Coordinated reconfigurable intelligent surfaces: non-diagonal group-connected design
Coordinated reconfigurable intelligent surfaces: non-diagonal group-connected design
Reconfigurable intelligent surfaces (RIS) constitute a promising technology for future wireless communications in terms of improving the spectral-efficiency and energy-efficiency. In this context, a novel RIS structure, which we refer to as coordinated RIS architecture, is formulated, where different RIS elements can be connected by configurable impedances to eliminate the channel fading. In the proposed RIS architecture, both the RIS element connection pattern and the configurable impedances can be optimized, based on the channel state information (CSI). The proposed architecture exhibits higher optimization flexibility than the state-of-the-art single-connected RIS architecture and group-connected RIS architecture, where only the configurable impedances can be optimized. Specifically, when considering base stations (BS) having a single antenna, the maximal ratio combining (MRC) criterion may be harnessed for designing the RIS element connection pattern, while in the case of multiple BS antennas, the alternating optimization algorithm may be employed for iteratively optimizing the BS's active beamforming vector and the RIS's passive beamforming matrix. Our numerical results show that the proposed coordinated RIS architecture achieves higher power gain than the group-connected RIS architecture having the same number of configurable impedances. Furthermore, the power gain in our proposed RIS architecture tends to that of the fully-connected architecture upon increasing the number of RIS elements, while requiring significantly fewer configurable impedances.
Li, Qingchao
69625501-d192-4a81-861f-f7ac9dd1e882
El-Hajjar, Mohammed
3a829028-a427-4123-b885-2bab81a44b6f
Hemadeh, Ibrahim
11f27b54-e3da-4699-bc72-9a3508e76ccf
Shojaeifard, Arman
a2b98bfd-74d2-4b8c-aa8b-839b5a8c4e4c
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Li, Qingchao
69625501-d192-4a81-861f-f7ac9dd1e882
El-Hajjar, Mohammed
3a829028-a427-4123-b885-2bab81a44b6f
Hemadeh, Ibrahim
11f27b54-e3da-4699-bc72-9a3508e76ccf
Shojaeifard, Arman
a2b98bfd-74d2-4b8c-aa8b-839b5a8c4e4c
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Li, Qingchao, El-Hajjar, Mohammed, Hemadeh, Ibrahim, Shojaeifard, Arman and Hanzo, Lajos
(2024)
Coordinated reconfigurable intelligent surfaces: non-diagonal group-connected design.
IEEE Transactions on Vehicular Technology.
(In Press)
Abstract
Reconfigurable intelligent surfaces (RIS) constitute a promising technology for future wireless communications in terms of improving the spectral-efficiency and energy-efficiency. In this context, a novel RIS structure, which we refer to as coordinated RIS architecture, is formulated, where different RIS elements can be connected by configurable impedances to eliminate the channel fading. In the proposed RIS architecture, both the RIS element connection pattern and the configurable impedances can be optimized, based on the channel state information (CSI). The proposed architecture exhibits higher optimization flexibility than the state-of-the-art single-connected RIS architecture and group-connected RIS architecture, where only the configurable impedances can be optimized. Specifically, when considering base stations (BS) having a single antenna, the maximal ratio combining (MRC) criterion may be harnessed for designing the RIS element connection pattern, while in the case of multiple BS antennas, the alternating optimization algorithm may be employed for iteratively optimizing the BS's active beamforming vector and the RIS's passive beamforming matrix. Our numerical results show that the proposed coordinated RIS architecture achieves higher power gain than the group-connected RIS architecture having the same number of configurable impedances. Furthermore, the power gain in our proposed RIS architecture tends to that of the fully-connected architecture upon increasing the number of RIS elements, while requiring significantly fewer configurable impedances.
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Accepted/In Press date: 11 March 2024
Identifiers
Local EPrints ID: 488056
URI: http://eprints.soton.ac.uk/id/eprint/488056
ISSN: 0018-9545
PURE UUID: dc75a61f-0f0a-4f20-948f-ca741d5ad5de
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Date deposited: 14 Mar 2024 17:32
Last modified: 14 Apr 2024 04:01
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Contributors
Author:
Qingchao Li
Author:
Mohammed El-Hajjar
Author:
Ibrahim Hemadeh
Author:
Arman Shojaeifard
Author:
Lajos Hanzo
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