Measurement-device-independent quantum key distribution with classical Bob and no joint measurement

被引:4
作者
He, Guang Ping [1 ]
机构
[1] Sun Yat Sen Univ, Sch Phys, Guangzhou 510275, Peoples R China
来源
QUANTUM INFORMATION PROCESSING | 2022年 / 21卷 / 01期
关键词
Quantum cryptography; Communication security; Quantum communication; Quantum key distribution; Measurement-device-independent; CRYPTOGRAPHY; STATE; SECURITY; SYSTEMS;
D O I
10.1007/s11128-021-03385-6
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
Measurement-device-independent quantum key distribution (MDI-QKD) provides a method for secret communication whose security does not rely on trusted measurement devices. In all existing MDI-QKD protocols, the participant Charlie has to perform Bell state measurement or other joint measurements. Here, we propose an MDI-QKD protocol which requires individual measurements only. Meanwhile, all operations of the receiver Bob are classical, without the need for preparing and measuring quantum systems. Thus, the implementation of the protocol has a lower technical requirement on Bob and Charlie.
引用
收藏
页数:15
相关论文
共 50 条
[31]   Higher key rate of measurement-device-independent quantum key distribution through joint data processing [J].
Jiang, Cong ;
Yu, Zong-Wen ;
Hu, Xiao-Long ;
Wang, Xiang-Bin .
PHYSICAL REVIEW A, 2021, 103 (01)
[32]   Finite-key analysis for measurement-device-independent quantum key distribution [J].
Song, Ting-Ting ;
Wen, Qiao-Yan ;
Guo, Fen-Zhuo ;
Tan, Xiao-Qing .
PHYSICAL REVIEW A, 2012, 86 (02)
[33]   Measurement-device-independent Quantum Key Distribution with Inaccurate Coherent Sources [J].
Kang, Guo-Dong .
PROCEEDINGS OF THE THIRD INTERNATIONAL CONFERENCE ON COMPUTER SCIENCE AND APPLICATION ENGINEERING (CSAE2019), 2019,
[34]   A High Dimensional Measurement-Device-Independent Quantum Key Distribution Scheme Based on Optical Quantum State Fusion and Fission [J].
Li, Li ;
Zhu, Changhua ;
Quan, Dongxiao ;
Pei, Changxing .
INTERNATIONAL JOURNAL OF THEORETICAL PHYSICS, 2018, 57 (12) :3902-3911
[35]   Measurement-device-independent Quantum Key Distribution based on W state [J].
Hu, Min ;
Guo, Banghong .
SEVENTH SYMPOSIUM ON NOVEL PHOTOELECTRONIC DETECTION TECHNOLOGY AND APPLICATIONS, 2021, 11763
[36]   Measurement-device-independent quantum key distribution with odd coherent state [J].
Dong Chen ;
Zhao Shang-Hong ;
Zhang Ning ;
Dong Yi ;
Zhao Wei-Hu ;
Liu Yun .
ACTA PHYSICA SINICA, 2014, 63 (20)
[37]   Plug-and-play measurement-device-independent quantum key distribution [J].
Choi, Yujun ;
Kwon, Osung ;
Woo, Minki ;
Oh, Kyunghwan ;
Han, Sang-Wook ;
Kim, Yong-Su ;
Moon, Sung .
PHYSICAL REVIEW A, 2016, 93 (03)
[38]   Measurement-device-independent quantum key distribution with uncharacterized coherent sources [J].
Guo-Dong Kang ;
Qing-Ping Zhou ;
Mao-Fa Fang .
Quantum Information Processing, 2020, 19
[39]   Measurement-Device-Independent Quantum Key Distribution over 200 km [J].
Tang, Yan-Lin ;
Yin, Hua-Lei ;
Chen, Si-Jing ;
Liu, Yang ;
Zhang, Wei-Jun ;
Jiang, Xiao ;
Zhang, Lu ;
Wang, Jian ;
You, Li-Xing ;
Guan, Jian-Yu ;
Yang, Dong-Xu ;
Wang, Zhen ;
Liang, Hao ;
Zhang, Zhen ;
Zhou, Nan ;
Ma, Xiongfeng ;
Chen, Teng-Yun ;
Zhang, Qiang ;
Pan, Jian-Wei .
PHYSICAL REVIEW LETTERS, 2014, 113 (19)
[40]   Practical measurement-device-independent quantum key distribution with advantage distillation [J].
Li-Wen Hu ;
Chun-Mei Zhang ;
Hong-Wei Li .
Quantum Information Processing, 22
12345