Quantum physics vs Probability theory

In summary, because quantum mechanics uses a different concept of probability, it's not compatible with classical probability theory. However, this doesn't answer the question of why quantum mechanics went this route instead of using Kolmogorov's approach.
  • #36
Stephen Tashi said:
In probabiity theory, the usual definition of an "event" is that it is a set in a sigma algebra of sets. To define an event as something that will form a boolean algebra
Sets form a Boolean algebra under union and intersection.
Stephen Tashi said:
We have the problem of defining an "event". Apparently it is no longer a proposition.
In quantum logic, an event is an orthogonal projector. These form a modular lattice, not a Boolean one.
Stephen Tashi said:
What's the definition of "the set of states"? As to density matrix, what's the definition of "density"?
The set of states is the set of positive linear functionals. In finite dimensions, they are in 1-1 correspondence with density matrices. This is just a label; no definition of density is needed.
Stephen Tashi said:
We're missing the mathematical definition of observables and what operations on them make them an algebra.
An observable is a positive operator-valued measure.
 
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  • #37
Usually observables are defined as being represented by self-adjoint operators and the possible values the eigenvalues of these operators. This refers to ideal von Neumann measurments.

POVMs are a (quite recent) addition to describe more complicated "weak measurements", being often more realistic though an unnecessary complication for discussing fundamental questions like the one discussed here.

Before you haven't understood the simpler case of precise measurements, it doesn't make sense to try to understand more complicated subjects.

That's an analogous further step as the one from the idealized definition of observables in classical Hamiltonian mechanics compared to the more realistic description of it in terms of phase-space distribution functions in classical statistical mechanics.
 
  • #38
A. Neumaier said:
Sets form a Boolean algebra under union and intersection.

It's interesting that a boolean algebra "of logic" ( https://en.wikipedia.org/wiki/Boolean_algebra) is defined differently than a boolean algebra "of sets".

In quantum logic, an event is an orthogonal projector. These form a modular lattice, not a Boolean one.

Ok, but my line of inquiry concerns whether terms like "quantum logic" and "quantum probability" have mathematical definitions - or are they merely informal terms that describe qualitative properties of how QM calculations are peformed?

The statement that an event is an orthogonal projector gives a property of the thing called an "event", but it doesn't define an event mathematically until there is some context is defined for a projection of something on something else. We should begin with a Hilbert space, correct?
 
  • #39
vanhees71 said:
I'm really puzzled what's still the problem.

If that refers to my questions, the problem is to show that "quantum logic" or "quantum probability" or "probability amplitudes" are organized mathematical topics that generalize ordinary probability theory. The alternative to that possibility is that these these terms are not defined in some unified mathematical context, but are informal descriptions of aspects of calculations in QM.

If you insist on going beyond this, i.e., asking for a framework considering all possible measurements, i.e., of all observables, then you need to extend the logic and the probability theory beyond the standard features, as explained by @atyy in #33 .

Post #33 doesn't describe a unified mathematical system. The unified mathematical system that begins with a Hilbert space and defines states and observables in that context is apparently the background for post #33. Within that context, what is the definition of "quantum logic"? What is the definition of a "quantum probability"? Is there a mathematical definition of the Kolmogorov probability spaces associated with the Hilbert space? - or are the associated probabiity spaces a matter of interpretation and application of the theory?
 
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  • #40
Stephen Tashi said:
A probability isn't completely defined until it's probability space is specified. So "probabilities are the squared moduli of probability amplitudes" doesn't define a context for using probability amplitudes unless we assume we begin with a probability space and define probability amplitudes in terms of probabilities on that space.

No, this is not correct. If the space of probability amplitudes is defined, and we know that probabilities are squared moduli of amplitudes, then the space of probabilities is defined. You don't have to assume the probability space first.
 
  • #41
vanhees71 said:
POVMs are a (quite recent) addition to describe more complicated "weak measurements",
This is quite misleading.

POVM measurements were introduced in 1970, which was 45 years after Heisenberg's 1925 paper initiating modern quantum physics. A very readable account was given 4 years later in
  • S.T. Ali and G.G. Emch, Fuzzy observables in quantum mechanics, J. Math. Phys. 15 (1974), 176--182.
Since this paper appeared, another 45 years passed. Thus it is not appropriate to call them ''a (quite recent) addition''.

Moreover, they are not used to describe weak measurements (which is a special class of continuous measurements on single quantum objects). They are needed to describe quite ordinary experiments (such as Stern-Gerlach or the double slit) without making the traditional textbook idealizations. See the books mentioned in another thread. They are indispensable in quantum information theory. Indeed, the well-known textbook
  • M.A. Nielsen and I.L, Chuang, Quantum computation and quantum information, Cambridge Univ. Press, Cambridge 2001.
introduces them even before defining the traditional projective measurements that you advocate one should restrict attention to!
 
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  • #42
Stephen Tashi said:
whether terms like "quantum logic" and "quantum probability" have mathematical definitions
The mathematical definition is that quantum logic is the logic specified by the algebraic properties of orthomodular lattices. Maybe you'd read the book 'Quantum Logic' by Svozil before ranting about the subject. Similarly, you'd first read the Wikipedia article on quantum probability, say, before making your unfounded claims.
 
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  • #43
PeterDonis said:
No, this is not correct. If the space of probability amplitudes is defined, ...

Yes, if it is defined. What is the definition of "the space of probability amplitudes"?
 
  • #44
A. Neumaier said:
The mathematical definition is that quantum logic is the logic specified by the algebraic properties of orthomodular lattices. Maybe you'd read the book 'Quantum Logic' by Svozil before ranting about the subject. Similarly, you'd first read the Wikipedia article on quantum probability, say, before making your unfounded claims.

I think characterising Stephen's posts as ranting (lengthy, angry and impassioned) is inappropriate.

Cheers
 
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  • #45
Stephen Tashi said:
What is the definition of "the space of probability amplitudes"?

The space of complex components in the chosen basis of all possible state vectors. The basis is chosen based on the observable you want to measure.
 
  • #46
cosmik debris said:
I think characterising Stephen's posts as ranting (lengthy, angry and impassioned) is inappropriate.
Lengthy uninformed criticism looks like a rant. Anger or passion are not necessarily implied in this word:
Wikipedia said:
A diatribe, also known less formally as rant, is a lengthy oration, though often reduced to writing, made in criticism of someone or something, often employing humor, sarcasm, and appeals to emotion.
(from https://en.wikipedia.org/wiki/Diatribe)

Stephen Tashi discounted the introductory informal short description, quoted from a book that later explains everything in detail, as
Stephen Tashi said:
I understand the book's statements as statements about properties of some mathematical structures and their applications, but the quoted text lacks definitions for these structures.
and then gave long superficial reasons (of ignorance) for his assessment. He should have spent the time for writing his critique on reading the subsequent pages of the book.
 
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  • #47
A. Neumaier said:
Lengthy uninformed criticism looks like a rant. Anger or passion are not necessarily implied in this word:

(from https://en.wikipedia.org/wiki/Diatribe)

Stephen Tashi discounted the introductory informal short description, quoted from a book that later explains everything in detail, as

and then gave long superficial reasons (of ignorance) for his assessment. He should have spent the time for writing his critique on reading the subsequent pages of the book.

OK, I understand that our definitions of rant maybe different, in my dictionary anger and passion are definite ingredients, additionally in my country rant is a pejorative term.

If everyone else thinks this is OK then I guess it is OK.

Cheers
 
  • #48
cosmik debris said:
I understand that our definitions of rant maybe different

Yes, and @A. Neumaier explained how he was using the word, so any ambiguity that might have been present before has been removed.

Please focus on the substance of the points being debated instead of on people's choice of words.
 
  • #49
Stephen Tashi said:
If that refers to my questions, the problem is to show that "quantum logic" or "quantum probability" or "probability amplitudes" are organized mathematical topics that generalize ordinary probability theory. The alternative to that possibility is that these these terms are not defined in some unified mathematical context, but are informal descriptions of aspects of calculations in QM.
Post #33 doesn't describe a unified mathematical system. The unified mathematical system that begins with a Hilbert space and defines states and observables in that context is apparently the background for post #33. Within that context, what is the definition of "quantum logic"? What is the definition of a "quantum probability"? Is there a mathematical definition of the Kolmogorov probability spaces associated with the Hilbert space? - or are the associated probabiity spaces a matter of interpretation and application of the theory?
Well, to be honest, for me as a phenomenologically oriented theoretical physicist there was nowhere any need for other mathematical logic and probabilities than the usual ones. As I said repeatedly, as long as you look at what's really measured in the lab, there's no problem whatsoever with the well-defined standard mathematics. Rather than quantum logic, what's really an important extension to standard textbook quantum theory seems to be the extension of the idea of (idealized) von Neumann meausrements to the more comprehensive description by positive operator valued measurements, and as far as I understand this is also a well-defined mathematical subject.
 
  • #50
A. Neumaier said:
This is quite misleading.

POVM measurements were introduced in 1970, which was 45 years after Heisenberg's 1925 paper initiating modern quantum physics. A very readable account was given 4 years later in
  • S.T. Ali and G.G. Emch, Fuzzy observables in quantum mechanics, J. Math. Phys. 15 (1974), 176--182.
Since this paper appeared, another 45 years passed. Thus it is not appropriate to call them ''a (quite recent) addition''.

Moreover, they are not used to describe weak measurements (which is a special class of continuous measurements on single quantum objects). They are needed to describe quite ordinary experiments (such as Stern-Gerlach or the double slit) without making the traditional textbook idealizations. See the books mentioned in another thread. They are indispensable in quantum information theory. Indeed, the well-known textbook
  • M.A. Nielsen and I.L, Chuang, Quantum computation and quantum information, Cambridge Univ. Press, Cambridge 2001.
introduces them even before defining the traditional projective measurements that you advocate one should restrict attention to!
Well, in my field we haven't ever needed POVMs at all. Where do you need them to understand the double-slit or Stern-Gerlach experiments?

Again, I'm not against the POVM formalism, but it's overcomplicating things if you start on a level where even the simpler and straight-forward case has been understood. Maybe it's a difference in the scientific culture in math vs. physics. The former tends to be taught in a deductive manner starting from the most general case and then treat the simple things as special cases (though in practice you cannot do this, because you have to start with the simple cases first, and I don't think that you can understand math in a purely Bourbakian approach) while the latter is an inductive empirical science.
 
  • #51
vanhees71 said:
Well, in my field we haven't ever needed POVMs at all.
Because there one doesn't care about the foundations. One would need them if one were to give a statistical interpretation to all the q-expectations of nonhermitian field products occurring in the derivation of quantum kinetic equations. They cannot be interpreted statistically in the pre-1970 measurement formalism.
vanhees71 said:
Where do you need them to understand the double-slit or Stern-Gerlach experiments?
The original Stern-Gerlach experiment did (in contrast to its textbook caricature) not produce two well-separated spots on the screen but two overlapping lips of silver.
This outcome cannot be described in terms of a projective measurement but needs POVMs.

Similarly, joint measurements of position and momentum, which are ubiqiotpus in engineering practice, cannot be described in terms of a projective measurement.
Born's rule in the pre-1970 form does not even have idealized terms for these.

For the double slit without the common idealizations, which also needs a POVM treatment, see the book mentioned in the POVM thread.
vanhees71 said:
Again, I'm not against the POVM formalism, but it's overcomplicating things if you start on a level where even the simpler and straight-forward case has been understood.
To motivate and understand Born's rule for POVMs is much easier (one just needs simple linear algebra) than to motivate and understand Born's rule in its original form, where all the fancy stuff about wave functions, probability amplitudes and spectral representations must be swallowed by the beginner.

Thus it is overcomplicating things if you start with probability amplitudes and spectral resolutions!
 
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  • #52
vanhees71 said:
If you insist on going beyond this, i.e., asking for a framework considering all possible measurements, i.e., of all observables, then you need to extend the logic and the probability theory beyond the standard features, as explained by @atyy in #33 .
No, there is no need to do this. All you have to do is to care about accurate formulations of the propositions you make about some quantum systems.

Of course, if you, say, define the negation of "measuring X gives always result x" as "measuring X gives never result x", this operator "not" does not follow classical logic, thus, it defines some "quantum logic". This is essentially all that has to be said about such "generalizations" of classical logic: Care about what you say, and follow the rules of classical logic, and you will not need any quantum logic in quantum theory too.

Same for probability theory. You can use the space of elementary events proposed by Kochen and Specker (in their paper about the impossibility of hidden variables, where they have given that construction but rejected it as not giving what is usually assumed to be meant with "hidden variables"). This and caring about not violating classical logic in the own reasoning is sufficient to live with classical probability theory there too.
 
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  • #53
Elias1960 said:
Same for probability theory. You can use the space of elementary events proposed by Kochen and Specker (in their paper about the impossibility of hidden variables, where they have given that construction but rejected it as not giving what is usually assumed to be meant with "hidden variables"). This and caring about not violating classical logic in the own reasoning is sufficient to live with classical probability theory there too.
Thank you! I must admit I didn't know any detail about Kochen-Specker other then being a No-Go theorem before but their article answers my original question quite well. It was a very interesting read and in particular the formulation of the framework they used to approach the problem.

That said I found simple attempts to model any quantum experiment to become highly contextual. Though i think that in attempting to model a much more general setup or set of experiments this could be remedied.

But what i can't see any PT model to do is to allow to fully describe all state in terms observable results one way or another (assuming any such model to correctly describe the experiment it models i.e. yields correct predictions). So this kind of approach should not come into conflict with this theorem.
 
  • #54
That construction on p.63 of the Kochen Specker paper was thought only as an illustration why one needs a more serious restriction for an adequate definition of "hidden variables" than a formula of some space ##\Lambda## which gives a quite trivial Kolmogorovian probability space for quantum theory too. It has been essentially ignored, so it is known only by those who have read the paper.

The QM pure states are defined in terms of observables, you observe a preparation measurement, then the observable result defines the eigenstate of the measured operator.

Instead, the interpretations are not restricted to describe the state in observable only terms. That would be an unreasonable restriction, motivated by nothing but positivism.

On the other hand, there is the objective Bayesian interpretation of probability (following Jaynes it is the "logic of plausible reasoning"). In some sense, it is not about anything hidden - it is about probabilities of things that make sense to us. But these things may be wrong (say a particular hypothesis about what has happened), maybe unrelated to anything real (like statements about what is true if a particular theory is true). So, this is not only about observables, and should not be, because we want to reason about how probable such things are and want to do this in a consistent way, and the rules of probability theory are what is appropriate for this.
 
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  • #55
Elias1960 said:
On the other hand, there is the objective Bayesian interpretation of probability (following Jaynes it is the "logic of plausible reasoning"). In some sense, it is not about anything hidden - it is about probabilities of things that make sense to us. But these things may be wrong (say a particular hypothesis about what has happened), maybe unrelated to anything real (like statements about what is true if a particular theory is true). So, this is not only about observables, and should not be, because we want to reason about how probable such things are and want to do this in a consistent way, and the rules of probability theory are what is appropriate for this.

Just to point out that this is controversial. Even among Bayesians, many object to the objective Bayesian view. There are alternatives such as the subjective Bayesian view of de Finetti.
 
  • #56
atyy said:
Just to point out that this is controversial. Even among Bayesians, many object to the objective Bayesian view. There are alternatives such as the subjective Bayesian view of de Finetti.
They both have their applications. If one wants to speculate beyond the information one objectively has, one may also want to do this in a logically consistent way. In this case, the subjective Bayesian point of view can be used.

The difference is roughly this: If you have no information about a dice which makes a difference between the numbers, then the objective Bayesian interpretation prescribes that one has to use ##\frac{1}{6}## for all of them. The subjective Bayesian interpretation makes no such prescriptions. You are free to speculate that 5 may be favored based on your subjective feeling. Whatever - there is not really a contradiction between them.

So I think the difference between objective and subjective Bayesians is in this question irrelevant. For physics, the objective view is clearly preferable. Already because it gives, for free, a base for the null hypothesis: If we have no information which suggests any causal connection between A and B we have to assume P(AB)=P(A)P(B). But also all that is named entropic inference (say, for the Bayesian variant of thermodynamics) depends on what can be said about the case when we have no information. In this case, objective Bayesians prescribe the probability distribution with the largest entropy, while subjective Bayesians tell us nothing at all.
 
  • #57
Elias1960 said:
They both have their applications. If one wants to speculate beyond the information one objectively has, one may also want to do this in a logically consistent way. In this case, the subjective Bayesian point of view can be used.
well, as for original question i was actually looking for merely modeling the information we objectively have and wanted to know PT was in general always suitable for that. if it didn't that would be a very interesting thing to understand - but never mind that now.

My problem with QM is that for me all its interpretations add more confusion then they help to understand what we are actually modelling. having a solid framework to view problems from that is free of all the confusing assumptions of QM interpretations (the actual math isn't the confusing part) might be a good way to reflect and understand which particular aspects are causing the trouble.

for example QM interpretations stick to the idea of point like particles even though the entire math framework does everything it can to model as far as possible from that intuition. and never mind the idea of a point like charged particle is already incomprehensible and paradox on a classical level. It feels like QM get's this to work only because it's math framework cheats its interpretations and secretly gives up all such assumptions.

I hoped to maybe use PT to get this sorted out in my head; to understand what kind of information is there to be modeled - on the very abstract level of minimalist PT approach since it is very lightweight on axioms which makes it extremely general. In that context it would like to stay minimalist and not add any assumptions i don't absolutely need to get correct predictions. that makes me go with the most basic interpretations of probability.
 
  • #58
Auto-Didact said:
Having said that, I agree that a B level thread might not be the correct avenue for raising such an issue.
I am terribly sorry to have misunderstood this classification. is there a way I can remedy this mistake?
 
  • #59
Killtech said:
I am terribly sorry to have misunderstood this classification. is there a way I can remedy this mistake?
Ask a moderator to change it to A
 
  • #60
Killtech said:
I am terribly sorry to have misunderstood this classification. is there a way I can remedy this mistake?

The moderators would have done so if they thought it was important enough.

The more important issue is that you don't understand QM:

Killtech said:
My problem with QM is that for me all its interpretations add more confusion then they help to understand
Killtech said:
for example QM interpretations stick to the idea of point like particles even though the entire math framework does everything it can to model as far as possible from that intuition.

This second quotation is, quite simply, nonsense. It does not reflect a failure of 100 years of QM development by the leading physicists of the 20th century. It reflects your failure, hitherto, to understand what QM is saying.

My concern is that we've indulged you in a fairly pointless exercise in analysing the foundations of QM vis-a-vis classical PT. Whereas, all along your issue is simply that of someone trying to learn QM for the first time and being confused by it.
 
  • #61
PeroK said:
This second quotation is, quite simply, nonsense. It does not reflect a failure of 100 years of QM development by the leading physicists of the 20th century. It reflects your failure, hitherto, to understand what QM is saying.
I don't have an issue understanding QM. to understand how to use the formalism and how to apply it to correctly calculate results for which you don't need to resolve those kind of issues. So in that i understand QM quite well.

But whenever phyiscs text-books tried to "intuitively"-explain QM aspects it left me more confused then before. Heisenbergs uncertainty principle is a prime example of this. but when i learned the theoretical proof of it was rather easy to understand what it meant. from that point i learned that at least for me it is far better to derive my intuition from the behavior of mathematical apparatus rather then rely on any attempt of physicist to explain it in "classical" terms that usually also contradicts the math of QM.

PeroK said:
My concern is that we've indulged you in a fairly pointless exercise in analysing the foundations of QM vis-a-vis classical PT. Whereas, all along your issue is simply that of someone trying to learn QM for the first time and being confused by it.
I found the answer i asked, albeit it took 3 pages.

Indeed i haven't realized that what i am looking for is a far more general framework to analyse possible constructions of theories capable of describing quantum experiments - just like the No-Go-theorems need it to discuss the possibility of hidden-variable theories. the underlying premise for the required framework is the same.

my concern is that the point of view is just too different from most physicist that it gets difficult to express the questions i have in terms they understand. Then again this was an issue i might have better posted in the probabily theory forums since it needed only basic information about several physical experiments in question but a deeper understanding of PT was needed for the entire rest. The idea that i explicitly did not want for a model it terms of classic QM may also be problematic for people that are too familiar with it to even understand why anyone would want that - given that QM works well enough. Then again the article of Kochen-Specker where such formalism was developed i wonder why for so many here it appeared initially unthinkable.
 
  • #62
Killtech said:
I don't have an issue understanding QM. to understand how to use the formalism and how to apply it to correctly calculate results for which you don't need to resolve those kind of issues. So in that i understand QM quite well.

But whenever phyiscs text-books tried to "intuitively"-explain QM aspects it left me more confused then before. Heisenbergs uncertainty principle is a prime example of this. but when i learned the theoretical proof of it was rather easy to understand what it meant. from that point i learned that at least for me it is far better to derive my intuition from the behavior of mathematical apparatus rather then rely on any attempt of physicist to explain it in "classical" terms that usually also contradicts the math of QM.

What book are you using?

One problem I can see with your approach is how you would map your mathematics to experiment? Especially as experiments involve macroscopic, classical apparatus. Can you explain the double-slit experiment, for example, purely in terms of the mathematical formalism?
 
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  • #63
Killtech said:
But whenever phyiscs text-books tried to "intuitively"-explain QM aspects it left me more confused then before. Heisenbergs uncertainty principle is a prime example of this. but when i learned the theoretical proof of it was rather easy to understand what it meant. from that point i learned that at least for me it is far better to derive my intuition from the behavior of mathematical apparatus rather then rely on any attempt of physicist to explain it in "classical" terms that usually also contradicts the math of QM.

That's it! You have to build your intuition from the math. There's no other way. It's good advice to stay away from any text that claims otherwise. In terms of the writings of the founding fathers for me that implied to rather read Schrödinger, Dirac, Born, Pauli, and particularly Sommerfeld than Bohr or Heisenberg.

Concerning foundations, stay away from philosophy books, where even usual words get rid of any clear meaning leaving you in the dark and fog of utmost confusion ;-)).

Concerning foundational physical questions like EPR, entanglement, and the like, it's also good to look at the real-lab experiments by quantum opticians and read their papers (with a good theoretical textbook as a background like Garrison and Ciao, Quantum optics, to get the full QFT description which is the only true thing).
 
  • #64
Killtech said:
The idea that i explicitly did not want for a model it terms of classic QM may also be problematic for people that are too familiar with it to even understand why anyone would want that - given that QM works well enough. Then again the article of Kochen-Specker where such formalism was developed i wonder why for so many here it appeared initially unthinkable.
This is the double edged sword of specialization into camps: the breeding of researchers into large silos who vehemently overreact to everyone who speaks against the accepted wisdom of the group; this is a widely documented phenomenon within the social sciences which has been studied from a variety of viewpoints (pedagogic, sociological, economic, political, doxastic, etc), but I digress.

The direct downside of specialization is that specialists in different fields are unable to converse with each other, even when talking about the same topic for a multitude of reasons. To quote Feynman: In this age of specialization men who thoroughly know one field are often incompetent to discuss another. The great problems of the relations between one and another aspect of human activity have for this reason been discussed less and less in public. When we look at the past great debates on these subjects we feel jealous of those times, for we should have liked the excitement of such argument.
 
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  • #65
PeroK said:
What book are you using?
over all the time 15 years i looked through quite a few different books but also scrips i could find on the internet. far from all, quite a few left me with a brain hemorrhage :) - more often those more akin to an experimental focus. But there were also those this only sticked to axiomatic approaches... i liked those the most.

PeroK said:
One problem I can see with your approach is how you would map your mathematics to experiment? Especially as experiments involve macroscopic, classical apparatus. Can you explain the double-slit experiment, for example, purely in terms of the mathematical formalism?
Now you are starting to understand where i am coming from because this is exactly the fundamental problem i am running into. For a parson initially home in pure mathematics and within the autistic spectrum this is the most difficult part to sort out. I just can't handle the constructions physics have made here (as for me it appears as far from canonical as it can get) and even something simple like a well defined mapping algorithm between an experimental setup and the corresponding observable operator it measures lacking a proper definition leaves me hanging with a something that prohibits me form a well-defined interpretation mapping.

Then again PT offers a framework to model experiments in a very clear an reasonable way i can fully understand so it is a natural tool to get back to in order to see how i can fix my experiment-to-math gap.
 
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  • #66
PeroK said:
Can you explain the double-slit experiment, for example, purely in terms of the mathematical formalism?
I am not sure what your question exactly means? "Explain" is a wide term. question: does any modelling of a random experiment in PT explain anything? i mean reading through Kochen-Specker i wonder whether you are asking if this can be done in an non-contextual way? in that sense it would have an canonical way to apply to a wide array of other instances. If that is the case of your question i think it might be possible.
 
  • #67
Killtech said:
I am not sure what your question exactly means? "Explain" is a wide term. question: does any modelling of a random experiment in PT explain anything? i mean reading through Kochen-Specker i wonder whether you are asking if this can be done in an non-contextual way? in that sense it would have an canonical way to apply to a wide array of other instances. If that is the case of your question i think it might be possible.

You might want to check that your mathematical formalism predicts the results obtained by experiment. Somehow you have to map the mathematical model to a specific experimental set-up.
 
  • #68
PeroK said:
You might want to check that your mathematical formalism predicts the results obtained by experiment. Somehow you have to map the mathematical model to a specific experimental set-up.
PT toolbox provides you with both - albeit the mapping is at first trivial. for example the way you distinguish outcomes implicitly defines what can be observed directly: observables. you could in general define a mapping between all types of possible detectors to these observables by which you identify outcomes. but of course this stays entirely on a macroscopic level. once this is estabilished and you have a correct model for your experiment you can start comparing the QM model vs yours since both yield the same results. now you try to find a mapping between each information stored in your quantum state model (e.g. wave function in the sense of a decomposition into some basis with each coefficient holding 1 real number of abstract information) to your macroscopic outcome space such that for each such information varieting (within its allowed frame) will yield the same change in results for both models.

now the problem is that a wave function stores a lot of information so you need a very general experimental setup to be able to make each information make a distinguishable difference in the results (taken over many realizations with same starting conditions). the simple double slit setup doesn't even have parameters to play with so it isn't suited for this. but one could think of each slit width as a parameter and so on until one gets enough degrees of freedom for this kind of mapping.

in the end you should have a mapping of paramters to outcome distributions (events in PT terminology) and those again are associated to QM mathematical framework via its interpretations. The final stage is now to rearrange the original state space of the PT model in terms of the mathematical objects of QM via that mapping function - which therefore functions as an interpretation.
 
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  • #69
Killtech said:
PT toolbox provides you with both - albeit the mapping is at first trivial. for example the way you distinguish outcomes implicitly defines what can be observed directly: observables. you could in general define a mapping between all types of possible detectors to these observables by which you identify outcomes. but of course this stays entirely on a macroscopic level. once this is estabilished and you have a correct model for your experiment you can start comparing the QM model vs yours since both yield the same results. now you try to find a mapping between each information stored in your quantum state model (e.g. wave function in the sense of a decomposition into some basis with each coefficient holding 1 real number of abstract information) to your macroscopic outcome space such that for each such information varieting (within its allowed frame) will yield the same change in results for both models.

now the problem is that a wave function stores a lot of information so you need a very general experimental setup to be able to make each information make a distinguishable difference in the results (taken over many realizations with same starting conditions).

Hmm. You're not saying anything specific here. Let's say I'm an experimenter and I have results from a double-slit experiment using electrons. When either slit is open I get a single-slit pattern. But, when both slits are open I do not get the sum of two single-slit patterns, I get a different pattern; an "interference" pattern.

How does the mathematical formalism of QM explain that result? It has to be specific to that experiment.

If you can't do that, then you are studying pure mathematics; but not physics. Not that there is anything wrong with pure mathematics!
 
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PeroK said:
Hmm. You're not saying anything specific here. Let's say I'm an experimenter and I have results from a double-slit experiment using electrons. When either slit is open I get a single-slit pattern. But, when both slits are open I do not get the sum of two single-slit patterns, I get a different pattern; an "interference" pattern.

How does the mathematical formalism of QM explain that result? It has to be specific to that experiment.
Sorry, i have edited my prior post after posting with a little more elaboration. but i think you misunderstand my goal a little. i do not aim to explain anything. i am rather looking for a clear construction principle how to associate elements of the QM formalism to macroscopic observations made in the experiments - other then using the standard interpretations i am struggling with.
 
<h2>What is the difference between quantum physics and probability theory?</h2><p>Quantum physics is a branch of physics that studies the behavior of matter and energy at a very small scale, such as atoms and subatomic particles. It is based on the principles of quantum mechanics, which describe the probabilistic nature of particles. Probability theory, on the other hand, is a branch of mathematics that deals with the analysis of random phenomena and the likelihood of events occurring.</p><h2>How do quantum physics and probability theory relate to each other?</h2><p>Quantum physics and probability theory are closely related. In quantum mechanics, particles are described by mathematical equations that involve probabilities of finding the particle in a particular state. These probabilities are calculated using the principles of probability theory, such as the wave function and the uncertainty principle.</p><h2>Can quantum physics be explained using probability theory?</h2><p>While probability theory is an important tool in understanding quantum phenomena, it cannot fully explain the behavior of particles at a quantum level. Quantum mechanics introduces concepts such as wave-particle duality and superposition, which are not fully explained by probability theory.</p><h2>Why is it important to study both quantum physics and probability theory?</h2><p>Studying both quantum physics and probability theory is crucial in understanding the behavior of matter and energy at a fundamental level. Quantum mechanics has led to many groundbreaking discoveries and technological advancements, while probability theory is essential in analyzing and predicting the behavior of complex systems.</p><h2>Are there any real-world applications of the principles of quantum physics and probability theory?</h2><p>Yes, there are many real-world applications of quantum physics and probability theory. Quantum mechanics has led to the development of technologies such as transistors, lasers, and MRI machines. Probability theory is used in fields such as finance, economics, and statistics to analyze and predict outcomes of complex systems.</p>

What is the difference between quantum physics and probability theory?

Quantum physics is a branch of physics that studies the behavior of matter and energy at a very small scale, such as atoms and subatomic particles. It is based on the principles of quantum mechanics, which describe the probabilistic nature of particles. Probability theory, on the other hand, is a branch of mathematics that deals with the analysis of random phenomena and the likelihood of events occurring.

How do quantum physics and probability theory relate to each other?

Quantum physics and probability theory are closely related. In quantum mechanics, particles are described by mathematical equations that involve probabilities of finding the particle in a particular state. These probabilities are calculated using the principles of probability theory, such as the wave function and the uncertainty principle.

Can quantum physics be explained using probability theory?

While probability theory is an important tool in understanding quantum phenomena, it cannot fully explain the behavior of particles at a quantum level. Quantum mechanics introduces concepts such as wave-particle duality and superposition, which are not fully explained by probability theory.

Why is it important to study both quantum physics and probability theory?

Studying both quantum physics and probability theory is crucial in understanding the behavior of matter and energy at a fundamental level. Quantum mechanics has led to many groundbreaking discoveries and technological advancements, while probability theory is essential in analyzing and predicting the behavior of complex systems.

Are there any real-world applications of the principles of quantum physics and probability theory?

Yes, there are many real-world applications of quantum physics and probability theory. Quantum mechanics has led to the development of technologies such as transistors, lasers, and MRI machines. Probability theory is used in fields such as finance, economics, and statistics to analyze and predict outcomes of complex systems.

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