Holographic metasurface-based beamforming for multi-altitude LEO satellite networks
Holographic metasurface-based beamforming for multi-altitude LEO satellite networks
Low Earth Orbit (LEO) satellite networks are capable of improving the global Internet service coverage. In this context, we propose a hybrid beamforming design for holographic metasurface based terrestrial users in multi-altitude LEO satellite networks. Firstly, the holographic beamformer is optimized by maximizing the downlink channel gain from the serving satellite to the terrestrial user. Then, the digital beamformer is designed by conceiving a minimum mean square error (MMSE) based detection algorithm for mitigating the interference arriving from other satellites. To dispense with excessive overhead of full channel state information (CSI) acquisition of all satellites, we propose a low-complexity MMSE beamforming algorithm that only relies on the distribution of the LEO satellite constellation harnessing stochastic geometry, which can achieve comparable throughput to that of the algorithm based on the full CSI in the case of a dense LEO satellite deployment. Furthermore, it outperforms the maximum ratio combining (MRC) algorithm, thanks to its inter-satellite interference mitigation capacity. The simulation results show that our proposed holographic metasurface based hybrid beamforming architecture is capable of outperforming the state-of-the-art antenna array architecture in terms of its throughput, given the same physical size of the transceivers. Moreover, we demonstrate that the beamforming performance attained can be substantially improved by taking into account the mutual coupling effect, imposed by the dense placement of the holographic metasurface elements.
inter-satellite interference, hybrid beamforming, holographic metasurface, Low Earth orbit (LEO) satellite communication, stochastic geometry
3103-3116
Li, Qingchao
504bc1ac-445e-4750-93ab-6ebe01591c9a
El-Hajjar, Mohammed
3a829028-a427-4123-b885-2bab81a44b6f
Cao, Kaijun
e7f3b9be-fe2e-4c87-91bd-69d9d8cc054d
Xu, Chao
5710a067-6320-4f5a-8689-7881f6c46252
Haas, Harald
febaac93-643b-40c8-ad87-bff8655a7f08
16 January 2025
Li, Qingchao
504bc1ac-445e-4750-93ab-6ebe01591c9a
El-Hajjar, Mohammed
3a829028-a427-4123-b885-2bab81a44b6f
Cao, Kaijun
e7f3b9be-fe2e-4c87-91bd-69d9d8cc054d
Xu, Chao
5710a067-6320-4f5a-8689-7881f6c46252
Haas, Harald
febaac93-643b-40c8-ad87-bff8655a7f08
Li, Qingchao, El-Hajjar, Mohammed, Cao, Kaijun, Xu, Chao and Haas, Harald
(2025)
Holographic metasurface-based beamforming for multi-altitude LEO satellite networks.
IEEE Transactions on Wireless Communications, 24 (4), .
(doi:10.1109/TWC.2025.3527962).
Abstract
Low Earth Orbit (LEO) satellite networks are capable of improving the global Internet service coverage. In this context, we propose a hybrid beamforming design for holographic metasurface based terrestrial users in multi-altitude LEO satellite networks. Firstly, the holographic beamformer is optimized by maximizing the downlink channel gain from the serving satellite to the terrestrial user. Then, the digital beamformer is designed by conceiving a minimum mean square error (MMSE) based detection algorithm for mitigating the interference arriving from other satellites. To dispense with excessive overhead of full channel state information (CSI) acquisition of all satellites, we propose a low-complexity MMSE beamforming algorithm that only relies on the distribution of the LEO satellite constellation harnessing stochastic geometry, which can achieve comparable throughput to that of the algorithm based on the full CSI in the case of a dense LEO satellite deployment. Furthermore, it outperforms the maximum ratio combining (MRC) algorithm, thanks to its inter-satellite interference mitigation capacity. The simulation results show that our proposed holographic metasurface based hybrid beamforming architecture is capable of outperforming the state-of-the-art antenna array architecture in terms of its throughput, given the same physical size of the transceivers. Moreover, we demonstrate that the beamforming performance attained can be substantially improved by taking into account the mutual coupling effect, imposed by the dense placement of the holographic metasurface elements.
Text
TAMS
- Accepted Manuscript
More information
Accepted/In Press date: 6 January 2025
Published date: 16 January 2025
Keywords:
inter-satellite interference, hybrid beamforming, holographic metasurface, Low Earth orbit (LEO) satellite communication, stochastic geometry
Identifiers
Local EPrints ID: 497698
URI: http://eprints.soton.ac.uk/id/eprint/497698
ISSN: 1536-1276
PURE UUID: 20877185-24d3-413f-9c3e-2c5c1a6f0562
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Date deposited: 29 Jan 2025 18:30
Last modified: 11 Sep 2025 04:16
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Contributors
Author:
Qingchao Li
Author:
Mohammed El-Hajjar
Author:
Kaijun Cao
Author:
Chao Xu
Author:
Harald Haas
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