A Segment-based Multipath Distribution Method in Partially-Trusted Relay Quantum Networks

As a promising application of quantum information technology, Quantum Key Distribution (QKD) can provide information-theoretically secure key exchange for adjacent communication parties. To achieve long-distance secure communication and scale expansion against inherent channel loss, trusted relays,...

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Bibliographic Details
Published in:IEEE communications magazine 2023-12, Vol.61 (12), p.1-7
Main Authors: Wang, Mingjun, Li, Jian, Xue, Kaiping, Li, Ruidong, Yu, Nenghai, Li, Yangyang, Liu, Yifeng, Sun, Qibin, Lu, Jun
Format: Magazinearticle
Language:English
Subjects:
Cryptography
Encryption
Networks
Quantum channels
Quantum cryptography
Quantum phenomena
Qubit
Relay
Relays
Security
Segments
Sun
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Summary:As a promising application of quantum information technology, Quantum Key Distribution (QKD) can provide information-theoretically secure key exchange for adjacent communication parties. To achieve long-distance secure communication and scale expansion against inherent channel loss, trusted relays, which are assumed to be absolutely secure, are introduced into QKD networks. However, in practice, trusted relays may be compromised by attacks from ubiquitous eavesdroppers even protected by powerful hardware. Thus, how to ensure the security of end-to-end key distribution in partially-trusted relay QKD networks with the coexistence of trusted relays and untrusted relays becomes a challenging but urgent problem to be solved. To address this critical problem, in this article, we design a segment-based multipath key distribution method. The basic idea of the method is to maximize the security of the end-toend key distribution through the segment-based multipath key distribution. Under the premise of security level requirements, we further propose a flexible key reconstruction scheme to improve the efficiency of key distribution and obtain available secret keys as many as possible. The extensive simulations are conducted and the results reveal that our method significantly outperforms the traditional multipath QKD method in terms of both security and efficiency.
ISSN:0163-6804
1558-1896
DOI:10.1109/MCOM.010.2200672