An Efficient Semi-Quantum Private Comparison Protocol Based on Entanglement Swapping of Four-Particle Cluster State and Bell State

被引:0
作者
Yuan Tian
Jian Li
Chaoyang Li
Xiu-Bo Chen
机构
[1] Beijing University of Post and Telecommunications,Information Security Center, State Key Laboratory of Networking and Switching Technology
[2] Beijing University of Post and Telecommunications,School of Artificial Intelligence
[3] Zhengzhou University of Light Industry,College of Software Engineering
来源
International Journal of Theoretical Physics | 2022年 / 61卷
关键词
Semi-quantum private comparison; Entanglement swapping; Four-particle cluster state; Bell state;
D O I
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中图分类号
学科分类号
摘要
Semi-quantum private comparison(SQPC) is the quantum method to compare the secrets’ equality for two distrustful classical participants without knowing the their accurate information. The four-particle cluster state is more robust against decoherence than any other four-particle state. In this paper, the novel entanglement swapping construction by the four-particle cluster state and Bell state can perform this SQPC protocol well. With the pre-shared secret key sequence, the two distrustful users can obtain promising results without leaking any information to the semi-honest third party (TP). Then, the security analyses indicate that this SQPC protocol is secure against the outside and participant attacks, and more efficient than the similar literature.
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