Quantum secure metrology for network sensing-based applications

Quantum secure metrology protocols harness quantum effects to probe remote systems with enhanced precision and security. Traditional QSM protocols require multi-partite entanglement, which limits its near-term implementation due to technological constraints. This paper proposes a QSM scheme that emp...

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Published in:Scientific reports 2023-07, Vol.13 (1), p.11630-11630, Article 11630
Main Authors: Rahim, Muhammad Talha, Khan, Awais, Khalid, Uman, Rehman, Junaid ur, Jung, Haejoon, Shin, Hyundong
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Khan, Awais
Khalid, Uman
Rehman, Junaid ur
Jung, Haejoon
Shin, Hyundong
description Quantum secure metrology protocols harness quantum effects to probe remote systems with enhanced precision and security. Traditional QSM protocols require multi-partite entanglement, which limits its near-term implementation due to technological constraints. This paper proposes a QSM scheme that employs Bell pairs to provide unconditional security while offering precision scaling beyond the standard quantum limit. We provide a detailed comparative performance analysis of our proposal under multiple attacks. We found that the employed controlled encoding strategy is far better than the parallel encoding of multi-partite entangled states with regard to the secrecy of the parameter. We also identify and characterize an intrinsic trade-off relationship between the maximum achievable precision and security under the limited availability of resources. The dynamic scalability of the proposed protocol makes it suitable for large-scale network sensing scenarios.
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subjects 639/766/483/1255
639/766/483/481
Humanities and Social Sciences
multidisciplinary
Parameter estimation
Protocol
Resource availability
Science
Science (multidisciplinary)
title Quantum secure metrology for network sensing-based applications
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