光子辅助的宽带太赫兹通信技术

doi:10.11959/j.issn.1000-436x.2022012

通信学报 ›› 2022, Vol. 43 ›› Issue (1): 11-23.doi: 10.11959/j.issn.1000-436x.2022012

• 专题：太赫兹通信关键技术 • 上一篇下一篇

光子辅助的宽带太赫兹通信技术

余建军, 周雯, 王心怡, 王凯辉

复旦大学信息科学与工程学院，上海 200433

修回日期:2021-12-07 出版日期:2022-01-25 发布日期:2022-01-01
作者简介:余建军（1968- ），男，湖南益阳人，博士，复旦大学教授，IEEE Fellow，OSA Fellow，主要研究方向为超宽带高速光纤通信、毫米波通信和太核兹通信
周雯（1987- ），女，江苏扬州人，博士，复旦大学青年副研究员，主要研究方向为高速光纤通信、大容量光子太赫兹通信及数字信号处理算法
王心怡（1997- ），女，江苏泰州人，复旦大学硕士生，主要研究方向为宽带通信技术
王凯辉（1994- ），男，浙江平湖人，博士，复旦大学在站博士后，主要研究方向为高速光通信系统和光子毫米波/太赫兹波通信技术
基金资助:
国家自然科学基金资助项目(61935005);国家自然科学基金资助项目(91938202);国家自然科学基金资助项目(61720106015);国家自然科学基金资助项目(61835002);国家自然科学基金资助项目(61805043);国家自然科学基金资助项目(62127802)

Photonics-aided broadband terahertz communication technology

Jianjun YU, Wen ZHOU, Xinyi WANG, Kaihui WANG

School of Information Science and Technology, Fudan University, Shanghai 200433, China

Revised:2021-12-07 Online:2022-01-25 Published:2022-01-01
Supported by:
The National Natural Science Foundation of China(61935005);The National Natural Science Foundation of China(91938202);The National Natural Science Foundation of China(61720106015);The National Natural Science Foundation of China(61835002);The National Natural Science Foundation of China(61805043);The National Natural Science Foundation of China(62127802)

摘要/Abstract

摘要：

首先，介绍了光子辅助的宽带太赫兹通信系统中的关键技术。然后，介绍了大容量和长距离太赫兹无线和有线通信技术方面的研究进展。采用这些关键技术，先后实现了太赫兹信号超过1 Tbit/s的无线传输，以及超过100 Gbit/s 太赫兹信号在无太赫兹放大器的情况下无线传输54.6 m。最后，介绍了采用空芯光纤进行有线传输超过100 Gbit/s的太赫兹信号。

关键词: 多输入多输出, 多维复用技术, 概率整形技术, 太赫兹空芯光纤

Abstract:

Firstly, the key technologies in photonics-aided broadband terahertz communication systems were introduced, and then the research progress in large-capacity and long-distance terahertz communication technologies was introduced.Using these key technologies, wireless transmission of THz signals had been successively achieved exceeding 1 Tbit/s, wireless transmission of THz signals exceeding 100 Gb/s for 54.6 meters without a THz amplifier.The use of air-core optical fiber to transmit terahertz signals exceeding 100 Gbit/s was also introduced.

Key words: multiple-input multiple-output, multi-dimensional multiplexing technology, probabilistic shaping technology, THz hollow-core fiber

中图分类号:

TN92

余建军, 周雯, 王心怡, 王凯辉. 光子辅助的宽带太赫兹通信技术[J]. 通信学报, 2022, 43(1): 11-23.

Jianjun YU, Wen ZHOU, Xinyi WANG, Kaihui WANG. Photonics-aided broadband terahertz communication technology[J]. Journal on Communications, 2022, 43(1): 11-23.

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参考文献 43

[12]	IP E , KAHN J M . Feedforward carrier recovery for coherent optical communications[J]. Journal of Lightwave Technology, 2007,25(9): 2675-2692.
[13]	ZHOU X , YU J J . Multi-level,multi-dimensional coding for high-speed and high-spectral-efficiency optical transmission[J]. Journal of Lightwave Technology, 2009,27(16): 3641-3653.
[14]	YU J J , ZHANG J W . Recent progress on high-speed optical transmission[J]. Digital Communications and Networks, 2016,2(2): 65-76.
[15]	SEEDS A J , SHAMS H , FICE M J ,et al. Terahertz photonics for wireless communications[J]. Journal of Lightwave Technology, 2015,33(3): 579-587.
[16]	田遥岭, 蒋均, 黄昆 ,等. 0.34 THz肖特基二极管高速OOK信号直接检波器[J]. 红外与激光工程, 2017,46(8): 0822001.
	TIAN Y L , JIANG J , HUANG K ,et al. 0.34 THz high speed on-off keying(OOK) signal direct detector based on Schottky diode[J]. Infra-red and Laser Engineering, 2017,46(8): 0822001.
[17]	HERMELO M F , SHIH P T B , STEEG M ,et al. Spectral efficient 64-QAM-OFDM terahertz communication link[J]. Optics Express, 2017,25(16): 19360-19370.
[18]	PANG X , JIA S , OZOLINS O ,et al. Single channel 106 Gbit/s 16QAM wireless transmission in the 0.4 THz band[C]// Proceedings of Optical Fiber Communication Conference. Washington:OSA Publishing, 2017: 1-4.
[19]	JIA S , YU X B , HU H ,et al. 120 Gbit/s multi-channel THz wireless transmission and THz receiver performance analysis[J]. IEEE Photonics Technology Letters, 2017,29(3): 310-313.
[20]	LIU K X , JIA S , WANG S W ,et al. 100 Gbit/s THz photonic wireless transmission in the 350-GHz band with extended reach[J]. IEEE Photonics Technology Letters, 2018,30(11): 1064-1067.
[21]	LI X Y , DONG Z , YU J J ,et al. Fiber-wireless transmission system of 108 Gbit/s data over 80 km fiber and 2×2multiple-input multiple-output wireless links at 100 GHz W-band frequency[J]. Optics Letters, 2012,37(24): 5106.
[22]	YU J J , LI X Y , CHI N . Faster than fiber:over 100-Gbit/s signal delivery in fiber wireless integration system[J]. Optics Express, 2013,21(19): 22885.
[23]	LI X Y , XIAO J N , YU J J . Long-distance wireless mm-wave signal delivery at W-band[J]. Journal of Lightwave Technology, 2016,34(2): 661-668.
[24]	LI X Y , YU J J , XIAO J N . Demonstration of ultra-capacity wireless signal delivery at W-band[J]. Journal of Lightwave Technology, 2016,34(1): 180-187.
[1]	谢莎, 李浩然, 李玲香 ,等. 太赫兹通信技术综述[J]. 通信学报, 2020,41(5): 168-186.
	XIE S , LI H R , LI L X ,et al. Survey of terahertz communication technology[J]. Journal on Communications, 2020,41(5): 168-186.
[2]	CHEN Z , MA X , ZHANG B ,et al. A survey on terahertz communications[J]. China Communications, 2019,16(2): 1-35.
[3]	姚建铨, 迟楠, 杨鹏飞 ,等. 太赫兹通信技术的研究与展望[J]. 中国激光, 2009,36(9): 2213-2233.
[25]	WANG C , YU J J , LI X Y ,et al. Fiber-THz-fiber link for THz signal transmission[J]. IEEE Photonics Journal, 2018,10(2): 1-6.
[26]	LI X Y , YU J J , WANG K H ,et al. 120Gbit/s wireless terahertz-wave signal delivery by 375GHz-500GHz multi-carrier in a 2 × 2 MIMO system[C]// Proceedings of 2018 Optical Fiber Communications Conference and Exposition (OFC). Piscataway:IEEE Press, 2018: 1-3.
[3]	YAO J Q , CHI N , YANG P F ,et al. Study and outlook of terahertz communication technology[J]. Chinese Journal of Lasers, 2009,36(9): 2213-2233.
[4]	林长星, 陆彬, 吴秋宇 ,等. 基于混频偏置合成的高速太赫兹无线通信系统[J]. 太赫兹科学与电子信息学报, 2017,15(1): 1-6,25.
[27]	YU J J . Photonics-assisted millimeter-wave wireless communication[J]. IEEE Journal of Quantum Electronics, 2017,53(6): 1-17.
[28]	CHEN M , XIAO X , YU J J ,et al. Real-time generation and reception of OFDM signals for X-band RoF uplink with heterodyne detection[J]. IEEE Photonics Technology Letters, 2017,29(1): 51-54.
[4]	LIN C X , LU B , WU Q Y ,et al. A high speed terahertz wireless com-munication system based on mixer and bias power combination[J]. Journal of Terahertz Science and Electronic Information Technology, 2017,15(1): 1-6,25.
[5]	吴秋宇, 林长星, 陆彬 ,等. 21 km,5 Gbps,0147 THz无线通信系统设计与实验[J]. 强激光与粒子束, 2017,29(6): 1-4.
[29]	LI C H , WU M F , LIN C H ,et al. W-band OFDM RoF system with simple envelope detector down-conversion[C]// Proceedings of Optical Fiber Communication Conference. Washington:OSA Publishing, 2015:W4G.6.
[30]	ZIBAR D , SAMBARAJU R , CABALLERO A ,et al. High-capacity wireless signal generation and demodulation in 75- to 110-GHz band employing all-optical OFDM[J]. IEEE Photonics Technology Letters, 2011,23(12): 810-812.
[5]	WU Q Y , LIN C X , LU B ,et al. Design and tests of 21 km,5 Gbps,0.14 THz wireless communication system[J]. High Power Laser and Particle Beams, 2017,29(6): 1-4.
[6]	邓贤进 . 太赫兹高速通信技术研究[C]// 中国工程物理研究院科技年报. 北京:中国原子能出版社, 2014: 45-48.
[31]	MCKENNA T P , NANZER J A , CLARK T R . Experimental demonstration of photonic millimeter-wave system for high capacity point-to-point wireless communications[J]. Journal of Lightwave Technology, 2014,32(20): 3588-3594.
[32]	DUCOURNAU G , SZRIFTGISER P , BECK A ,et al. Ultrawide-bandwidth single-channel 0.4-THz wireless link combining broadband quasi-optic photomixer and coherent detection[J]. IEEE Transactions on Terahertz Science and Technology, 2014,4(3): 328-337.
[6]	DENG X J , . Research on terahertz High Speed Communication Tech-nology[C]// Science and Technology Annual Report of China Academy of Engineering Physics. Beijing:Atomic Energy Press, 2014: 45-48.
[7]	JIA S , ZHANG L , WANG S W ,et al. PS-64QAM-OFDM THz photonic-wireless transmission with 2 × 300 Gbit/s line rate[C]// Proceedings of Conference on Lasers and Electro-Optics. Washington:OSA Publishing, 2020: 1-2.
[33]	LI F , CAO Z Z , LI X Y ,et al. Fiber-wireless transmission system of PDM-MIMO-OFDM at 100 GHz frequency[J]. Journal of Lightwave Technology, 2013,31(14): 2394-2399.
[34]	GHAZISAEIDI A , FERNANDEZ D J R I , RIOS-MüLLER R ,et al. Advanced C L-band transoceanic transmission systems based on probabilistically shaped PDM-64QAM[J]. Journal of Lightwave Technology, 2017,35(7): 1291-1299.
[8]	余建军 . 宽带太赫兹通信技术[M]. 北京: 清华大学出版社, 2018.
	YU J J . Broadband terahertz communication technology[M]. Beijing: Tsinghua University Press, 2018.
[35]	CHO J , CHEN X , CHANDRASEKHAR S ,et al. Trans-Atlantic field trial using high spectral efficiency probabilistically shaped 64-QAM and single-carrier real-time 250-gbit/s 16-QAM[J]. Journal of Lightwave Technology, 2018,36(1): 103-113.
[36]	LI X Y , DONG Z , YU J J ,et al. Demonstration of ultra-high bit rate fiber wireless transmission system of 108-Gbit/s data over 80-km fiber and 2 × 2 MIMO wireless links at 100GHz W-band frequency[C]// Proceedings of Optical Fiber Communication Conference/National Fiber Optic Engineers Conference 2013. Washington:OSA Publishing, 2013:JW2A.75.
[9]	王成, 刘杰, 吴尚昀 ,等. 0.14 THz 10 Gbps无线通信系统[J]. 信息与电子工程, 2011,9(3): 265-269.
	WANG C , LIU J , WU S Y ,et al. 0.14 THz 10 Gbps wireless commu-nication system[J]. Journal of Terahertz Science and Electronic Infor-mation Technology, 2011,9(3): 265-269.
[37]	LI X Y , YU J J , ZHAO L ,et al. 1-Tbit/s millimeter-wave signal wireless delivery at D-band[J]. Journal of Lightwave Technology, 2019,37(1): 196-204.
[38]	SHARIF V , PAKARZADEH H . Terahertz hollow-core optical fibers for efficient transmission of orbital angular momentum modes[J]. Journal of Lightwave Technology, 2021,39(13): 4462-4468.
[10]	WINZER P J . High-spectral-efficiency optical modulation formats[J]. Journal of Lightwave Technology, 2012,30(24): 3824-3835.
[11]	ZHANG J W , LI X Y , DONG Z . Digital nonlinear compensation based on the modified logarithmic step size[J]. Journal of Lightwave Technology, 2013,31(22): 3546-3555.
[39]	DING J J , WANG Y Y , ZHANG J ,et al. Demonstration of 352-Gbit/s single line rate PS-4096QAM THz wired transmission over hollow-core fiber[C]// Proceedings of 26th Optoelectronics and Communications Conference. Washington:OSA Publishing, 2021:T5A.1.
[40]	YANG Y H , SHUTLER A , GRISCHKOWSKY D . Measurement of the transmission of the atmosphere from 0.2 to 2 THz[J]. Optics Express, 2011,19(9): 8830-8838.
[41]	RAPPAPORT T S , XING Y C , KANHERE O ,et al. Wireless communications and applications above 100 GHz:opportunities and challenges for 6G and beyond[J]. IEEE Access, 2019,7: 78729-78757.
[42]	SONG H J , NAGATSUMA T . Present and future of terahertz communications[J]. IEEE Transactions on Terahertz Science and Technology, 2011,1(1): 256-263.
[43]	LI W P , DING JJ , WANG YY ,et al. 54/104 meters Terahertz wireless delivery of 124.8/44.8 Gbit/s Signals without Terahertz Amplifier[C]// Asia Communications and Photonics Conference. Washington:OSA Publishing, 2021:T4D.8.

光子辅助的宽带太赫兹通信技术

Photonics-aided broadband terahertz communication technology

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