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A Poisson model for entanglement optimization in the quantum internet

A Poisson model for entanglement optimization in the quantum internet
A Poisson model for entanglement optimization in the quantum internet

A Poisson model for entanglement optimization in quantum repeater networks is defined in this paper. The optimization framework fuses the fundamental concepts of quantum Shannon theory with the theory of evolutionary algorithms and seismic wave propagations in nature. The optimization model aims to maximize the entanglement fidelity and relative entropy of entanglement for all entangled connections of the quantum network. The cost functions are subject of a minimization defined to cover and integrate the physical attributes of entanglement transmission, purification, and storage of entanglement in quantum memories. The method can be implemented with low complexity that allows a straightforward application in future quantum Internet and quantum networking scenarios.

quantum entanglement, quantum Internet, quantum networks, quantum repeater, quantum Shannon theory
SPIE
Gyongyosi, L.
bbfffd90-dfa2-4a08-b5f9-98376b8d6803
Imre, S.
210dce74-aeca-453e-81d0-96d4e866cf0f
Gyongyosi, L.
bbfffd90-dfa2-4a08-b5f9-98376b8d6803
Imre, S.
210dce74-aeca-453e-81d0-96d4e866cf0f

Gyongyosi, L. and Imre, S. (2018) A Poisson model for entanglement optimization in the quantum internet. In Quantum Information Science, Sensing, and Computation X. vol. 10660, SPIE.. (doi:10.1117/12.2309416).

Record type: Conference or Workshop Item (Paper)

Abstract

A Poisson model for entanglement optimization in quantum repeater networks is defined in this paper. The optimization framework fuses the fundamental concepts of quantum Shannon theory with the theory of evolutionary algorithms and seismic wave propagations in nature. The optimization model aims to maximize the entanglement fidelity and relative entropy of entanglement for all entangled connections of the quantum network. The cost functions are subject of a minimization defined to cover and integrate the physical attributes of entanglement transmission, purification, and storage of entanglement in quantum memories. The method can be implemented with low complexity that allows a straightforward application in future quantum Internet and quantum networking scenarios.

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More information

e-pub ahead of print date: 14 May 2018
Published date: 2018
Venue - Dates: Quantum Information Science, Sensing, and Computation X 2018, , Orlando, United States, 2018-04-18 - 2018-04-19
Keywords: quantum entanglement, quantum Internet, quantum networks, quantum repeater, quantum Shannon theory

Identifiers

Local EPrints ID: 422922
URI: http://eprints.soton.ac.uk/id/eprint/422922
PURE UUID: e8070d4a-fece-4424-a4ae-62ef96f953a0

Catalogue record

Date deposited: 08 Aug 2018 16:30
Last modified: 17 Mar 2024 12:09

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Contributors

Author: L. Gyongyosi
Author: S. Imre

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