面向6G物联网的智能反射表面设计

doi:10.11959/j.issn.2096-3750.2020.00160

Abstract

Abstract:

In the era of the 6G cellular networks,the base station (BS) should be able to provide seamless connectivity for a large number of Internet of things (IoT) devices distributed in various areas.However,constrained by their locations,some IoT devices may possess unreliable communication channels to the BS due to the obstacles between them.It is a big obstacle on the roadmap towards the massively connected IoT networks in the era of 6G .To tackle this challenge,the possibility was studied to employ the newly emerging technique of intelligent reflecting surface (IRS) for enhancing the strength of the IoT devices’ signals at the BS.Specifically,the transmit power minimization problem in an uplink IoT communication system was focused on,where the overhead for channel estimation was taken into account.On one hand,for the case where the BS was equipped with a small or moderate number of antennas,an iterative algorithm was proposed to jointly optimize the user power allocation,the IRS reflecting coefficients,and the BS beamforming vectors.On the other hand,for the case where the BS had a massive number of antennas,i.e.,massive multiple-input multiple-output (MIMO),a low-complexity design of the user power allocation,the IRS reflecting coefficients,and the BS beamforming vectors was provided in a closed-form.Numerical results validate the great potential of IRS for enhancing massive connectivity in the future 6G-assisted IoT networks.

Key words: intelligent reflecting surface, 6G, Internet of things, resource allocation, massive MIMO technology

CLC Number:

TN919

Zhaorui WANG,Liang LIU,Hang LI,Shuguang CUI. Intelligent reflecting surface design for 6G-assited Internet of things[J]. Chinese Journal on Internet of Things, 2020, 4(2): 84-95.

Figures/Tables 5

References 17

[1]	邬贺铨 . 物联网技术与应用的新进展[J]. 物联网学报, 2017,1(1): 1-6.
	WU H Q . Technology and application progress on Internet of things[J]. Chinese Journal on Internet of Things, 2017,1(1): 1-6.
[2]	孙玉 . 我国物联网产业发展趋势[J]. 物联网学报, 2017,1(3): 1-5.
	SUN Y . Development trend of IoT industry in China[J]. Chinese Journal on Internet of Things, 2017,1(3): 1-5.
[3]	LIASKOS C , NIE S , TSIOLIARIDOU A ,et al. A new wireless communication paradigm through software-controlled metasurfaces[J]. IEEE Communications Magazine, 2018,56(9): 162-169.
[4]	RENZO M D , DEBBAH M , PHAN-HUY D ,et al. Smart radio environments empowered by reconfigurable AI meta-surfaces:an idea whose time has come[J]. EURASIP Journal on Wireless Communications and Networking, 2019,129: 1-20.
[5]	BASAR E , RENZOM D , ROSNY J ,et al. Wireless communications through reconfigurable intelligent surfaces[J]. IEEE Access, 2019,7: 116753-116773.
[6]	LIASKOS C K , TSIOLIARIDOU A , PITSILLIDES A ,et al. Design and development of software defined metamaterials for nanonetworks[J]. IEEE Circuits and Systems Magazine, 2015,15(4): 12-25.
[7]	WU Q Q , ZHANG R . Intelligent reflecting surface enhanced wireless network:joint active and passive beamforming design[C]// 2018 IEEE Global Communications Conference (GLOBECOM). IEEE, 2018.
[8]	ZHANG S W , ZHANG R . Capacity characterization for intelligent reflecting surface aided MIMO communication[J]. arXiv:1910.01573, 2019
[9]	YU X H , XU D F , SCHOBER R . Enabling secure wireless communications via intelligent reflecting surfaces[C]// 2019 IEEE Global Communications Conference (GLOBECOM). IEEE, 2019.
[10]	MISHRA D , JOHANSSON H . Channel estimation and low-complexity beamforming design for passive intelligent surface-assisted MISO wireless energy transfer[C]// 2019 IEEE International Conference on Acoustics,Speech and Signal Processing (ICASSP). IEEE, 2019.
[11]	YANG Y , ZHENG B , ZHANG S ,et al. Intelligent reflecting surface meets OFDM:protocol design and rate maximization[J]. arXiv:1906.09956, 2019
[12]	ZHENG B , ZHANG R . Intelligent reflecting surface-enhanced OFDM:channel estimation and reflection optimization[J]. arXiv:1909.03272, 2019
[13]	JENSEN T L , CARVALHO E D . On optimal channel estimation scheme for intelligent reflecting surfaces based on a minimum variance unbiased estimator[J]. arXiv:1909.09440, 2019
[14]	WANG Z , LIU L , CUI S . Channel estimation for intelligent reflecting surface assisted multiuser communications[J]. arXiv:1912.11783, 2019
[15]	CHIANG M , HANDE P , LAN T ,et al. Power control in wireless cellular networks[J]. Foundations and Trends in Networking, 2007,2(4): 381-533.
[16]	HASSIBI B , HOCHWALD B M . How much training is needed in multiple-antenna wireless links[J]. IEEE Transactions on Information Theory, 2003,49(4): 951-963.
[17]	NGO H Q , LARSSON E G , MARZETTA T L . Energy and spectral efficiency of very large multiuser MIMO systems[J]. IEEE Transactions on Communications, 2013,61(4): 1436-1449.

Metrics

Recommended 0

No Suggested Reading articles found!

Intelligent reflecting surface design for 6G-assited Internet of things

RichHTML

PDF下载

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 5

References 17

Related Articles 15

Metrics

Recommended 0

[1]	Jing WU, Sheng LI, Jing ZHANG, Ming XIN, Ruowen TAO, Zhou ZHOU, Lijia PAN, Yi SHI. New flexible sensor for the internet of things [J]. Chinese Journal on Internet of Things, 2023, 7(2): 1-14.
[2]	Guanglei GENG, Bo GAO, Ke XIONG, Pingyi FAN, Yang LU, Yuwei WANG. A survey of federated learning for 6G networks [J]. Chinese Journal on Internet of Things, 2023, 7(2): 50-66.
[3]	Qingyang LI, Xueting LI, Xiaorong ZHU. A joint optimization method of multi backhaul link selection and power allocation in 6G [J]. Chinese Journal on Internet of Things, 2023, 7(2): 67-75.
[4]	Zhihong WANG, Supeng LENG, Kai XIONG. Multi-agent resource allocation strategy for UAV swarm-based cooperative sensing [J]. Chinese Journal on Internet of Things, 2023, 7(1): 18-26.
[5]	Xueqiang YAN, Guanjie CHENG, Shuiguang DENG, Jianjun WU, Lu LU, Mingyu ZHAO, Yan XI, Chao LIU, Weiyuan LI, Lei FENG, Tong ZHANG. Data services and data plane for 6G mobile communication network [J]. Chinese Journal on Internet of Things, 2023, 7(1): 60-72.
[6]	Bei TANG, Qian WANG, Siguang CHEN. Radio frequency energy harvesting-combined collaborative energy-saving computation offloading mechanism [J]. Chinese Journal on Internet of Things, 2023, 7(1): 83-92.
[7]	Bin SHEN, Yinbo LI, Xiaowei LIANG. Spectrum access control for cognitive internet of things users based on enhanced weighted centroid localization [J]. Chinese Journal on Internet of Things, 2023, 7(1): 93-108.
[8]	Yao LIU, Yueyuan HE, Hongjing ZHOU, Chaoliang LI, Chuang LI. Partial computation offloading method based on joint resource allocation for mobile edge computing [J]. Chinese Journal on Internet of Things, 2023, 7(1): 140-148.
[9]	Jun SUN, Shangweikang ZHAO. Energy-saving computation offloading scheme based on Sarsa algorithm in industrial internet of things [J]. Chinese Journal on Internet of Things, 2022, 6(3): 82-90.
[10]	Zaichen ZHANG, Xiaohu YOU, Jian DANG, Liang WU, Bingcheng ZHU, Ji CHEN, Lei WANG. Optical wireless communication and internet of things [J]. Chinese Journal on Internet of Things, 2022, 6(3): 1-13.
[11]	Nuo HUANG, Weijie LIU, Chen GONG. Industrial IoT oriented petahertz communication [J]. Chinese Journal on Internet of Things, 2022, 6(3): 37-46.
[12]	Ning LUAN, Ke XIONG, Yu ZHANG, Ruisi HE, Gang QU, Bo AI. 6G: typical applications, key technologies and challenges [J]. Chinese Journal on Internet of Things, 2022, 6(1): 29-43.
[13]	Wei WANG, Renqian GU, Li3 PENG, Jijun ZHAO, Zhongcheng WEI, Cunxi CHANG. Robust optimization of air based relay for internet of things based on UAV [J]. Chinese Journal on Internet of Things, 2022, 6(1): 101-112.
[14]	Mingjuan WU, Shuyi CHEN, Haitao LIU. Study of international standard ISO/IEC 30144: 2020 applied in intelligent substation auxiliary monitoring [J]. Chinese Journal on Internet of Things, 2022, 6(1): 123-132.
[15]	Hao JIANG, Hongming CHEN, Yilong CAO, Haoyang CUI. Comparison of MIMO based on high capacity LPWAN technology TurMass^TM and LoRa [J]. Chinese Journal on Internet of Things, 2021, 5(4): 54-61.