Semiquantum private comparison based on Bell states without quantum measurements from the classical user
- URL: http://arxiv.org/abs/2205.04927v4
- Date: Wed, 4 Sep 2024 16:02:57 GMT
- Title: Semiquantum private comparison based on Bell states without quantum measurements from the classical user
- Authors: Mao-Jie Geng, Xia Li, Tian-Yu Ye,
- Abstract summary: We propose a novel semiquantum private comparison protocol based on Bell states.
TP is assumed to be semi-honest in the sense that she may take all possible attacks to steal users' private inputs except conspiring with anyone.
Our protocol can take advantage over previous SQPC protocols based on Bell states in qubit efficiency.
- Score: 4.4053348026380235
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: In this paper, we propose a novel semiquantum private comparison (SQPC) protocol based on Bell states, which enables one quantum user and one classical user to compare the equality of their private inputs with the help of a semi-honest quantum third party (TP). TP is assumed to be semi-honest in the sense that she may take all possible attacks to steal users' private inputs except conspiring with anyone. The security analysis validates that our protocol can resist not only the attacks from internal participants but also the attacks from an external eavesdropper. Besides, our protocol only asks TP to perform Bell basis measurements but doesn't need quantum entanglement swapping; and it releases the classical user from conducting quantum measurements and having a quantum memory. Moreover, our protocol can take advantage over previous SQPC protocols based on Bell states in qubit efficiency. Finally, our protocol can be generalized into its counterpart of the collective-dephasing noise quantum channel.
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