Is it Possible to Measure Q or P Without Determining x1 and x2 or p1 and p2?

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This discussion centers on the measurement of observables Q (particle separation) and P (total momentum) in a two-particle system, emphasizing their commutation properties. It is established that measuring individual particle positions (x1, x2) and momenta (p1, p2) can lead to violations of the uncertainty principle. The conversation explores whether Q and P can be measured independently without determining the individual particle properties, suggesting that they belong to different subsystems and can be directly measurable. A specific method involving a position detector with 100% sensitivity is proposed to prepare an eigenstate of Q without violating the uncertainty principle.

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Question about measuring observables. If have 2 particle system the particle separation
Q=x1-x2 and total momentum P=p1+p2 are observables of the system as a whole and are
commuting. How do you measure these observables. It would seem the only way to
measure the separation is to measure the individual particle positions x1,x2 and subtract
them. With the total momentum you measure the particle momentum's separation and add.
However, since Q,P commute you should be able to measure Q,P simultaneously. But if do
it by measuring individual particle properties you have violated uncertainty principle since
you have both position and momentum for each particle. So is there some way to measure
Q or P without determining x1 and x2 or p1 and p2 or are Q and P nonmeasurable and only really mathematical fictions.
 
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Your P and Q belong to different, independent subsystems or quasi-particles. They are directly measurable. See Chapters 1 and 3 in http://arxiv.org/abs/0811.4416.
 
My question is not the measuring of P and Q together, but how do you measure just Q say. If you measure each particles position separately then subtract I don't think you are actually in an eigenstate of Q but rather in 2 separate 1 particle eigenstates.
 
No, not even so because the variables x1 and x2 are correlated (not independent). The relative motion is a subsystem with its own properties - proper frequencies, angular momenta, energies, etc.
 
so you're saying that if I measure x1 and x2 that put's me into an eigenstate of Q.
What about the fact that Q and P commute. If I now measure P haven't I got
x1,x2,p1,p2 and now know each particles position and momentum with certainty thus
violating the uncertainty principle.
 
Hi.

clacker said:
My question is not the measuring of P and Q together, but how do you measure just Q say.

I considered it on such a case that x1 and x2 are not positions of the different particles but different directions say x and y of the same particle.

Let a particle be on the plane. Position detector of 100% sensitivity is placed on each point of the plane except on the line x - y = a. If no detector works when you make observation, you succeed to prepare eigenstate of Q of eigenvalue a.
It's the case of particle beam shoot on the screen with line slit. Momentum component along with the slit line, say px + py = P is not disturbed by the position measurement at the slit. So P and Q commute.

I hope it will make any sense.
Regards.
 
Last edited:

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