE SPAN] . . . w, . . . w + g . . . and identify that A = W + g, a transfinite with w the first transfinite ordinal and g some large finite [so still of the scale aleph null] will be such that in a descent . . . A, A~1 [= w + (g - 1)], A ~ 2, . . . 2, 1, 0, 1*, 2* . . . n, n being now, we see A, A~1 [= w + (g - 1)], A ~ 2, . . . 0, 1#, 2#, . . . and so we run into a transfinite bridge and the count down will not reach from A to 0, no more than it can reach up from 0 to A. The causal, finite step by step succession of the past will inherently be finite, strongly grounding the conclusion that the past was finite. KF kairosfocus

Well, I can tell you it has exhausted me! ;-) daveS

daveS: ...which we have discussed exhaustively with no progress. Actually, that never happened. Mung

Dave @3 That is why I always bring in the Biblical concepts of time found in God. To me that is the only solution and end of the argument. The old "If something exists now, then something must have always existed." axiom. I cannot believe I have had people tell me that it is a false statement. jimmontg

KF, I think Craig and I are in agreement, at least regarding a "beginningless" or infinite past. For example:

So when we say that the number of past events is infinite, we mean that prior to today ℵ0 events have elapsed.

Durston, however, makes the erroneous assumption that an infinite past implies counting down from infinity to 0, which we have discussed exhaustively with no progress. daveS

Only God has an infinite past if there are even any words to explain where God is, as where He is(in Himself) must be timeless and is not subject to time until He took on human form and only in that sense can it be said God is subject to time because He took time into Himself. We have no linguistics or true comprehension of how this can be, the Kenosis. The emptying of his Deity to become a man. One only has to have faith that the Great I AM is a reality and He is visible in Jesus of Nazareth. Part of God's name He gave Moses "I AM THAT I AM" is part and parcel of Moses' description of God as "From Everlasting to Everlasting Thou art God." We simply cannot comprehend this, it is beyond any temporal creature even Angels. This is a part of the ontological argument for God that Anselm spoke about in his God as the greatest conceivable Being argument I believe. I am of the opinion that this whole subject and the fact that we can even conceive of a God from Everlasting and speak about Him in any meaningful way shows that we are no mere end product of materialist descent. We came from an Eternal God who in some way imprinted His Image on us. The Imago Dei. jimmontg

Durston and Craig on a claimed infinite actual past. kairosfocus