Quantum amplitudes are a consequence of elementary probability theory

Alexey L. Krugly

arXiv:0904.1862·physics.gen-ph·September 26, 2012·2 cites

Quantum amplitudes are a consequence of elementary probability theory

Alexey L. Krugly

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TL;DR

This paper explores how quantum amplitudes can be derived from elementary probability theory using matrix calculus, linking classical probability with quantum phenomena.

Contribution

It introduces a novel approach connecting elementary probability theory to quantum amplitudes through matrix calculus, with an example involving discrete pregeometry.

Findings

01

Quantum amplitudes can be derived from elementary probability theory.

02

Matrix calculus provides a bridge between classical probability and quantum mechanics.

03

Discrete pregeometry exemplifies this connection.

Abstract

I suppose that quantum objects obey elementary probability theory. I consider a connection of elementary probability theory and complex quantum amplitudes by a matrix calculus. A special case of a discrete pregeometry is an example of this approach.

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Taxonomy

TopicsNoncommutative and Quantum Gravity Theories · Quantum Mechanics and Applications · Black Holes and Theoretical Physics