entropy1 said:Suppose we have an operator with three eigenvectors/eigenvalues ##e_1##, ##e_2## and ##e_3##. The operator measures wavefunction ##\psi##. Could we say that we find outcome ##e_x## with probability ##P(\psi,e_x)##, and could we extend this to an infinite dimensional operator as a spectrum of probability?
I see it kind like this: In MWI, if we pair the (possible) outcomes with the probability of getting them, we practically end up with Copenhagen. The MWI in a way is the (preservation of the) probability distribution, while Copenhagen is the result of partitioning the measured wavefunction in orthogonal components given by the eigenvectors, causing that only one of those components can yield an outcome (because the possible outcomes are orthogonal). If I see it correctly, with Unitarity the probability distribution is preserved in the propagation of the wavefunction. We have entanglement between measured and measuring, no collapse yielding an outcome, but rather the process of decoherence that converges to a macroscopic result.PeterDonis said:In the MWI the answer (unless you come up against a true hard-core MWI proponent who is willing to abandon the concept of "probability" altogether and just answer "no") will be a complicated explanation of how it's still ok to use the term "probability" even though all of the possible outcomes are realized.
entropy1 said:In MWI, if we pair the (possible) outcomes with the probability of getting them, we practically end up with Copenhagen.
entropy1 said:Copenhagen is the result of partitioning the measured wavefunction in orthogonal components given by the eigenvectors
entropy1 said:causing that only one of those components can yield an outcome (because the possible outcomes are orthogonal)
entropy1 said:If I see it correctly, with Unitarity the probability distribution is preserved in the propagation of the wavefunction
entropy1 said:We have entanglement between measured and measuring, no collapse yielding an outcome, but rather the process of decoherence that converges to a macroscopic result.
entropy1 said:Perhaps is it also possible that the different macro-worlds of MWI are optional
Are you familiar with the von Neumann theory of quantum measurements? If not, I think you should first familiarize with it before asking such questions.entropy1 said:Suppose we have an operator with three eigenvectors/eigenvalues ##e_1##, ##e_2## and ##e_3##. The operator measures wavefunction ##\psi##. Could we say that we find outcome ##e_x## with probability ##P(\psi,e_x)##, and could we extend this to an infinite dimensional operator as a spectrum of probability?
entropy1 said:If I understand correctly, under certain conditions, with measurement, the microscopic outcome entangles with the macroscopic outcome.
entropy1 said:would that mean that if we find ourselves reading macroscopic outcome ##M_x## off the measurement device, the microscopic outcome is (assumed to be) ##e_x##?
Is the mechanism that determines which pair gets to be experienced completely unknown? Probably the answer for MWI is: all pairs get to be experienced.PeterDonis said:In the MWI, all of the outcomes are realized: each entangled pair is a branch of the wave function and all branches are real. In Copenhagen, only one outcome is realized: one entangled pair gets picked according to the Born rule as the one that is realized.
entropy1 said:Is the mechanism that determines which pair gets to be experienced completely unknown?
entropy1 said:Probably the answer for MWI is: all pairs get to be experienced.
The Copenhagen Interpretation of probability, also known as the standard interpretation, states that the act of observation or measurement causes a collapse of the wave function, resulting in a single outcome. This means that only one reality exists at any given time. On the other hand, the Many-Worlds Interpretation proposes that every possible outcome of a quantum event actually occurs in a different universe, resulting in a branching or splitting of realities.
In the Many-Worlds Interpretation, probability is used to describe the likelihood of a particular outcome occurring in a specific universe. This means that each possible outcome has a unique probability of occurring in its respective universe. However, since all possible outcomes do occur in different universes, the total probability of all outcomes is 1.
Some scientists believe that both interpretations can coexist, as they are simply different ways of understanding and interpreting quantum mechanics. However, others argue that the two are fundamentally incompatible, as the Many-Worlds Interpretation suggests the existence of multiple realities, while the Copenhagen Interpretation suggests a single reality.
In the Many-Worlds Interpretation, quantum superposition is explained as the coexistence of multiple states in different universes. This means that an object or particle can exist in multiple states simultaneously, each in a different universe. This is in contrast to the Copenhagen Interpretation, which explains superposition as a temporary state that collapses upon observation.
Currently, there is no direct evidence to support the Many-Worlds Interpretation. However, some scientists argue that it is a valid interpretation of quantum mechanics, as it is consistent with the mathematical equations and predictions of quantum theory. Others argue that the lack of evidence and the inability to test the theory make it unscientific.