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The entanglement-assisted communication capacity over quantum trajectories

The entanglement-assisted communication capacity over quantum trajectories
The entanglement-assisted communication capacity over quantum trajectories
The unique and often-weird properties of quantum mechanics allow an information carrier to propagate through multiple trajectories of quantum channels simultaneously. This ultimately leads us to quantum trajectories with an indefinite causal order of quantum channels. It has been shown that indefinite causal order enables the violation of bottleneck capacity, which bounds the amount of the transferable classical and quantum information through a classical trajectory with a well-defined causal order of quantum channels. In this treatise, we investigate this beneficial property in the realm of both entanglement-assisted classical and quantum communications. To this aim, we derive closed-form capacity expressions of entanglement-assisted classical and quantum communication for arbitrary quantum Pauli channels over classical and quantum trajectories. We show that by exploiting the indefinite causal order of quantum channels, we obtain capacity gains over classical trajectory as well as the violation of bottleneck capacity for various practical scenarios. Furthermore, we determine the operating region where entanglement-assisted communication over quantum trajectory obtains capacity gain against classical trajectory and where the entanglement-assisted communication over quantum trajectory violates the bottleneck capacity.
Encoding, Quantum channels, Quantum communication, Quantum entanglement, Quantum mechanics, Trajectory, Wireless communication, quantum communications, quantum decoherence, quantum superposition, quantum trajectory
1536-1276
3632-3647
Chandra, Daryus
d629163f-25d0-42fd-a912-b35cd93e8334
Caleffi, Marcello
da95cb17-0bc4-4902-87c3-b4cc6bf48493
Cacciapuoti, Angela Sara
fc7d8318-c754-4879-9a91-6b4a45d8d41c
Chandra, Daryus
d629163f-25d0-42fd-a912-b35cd93e8334
Caleffi, Marcello
da95cb17-0bc4-4902-87c3-b4cc6bf48493
Cacciapuoti, Angela Sara
fc7d8318-c754-4879-9a91-6b4a45d8d41c

Chandra, Daryus, Caleffi, Marcello and Cacciapuoti, Angela Sara (2022) The entanglement-assisted communication capacity over quantum trajectories. IEEE Transactions on Wireless Communications, 21 (6), 3632-3647. (doi:10.1109/TWC.2021.3122962).

Record type: Article

Abstract

The unique and often-weird properties of quantum mechanics allow an information carrier to propagate through multiple trajectories of quantum channels simultaneously. This ultimately leads us to quantum trajectories with an indefinite causal order of quantum channels. It has been shown that indefinite causal order enables the violation of bottleneck capacity, which bounds the amount of the transferable classical and quantum information through a classical trajectory with a well-defined causal order of quantum channels. In this treatise, we investigate this beneficial property in the realm of both entanglement-assisted classical and quantum communications. To this aim, we derive closed-form capacity expressions of entanglement-assisted classical and quantum communication for arbitrary quantum Pauli channels over classical and quantum trajectories. We show that by exploiting the indefinite causal order of quantum channels, we obtain capacity gains over classical trajectory as well as the violation of bottleneck capacity for various practical scenarios. Furthermore, we determine the operating region where entanglement-assisted communication over quantum trajectory obtains capacity gain against classical trajectory and where the entanglement-assisted communication over quantum trajectory violates the bottleneck capacity.

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The Entanglement-Assisted Communication Capacity over Quantum Trajectories - Accepted Manuscript
Available under License University of Southampton Accepted Manuscript Licence.
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Accepted/In Press date: 15 October 2021
e-pub ahead of print date: 13 November 2021
Published date: 1 June 2022
Additional Information: Publisher Copyright: © 2002-2012 IEEE.
Keywords: Encoding, Quantum channels, Quantum communication, Quantum entanglement, Quantum mechanics, Trajectory, Wireless communication, quantum communications, quantum decoherence, quantum superposition, quantum trajectory
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Identifiers

Local EPrints ID: 452509
URI: http://eprints.soton.ac.uk/id/eprint/452509
DOI: doi:10.1109/TWC.2021.3122962
ISSN: 1536-1276
PURE UUID: 71caa904-ca29-4b7c-a886-b68fa724edbf
ORCID for Daryus Chandra: ORCID iD orcid.org/0000-0003-2406-7229

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Date deposited: 11 Dec 2021 11:25
Last modified: 17 Mar 2024 04:06

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Contributors

Author: Daryus Chandra ORCID iD
Author: Marcello Caleffi
Author: Angela Sara Cacciapuoti

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