Questionable and Unquestionable in Quantum Mechanics

• URL: http://arxiv.org/abs/2309.01928v2
• Date: Thu, 7 Sep 2023 21:42:31 GMT
• Title: Questionable and Unquestionable in Quantum Mechanics
• Authors: Laszlo E. Szabo, Marton Gomori, Zalan Gyenis
• Abstract summary: We derive the basic postulates of quantum physics from a few very simple operational assumptions. We show that anything that can be described in operational terms can, if we wish, be represented in the Hilbert space quantum mechanical formalism.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: We derive the basic postulates of quantum physics from a few very simple operational assumptions based exclusively on the relative frequencies of observable events (measurement operations and measurement outcomes). We isolate a notion which can be identified with the system's own state, in the sense that it characterizes the system's probabilistic behavior against all possible measurement operations. We investigate some important features of the possible states of the system. All those investigations remain within the framework of classical Kolmogorovian probability theory, meaning that any physical system (traditionally categorized as classical or quantum) that can be described in operational terms can be described within classical Kolmogorovian probability theory. In the second part of the paper we show that anything that can be described in operational terms can, if we wish, be represented in the Hilbert space quantum mechanical formalism. The outcomes of each measurement can be represented by a system of pairwise orthogonal closed subspaces spanning the entire Hilbert space; the states of the system can be represented by pure state operators, and the probabilities of the outcomes can be reproduced by the usual trace formula. Each real valued quantity can be associated with a suitable self-adjoint operator, such that the possible measurement results are the eigenvalues and the outcome events are represented by the eigenspaces, according to the spectral decomposition of the operator in question. This suggests that the basic postulates of quantum theory are in fact analytic statements: they do not tell us anything about a physical system beyond the fact that the system can be described in operational terms. This is almost true. At the end of the paper we discuss a few subtle points where the representation we obtained is not completely identical with standard quantum mechanics.

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