Simultaneously transmitting and reflecting reconfigurable intelligent surface (STAR-RIS) assisted UAV communications
Simultaneously transmitting and reflecting reconfigurable intelligent surface (STAR-RIS) assisted UAV communications
A novel air-to-ground communication paradigm is conceived, where an unmanned aerial vehicle (UAV)-mounted base station (BS) equipped with multiple antennas sends information to multiple ground users (GUs) with the aid of a simultaneously transmitting and reflecting reconfigurable intelligent surface (STAR-RIS). In contrast to the conventional RIS whose main function is to reflect incident signals, the STAR-RIS is capable of both transmitting and reflecting the impinging signals from either side of the surface, thereby leading to full-space 360 degree coverage. However, the transmissive and reflective capabilities of the STAR-RIS require more complex transmission/reflection coefficient design. Therefore, in this work, a sum-rate maximization problem is formulated for the joint optimization of the UAV’s trajectory, the active beamforming at the UAV, and the passive transmission/reflection beamforming at the STAR-RIS. This cutting-edge optimization problem is also subject to the UAV’s flight safety, to the maximum flight duration constraint, as well as to the GUs’ minimum data rate requirements. Given the unknown locations of obstacles prior to the UAV’s flight, we provide an online decision making framework employing reinforcement learning (RL) to simultaneously adjust both the UAV’s trajectory as well as the active and passive beamformer. To enhance the system’s robustness against the associated uncertainties caused by limited sampling of the environment, a novel “distributionally-robust” RL (DRRL) algorithm is proposed for offering an adequate worst-case performance guarantee. Our numerical results unveil that: 1) the STAR-RIS assisted UAV communications benefit from significant sum-rate gain over the conventional reflecting-only RIS; and 2) the proposed DRRL algorithm achieves both more stable and more robust performance than the state-of-the-art RL algorithms.
Air-to-ground communications, collision avoidance, distributionally-robust reinforcement learning, joint beamforming design, simultaneously transmitting and reflecting reconfigurable intelligent surface
3041-3056
Zhao, Jingjing
2ca500a3-3fbf-4660-a247-7928642584dc
Zhu, Yanbo
4341d9db-c385-4b0b-84dd-ca39a58a60fa
Mu, Xidong
0c966110-53a8-46e4-993c-c864483b54ce
Cai, Kaiquan
c37db6a9-880d-4fc5-b2df-ccc28cb7b719
Liu, Yuanwei
2767c2bc-6199-4106-ac28-81c3dadcfa29
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
1 October 2022
Zhao, Jingjing
2ca500a3-3fbf-4660-a247-7928642584dc
Zhu, Yanbo
4341d9db-c385-4b0b-84dd-ca39a58a60fa
Mu, Xidong
0c966110-53a8-46e4-993c-c864483b54ce
Cai, Kaiquan
c37db6a9-880d-4fc5-b2df-ccc28cb7b719
Liu, Yuanwei
2767c2bc-6199-4106-ac28-81c3dadcfa29
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Zhao, Jingjing, Zhu, Yanbo, Mu, Xidong, Cai, Kaiquan, Liu, Yuanwei and Hanzo, Lajos
(2022)
Simultaneously transmitting and reflecting reconfigurable intelligent surface (STAR-RIS) assisted UAV communications.
IEEE Journal on Selected Areas in Communications, 40 (10), , [22050962].
(doi:10.1109/JSAC.2022.3196102).
Abstract
A novel air-to-ground communication paradigm is conceived, where an unmanned aerial vehicle (UAV)-mounted base station (BS) equipped with multiple antennas sends information to multiple ground users (GUs) with the aid of a simultaneously transmitting and reflecting reconfigurable intelligent surface (STAR-RIS). In contrast to the conventional RIS whose main function is to reflect incident signals, the STAR-RIS is capable of both transmitting and reflecting the impinging signals from either side of the surface, thereby leading to full-space 360 degree coverage. However, the transmissive and reflective capabilities of the STAR-RIS require more complex transmission/reflection coefficient design. Therefore, in this work, a sum-rate maximization problem is formulated for the joint optimization of the UAV’s trajectory, the active beamforming at the UAV, and the passive transmission/reflection beamforming at the STAR-RIS. This cutting-edge optimization problem is also subject to the UAV’s flight safety, to the maximum flight duration constraint, as well as to the GUs’ minimum data rate requirements. Given the unknown locations of obstacles prior to the UAV’s flight, we provide an online decision making framework employing reinforcement learning (RL) to simultaneously adjust both the UAV’s trajectory as well as the active and passive beamformer. To enhance the system’s robustness against the associated uncertainties caused by limited sampling of the environment, a novel “distributionally-robust” RL (DRRL) algorithm is proposed for offering an adequate worst-case performance guarantee. Our numerical results unveil that: 1) the STAR-RIS assisted UAV communications benefit from significant sum-rate gain over the conventional reflecting-only RIS; and 2) the proposed DRRL algorithm achieves both more stable and more robust performance than the state-of-the-art RL algorithms.
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Accepted/In Press date: 25 February 2022
e-pub ahead of print date: 3 August 2022
Published date: 1 October 2022
Keywords:
Air-to-ground communications, collision avoidance, distributionally-robust reinforcement learning, joint beamforming design, simultaneously transmitting and reflecting reconfigurable intelligent surface
Identifiers
Local EPrints ID: 472240
URI: http://eprints.soton.ac.uk/id/eprint/472240
ISSN: 1558-0008
PURE UUID: 96c7a3d5-e152-4673-a628-fc54bd010283
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Date deposited: 30 Nov 2022 17:32
Last modified: 18 Mar 2024 02:36
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Contributors
Author:
Jingjing Zhao
Author:
Yanbo Zhu
Author:
Xidong Mu
Author:
Kaiquan Cai
Author:
Yuanwei Liu
Author:
Lajos Hanzo
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