无源物联网通信研究进展与演进思考

李源; 张雨露; 丁郁; 马帅; 肖善鹏; 肖建明; 李建

doi:10.11959/j.issn.2096-3750.2023.00315

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无源物联网通信研究进展与演进思考

专题：短距无线通信技术 | 更新时间：2024-08-16

- 无源物联网通信研究进展与演进思考
- Research progress and evolution prospect of passive internet of things communication
- 物联网学报 2023年7卷第3期页码：15-23
- 作者机构：
  
  1. 中国移动通信研究院物联网技术与应用研究所，北京 100032
  2. 中国移动通信集团供应链管理中心，北京 100032
  3. 电子科技大学，四川成都 611731
- 作者简介：
  
  [ "李源（1990- ），女，中国移动通信研究院物联网技术与应用研究所工程师，主要研究方向为无源物联网、车联网、物联网体系架构、无线通信技术等" ]
  [ "张雨露（1997- ），女，中国移动通信研究院物联网技术与应用研究所研究员，主要研究方向为无源物联网、行业现场网技术及标准等" ]
  [ "丁郁（1984- ），女，博士，中国移动通信研究院物联网技术与应用研究所研究员，主要研究方向为车联网关键技术与应用、物联网通信技术、下一代物联网体系架构等" ]
  [ "马帅（1981- ），男，中国移动通信研究院物联网技术与应用研究所副所长，主要研究方向为无源物联网、工业现场网、车联网、物联网感知等" ]
  [ "肖善鹏（1976- ），男，中国移动通信研究院物联网技术与应用研究所所长、高级工程师，主要研究方向为物联网新技术和产业数字化等" ]
  [ "肖建明（1967- ），男，博士，中国移动通信集团供应链管理中心物流管理与运营部副经理、教授级高级工程师，主要研究方向为电磁场与微波技术、天线和现代供应链数智化转型管理等" ]
  [ "李建（1983- ），男，博士，电子科技大学教授，主要研究方向为射频识别、物联网、移动通信等无线通信核心芯片与集成系统" ]
- 基金信息：
  
  中国移动研究院-中关村创新院联合研发项目;The Joint Project of China Mobile Research Institute＆ X-NET(2022H002)
- DOI：10.11959/j.issn.2096-3750.2023.00315
  中图分类号： TN919
- 纸质出版日期：2023-09-30，
  
  网络出版日期：2023-09，
- 稿件说明：
移动端阅览
李源, 张雨露, 丁郁, 等. 无源物联网通信研究进展与演进思考[J]. 物联网学报, 2023,7(3):15-23.

YUAN LI, YULU ZHANG, YU DING, et al. Research progress and evolution prospect of passive internet of things communication. [J]. Chinese journal on internet of things, 2023, 7(3): 15-23.
李源, 张雨露, 丁郁, 等. 无源物联网通信研究进展与演进思考[J]. 物联网学报, 2023,7(3):15-23. DOI： 10.11959/j.issn.2096-3750.2023.00315.

YUAN LI, YULU ZHANG, YU DING, et al. Research progress and evolution prospect of passive internet of things communication. [J]. Chinese journal on internet of things, 2023, 7(3): 15-23. DOI： 10.11959/j.issn.2096-3750.2023.00315.

摘要

无源物联网是产业数字化转型升级的基础性使能技术，近年来，射频识别等无源物联网通信技术以其低成本、零功耗、易部署等优势被广泛应用于资产管理领域。在此背景下，介绍了无源物联网通信技术最新研究进展，详细分析了潜在演进趋势，深入思考无源物联网通信技术的发展瓶颈及技术挑战，并提出与蜂窝网络深度融合的新型无源物联网通信解决方案与关键技术研究方向，希望能为无源物联网通信技术发展提供新的思路。

Abstract

Passive internet of things (IoT) is the fundamentally enabling technology of promoting digital transformation and upgrading of industries.In recent years

passive IoT communication technology such as radio frequency identification has been widely used in asset management fields due to its advantages of low cost

zero power consumption

and easy deployment.In this context

passive IoT communication technology and the latest research progress were introduced

the potential evolution prospects of passive IoT were analyzed.Based on that

development bottlenecks and challenges of passive IoT communication were given

a novel passive IoT communication system with deep fusion of the cellular system was presented

and the key technology research directions of this field were proposed.It is aimed to inspire new thoughts for the development of passive IoT communication technology.

关键词

无源物联网通信反向散射环境能量采集蜂窝系统

Keywords

passive IoT communicationbackscatterambient energy harvestingcellular system

references

于季弘, 刘昊, 王帅 . 无源物联网综述——从感知通信与管理的视角[J]. 重庆邮电大学学报:自然科学版, 2020,32(5): 16.

YU J H, LIU H, WANG S . Survey on passive internet of things:from the perspective of sensing,communications and management[J]. Journal of Chongqing University of Posts and Telecommunications(Natural Science Edition), 2020,32(5): 16.

OPPO研究院. 零功耗通信白皮书[R]. 2022.

OPPO Research Institute. Zero power communication[R]. 2022.

崔子琦, 王公仆, 魏旭昇 ,等. 反向散射通信的未来应用与技术挑战[J]. 移动通信, 2021,45(4): 29-36.

CUI Z Q, WANG G P, WEI X S ,et al. Future applications and technical challenges of backscatter communications[J]. Mobile Communications, 2021,45(4): 29-36.

TORO U S, WU K S, LEUNG V C M . Backscatter wireless communications and sensing in green internet of things[J]. IEEE Transactions on Green Communications and Networking, 2022,6(1): 37-55.

AIoT星图研究院. 中国RFID无源物联网市场调研报告（2022版）[R]. 2022.

AIoT Xingtu Research Institute. China RFID passive internet of things market research report(2022)[R]. 2022.

STOCKMAN H . Communication by means of reflected power[J]. Proceedings of the IRE, 1948,36(10): 1196-1204.

黄玉兰 . 物联网射频识别（RFID）核心技术详解（第三版）[M]. 北京: 人民邮电出版社, 2016.

HUANG Y L . Radio frequency identification development internals (Version 3)[M]. Beijing: Posts ＆ Telecom Press, 2016.

HU G, ZHU Y, ZHAO W ,et al. Signal detection for batteryless backscatter systems with multiple-antenna tags[C]// Proceedings of 2019 IEEE/CIC International Conference on Communications Workshops in China (ICCC Workshops).[S.l.:s.n], 2019.

CHEN C, WANG G P, GUAN H ,et al. Transceiver design and signal detection in backscatter communication systems with multiple-antenna tags[J]. IEEE Transactions on Wireless Communications, 2020,19(5): 3273-3288.

MA W Y, WANG W, JIANG T . Joint energy harvest and information transfer for energy beamforming in backscatter multiuser networks[J]. IEEE Transactions on Communications, 2021,69(2): 1317-1328.

YANG C C, GUMMESON J, SAMPLE A . Riding the airways:ultra-wideband ambient backscatter via commercial broadcast systems[C]// Proceedingsof IEEE INFOCOM 2017 - IEEE Conference on Computer Communications. Piscataway:IEEE Press, 2017: 1-9.

MEKKI K, NECIBI O, DINIS H ,et al. Backscatter analysis in UWB chipless RFID based on UWB-IR[C]// Proceedings of 2021 IEEE Texas Symposium on Wireless and Microwave Circuits and Systems (WMCS). Piscataway:IEEE Press, 2021: 1-5.

OH S J, KHAN D, IN S H ,et al. A solar/thermoelectric/triboelectric/vibration/RF hybrid energy harvesting based high efficiency wireless power receiver[C]// Proceedings of 2019 26th IEEE International Conference on Electronics,Circuits and Systems (ICECS). Piscataway:IEEE Press, 2020: 911-914.

LIU Y F, SHENG X T, FANG K P ,et al. Energy efficiency maximization in bistatic backscatter communications with QoS constraint[C]// Proceedings of 2019 IEEE 19th International Conference on Communication Technology (ICCT). Piscataway:IEEE Press, 2020: 920-925.

RANSFORD B, SORBER J, FU K . Mementos:system support for long-running computation on RFID-scale device[J]. ACM SIGARCH Computer Architecture News, 2011,39(1): 159-170.

WANG X Y, YIĞITLER H, DUAN R F ,et al. Coherent multiantenna receiver for BPSK-modulated ambient backscatter tags[J]. IEEE Internet of Things Journal, 2021,9(2): 1197-1211.

THOMAS S J, REYNOLDS M S . A 96 Mbit/sec,15.5 pJ/bit 16-QAM modulator for UHF backscatter communication[C]// Proceedings of 2012 IEEE International Conference on RFID (RFID). Piscataway:IEEE Press, 2012: 185-190.

CORREIA R, CARVALHO N B . OFDM-like high order backscatter modulation[C]// Proceedings of 2018 IEEE MTT-S International Microwave Workshop Series on 5G Hardware and System Technologies (IMWS-5G). Piscataway:IEEE Press, 2018: 1-3.

TANG A, KIM Y, KIM Y ,et al. A 5.8 GHz 1.77mw AFSK-OFDM cmos backscatter transmitter for low power IoT applications[C]// Proceedings of 2018 IEEE/MTT-S International Microwave Symposium IMS. Piscataway:IEEE Press, 2018: 259-261.

ZHANG Y F, LI E T, ZHU Y H ,et al. Energy-efficient prefix code based backscatter communication for wirelessly powered networks[J]. IEEE Wireless Communications Letters, 2018,8(2): 348-351.

ZHANG D C, WU Q Q, CUI M ,et al. Throughput maximization for IRS-assisted wireless powered hybrid NOMA and TDMA[J]. IEEE Wireless Communications Letters, 2021,10(9): 1944-1948.

YANG G, XU X Y, LIANG Y C . Resource allocation in NOMA-enhanced backscatter communication networks for wireless powered IoT[J]. IEEE Wireless Communications Letters, 2020,9(1): 117-120.

XU Y J, QIN Z J, GUI G ,et al. Energy efficiency maximization in NOMA enabled backscatter communications with QoS guarantee[J]. IEEE Wireless Communications Letters, 2021,10(2): 353-357.

YAO C, LIU Y, WEI X ,et al. Backscatter technologies and the future of internet of things:challenges and opportunities[J]. Intelligent and Converged Networks, 2020,1(2): 170-180.

KIMIONIS J, BLETSAS A, SAHALOS J N . Increased range bistatic scatter radio[J]. IEEE Transactions on Communications, 2014,62(3): 1091-1104.

KIMIONIS J, BLETSAS A, SAHALOS J N . Bistatic backscatter radio for tag read-range extension[C]// Proceedings of 2012 IEEE International Conference on RFID-Technologies and Applications (RFID-TA). Piscataway:IEEE Press, 2013: 356-361.

YU S C, PENTY R, CRISP M . Analysis of phase noise performance in spatially separated backscatter systems[C]// Proceedings of 2021 IEEE International Conference on RFID Technology and Applications (RFID-TA). Piscataway:IEEE Press, 2021: 169-172.

3GPP. Study on ambient power-enabled internet of things:TR 22.840[S]. 2021.

3GPP. Motivation for NR passive IoT for automotive industry CMCC,BMW brilliance automotive:RP-211990[S]. 2021.

中国通信标准化协会. 基于蜂窝通信的无源物联网应用需求研究:2021B108[S]. 2021.

CCSA. Research on application requirements for passive IoT technology based on mobile communications:2021B108[S]. 2021.

FU Y Z, ZHANG H Y, ZHANG H . Bluetooth AoA positioning based on backscatter technology[C]// Proceedings of 2020 IEEE 20th International Conference on Communication Technology (ICCT). Piscataway:IEEE Press, 2020: 559-565.

MADRAY I, SUIRE J, DESFORGES J ,et al. Relative angle correction for distance estimation using K-nearest neighbors[J]. IEEE Sensors Journal, 2020,20(14): 8155-8163.

3GPP. Enhanced NR sidelink relay:RP-213585[S]. 2021.

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