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Throughput maximization for intelligent refracting surface assisted mmWave high-speed train communications

Throughput maximization for intelligent refracting surface assisted mmWave high-speed train communications
Throughput maximization for intelligent refracting surface assisted mmWave high-speed train communications

With the increasing demands from passengers for data-intensive services, millimeter-wave (mmWave) communication is considered as an effective technique to release the transmission pressure on high-speed train (HST) networks. However, mmWave signals encounter severe losses when passing through the carriage, which decreases the quality of services on board. In this article, we investigate an intelligent refracting surface (IRS)-assisted HST communication system. Herein, an IRS is deployed on the train window to dynamically reconfigure the propagation environment, and a hybrid time division multiple access-nonorthogonal multiple access scheme is leveraged for interference mitigation. We aim to maximize the overall throughput while taking into account the constraints imposed by base station beamforming, IRS discrete phase shifts and transmit power. To obtain a practical solution, we employ an alternating optimization method and propose a two-stage algorithm. In the first stage, the successive convex approximation method and branch and bound algorithm are leveraged for IRS phase shift design. In the second stage, the Lagrangian multiplier method is utilized for power allocation. Simulation results demonstrate the benefits of IRS adoption and power allocation for throughput improvement in mmWave HST networks.

Hybrid time division multiple access (TDMA)-nonorthogonal multiple access, intelligent refracting surface (IRS), millimeter wave (mmWave), phase shift design, power allocation
2327-4662
13299-13311
Li, Jing
1c8f367e-c966-4d7b-b4dc-aa9162070f1b
Niu, Yong
1e9137e1-87f3-4e65-b0e2-806a2f249b4a
Wu, Hao
8d0e3477-dc5a-4ce8-8121-991ad1bbb48d
Ai, Bo
1223d2a6-5b0c-4065-8545-5ed608c5024c
He, Ruisi
53adbb41-b3e3-4287-a6b5-61f3f7bc9274
Wang, Ning
12c074fb-be39-46a1-b3b1-670e6e57c16c
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Li, Jing
1c8f367e-c966-4d7b-b4dc-aa9162070f1b
Niu, Yong
1e9137e1-87f3-4e65-b0e2-806a2f249b4a
Wu, Hao
8d0e3477-dc5a-4ce8-8121-991ad1bbb48d
Ai, Bo
1223d2a6-5b0c-4065-8545-5ed608c5024c
He, Ruisi
53adbb41-b3e3-4287-a6b5-61f3f7bc9274
Wang, Ning
12c074fb-be39-46a1-b3b1-670e6e57c16c
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80

Li, Jing, Niu, Yong, Wu, Hao, Ai, Bo, He, Ruisi, Wang, Ning and Chen, Sheng (2024) Throughput maximization for intelligent refracting surface assisted mmWave high-speed train communications. IEEE Internet of Things Journal, 11 (8), 13299-13311. (doi:10.1109/JIOT.2023.3337131).

Record type: Article

Abstract

With the increasing demands from passengers for data-intensive services, millimeter-wave (mmWave) communication is considered as an effective technique to release the transmission pressure on high-speed train (HST) networks. However, mmWave signals encounter severe losses when passing through the carriage, which decreases the quality of services on board. In this article, we investigate an intelligent refracting surface (IRS)-assisted HST communication system. Herein, an IRS is deployed on the train window to dynamically reconfigure the propagation environment, and a hybrid time division multiple access-nonorthogonal multiple access scheme is leveraged for interference mitigation. We aim to maximize the overall throughput while taking into account the constraints imposed by base station beamforming, IRS discrete phase shifts and transmit power. To obtain a practical solution, we employ an alternating optimization method and propose a two-stage algorithm. In the first stage, the successive convex approximation method and branch and bound algorithm are leveraged for IRS phase shift design. In the second stage, the Lagrangian multiplier method is utilized for power allocation. Simulation results demonstrate the benefits of IRS adoption and power allocation for throughput improvement in mmWave HST networks.

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Accepted/In Press date: 13 November 2023
e-pub ahead of print date: 28 November 2023
Published date: 15 April 2024
Additional Information: Publisher Copyright: © 2014 IEEE.
Keywords: Hybrid time division multiple access (TDMA)-nonorthogonal multiple access, intelligent refracting surface (IRS), millimeter wave (mmWave), phase shift design, power allocation
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Identifiers

Local EPrints ID: 489428
URI: http://eprints.soton.ac.uk/id/eprint/489428
DOI: doi:10.1109/JIOT.2023.3337131
ISSN: 2327-4662
PURE UUID: eadfb6a8-2d5a-44f0-a8a9-17c65e907ade

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Date deposited: 24 Apr 2024 16:31
Last modified: 21 May 2024 16:33

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Contributors

Author: Jing Li
Author: Yong Niu
Author: Hao Wu
Author: Bo Ai
Author: Ruisi He
Author: Ning Wang
Author: Sheng Chen

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