atyy said:But it that's what you do, then your interpretation would solve the measurement problem. Yet in other posts you say it doesn't solve the measurement problem.
bhobba said:Its obvious. I simply assume it - I don't explain why. BM explains why for example - I don't.
The issue is whether explaining why or not worries you - it doesn't worry me. Axiomatically it makes no difference - but some like certain axioms - others don't.
atyy said:I don't agree with that. Why should we need to explain why?
bhobba said:You don't need to explain why. But by the definition of solving the measurement problem you need to explain the three parts I have mentioned in past posts not simply assume it. Decoherence explains the first two - well at least its reasonable to assume it does - there are issues - but not the third part. I simply assume it therefore I have not explained the measurement problem. BM for instance explains all three. Its even easier to see when you understand my interpretation is entirely compatible with BM - as is the statistical interpretation of Ballentine.
atyy said:I don't agree. The traditional statement of the measurement problem is "How can we have quantum mechanics without observers?"
bhobba said:You are using a different definition than me. I am using the definition I have posted many many times from the following standard text:
https://www.amazon.com/dp/3540357734/?tag=pfamazon01-20
It has three parts:
1. The preferred basis problem.
2. The non observability of interference effects
3. Why we get any outcomes at all - technically how does an improper mixture become a proper one.
Again, as stated clearly in that text, decoherence can reasonably explain the first two. It stands powerless before the third. I simply assume an improper mixture is a proper one - I don't explain it.
atyy said:existence of a classical world, so classical physics is not a less fundamental theory from which quantum mechanics is derived.
bhobba said:That's a blemish in Copenhagen and others - not what I call the measurement problem.
That said if you can explain issue 3 then you have explained the emergence of the classical world.
Also its not the only way to fix that blemish.
bhobba said:That's a blemish in Copenhagen and others - not what I call the measurement problem.
That said if you can explain issue 3 then you have explained the emergence of the classical world.
Also its not the only way to fix that blemish.
atyy said:Doesn't your interpretation have this "blemish"?
bhobba said:No. By interpreting a mixed state as a proper mixed state it exists independent of observation. The classical world emerges from the quantum.
atyy said:I don't think you have shown that the classical world is independent of the choice of F (Factoriation), T (Deviation from diagonal).
atyy said:In your interpretation, the quantum state is not necessarily real. The classical world is real. How can reality emerge from something subjective?
bhobba said:I was very careful to quote Schlosshauer exactly, and its my view as well. It's REASONABLE to assume decoherence solves 1 and 2. There are issues that need to be resolved like the factorisation problem. There are others as well. If you want to delve further into it check out:
https://www.amazon.com/dp/0691004358/?tag=pfamazon01-20
But the consensus is 1 and 2 are basically solved. Its only on this forum you get these long threads about this fringe stuff like the factorisation and similar issues. The book above acknowledges them but puts them in much better perspective.
If you want to say they are a deal breaker - be my guest. I won't argue about it - we have had tons and tons of threads doing that and there is nothing to gain by going over it again and again.
bhobba said:But the observation is very real.
atyy said:But that again seems to promote the observer to special status, because if the wave function is not real, then the criterion for reality is again subjective.
bhobba said:I knew it was going down this path. It really is philosophy which I find rather useless semantic sophistry. The key point is if an object always has a certain property if you observe it there is no difference to it actually having that property. Because its assumed to be a proper mixed state it is indistinguishable from actually having that property and being part of an objective world existing independent of observation.
atyy said:But could you clearly answer the question: doesn't what you are saying give the observer special status, exactly the same as in Copenhagen?
bhobba said:No - and obviously so.
atyy said:It doesn't seem obvious to me. The basic problem is if the wave function is subjective - how can objective reality emerge from something subjective?
bhobba said:The properties revealed by observation are very real. If a state is in an eigenstate of an observable it has that property regardless of observation. Since it is assumed to be in a proper mixed state it actually has that property prior to observation regardless of if you observe it or not.
atyy said:But in that case, isn't the wave function real? Also, isn't collapse real?
bhobba said:But the consensus is 1 and 2 are basically solved. Its only on this forum you get these long threads about this fringe stuff like the factorisation and similar issues. The book above acknowledges them but puts them in much better perspective.
Jimster41 said:...the following paper seems less confusing, and seems to state pretty clearly that 2 is not proved?
bhobba said:All the state is is a codification of the results of observations. If it is in an eigenstate it actually has that property - that's what the state tells us.
Please use state instead of wavefunction - its much clearer.
atyy said:OK, perhaps it is just semantics.
bhobba said:That's all much of this is IMHO.
Jimster41 said:It is an intriguing open question whether the linearity of quantum mechanics extends into the macroscopic domain.
bhobba said:The key point of assuming its a proper mixture is there is some process that makes it a proper mixture - that linearity breaks down is one way to explain it - but not the only one.
Just want to mention that @bhobba (as well as others) pointed me to that paper.atyy said:I'm not sure. If you agree with my analogy with GRW/CSL versus Copenhagen Continuous Measurement, then in the former we can have a state of the universe including the observer (ie. quantum mechanics without observers), while in the latter there is no meaning to the state of the universe.
Also, GRW and CSL and Bohmian Mechanics, as I understand, do eventually lead to deviations from quantum mechanics, which I think can be in principle tested (maybe even in practice as discussed by the link http://arxiv.org/abs/1410.0270 posted by Jimster41).