雷达通信频谱共享及一体化：综述与展望

刘凡; 袁伟杰; 原进宏; 张健; 费泽松; 周建明

doi:10.12000/JR20113

雷达通信频谱共享及一体化：综述与展望

doi: 10.12000/JR20113

刘凡^1,,
袁伟杰^2, ,,
原进宏^2, ,,
张健^3,,
费泽松⁴,
周建明^4,

1.
伦敦大学学院电子与电气工程系伦敦 WC1E 7JE
2.
新南威尔士大学电气工程与通信学院悉尼 NSW 2052
3.
悉尼科技大学全球大数据技术中心悉尼 NSW 2007
4.
北京理工大学信息与电子学院北京 100081

详细信息

作者简介:
刘　凡(1992–)，男，湖北潜江人，博士。2018年在北京理工大学信息与电子学院获得博士学位，现担任英国伦敦大学学院“玛丽·居里”研究员。主要研究方向为雷达通信一体化、车联网、毫米波通信等，目前已发表论文40余篇

袁伟杰(1991–)，男，四川达州人，博士。2019年在悉尼科技大学获得博士学位，现为新南威尔士大学博士后。主要研究方向为无线通信和信号处理，目前已经发表学术论文30余篇

原进宏(1969–)，男，山西人，博士，教授，IEEE Fellow。1997年在北京理工大学获得博士学位，而后加入悉尼大学电气工程学院担任研究员。于2000年加入新南威尔士大学，现为新南威尔士大学电气工程与通信学院教授及通信学科负责人。主要研究方向为差错控制编码、无线通信理论及信息论。已经出版著作2本，在国际期刊和会议上发表学术论文超过400篇，并得到了多项国际发明专利授权

张　健(ZHANG J. Andrew, 1973–)，男，江苏张家港市人，博士，副教授。2004年在澳洲国立大学获得博士学位，现为悉尼科技大学副教授。主要研究方向为无线通信和信号处理，目前侧重于雷达通信一体化、无线感知和模式识别以及毫米波通信。已经发表论文180多篇

费泽松(1977–)，男，安徽人，博士，教授。2004年在北京理工大学信息与电子学院获工学博士学位。主要研究方向为信道编码、5G/6G移动通信关键技术、雷达通信一体化、低轨卫星接入与组网、MIMO等。目前已经发表论文150余篇

周建明(1976–)，男，浙江省江山人，博士，副研究员。2004年获北京理工大学电磁场与微波技术专业工学博士学位，2004年至今在北京理工大学信息与电子学院从事教学和科研方面的工作，主要研究方向为微波、毫米波电路与系统、机载宽带数据链、相控阵通信和雷达一体化。主持1项国家自然科学基金项目，已完成10多项科技合作项目。发表论文10多篇。获批3项发明专利

通讯作者:
袁伟杰 weijie.yuan@unsw.edu.au

原进宏 j.yuan@unsw.edu.au

责任主编：张群 Corresponding Editor: ZHANG Qun
中图分类号: TN929.5
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出版历程
- 收稿日期: 2020-08-02
- 修回日期: 2020-10-14
- 网络出版日期: 2020-11-03
- 刊出日期: 2021-06-28

Radar-communication Spectrum Sharing and Integration: Overview and Prospect

LIU Fan^1
,,
YUAN Weijie^{2
, ,},
YUAN Jinhong^{2
, ,},
ZHANG J. Andrew^3
,,
FEI Zesong⁴,
ZHOU Jianming^4
,

1.
Department of Electronic and Electrical Engineering, University College London, London WC1E 7JE, UK
2.
School of Electrical Engineering and Telecommunications, University of New South Wales, Sydney NSW 2052, Australia
3.
Global Big Data Technologies Centre, University of Technology Sydney, Sydney NSW 2007, Australia
4.
School of Information and Electronics, Beijing Institute of Technology, Beijing 100081, China

More Information

Corresponding author: YUAN Weijie, weijie.yuan@unsw.edu.au; YUAN Jinhong, j.yuan@unsw.edu.au

摘要

摘要: 随着无线通信技术的发展，全球通信产业对于无线频谱的需求日益增加。在此背景下，雷达与通信的频谱共享(RCSS)引起了工业界和学术界的极大关注。其内涵不仅包括促成雷达与通信设备的同频共存、互不干扰，从而高效利用频谱，还包括设计一种兼容二者的新型一体化系统，使得该系统能同时完成信息传输与目标探测两种功能。该文围绕雷达与通信频谱共享的两种解决方案：(1)雷达与通信系统的同频共存(RCC); (2)雷达通信一体化(DFRC)系统设计，进行了深入而系统的综述。具体而言，该文首先讨论雷达通信在多个频段共存的实例，然后简要介绍了雷达通信一体化技术在多个领域的应用场景。进一步地，讨论雷达通信同频共存和一体化系统的研究进展。最后，总结全文并讨论了该领域内的若干开放问题。
- 频谱共享 /
- 雷达通信同频共存 /
- 雷达通信一体化
Abstract: The need of extra wireless spectrum is on the rise, given the rapid development of global wireless communication industry. To this end, Radar and Communication Spectrum Sharing (RCSS) has gained considerable attentions recently from both industry and academia. In particular, RCSS aims not only at enabling the spectral cohabitation of radar and communication systems, but also at designing a novel joint system that is capable of both functionalities. In this paper, a systematic overview of RCSS by focusing on the two main research directions are provided, i.e., Radar-Communication Coexistence (RCC) and Dual-Functional Radar-Communication (DFRC). We commence by discussing the coexistence examples of radar and communication at various frequency bands, and then elaborate on the practical application scenarios of the DFRC techniques. As a further step, the state-of-the-art approaches of both RCC and DFRC are reviewed. Finally we conclude the paper by identifying a number of open problems in the research area of RCSS.
- Spectrum sharing /
- Radar-Communication Coexistence (RCC) /
- Dual-Functional Radar-Communication (DFRC)

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图 1 RCSS技术的两条研究路径

Figure 1. The two research directions of RCSS

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