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Supermeasured: Violating Bell-Statistical Independence Without Violating Physical Statistical Independence

Jonte R. Hance, Sabine Hossenfelder, T. N. Palmer

2022Foundations of Physics25 citationsDOIOpen Access PDF

Abstract

Abstract Bell’s theorem is often said to imply that quantum mechanics violates local causality, and that local causality cannot be restored with a hidden-variables theory. This however is only correct if the hidden-variables theory fulfils an assumption called Statistical Independence. Violations of Statistical Independence are commonly interpreted as correlations between the measurement settings and the hidden variables (which determine the measurement outcomes). Such correlations have been discarded as “fine-tuning” or a “conspiracy”. We here point out that the common interpretation is at best physically ambiguous and at worst incorrect. The problem with the common interpretation is that Statistical Independence might be violated because of a non-trivial measure in state space, a possibility we propose to call “supermeasured”. We use Invariant Set Theory as an example of a supermeasured theory that violates the Statistical Independence assumption in Bell’s theorem without requiring correlations between hidden variables and measurement settings (physical statistical independence).

Topics & Concepts

Hidden variable theoryIndependence (probability theory)Causality (physics)MathematicsLocal hidden variable theoryMeasure (data warehouse)Interpretation (philosophy)Statistical modelBell's theoremStatisticsQuantumComputer scienceQuantum mechanicsPhysicsQuantum entanglementDatabaseProgramming languageQuantum Mechanics and ApplicationsPhilosophy and History of ScienceStatistical Mechanics and Entropy
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