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集成分布式传感与量子通信网络

Integrated Distributed Sensing and Quantum Communication Networks.

作者信息

Xu Yuehan, Wang Tao, Huang Peng, Zeng Guihua

机构信息

State Key Laboratory of Advanced Optical Communication Systems and Networks, Center of Quantum Sensing and Information Processing, Shanghai Jiao Tong University, Shanghai 200240, China.

Shanghai Research Center for Quantum Sciences, Shanghai 201315, China.

出版信息

Research (Wash D C). 2024 Aug 5;7:0416. doi: 10.34133/research.0416. eCollection 2024.

DOI:10.34133/research.0416
PMID:39105049
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11298414/
Abstract

The integration of sensing and communication can achieve ubiquitous sensing while enabling ubiquitous communication. Within the gradually improving global communication, the integrated sensing and communication system based on optical fibers can accomplish various functionalities, such as urban structure imaging, seismic wave detection, and pipeline safety monitoring. With the development of quantum communication, quantum networks based on optical fiber are gradually being established. In this paper, we propose an integrated sensing and quantum network (ISAQN) scheme, which can achieve secure key distribution among multiple nodes and distributed sensing under the standard quantum limit. The continuous variables quantum key distribution protocol and the round-trip multiband structure are adopted to achieve the multinode secure key distribution. Meanwhile, the spectrum phase monitoring protocol is proposed to realize distributed sensing. It determines which node is vibrating by monitoring the frequency spectrum and restores the vibration waveform by monitoring the phase change. The scheme is experimentally demonstrated by simulating the vibration in a star structure network. Experimental results indicate that this multiuser quantum network can achieve a secret key rate of approximately 0.7 Mbits/s for each user under 10-km standard fiber transmission, and its network capacity is 8. In terms of distributed sensing, it can achieve a vibration response bandwidth ranging from 1 Hz to 2 kHz, a strain resolution of 0.50 , and a spatial resolution of 0.20 m under shot-noise-limited detection. The proposed ISAQN scheme enables simultaneous quantum communication and distributed sensing in a multipoint network, laying a foundation for future large-scale quantum networks and high-precision sensing networks.

摘要

传感与通信的融合能够在实现无处不在的通信的同时达成无处不在的传感。在全球通信不断改善的背景下,基于光纤的集成传感与通信系统可以实现多种功能,如城市结构成像、地震波检测和管道安全监测。随着量子通信的发展,基于光纤的量子网络正逐渐建立起来。在本文中,我们提出了一种集成传感与量子网络(ISAQN)方案,该方案能够在标准量子极限下实现多个节点之间的安全密钥分发以及分布式传感。采用连续变量量子密钥分发协议和往返多频段结构来实现多节点安全密钥分发。同时,提出了频谱相位监测协议以实现分布式传感。它通过监测频谱来确定哪个节点在振动,并通过监测相位变化来恢复振动波形。该方案通过在星型结构网络中模拟振动进行了实验验证。实验结果表明,在10公里标准光纤传输下,这个多用户量子网络每个用户能够实现约0.7 Mbits/s的密钥率,其网络容量为8。在分布式传感方面,在散粒噪声受限检测下,它能够实现1 Hz到2 kHz的振动响应带宽、0.50 的应变分辨率以及0.20 m的空间分辨率。所提出的ISAQN方案能够在多点网络中同时实现量子通信和分布式传感,为未来大规模量子网络和高精度传感网络奠定了基础。

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