A decision-theoretic model is developed in which quantum measurements act as uncertain decisions whose utilities encode Born's rule, enabling an imprecise-probabilities treatment of quantum uncertainty.
Computational Complexity and the Nature of Quantum Mechanics
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abstract
Quantum theory (QT) has been confirmed by numerous experiments, yet we still cannot fully grasp the meaning of the theory. As a consequence, the quantum world appears to us paradoxical. Here we shed new light on QT by being based on two main postulates: 1. the theory should be logically consistent; 2. inferences in the theory should be computable in polynomial time. The first postulate is what we require to each well-founded mathematical theory. The computation postulate defines the physical component of the theory. We show that the computation postulate is the only true divide between QT, seen as a generalised theory of probability, and classical probability. All quantum paradoxes, and entanglement in particular, arise from the clash of trying to reconcile a computationally intractable, somewhat idealised, theory (classical physics) with a computationally tractable theory (QT) or, in other words, from regarding physics as fundamental rather than computation.
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quant-ph 1years
2025 1verdicts
UNVERDICTED 1representative citing papers
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A decision-theoretic approach to dealing with uncertainty in quantum mechanics
A decision-theoretic model is developed in which quantum measurements act as uncertain decisions whose utilities encode Born's rule, enabling an imprecise-probabilities treatment of quantum uncertainty.