StevieTNZ
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Qunatum Mechanics doesn't state a collapse will occur - and if the theory holds then a collapse never occurs - correct? When we say the wavefunction has collapsed, it really hasn't?
StevieTNZ said:Qunatum Mechanics doesn't state a collapse will occur - and if the theory holds then a collapse never occurs - correct? When we say the wavefunction has collapsed, it really hasn't?
jambaugh said:Consider it this way. Suppose you did make the [1] measurement but did so to a given system after I had measured it (but haven't yet told you what observable I measured nor what value I got.)
You would still write the |1> wave-function, even to describe the system prior to your measurement. If I then told you I measured a specific observable you would use that |1> wave function to predict the probability of the value I measured and finally if I said I measured |+> you would collapse the wave-function to |+> prior to my measurement to see what "alice" measured before me.
By reversing the sequence of assumptions made, I have totally change where you write the |+> description and where you write the |1> description. Can you still then say these are states of reality? Or are they not truly representations of our knowledge about the system in question?
StevieTNZ said:Qunatum Mechanics doesn't state a collapse will occur - and if the theory holds then a collapse never occurs - correct? When we say the wavefunction has collapsed, it really hasn't?
StevieTNZ said:Qunatum Mechanics doesn't state a collapse will occur - and if the theory holds then a collapse never occurs - correct? When we say the wavefunction has collapsed, it really hasn't?
Zarqon said:When I think of an example where you measure on the state without telling me I get the opposite conclusion, explained by the following:
Consider that I start with the state |+>. If I measure in the |+>,|-> basis I would now find the state |+> with 100% probability. Let's now consider what happens if you did a measurement in the |0>,|1> basis without telling me. You would "collapse" the state to one of them, let's just say it happened to be |1>.
Now, without you telling me anything, i.e. my knowledge about the system does not change, I now have a non-zero probability of measuring |-> (50%) if I again measure in my basis. The probability of measuring |-> has thus changed without my knowledge being changed at all.
I can only interpret this as the fact that the physical state has actually changed, which is completely different from any classical analogy, where no amount of information update can ever change the location of neither keys nor glasses.
jambaugh said:Even if "collapse has been realized" we will still, until integrating that assumption describe the system as via the equivalent of a density operator. In this setting "collapse" is represented by decoherence. There is a change in the entropy of the representation. This implies a non-unitary (though still linear?) evolution of the system itself during the measurement process.
StevieTNZ said:linear and nonlinear quantum mechanics? Which one is correct?
You're speaking of a particle track in a cloud chamber. We can describe that track as a sequence of position measurements and indeed speak of the idealized limit of continuous measurement. But the reality is that the track is a discrete sequence of position measurements. This has nothing to say as to the discussions. Yes we can measure the position of a quantum. Yes we can measure it twice, three times, 10^14 times.arkajad said:If the collapse would be described mathematically in this way - then we would certainly have a problem. But it can be described in a different way. Collapse happens objectively - as it leaves an objective "track", the wave function changes in a mildly nonlinear way, then it continues its non-unitary evolution until the next collapse etc. The nonunitarity is negligible far from the detectors, the evolution is the standard and unitary in an empty space without detectors.
This completely describes the evolution of a single quantum system under a continuous monitoring.
Yet, if we are not interested in a single quantum system, but care only about averages over an infinite ensemble of similarly prepared systems, only then, if we wish, we do the averaging and get the perfect linear Liouville master equation for the density matrix.
In short:
Single systems are described by collapsing wave functions, ensembles are described by non-collapsing, continuous in time, linear master equation for the density matrix. That's all.
jambaugh said:If you want to describe a quantum system with position observable, observed every 10^-5 seconds or so. [/tex]
In a cloud chamber it is not you who decides how often the the records are being made. It is decided by the coupling. The timing is random is part of the random process.
You update your description by inputting say the first or say the 108th position measurement value and you get a different description because you input more information. The description has "collapsed". Input more actualized values and you collapse it more.
I am not imputing anything. All is done through the coupling. What I do is - at the end I may have a look at the track.
Eventually you have something which looks very close to a classical particle trajectory but it is still an expression of where you saw bubbles i.e. records of measurements. You still express the measurement within the linear algebra over the Hilbert space. There is no need for nor empirical evidence supporting the introduction of non-linearity in the dynamics at the level of the operator algebra.
Try to accomplish the above with a linear process and show me the result.
[QUOTE}Now getting back to quantum theory. How can you define a probability for a single quantum?
If you can bring yourself to acknowledge that it is possible, and useful to sometimes... upon occasion, speak of a class of quantum systems with the same set of values for a given complete observable, and hence the same wave-function, then can you explain to me, other for personal spiritual reasons, how you can say this is ever not the case?
Your simulation matches experiments only in the aggregate, (same relative frequencies, same lines of cloud chamber bubbles but not identical individual outcomes) thus your inference is again about classes of individual quanta. I'm sure you're doing good work but my objections are to how you use the term "collapse". If you are simulating entanglement then you are positively not simulating the physical states of the quantum systems since you would necessarily satisfy Bell's inequality and/or failing to get the proper correlations). You would need to be simulating the (probability) distributions of outcomes directly which would involve nothing more than doing the QM calculations.arkajad said:I am describing the stochastic process that reproduces what we see, including the timing of the events. You can compare my simulation with experiment. And how you compare two results of an experiments? You have two photographs of an interfence pattern with 10000 electrons each time. One done on Monday and one on Tuesday. Of course the dots are in different places. And yet you notice that both describe the same phenomenon. How? Because you neglect the exact places and compare statistical distributions computed using statistical procedures applied to your photographs each with 10000 dots.
Is there a probability involved? Somehow is, but it is hidden.
The same when you compare two tracks in an external field. They are not the same. And yet they have similar "features". For instance the average distance between dots, approximately the same curvature, when you average etc. Is probability involved? Somehow is, but it is hidden in the application of statistics to finite samples.
The issue is what the theory says, the semantics of the language you use. Words mean things. I can simulate a given probability distribution but that won't mean the internals of my simulation correspond to a physical process which upon repetition match that distribution. My point is that the theory matches what goes on in the lab only in so far as it makes probabilistic predictions, quite accurate ones, but only for aggregates of (and hence classes of) experiments.I prefer down to Earth approach - comparing simulations based on a theory with real data coming from rel experiments. I have nothing against classes. But for me the success of any theory is in being able to simulate processes that we observe in our labs.
I am stressing the importance of timing - which is usually dynamical and not by "instantaneous measurement at chosen time" from the textbooks. Textbooks do not know how to deal with the dynamical timing - which a standard in the labs.
jambaugh said:Your simulation matches experiments only in the aggregate, (same relative frequencies, same lines of cloud chamber bubbles but not identical individual outcomes) thus your inference is again about classes of individual quanta. I'm sure you're doing good work but my objections are to how you use the term "collapse". If you are simulating entanglement then you are positively not simulating the physical states of the quantum systems since you would necessarily satisfy Bell's inequality and/or failing to get the proper correlations). You would need to be simulating the (probability) distributions of outcomes directly which would involve nothing more than doing the QM calculations.
The issue is what the theory says, the semantics of the language you use. Words mean things. I can simulate a given probability distribution but that won't mean the internals of my simulation correspond to a physical process which upon repetition match that distribution. My point is that the theory matches what goes on in the lab only in so far as it makes probabilistic predictions, quite accurate ones, but only for aggregates of (and hence classes of) experiments.
The fact that you think the measurement is an instantaneous process as represented in the textbooks is where I see you misinterpreting. The mathematics is instantaneous because it represents something one level of abstraction above the the physical process, namely the logic of the inferences we make about predictions. (There is no "timing" in mathematics 2+2=4 eternally.) The "collapse problem" is not with the theory but with the mind misunderstanding to what a specific component of the theory is referring.
The representation of measurement goes beyond "instantaneous" as I pointed out in the (logically) reversed representation of an experiment. I'll repeat in more detail:
Consider a single experimental setup. A quantum is produced from a random source, a sequence of measurements are made, A then B then C, (which take time and room on the lab's optical bench or whatever) and then final system detector registers the system to assure a valid experiment. If you like you can consider intermediate dynamics as well but for now let's keep it simple.
What does theory tell us about the sequence of measurements?
Your humble stochastic simulations are fine research --I am sure-- but please refer to the physical processes by their rightful name, "interaction", not "collapse".
Bell's inequalities (and their violation) are about correlations, if you don't care then you don't care.arkajad said:I am sure I am getting all the correlations that are seen in experiments. I do not care about Bell inequalities which do not even address the continuous monitoring of single quantum systems.
I know you are not talking about it but that is what you are doing. You are saying your computer model stochastic process matches the probability distributions for physical systems. There and only there can you compare with experiment. You speak of "collapse" but there's no reason to believe the "collapses" in your stochastic model matches anything "out there in actuality". It is the old classic phenomenologist's barrier. "We can only know what we experience." Yes it is too restrictive for science in general. At the classical scale we can infer beyond the pure experience but QM specifically pushes us to the level where that barrier is relevant and we must be more the positivist or devolve into arguments over "how many angels can dance on the head of a pin".I am not talking about simulating of probability distributions. I am talking about stochastic processes and their trajectories in time.
Yes the collapse is a part of a stochastic process, but that process is a conceptual process, (your model or mine) not a physical process (actual electrons). Again you speak of "the time of the collapse" as if you can observe physical collapse and again I ask "HOW?" Until then the "why QM does not take this into account" question lacks foundation.The collapse is a part of a stochastic process. Sometimes we have one collapse - the time of the collapse is always a random variable. That is what the standard approach to QM does not takes into account - because of the historical reasons and because of the inertia of human thought.
And I'm explaining why it not only can be neglected but should be. The timing of "collapse" is not a physically meaningful phrase. I can collapse the wave-function (on paper) at any time I choose after the measurement is made. If you'd like to discuss the physical process of measurement itself then let's but in a different thread as that is quite a topic in itself.It tells us absolutely nothing about the timing. You are consistently neglecting this issues.
"Coupling" is "interaction", Hamiltonians are how we represent the evolution of the whole composite of the two systems being coupled. When you focus on part of that whole you loose the Hamiltonian format but it is still an interaction. You can still work nicely with this focused case using ... pardon my bringing this up again... density matrices and a higher order algebra. The density operators can still be "evolved" linearly but no longer with a adjoint action of Hamiltonian within the original operator algebra. You see then decoherence occur (the entropy of the DO increases over time, representing this random stochastic process you're modeling). I think you'd find it of value to determine exactly how your computer models of stochastic processes differs from or is equivalent to this sort of representation.In fact, I do not the term "interaction", because interaction is usually understood as a "Hamiltonian interaction". I prefer the term "non-Hamiltonian coupling".
jambaugh said:Bell's inequalities (and their violation) are about correlations, if you don't care then you don't care.
I know you are not talking about it but that is what you are doing. You are saying your computer model stochastic process matches the probability distributions for physical systems.
You speak of "collapse" but there's no reason to believe the "collapses" in your stochastic model matches anything "out there in actuality".
It is the old classic phenomenologist's barrier. "We can only know what we experience." Yes it is too restrictive for science in general. At the classical scale we can infer beyond the pure experience but QM specifically pushes us to the level where that barrier is relevant and we must be more the positivist or devolve into arguments over "how many angels can dance on the head of a pin".
Yes the collapse is a part of a stochastic process, but that process is a conceptual process, (your model or mine) not a physical process (actual electrons).
Again you speak of "the time of the collapse" as if you can observe physical collapse and again I ask "HOW?" Until then the "why QM does not take this into account" question lacks foundation.
I think you misuse the term "collapse" where you should be speaking of "decoherence" which is the physical process (of external random physical variables i.e. "noise" being introduced into the physical system.)
And I'm explaining why it not only can be neglected but should be. The timing of "collapse" is not a physically meaningful phrase.
I can collapse the wave-function (on paper) at any time I choose after the measurement is made. If you'd like to discuss the physical process of measurement itself then let's but in a different thread as that is quite a topic in itself.
"Coupling" is "interaction", Hamiltonians are how we represent the evolution of the whole composite of the two systems being coupled. When you focus on part of that whole you loose the Hamiltonian format but it is still an interaction. You can still work nicely with this focused case using ... pardon my bringing this up again... density matrices and a higher order algebra. The density operators can still be "evolved" linearly but no longer with a adjoint action of Hamiltonian within the original operator algebra. You see then decoherence occur (the entropy of the DO increases over time, representing this random stochastic process you're modeling). I think you'd find it of value to determine exactly how your computer models of stochastic processes differs from or is equivalent to this sort of representation.
I think your prejudice against DO's (describing a single system) is what is keeping you from understanding this fully. The dynamics of the coupling of system to episystem can be expressed via a hamiltonian on the composite system + episys. and then tracing over the "epi" part yields a non-sharp and "decohering" system description...but again only expressible as a density operator.
Again I submit when you speak of a "wave function valued random variable" (which it seems to me you are using) you are effectively describing a density operator.
This is one way. Now, try to go uniquely from your density matrix to the particular realization of the stochastic process. You know it can't be done. Therefore there is more potential information in the process than in the Markov semi-group equation.Consider a random distribution of Hilbert space vectors with corresponding probabilities:
[tex]\{(\psi_1,p_1),(\psi_2,p_2),\cdots\}[/tex]
it is equivalently realized as a density operator:
[tex]\rho = \sum_k p_k \rho_k[/tex]
where
[tex]\rho_k = \psi_k\otimes\psi^\dagger_k.[/tex]
That IS what the density operator represents pragmatically and within the modern literature. Yes when we speak of a (random) ensemble of systems we must use density operators but that isn't the D.O.'s definition.
A probability can be associated with a single system in that it expresses our knowledge about that system in the format of: to what class of systems that one belongs. In expressing this we understand the definition of the value of a probability comes from the class not from the singular system. A D.O. is a probability distribution over a set of Hilbert space vectors e.g. wave-functions.
Then you see no distinction between belief in voodoo and belief in atoms. There is so much wrong with this statement I don't know where to begin.arkajad said:...
There are no reasons to believe anything. Each believe is just a personal choice. Like choosing "we only need to know how to calculate numbers and nothing more".
Resistant or not, what you can calculate doesn't validate the identification of your calculus with "reality", especially when there exists multiple methods of calculation. Reality is not the mathematics it is the empirical assumptions which cannot be ignored. I can ignore your stochastic processes without any loss in the fidelity of the predictions of QM.QM "pushes" some physicists and some philosphers into what you call "positivism", but some are more resistant than others. But even so, the "event" based model can calculate more than the posivitistic "don't ask questions, just calculate" model. So, also with a positivistic attitude you are behind.
So they are not "the reality" but our tools for calculating what does or may happen... and we err in forgetting this fact. (e.g. when we wonder about collapse (and the timing thereof) as if it were happening other than on paper or in the mind of the holder of the concept.)Well, Hilbert spaces, wave functions, operators, spacetime metrics, are also conceptual. So what?
OMG you are a Platonist? No wonder...They always come in pairs: collapse, event). We observe events. Collapses are in the Platonic part of the world. Nevertheless if you want to simulate events you need the collapses. Like in order to calculate orbits of planets you need to solve differential equations. Differential equations are in the Platonic world as well.
I placed some of these terms in quotes, because they were common usage synonyms for the sharper ones. But YES "Random variable" has a specific sharp meaning, the symbol representing outcomes of a class of empirical events, specifically outcomes to which we can assign probabilities. And "External" has a perfectly well defined operational meaning. We can isolate a system from external effects without changing the system itself (as a class, i.e. defined by its spectrum of observables and degrees of freedom)."Random variables"? "External"? "noise"? Are these better or sharper terms? I strongly doubt.
Very good. That's progress. Now then you agree there is a "collapse on paper" but you seem to be saying there is also a "collapse in reality" which the paper process is representing. Correct?Right. You can collapse wave-function on paper and you can erase diffrential equation on paper. This will not destroy the planet's orbit.
"anything better" is a value judgment. Let us establish the value judgment within which we work as physicists. I say "there can't be anything better" specifically in the context of the prediction of physical outcomes of experiments and observables. By what value system do you claim something that is "better"?You can play with density matrices, but they will not let you to understand and to simulate the observed behavior of a unique physical system. You may deliberately abandon that, you may decide "I don't need it, I don't care", but even in this case I am pretty sure that is a forced choice. You choose it because you do not know anything better than that. You even convince yourself that there can't be anything better. But what if there can be?
A prejudice may or may not be a conscious choice. The point is that it is an a priori judgment. Revisit it, and ask instead what is the justification for that judgment. I know a man who consciously ignores the evidence of evolution because it might undermine his faith in the literal "truth" of the bible. Are you doing the same w.r.t. density operators?It is not so much my prejudice. It's my conscious choice.
Yes you have more components to play with (like with epicycles you have more variables to tweak). The important point is that with the DO's you have less yet no loss of predictive information. Thus the "more" you refer to is not linked or linkable to any empirical phenomena. Does it then still have physical meaning in your considered opinion?Well, it is like saying: when you speak of a function, you effectively speak about its integral. In a sense you are right, but knowing a function you can do with more than just computing one of its characteristics.
Again see my point above... what utility does this procedure have if it does not change what one can empirically predict? (I do not deny it might have some utility but I call your attention to the nature of that utility if it does manifest.)This is one way. Now, try to go uniquely from your density matrix to the particular realization of the stochastic process. You know it can't be done. Therefore there is more potential information in the process than in the Markov semi-group equation.
Yes you can do what you like as a person but are you then doing physics or astrology? To express the maximal known information about a system in terms of usage common to the physics community you really really should use density operators as they are understood in that community.No, I don't have to. Like having a function I don't have to calculate it's integral. I can be more interested in its derivative, for example. Or I can modify its values on some interval.
Then you are on a speculative quest. That is fine and good. But acknowledge that you speculate instead of declaring the orthodox to be "wrong". When you find that mechanism and can justify the superiority of believing the reality of it then come back.Well, you are speaking about "our knowledge" while I am speaking about our attempts to understand the mechanism of formation of events. A mechanism that can lead us to another, perhaps even better mechanism, without random numbers at the start.
jambaugh said:So they are not "the reality" but our tools for calculating what does or may happen... and we err in forgetting this fact. (e.g. when we wonder about collapse (and the timing thereof) as if it were happening other than on paper or in the mind of the holder of the concept.)
arkajad said:You are missing the point. Everybody is calculating lot of things. And you too. There is nothing wrong with calculations. There is nothing wrong with solving differential equations - they are on paper or in the mind.
The point is whether at the end of your calculation you get something that you can compare with observations. In this respect there is no difference between solving differential equations and models with collapses. In each case at the end you get numbers or graphs that you can compare with experimental data.
So, your war is misdirected.
jambaugh said:There is a distinct physical process of decoherence which one can express easily in the density operator language (which you resist accepting) which is not the same as collapse and indeed shows that classical and quantum collapse are indistinguishable. (Classical collapse being the baysian updating of probabilities given subsequent observations.)
arkajad said:There are distinct physical events which one can express easily in the stochastic processes' language.
I did not see one event in finite time for an individual quantum system derived from the decoherence formalism. But if you show me one - I may even change the team.
BTW. Collapse is NOT bayesian updating probabilities. It is a sudden change of the wave function. Probabilities is a related (in a not so simple way)- but not the same - business. Moreover, they are not bayesian. At least not those that I am talking about.
arkajad said:You are missing the point. Everybody is calculating lot of things. And you too. There is nothing wrong with calculations. There is nothing wrong with solving differential equations - they are on paper or in the mind.
The point is whether at the end of your calculation you get something that you can compare with observations. In this respect there is no difference between solving differential equations and models with collapses. In each case at the end you get numbers or graphs that you can compare with experimental data.
So, your war is misdirected.
arkajad said:BTW. Collapse is NOT bayesian updating probabilities. It is a sudden change of the wave function. Probabilities is a related (in a not so simple way)- but not the same - business. Moreover, they are not bayesian. At least not those that I am talking about.
jambaugh said:If you've further interest in the matter I'll see if I can cook up a detailed description of a particular act of measurement. (It's something I need to do anyway.)
ZPower said:So decoherence does not collapse the wavefunction?
arkajad said:It's not been done so far? So unimportant? Amazing!
Alfrez said:a mathematical formalism that can be used to calculate probabilities of possible results of experiments
A. Neumaier said:Quantum mechanics does much more than predict probabilities of possible results of experiments.
For example, it is used to predict the color of molecules, their response to external electromagnetic fields, the behavior of material made of these molecules under changes of pressure or temperature, the production of energy from nuclear reactions, the behavior of transistors in the chips on which your computer runs, and a lot more. Most of these predictions have nothing at all to do with collapse.
It is a pity that public reception of quantum mechanics is so much biased towards the queer aspects of quantum systems. The real meaning and the power of quantum mechanics does not come from studying the foundations but from studying the way how QM is applied when put to actual use.
Alfrez said:You and Jambaugh are bonafide Copenhagen.
Alfrez said:Is there any implication by knowing the correct interpretations.