Vanadium 50 said:These fall into a category of theories called "hidden variable theories", and it has been shown by John Bell that such theories do not give the same predictions as quantum mechanics.
I don't understand your question. Do you mean something like: are the laws of physics unique to the universal evolutionary epoch in which they're discovered? That is, might the laws of physics be different, say, a trillion years from now, or is it possible that they were different in the distant past? That is, is it possible that the laws of physics are evolving as the universe evolves?Runner 1 said:Are any known laws of physics a function of a unique spacetime coordinate?
Be careful reading my question -- I'm not asking if the laws of physics vary throughout spacetime (since they don't).
Runner 1 said:Are any known laws of physics a function of a unique spacetime coordinate?
De Broglie-Bohm interpretation is a hidden variable theory and quite a few percent of physicists believe in it to some degree.Runner 1 said:Roughly what percentage of (non-crackpot) physicists believe in a hidden variable theory?
Wouldn't this be due to the fact that the universe is evolving, rather than due to the HUP?Runner 1 said:I'll try to give an example.
Basically, the wavefunction for any particle's state "collapses" upon measurement into a value that can only predicted statistically. An identically prepared state gives different measurements each time one is taken.
My question though -- the experiments aren't "really" identical. One may be performed at 12:05 PM and the other at 12:20 PM. A different amount of time has elapsed since the universe began. Not to mention that it's impossible to get one particle into the same exact position that it once was (HUP limits these sort of things).
That's sort of how I was framing your question in my previous post. I don't know if that question is answerable.Runner 1 said:Is it possible that something deeper below Planck scale is taking place that is dependent on the time since the universe began?
During humanity's expected short existence I wouldn't suppose that we'd see any changes in physical laws depending on t. Again, I don't see our inability to find f(t) as being due to HUP. Rather, we just don't have any direct physical apprehension of any spacetime epoch other than the one we happen to be evolving in. We can extrapolate and project, but that's based on the laws of physics as they've been formulated during our particular interval of existence.Runner 1 said:I.e., the electron's measurement will depend on f(t), where t is the time since the universe began. Except that we can't find what f(t) is because of HUP.
I think that, sure, in that case, you would find a correlation. If that experiment could be done. But it can't.Runner 1 said:So imagine you position identical electrons with identically prepared states in a 3D lattice in space with equal spacing. And suppose you could take a measurement at the same time for all of these electrons. The data for each individual measurement is unpredictable. Is it possible that if you analyzed the data from all of the measurements together you would find a correlation? (That's not to say you would -- this is just an example).
Electrons are identical in the sense that they're defined in terms of certain attributes or properties. But the electrons that are moving in my computer aren't the same electrons that are moving in your computer, even though we couldn't differentiate one of your electrons from one of my electrons if we were able to put them side by side and compare them.Runner 1 said:In other words, it's sort of a spacetime analogy to indistinguishable electrons. If you assume electrons are not unique, then you get statistics that correctly predict their behavior. If you assume they are unique, then you get statistics that don't fit any experiments so far.
No. They're distinguishable. Spacetime point (x,y,z,t) is distinguishable from spacetime point (x',y',z',t').Runner 1 said:My question -- is each point in spacetime indistinguishable?
Why "of course"? All we know is that wrt our very limited perspective during our exceedingly short existence our current formulation of the 'laws of physics' seems to hold. But there's still no understanding of things in terms of a fundamental dynamical principle or law.Runner 1 said:The laws are of course the same everywhere ...
I still only understand what you're saying in connection with what I've conjectured that it might mean.Runner 1 said:... but theoretically could be a function of a unique spacetime coordinate (unless someone's already proven why this isn't the case).
ThomasT said:Wouldn't this be due to the fact that the universe is evolving, rather than due to the HUP?
ThomasT said:That's sort of how I was framing your question in my previous post. I don't know if that question is answerable.
Is it possible that the evolution of the universe is governed by fundamental dynamics that remain the same as the universe evolves?
During humanity's expected short existence I wouldn't suppose that we'd see any changes in physical laws depending on t. Again, I don't see our inability to find f(t) as being due to HUP. Rather, we just don't have any direct physical apprehension of any spacetime epoch other than the one we happen to be evolving in. We can extrapolate and project, but that's based on the laws of physics as they've been formulated during our particular interval of existence.
ThomasT said:Electrons are identical in the sense that they're defined in terms of certain attributes or properties. But the electrons that are moving in my computer aren't the same electrons that are moving in your computer, even though we couldn't differentiate one of your electrons from one of my electrons if we were able to put them side by side and compare them.
ThomasT said:Why "of course"? All we know is that wrt our very limited perspective during our exceedingly short existence our current formulation of the 'laws of physics' seems to hold. But there's still no understanding of things in terms of a fundamental dynamical principle or law.
"Points of spacetime" refer to the fundamental building blocks of the universe, where space and time are combined into a single entity. These points represent the coordinates in space where events occur.
Yes, points of spacetime are unique in the sense that each point has its own set of coordinates that are different from any other point. This means that no two points of spacetime are exactly the same.
Understanding the uniqueness of points of spacetime is essential in order to accurately describe and predict the behavior of the universe. It allows scientists to track the location and timing of events, and to make precise measurements and calculations.
While points of spacetime themselves cannot be directly measured, scientists can measure the distance between points in space and the duration of time between events. This allows for the calculation of coordinates and the mapping of points of spacetime.
Einstein's theory of relativity proposes that space and time are not separate entities, but are interconnected and can be affected by objects and events. The idea of points of spacetime supports this theory, as it suggests that space and time are combined into a single entity.