Imagination and the Unreasonable Effectiveness of Mathematics by Armin Nikkhah Shirazi

Hi Armin,

I responded to your "kind and heartwarming" comments regarding my Digital Physics movie essay in the discussion forum on my page. I also had some thoughts on your Copenhagen Interpretation youtube video which I included in my response.

Thanks for reading my essay and your interest in the movie! Your FQXi essay, as opposed to more of your youtube videos, will be the next thing I will be taking a look at and commenting on.

Thanks again,

Jon

Dear Armin,

Thanks for starting at this point, especially as some "local realists" tend avoid it.

I trust we agree that all Nature's extant objects have actual and potential properties?

We then note: Bohr says, "the result of a 'measurement' (with scare quotes) does not in general reveal some pre-existing property." Thus, if I send you a randomly polarised particle, its interaction (without scare quotes) with your polarising apparatus will produce (P>0) a new orientation of polarisation; which is NOT the same as revealing a pre-existing one. Rather

ACTUAL POTENTIAL -> INTERACTION -> NEW ACTUAL NEW POTENTIAL.

This is my reason for linking Bohr's view here (not elsewhere) to your own.

BUT now we must clean up these intuitive ideas MATHEMATICALLY.

So, taking care with Nature, we hold a consequence of realism to be: 'At all times, the set of actual properties possessed by a system (here, particle plus apparatus)* fully determines all relevant probabilities of potential properties of the system.' See paragraph #2.1, etc., in my essay.

* Including my sister's cat in the system if it might be relevant!

Armin, in closing, and subject to some refinements, I trust we are close to agreement here? More questions, please, if we are not.

With best regards; Gordon Watson: Essay Forum. Essay Only.

Armin, I've added this note here to facilitate continuity in our discussion:

Discussion on the above components of this thread continues here.

With best regards; Gordon Watson: Essay Forum. Essay Only.

Dear Armin,

Thanks for the exchange. It gives me a kind of pleasure when my "opponents", wriggle and wreathe trying to explain a question in a convoluted kind of way because of a belief that they must not let go a dogma they are holding on to. When I say opponent, I mean it in a friendly way.

An example of this wriggling is that: "the relation, distance travelled/ time taken does not apply to light speed"! Roemer, Galileo, Newton, Maxwell would probably convulse in their graves :)

Then, in addition "light IS NOT something that is traveling in space", "photons do not have definite trajectories", "you cannot apply the notion of distance per time to the speed associated with their "travel".

This new doctrine is thus meant to replace what we know about the rectilinear propagation of light, how light is focused by a lens at a focal point without any probability that the focal point will change, etc.

So as not to cause a distraction from your essay, may I just ask one more question and we can continue this outside your essay forum.

Given a light source, e.g. a pulsar say 10^3 light seconds away, and sending out pulses once every 60 seconds, such that the moment a pulse is detected, another is already emitted and on on its way and would be detected also after 60 seconds. So we have detections every 60 seconds. Now if, on detecting a pulse, the observer moves towards the next incoming pulse, can he reduce the detection time to 59 seconds? Again, if on detection, the observer moves away from the already incoming and in-flight photon, can he delay the detection time to 61 seconds?

Why I frame the question this way is that the fundamental issues under contention between Galilean relativity and SR are easily mixed up or swept under the carpet, the same way Bekenstein has swept your photon existence paradox under the carpet.

Your answer to these framed question will indicate whether you appreciate what SR doctrine really means to physics and what is under contention. At your free time crosscheck that the Einstein quote I send is correct (about the validity of SR depending on earth motion not influencing optical phenomena).

All the best,

Akinbo

*If you don't mind can you find any fault in the math used by Gordon Watson. You are better than me at math. I note you have made some non-mathematical comments.

Dear Armin,

I also belief, that the distinction between actuality and possibility is needed to give a consistent interpretation of quantum mechanics. In my essay - following Carl Friedrich von Weizsäcker - the time structure is essential. The past being factual (something has happened or not), the future being possible. Mathematics is then the imagination of possible acts in the future, which would lead to a constructivistic justification of mathematics. What role plays time in your theory?

I'd would be happy you could read my essay and comment on it.

Many thanks

Luca

Hi Armin,

I must admit, learning a new form of logic is difficult, but I still want to ask you some questions even though I did not grasp all of your essay.

Do you think in your model where you consider a quantum 2-D object which has the potential to become a 3-D object (instead of a 3-D object with one dimension consisting of every possible value) you could still account for interference patterns as seen in the double slit experiment?

Your talk about our freedom to choose consistent axiom systems made me think about how certain propositions may not be provable in certain axiom systems, but may be provable in others. Have you seen Stephen Wolfram's work where he talks about enumerating different axiom systems and showing what theorems are provable under each? There's a lot of overlap in what theorems are provable in each consistent axiom system, but there are still some differences. How do you think this relates to your view that the "freedom to choose one's axioms coupled with the requirement of consistency should naturally lead us to expect mathematics to be unreasonably effective in modeling reality, but that this unreasonable effectiveness only exists, as it were, as an actualizability until human imagination transforms (parts of) mathematics into an actually effective model of reality."?

You talk of ZFC (and your ZFCD)... Do you think the axiom of choice is reasonable axiom in a system that contains real numbers which are uncomputable? How could one actually choose one of these uncomputable reals, if they cannot be specified in a finite way. Unlike computable real numbers like pi and e, most real numbers cannot be referred to in an algorithmic way because they have uncompressible information, so therefore there is no finite way to refer to them. Maybe this is where your thoughts on "imagination" comes in?

Also, is ZFCD trying to be a meta-mathematical theory that tries to explore the ramifications of an incomplete system being consistently extended, from a general perspective?

Is what you describe as "pro-actually" a form of determinism, where what you define as "actualizably" a more probabilistic view of the future? How would you view the question of whether a 10,000 digit number was prime or not from this perspective?

You said:

"Thus, the context can be interpreted as a sample space and the measure associated with the "collapse" of actualizabilities (i.e emergence of an actual outcome) in the absence of an e-spec is just what we call probability. This measure is different from non-probabilistic measures because it is over a set in the outer domain, and thereby captures the concept of probability."

Is this related to the idea that something may be considered probabilistic until a proper fully-predictive theory is found? Is it related to the mathematical fact that we don't know if we are up against a true and unprovable statement or if we just haven't done enough searching to find a proof? Is something that is undecidable, probabilistic from this point of view? Are you familiar with Gregory Chaitin's omega constant?

I think you might have some interest in some of the questions I posed at the end of my essay. Somehow many of them seem very relevant to your work. Please consider taking a crack at answering one of them.

Thanks,

Jon

Dear Armin,

You commented upon my paper so early in the process that I've been under the impression that I had read your essay and commented on it. I see that is not the case. As you've recently returned to offer valuable suggestions, I thank you for those and offer my views on your essay.

You begin by extolling the freedom to choose one's starting assumptions as a great virtue of mathematics, limited only by consistency. You then note that the ZFC is generally regarded today as the foundation of mathematics, yet it is not known with absolute certainty that it is itself consistent.

Your own contribution, which you label tentative, is based in "free logic" which, as I understand it, deals with the context of potentiality 'surrounding' the inner logic of things that 'exist', with the key operators being: 'Possibly', 'Actually', and 'Necessarily'. Based on these you formulate the Axis of Default Specification intended to extend the ZFC to handle "incompleteness".

Your first example is designed to illustrate the use of these terms leading to an "emergence specification" which

"Collapses" the superposition of actualizability to permit the emergence of the actual element,"

which of course is the relation to the "quantum mechanics" in the title of your essay, and you say

"The measure associated with the "collapse" of actualizability ... is ... probability."

You then discuss contextuality in the context of the Peres-Mermin Magic Square which [as I understand it] is a special case of Peres table 6-1 [page 167] of 'Actual and hypothetical outcomes of N quantum tests", in which he claims that none of the possible 'filled in tables' obey the cosine correlation. He then [page 197] proves the Kochen-Specker theorem using 33 vectors in R^3.

You note "the quantum mechanical situation invoking commuting spin operators" involves e-specs. As I develop these operators in my endnotes [and in more detail in my reference [2]] it is clear that this idealization of spin as a 'qubit' or two-state system leads to non-intuitive results and much of the mysticism of QM is traceable to this idealization.

As QM is based on analysis of outputs, and a "good" experiment is generally one with discrete output states, the apparent fact that all measurements based on constant magnetic field tend to satisfy this "two-state" requirement is, in some respects, a "self-licking ice cream cone".

My essay, of course, asks what happens when this overly simple characterization of spin is loosened. You recall that "the quantum state is a superposition state" which is also fascinating, given Matt Leifer's contention (also quoted in my endnotes) that, in 2015, we don't know what a quantum state is, whether it is ontological or epistemological. Yet, in our math formulas, we are free to superimpose whatever they are! And then to talk about the "collapse" of the superposition.

You state the current consensus, that "the quantum correlations between the particles go beyond what is possible in any classical arrangement, and this was proven in a theorem by Bell."

Of course my essay claims that Bell's "proof" is a mathematio-logical proof based on over-simplified physics. Even his basic model, before getting into the proof, is contradictory, as he assumes a constant field which yields zero, while he requires ±1 results. But you know this.

In short, given the false conclusions (in my opinion) of the Bell theorem, you have performed an admirable analysis of the logic necessary to support or explain these false conclusions.

You comment on my thread that to seriously consider my argument, one must be willing to question the 90 year interpretation of Stern-Gerlach. Yes indeed. The current state of confusion in quantum mechanics is such that, if after almost a century the early ideas have not yet led to clarity [I don't consider Kochen-Specker's 33-ray proof in any way 'clear', with respect to physical reality] it may well be time to revisit both the experiments, with century newer technology, and the early ideas and concepts of spin -- essentially unchanged since Goudsmit and Uhlenbeck.

Finally, as you end your essay with a discussion of the Feynman path integral, the basis of which is the progression from state n-1 to state n [see your theorem, post equation 6 on page 8] I would call your attention to the second diagram on page 10 in my essay which links the generalized automata-representation I develop in The Automatic Theory of Physics to a Feynman quantum field theory kernel, and show the equivalence of the "next-state-address" in the automata to "potential" in standard physics. This is a novel identification that you may or may not find interesting.

My very best regards,

Edwin Eugene Klingman

Hello Armin,

I smell a 'dialectic' bait meant to entrap me and I am in a dilemma whether to swallow the bait or not :)

I was therefore forced to Google "wavelength" and came up with these:

*Wavelength is the distance between identical points in the adjacent cycles of a waveform signal propagated in space or along a wire.

*In physics, the wavelength of a sinusoidal wave is the spatial period of the wave-- the distance over which the wave's shape repeats,[1] and the inverse of the spatial frequency.

Asking whether I hold this definition to be exact or not will certainly take us into debate whether light is wave or particle or both. It would also take us into whether a medium of propagation is present or not. While not shying away from debating those contentious territories, it would becloud the fundamental basis for the validity of SR where we started this discussion from. To repeat;

Einstein himself says, "But ALL experiments (without exception) have shown that... optical phenomena, relatively to the earth as the body of reference, ARE NOT influenced by the translational velocity of the earth...". Do you agree?

Now, if your only condition to answer the question is my response, then I confirm that to almost all intents and purposes I hold the definition to be exact!

Regards,

Akinbo

*In addition to the links on this thread, I thought I linked Herbert Dingle's book but I obviously must have done so elsewhere. SCIENCE At the Crossroads. Read these links critically and you will understand my excitement about photon existence paradox and the lack of interest by the establishment in your paradox.

Armin,

You are a veritable and formidable opponent. Perhaps, you should have been invited to Copenhagen when Bohr and Einstein were debating...

I cannot swallow what non-commutation relations of QM, to the extent that QM is valid ONLY IF special relativity is valid. So yes, I reject the version of QM that is founded on SR. The experimental successes of QM must therefore have alternative explanations. There can be more than one explanation for an experimental result with one of them being the eventually correct answer.

Read, Pentcho's latest post on Faster than Light concerning what the postulate of SR we are finding contentious means.

Regards,

Akinbo

Dear Jon,

Thank you for your comments and for your questions. I will try to answer them as best as I can. Keep in mind that I have not yet completely worked out everything, but I like to think that I am close.

"Do you think in your model where you consider a quantum 2-D object which has the potential to become a 3-D object (instead of a 3-D object with one dimension consisting of every possible value) you could still account for interference patterns as seen in the double slit experiment?"

The mathematical model alone cannot do this because it doesn't explain 1) where the phase factor comes from and 2) How the double slit potential is to be modeled.

However, if you combine the mathematical model with the physical model I presented at my talk in Vaxjo, then I believe it is in principle possible because the physical model supplies basis from which one can get both: The phase factor comes out of a postulated mechanism that compares the passage of time in areatime to the passage of time in spacetime, and the potential corresponds to where you set your point of origin in the abstract plane formed out of the two proper times. I say "in principle" because I have not yet performed the calculation, as I have been still focused on much more basic issues in my framework.

"Have you seen Stephen Wolfram's work where he talks about enumerating different axiom systems and showing what theorems are provable under each?"

No, I was unaware of Wolfram's work in this area. I just read the linked talk and found it very interesting. Essentially, it appears he has taken this idea of exploiting the freedom of choosing axioms several steps further. I think that this work has the potential to be very useful in mathematics, but because the space of possible axioms is infinite, you will still need something like imagination to pick out the most useful ones. Reading his talk made me wonder whether it will ever be able to simulate imagination in machines. I think that would be both a profoundly exhilarating and terrifying prospect. HAL had imagination.

"There's a lot of overlap in what theorems are provable in each consistent axiom system, but there are still some differences. How do you think this relates to your view that the "freedom to choose one's axioms coupled with the requirement of consistency should naturally lead us to expect mathematics to be unreasonably effective in modeling reality, but that this unreasonable effectiveness only exists, as it were, as an actualizability until human imagination transforms (parts of) mathematics into an actually effective model of reality."?"

Remember, we are talking about modeling nature, that is, we are talking about something within the realm of physics. As a physicist, I really don't care that much which axiom system to use as long as it serves as a foundation that gives me the desired model of the world that has the qualities that I desire: Above all, predictions that match real world observations, but also conceptual clarity, relative simplicity of the calculations, and some elegance wouldn't hurt either. Most physics models are several layers separated from the axiomatic foundation of mathematics. In that sense, I would say my work is atypical. But that is the direct result of trying to incorporate a new distinction into mathematics which beyond the level of logic, and possibly some poorly explored models of set theory simply didn't exist. I must admit that until about 1.5 years ago, when I first started the effort of learning about these formal systems, I was not all that interested in mathematics for its own sake.

"You talk of ZFC (and your ZFCD)... Do you think the axiom of choice is reasonable axiom in a system that contains real numbers which are uncomputable?"

Well, I can live with non-constructive proofs, and I can live with the Banach-Tarski paradox. I think my pragmatic physicist side is showing its side when I admit that I prefer a more powerful formal system over a less powerful one, even if, as a side effect, it proves to be sometimes "too powerful" because it allows you to derive highly non-intuitive results. The cap on this is of course provided by consistency. I don't want a system that is so "powerful" that you can prove literally anything at all. Incidentally, I am certain that once the formal system I am working out is complete, there will be highly counterintuitive implications lurking in the background, waiting to be discovered.

"How could one actually choose one of these uncomputable reals, if they cannot be specified in a finite way."

Actually, Wolfram's work to which you pointed me might be a possible way to do it. If Wolfram's system could be used to enumerate many different very similar but not identical set theoretic models based on the enumerated axiom system, perhaps it might be possible to devise an algorithm which chooses the model in which you can approximate the number to the desired level of precision. The analogy that pops into my mind is that of traditional musicians and filmmakers, who use notes and individual frames, respectively, as a their basic building blocks, whereas "mash-up artists" use entire blocks of these as their basic building blocks.

"Maybe this is where your thoughts on "imagination" comes in? "

Most definitely, I believe devising any sort of algorithm from scratch for a particular purpose requires at least a modicum of imagination.

"Also, is ZFCD trying to be a meta-mathematical theory that tries to explore the ramifications of an incomplete system being consistently extended, from a general perspective?"

I don't think so. ZFCD is a set-theoretical model, and all the relevant propositions pertaining to incomplete systems are made within it, where I assume by "incomplete system" you mean objects such as incomplete pairs etc. However, ZFCD may well have metamathematical (as well as metaphysical) implications, because the lintroduction of the formal distinction between actuality and potentiality into established mathematics is (at least in my totally biased opinion) a very important and largely unexplored area.

"Is what you describe as "pro-actually" a form of determinism, where what you define as "actualizably" a more probabilistic view of the future?"

Well, you have the right idea, but I wouldn't put it quite that way. I would say, as a conjecture, a world is deterministic iff in this world every actualizability at every moment is a proactuality. Actualizability is the more general concept which captures the ontological distinction; pro-actuality is a more specific concept which applies it to the context where the actualizability could most easily be confused for actuality. For instance, someone thinking that measuring some property of one of an entangled pair of particles causes the other to "have" the corresponding property at that moment reflects, in my opinion, such confusion.

"How would you view the question of whether a 10,000 digit number was prime or not from this perspective?"

As you asked it, without any further qualification, I would interpret the question to ask about an actuality because numbers, without further qualification, are abstractions of objects in the inner domain. If you had asked me "suppose this number was in the outer domain", then my answer would be that you are asking about a proactuality, because numbers in the outer domain are abstractions of objects in the outer domain, and no elements of the outer domain are "actual".

"Is this related to the idea that something may be considered probabilistic until a proper fully-predictive theory is found?"

No, I meant to simply point out that what distinguishes probability from non-probabilistic measures is this aspect of "coming into existence" that the others lack. As you know, Kolmogorov's axioms are not sufficient to capture the concept of probability. There is no way you can conceptually frame a unit length or a unit mass as a measure of "coming into existence". But that is not the fault of probability theory, because it just works with the sets that it is given by the set theoretical model. That is why I think that the outer domain is an important addition to set theory: It is exactly the home of the probability measure. The claim that "something may be considered probabilistic until a proper fully-predictive theory is found" strikes me as far too metaphysical for mathematics.

Is it related to the mathematical fact that we don't know if we are up against a true and unprovable statement or if we just haven't done enough searching to find a proof?

This is a great question. Although the "coming into existence" could refer merely to one's certainty of belief, I am at this point only treating probability in an objectivist manner. And from an objectivist point of view, it seems to me that it is already a matter of fact whether a statement is true but unprovable, or whether it can be proved in finite time. And that means that if the proof exists, it is already determined to be a pro-actuality (ignoring facts of reality that the computers could catch fire, or that in a few billions years our planet will be destroyed etc.), and if it doesn't exist, then it is already a matter of fact that it doesn't.

"Is something that is undecidable, probabilistic from this point of view?"

I assume you are referring to undecidability within the context of propositions. I suspect there is more than one way of relating this sort of undecidability to my framework, and for this reason I am not quite sure. However, I think if one really set out to relate undecidability to probability in it, then it would be possible to do, but that would lead to a very unfamiliar conception of probability. On the other hand, there is much that is not well understood about probability. Who knows if we have really exhausted all the possible meanings it could have?

"Are you familiar with Gregory Chaitin's omega constant?"

I was not familiar with it, and even after reading the wikipedia article, I do not have a good intuition for it.

"I think you might have some interest in some of the questions I posed at the end of my essay. Somehow many of them seem very relevant to your work. Please consider taking a crack at answering one of them."

OK, you asked:"If quantum mechanics is a world where things can be both "yes" and "no" at the same time, should experimental results be analyzed with Zen Koans instead of logical inferences?"

I would say that it is not the case that "quantum mechanics is a world where things can be both yes and no at the same time" but rather that within the domain of objects described by quantum mechanics, there are simply no things with actual properties describable in terms of "yes" and "no" until they are "measured". Zen Koans, I think, while often bringing home illuminating insights, do not seem very efficient (or even workable) as deductive systems to me (but then, I know very little about them).

I like the question in particular because it demonstrates how the confusion between actuality and actualizability can create a much more pervasive confusion in our worldview. If I had a fair coin in my hand, not yet flipped, and you asked me "is the outcome the flip heads?" and I suffered from the same confusion with respect to actuality and actualizability, of course I would say "Yes and no". Since we know what is really going on, does that not seem silly?

Thank you again for your questions.

Best,

Armin