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Auteurs principaux: Zaballos, Agustin, Mallorqui, Adria, Navarro, Joan
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2404.16463
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author Zaballos, Agustin
Mallorqui, Adria
Navarro, Joan
author_facet Zaballos, Agustin
Mallorqui, Adria
Navarro, Joan
contents Device redundancy is one of the most well-known mechanisms in distributed systems to increase the overall system fault tolerance and, consequently, trustworthiness. Existing algorithms in this regard aim to exchange a significant number of messages among nodes to identify and agree which communication links or nodes are faulty. This approach greatly degrades the performance of those wireless communication networks exposed to limited available bandwidth and/or energy consumption due to messages flooding. Lately, quantum-assisted mechanisms have been envisaged as an appealing alternative to improve the performance in this kind of communication networks and have been shown to obtain levels of performance close to the ones achieved in ideal conditions. The purpose of this paper is to further explore this approach by using super-additivity and superposed quantum trajectories in quantum Internet to obtain a higher system trustworthiness. More specifically, the wireless communication network that supports the permafrost telemetry service for the Antarctica together with five operational modes (three of them using classical techniques and two of them using quantum-assisted mechanisms) have been simulated. Obtained results show that the new quantum-assisted mechanisms can increase the system performance by up to a 28%.
format Preprint
id arxiv_https___arxiv_org_abs_2404_16463
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Quantum-assisted trustworthiness for the Quantum Internet
Zaballos, Agustin
Mallorqui, Adria
Navarro, Joan
Quantum Physics
Networking and Internet Architecture
81-11
C.2.1
Device redundancy is one of the most well-known mechanisms in distributed systems to increase the overall system fault tolerance and, consequently, trustworthiness. Existing algorithms in this regard aim to exchange a significant number of messages among nodes to identify and agree which communication links or nodes are faulty. This approach greatly degrades the performance of those wireless communication networks exposed to limited available bandwidth and/or energy consumption due to messages flooding. Lately, quantum-assisted mechanisms have been envisaged as an appealing alternative to improve the performance in this kind of communication networks and have been shown to obtain levels of performance close to the ones achieved in ideal conditions. The purpose of this paper is to further explore this approach by using super-additivity and superposed quantum trajectories in quantum Internet to obtain a higher system trustworthiness. More specifically, the wireless communication network that supports the permafrost telemetry service for the Antarctica together with five operational modes (three of them using classical techniques and two of them using quantum-assisted mechanisms) have been simulated. Obtained results show that the new quantum-assisted mechanisms can increase the system performance by up to a 28%.
title Quantum-assisted trustworthiness for the Quantum Internet
topic Quantum Physics
Networking and Internet Architecture
81-11
C.2.1
url https://arxiv.org/abs/2404.16463