OTFS技术研究现状与展望

龙航; 王森; 徐林飞; 贾寅华; 代璐

doi:10.11959/j.issn.1000-0801.2021221

您当前的位置：

首页 >

文章列表页 >

OTFS技术研究现状与展望

专题：6G | 更新时间：2024-06-05

- OTFS技术研究现状与展望
- OTFS technology research and prospect
- 电信科学 2021年37卷第9期页码：57-63
- 作者机构：
  
  1. 北京邮电大学，北京 100876
  2. 中国移动通信有限公司研究院，北京 100053
- 作者简介：
  
  [ "龙航（1984− ），男，博士，北京邮电大学教授，主要研究方向为无线通信技术" ]
  [ "王森（1983− ），男，博士，中国移动通信有限公司研究院高级研究员，主要研究方向为移动通信技术" ]
  [ "徐林飞（1996− ），男，北京邮电大学硕士生，主要研究方向为多载波调制技术" ]
  [ "贾寅华（1998− ），男，北京邮电大学硕士生，主要研究方向为多载波调制技术" ]
  [ "代璐（1998− ），女，北京邮电大学硕士生，主要研究方向为多载波调制技术" ]
- 基金信息：
  
  国家自然科学基金资助项目;The National Natural Science Foundation of China(61931005);北京邮电大学-中国移动研究院联合创新中心资助项目;Funded by Beijing University of Posts and Telecommunications-China Mobile Research Institute Joint Innovation Center
- DOI：10.11959/j.issn.1000-0801.2021221
  中图分类号： TP393
- 网络出版日期：2021-09，
  
  纸质出版日期：2021-09-20
- 稿件说明：
移动端阅览
龙航, 王森, 徐林飞, 等. OTFS技术研究现状与展望[J]. 电信科学, 2021,37(9):57-63.

Hang LONG, Sen WANG, Linfei XU, et al. OTFS technology research and prospect[J]. Telecommunications science, 2021, 37(9): 57-63.
龙航, 王森, 徐林飞, 等. OTFS技术研究现状与展望[J]. 电信科学, 2021,37(9):57-63. DOI： 10.11959/j.issn.1000-0801.2021221.

Hang LONG, Sen WANG, Linfei XU, et al. OTFS technology research and prospect[J]. Telecommunications science, 2021, 37(9): 57-63. DOI： 10.11959/j.issn.1000-0801.2021221.

摘要

正交时频空（orthogonal time frequency space，OTFS）技术是近年来出现的一种新型多载波调制技术。在 OTFS 技术中，数据信号在时延—多普勒域产生，经过逆偶有限傅里叶变换实现信号的时频二维扩展，以解决正交频分复用（orthogonal frequency division multiplexing，OFDM）技术在时频双选信道下干扰严重的问题。介绍了OTFS技术的基本原理，通过仿真验证其相比于OFDM技术的优势。对其研究现状进行分析总结，指出 OTFS 技术中的多址接入、信道估计和线性接收机等研究方向目前有待解决的问题。对 OTFS 技术在雷达—通信一体化系统中的应用前景进行分析和展望。

Abstract

Recently

a new multi-carrier modulation technique termed orthogonal time frequency space (OTFS) was proposed.In the OTFS modulation

the data symbols are modulated at the delay-Doppler plane and spread on all the time-frequency resource elements with the inverse symplectic finite Fourier transform.Compared with the conventional orthogonal frequency division multiplexing (OFDM) technique

the OTFS modulation performs better in the time-varying and frequency-selective channel.The state of art of OTFS was reviewed and summarized.Simulation results were presented to demonstrate the performance advantage of OTFS over the conventional OFDM.The remainder problems of multi-accessing

channel estimation and linear equalization in OTFS was given.The application of OTFS signal in joint Radar and communication system was also analyzed.

关键词

Keywords

references

IMT-2020(5G)推进组 . 5G愿景与需求白皮书 [R ] . 2014 .

IMT-2020 (5G) Promotion Group . White paper on 5G vision and demand [R ] . 2014 .

赵亚军 , 郁光辉 , 徐汉青 . 6G移动通信网络:愿景、挑战与关键技术 [J ] . 中国科学:信息科学 , 2019 , 49 ( 8 ): 963 - 987 .

ZHAO Y J , YU G H , XU H Q . 6G mobile communication net-works:vision,challenges,and key technologies [J ] . Scientia Si-nica (Informationis) , 2019 , 49 ( 8 ): 963 - 987 .

陈亮 , 余少华 . 6G 移动通信发展趋势初探(特邀) [J ] . 光通信研究 , 2019 ( 4 ): 1 - 8 .

CHEN L , YU S H . Preliminary study on the trend of 6G mobile communication [J ] . Study on Optical Communications , 2019 ( 4 ): 1 - 8 .

TIWARI S , DAS S S , RANGAMGARI V . Low complexity LMMSE receiver for OTFS [J ] . IEEE Communications Letters , 2019 , 23 ( 12 ): 2205 - 2209 .

HADANI R , RAKIB S S . OTFS methods of data channel characterization and uses thereof:US9444514 [P ] .2016-09-13.

HADANI R , RAKIB S , TSATSANIS M , et al . Orthogonal time frequency space modulation [C ] // 2017 IEEE Wireless Communications and Networking Conference (WCNC) . Piscataway:IEEE Press , 2017 : 1 - 6 .

HADANI R , MONK A . OTFS—a novel modulation technique meeting 5G high mobility and massive MIMO challenges [R ] . 2017 .

李伶珺 . 抗多普勒频移正交时频空系统性能分析与优化 [D ] . 成都:西南交通大学 , 2019 .

LI L J . Performance analysis and optimizition of Doppler resi-lient orthogonal time frequency space ststems [D ] . Chengdu:Southwest Jiaotong University , 2019 .

SURABHI G D , AUGUSTINE R M , CHOCKALINGAM A . Peak-to-average power ratio of OTFS modulation [J ] . IEEE Communications Letters , 2019 , 23 ( 6 ): 999 - 1002 .

NIMR A , CHAFII M , MATTHE M , et al . Extended GFDM framework:OTFS and GFDM comparison [C ] // 2018 IEEE Global Communications Conference (GLOBECOM) . Piscataway:IEEE Press , 2018 : 1 - 6 .

REZAZADEHREYHANI A , FARHANG A , JI M Y , et al . Analysis of discrete-time MIMO OFDM-based orthogonal time frequency space modulation [C ] // 2018 IEEE International Conference on Communications (ICC) . Piscataway:IEEE Press , 2018 : 1 - 6 .

FARHANG A , REZAZADEHREYHANI A , DOYLE L E , et al . Low complexity modem structure for OFDM-based orthogonal time frequency space modulation [J ] . IEEE Wireless Communi-cations Letters , 2018 , 7 ( 3 ): 344 - 347 .

RAVITEJA P , HONG Y , VITERBO E , et al . Practical pulse-shaping waveforms for reduced-cyclic-prefix OTFS [J ] . IEEE Transactions on Vehicular Technology , 2019 , 68 ( 1 ): 957 - 961 .

TIWARI S , DAS S S . Circularly pulse-shaped orthogonal time frequency space modulation [J ] . Electronics Letters , 2020 , 56 ( 3 ): 157 - 160 .

HOSSAIN M N , SUGIURA Y , SHIMAMURA T , et al . Waveform design of low complexity WR-OTFS system for the OOB power reduction [C ] // 2020 IEEE Wireless Communications and Networking Conference Workshops (WCNCW) . Piscataway:IEEE Press , 2020 : 1 - 5 .

MARSALEK R , BLUMENSTEIN J , PROKES A , et al . Orthogonal time frequency space modulation:pilot power allocation and nonlinear power amplifiers [C ] // 2019 IEEE International Symposium on Signal Processing and Information Technology (ISSPIT) . Piscataway:IEEE Press , 2019 : 1 - 4 .

GAO S , ZHENG J P . Peak-to-average power ratio reduction in pilot-embedded OTFS modulation through iterative clipping and filtering [J ] . IEEE Communications Letters , 2020 , 24 ( 9 ): 2055 - 2059 .

NAVEEN C , SUDHA V . Peak-to-Average power ratio reduction in OTFS modulation using companding technique [C ] // 2020 5th International Conference on Devices,Circuits and Systems (ICDCS) . Piscataway:IEEE Press , 2020 : 140 - 143 .

DING Z G , SCHOBER R , FAN P Z , et al . OTFS-NOMA:an efficient approach for exploiting heterogenous user mobility profiles [J ] . IEEE Transactions on Communications , 2019 , 67 ( 11 ): 7950 - 7965 .

CHATTERJEE A , RANGAMGARI V , TIWARI S , et al . Nonorthogonal multiple access with orthogonal time–frequency space signal transmission [J ] . IEEE Systems Journal , 2021 , 15 ( 1 ): 383 - 394 .

SURABHI G D , AUGUSTINE R M , CHOCKALINGAM A . Multiple access in the delay-Doppler domain using OTFS modulation [EB ] . 2019 .

KHAMMAMMETTI V , MOHAMMED S K . OTFS-based multiple-access in high Doppler and delay spread wireless channels [J ] . IEEE Wireless Communications Letters , 2019 , 8 ( 2 ): 528 - 531 .

AUGUSTINE R M , CHOCKALINGAM A . Interleaved time-frequency multiple access using OTFS modulation [C ] // 2019 IEEE 90th Vehicular Technology Conference (VTC2019-Fall) . Piscataway:IEEE Press , 2019 : 1 - 5 .

RAKIB S , HADANI R . Multiple access in wireless telecommunications system for high-mobility applications:US9722741 [P ] .2017-08-01.

刘天俊 . 基于正交时频空(OTFS)系统的导频序列设计与信道估计 [D ] . 成都:西南交通大学 , 2019 .

LIU T J . On pilot sequence design and channel estimation in OTFS system [D ] . Chengdu:Southwest Jiaotong University , 2019 .

SHEN W Q , DAI L L , AN J P , et al . Channel estimation for orthogonal time frequency space (OTFS) massive MIMO [J ] . IEEE Transactions on Signal Processing , 2019 , 67 ( 16 ): 4204 - 4217 .

RAVITEJA P , PHAN K T , HONG Y , et al . Embedded delay-Doppler channel estimation for orthogonal time frequency space modulation [C ] // 2018 IEEE 88th Vehicular Technology Conference (VTC-Fall) . Piscataway:IEEE Press , 2018 : 1 - 5 .

RAVITEJA P , PHAN K T , HONG Y . Embedded pilot-aided channel estimation for OTFS in delay–Doppler channels [J ] . IEEE Transactions on Vehicular Technology , 2019 , 68 ( 5 ): 4906 - 4917 .

GAUDIO L , KOBAYASHI M , BISSINGER B , et al . Performance analysis of joint radar and communication using OFDM and OTFS [C ] // 2019 IEEE International Conference on Communications Workshops (ICC Workshops) . Piscataway:IEEE Press , 2019 : 1 - 6 .

GAUDIO L , KOBAYASHI M , CAIRE G , et al . On the effectiveness of OTFS for joint radar parameter estimation and communication [J ] . IEEE Transactions on Wireless Communications , 2020 , 19 ( 9 ): 5951 - 5965 .

SURABHI G D , CHOCKALINGAM A . Low-complexity linear equalization for OTFS modulation [J ] . IEEE Communications Letters , 2020 , 24 ( 2 ): 330 - 334 .

RAVITEJA P , PHAN K T , HONG Y , et al . Interference cancellation and iterative detection for orthogonal time frequency space modulation [J ] . IEEE Transactions on Wireless Communications , 2018 , 17 ( 10 ): 6501 - 6515 .

LI L J , LIANG Y , FAN P Z , et al . Low complexity detection algorithms for OTFS under rapidly time-varying channel [C ] // 2019 IEEE 89th Vehicular Technology Conference (VTC2019-Spring) . Piscataway:IEEE Press , 2019 : 1 - 5 .

ZHANG M C , WANG F G , YUAN X J , et al . 2D structured turbo compressed sensing for channel estimation in OTFS systems [C ] // 2018 IEEE International Conference on Communication Systems (ICCS) . Piscataway:IEEE Press , 2018 : 45 - 49 .

THAJ T , VITERBO E . Low complexity iterative rake detector for orthogonal time frequency space modulation [C ] // 2020 IEEE Wireless Communications and Networking Conference (WCNC) . Piscataway:IEEE Press , 2020 : 1 - 6 .

YUAN W J , WEI Z Q , YUAN J H , et al . A simple variational Bayes detector for orthogonal time frequency space (OTFS) modulation [J ] . IEEE Transactions on Vehicular Technology , 2020 , 69 ( 7 ): 7976 - 7980 .

LI L , WEI H , HUANG Y , et al . A simple two-stage equalizer with simplified orthogonal time frequency space modulation over rapidly time-varying channels [EB ] . 2017 .

ZEMEN T , HOFER M , LOESCHENBRAND D . Low-complexity equalization for orthogonal time and frequency signaling (OTFS) [EB ] . 2017 .

浏览量

937

下载量

CSCD

文章被引用时，请邮件提醒。

提交

工具集

关联资源

HSM：支持6G密集部署和高速移动性场景的新型网络架构

基于优化CCSK调制的低轨卫星通信导航一体化信号设计方法

基于IRS辅助的OFDM-IM系统设计

基于准恒包络正交频分复用的临近空间通信抗衰落技术

非正交多址系统资源分配研究综述