Flexible intelligent metasurfaces for downlink multiuser MISO communications
Flexible intelligent metasurfaces for downlink multiuser MISO communications
Flexible intelligent metasurface (FIM) technology shows promise in terms of enhancing both the spectral and energy efficiency of wireless networks. An FIM is composed of an array of low-cost radiating elements, each of which can independently radiate electromagnetic signals, while flexibly adjusting its position along the direction perpendicular to the surface by a process termed as “morphing”. This is of particular interest for wireless communication systems operating at TeraHertz frequencies, where deep fading generally occurs within a few millimeters. Hence, in contrast to conventional rigid 2D antenna arrays, the FIM surface shape may be reconfigured to improve the channel quality by beneficial 3D morphing. In this paper, we investigate the multiuser downlink, where an FIM deployed at a base station (BS) communicates with multiple single-antenna users. We formulate an optimization problem for minimizing the total downlink transmit power at the BS, by jointly optimizing transmit beamforming and the FIM surface shape, subject to an individual signal-to-interference-plus-noise ratio (SINR) constraint of each user as well as a constraint on the maximum FIM morphing range. To solve this problem, we first consider a simple single-user scenario and show that the optimal 3D surface shape is achieved by independently adjusting each FIM element to the position having the strongest channel gain. However, in realistic multiuser scenarios, FIM surface-shape morphing involves complex tradeoffs. To address this issue, an efficient alternating optimization method is proposed to iteratively update the FIM surface shape and the transmit beamformer to gradually reduce the transmit power. Additionally, we analyze the performance gain of the FIM, showcasing a logarithmic received power scaling law versus its maximum morphing range. Finally, simulation results show that the FIM reduces the transmit power by about 3 dB compared to conventional rigid 2D arrays at a given data rate.
An, Jiancheng
197a3cbe-25f1-4102-8145-0962519c70f5
Yuen, Chau
0dd04333-bade-4812-b3df-a416597f1325
Renzo, Marco di
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Debbah, Merouane
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Poor, H. Vincent
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Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
An, Jiancheng
197a3cbe-25f1-4102-8145-0962519c70f5
Yuen, Chau
0dd04333-bade-4812-b3df-a416597f1325
Renzo, Marco di
950fb927-43b2-4b8f-b387-9b0a2e669f15
Debbah, Merouane
fe23e026-1926-49c7-97d7-425ad555152a
Poor, H. Vincent
ace801ca-0c45-451f-9509-217ea29e32e1
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
An, Jiancheng, Yuen, Chau, Renzo, Marco di, Debbah, Merouane, Poor, H. Vincent and Hanzo, Lajos
(2024)
Flexible intelligent metasurfaces for downlink multiuser MISO communications.
IEEE Transactions on Wireless Communications.
(doi:10.1109/TWC.2025.3526843).
(In Press)
Abstract
Flexible intelligent metasurface (FIM) technology shows promise in terms of enhancing both the spectral and energy efficiency of wireless networks. An FIM is composed of an array of low-cost radiating elements, each of which can independently radiate electromagnetic signals, while flexibly adjusting its position along the direction perpendicular to the surface by a process termed as “morphing”. This is of particular interest for wireless communication systems operating at TeraHertz frequencies, where deep fading generally occurs within a few millimeters. Hence, in contrast to conventional rigid 2D antenna arrays, the FIM surface shape may be reconfigured to improve the channel quality by beneficial 3D morphing. In this paper, we investigate the multiuser downlink, where an FIM deployed at a base station (BS) communicates with multiple single-antenna users. We formulate an optimization problem for minimizing the total downlink transmit power at the BS, by jointly optimizing transmit beamforming and the FIM surface shape, subject to an individual signal-to-interference-plus-noise ratio (SINR) constraint of each user as well as a constraint on the maximum FIM morphing range. To solve this problem, we first consider a simple single-user scenario and show that the optimal 3D surface shape is achieved by independently adjusting each FIM element to the position having the strongest channel gain. However, in realistic multiuser scenarios, FIM surface-shape morphing involves complex tradeoffs. To address this issue, an efficient alternating optimization method is proposed to iteratively update the FIM surface shape and the transmit beamformer to gradually reduce the transmit power. Additionally, we analyze the performance gain of the FIM, showcasing a logarithmic received power scaling law versus its maximum morphing range. Finally, simulation results show that the FIM reduces the transmit power by about 3 dB compared to conventional rigid 2D arrays at a given data rate.
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Flexible_Intelligent_Metasurfaces_for_Downlink_Multiuser_MISO_Communications (1)
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Accepted/In Press date: 20 November 2024
Identifiers
Local EPrints ID: 496956
URI: http://eprints.soton.ac.uk/id/eprint/496956
ISSN: 1536-1276
PURE UUID: d8ac6b17-ea8f-44ce-bdc5-9dde731ebe0e
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Date deposited: 08 Jan 2025 15:31
Last modified: 26 Feb 2025 05:01
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Contributors
Author:
Jiancheng An
Author:
Chau Yuen
Author:
Marco di Renzo
Author:
Merouane Debbah
Author:
H. Vincent Poor
Author:
Lajos Hanzo
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