Difference between revisions of "Nonlocality, Unreality, and Bell Theorem"
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==Abstract== | ==Abstract== | ||
− | I argue that Bell?s argument for nonlocality is the result of an error in the use of Bayes? formula. By correcting this error all derivations of Bell Inequalities become impossible. Further, I show by direct construction and simulation that the data from EPR- and GHZ-type experiments can be explained by the classical formulas for higher order correlations. Additionally, I argue that irreality is a consequence of the assumption that QM is complete. Superposition of mutually exclusive states arise in classical mechanics for coupled oscillators where the energy sloshes back and forth between two modes.[[Category:Scientific Paper]] | + | I argue that Bell?s argument for nonlocality is the result of an error in the use of Bayes? formula. By correcting this error all derivations of Bell Inequalities become impossible. Further, I show by direct construction and simulation that the data from EPR- and GHZ-type experiments can be explained by the classical formulas for higher order correlations. Additionally, I argue that irreality is a consequence of the assumption that QM is complete. Superposition of mutually exclusive states arise in classical mechanics for coupled oscillators where the energy sloshes back and forth between two modes. |
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+ | [[Category:Scientific Paper|nonlocality unreality bell theorem]] |
Latest revision as of 10:46, 1 January 2017
Scientific Paper | |
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Title | Nonlocality, Unreality, and Bell Theorem |
Author(s) | Al F Kracklauer |
Keywords | {{{keywords}}} |
Published | 2006 |
Journal | None |
Abstract
I argue that Bell?s argument for nonlocality is the result of an error in the use of Bayes? formula. By correcting this error all derivations of Bell Inequalities become impossible. Further, I show by direct construction and simulation that the data from EPR- and GHZ-type experiments can be explained by the classical formulas for higher order correlations. Additionally, I argue that irreality is a consequence of the assumption that QM is complete. Superposition of mutually exclusive states arise in classical mechanics for coupled oscillators where the energy sloshes back and forth between two modes.