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Quantum Algorithms

Ternary and Binary Representation of Coordinate and Momentum in Quantum Mechanics

arXiv
Authors: M. G. Ivanov, A. Yu. Polushkin

Year

2020

Paper ID

20350

Status

Preprint

Abstract Read

~2 min

Abstract Words

106

Citations

N/A

Abstract

To simulate a quantum system with continuous degrees of freedom on a quantum computer based on quantum digits, it is necessary to reduce continuous observables (primarily coordinates and momenta) to discrete observables. We consider this problem based on expanding quantum observables in series in powers of two and three analogous to the binary and ternary representations of real numbers. The coefficients of the series ("digits") are, therefore, Hermitian operators. We investigate the corresponding quantum mechanical operators and the relations between them and show that the binary and ternary expansions of quantum observables automatically leads to renormalization of some divergent integrals and series (giving them finite values).

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  • To simulate a quantum system with continuous degrees of freedom on a quantum computer based on quantum digits, it is necessary to reduce continuous observables (primarily...

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