Near-field hierarchical beam training for reconfigurable holographic surfaces
Near-field hierarchical beam training for reconfigurable holographic surfaces
Reconfigurable holographic surfaces (RHS) are expected to play a key role in future mobile networks. However, the substantial increase in antenna aperture and operating frequency brings new challenges for near-field communication. We propose a near-field multi-user 3D hierarchical beam training scheme tailored for RHS-based multi-input multi-output (MIMO) systems, supporting both near-field and far-field user deployment, while considering hardware constraints. Since the hierarchical beam training scheme involves activating varying numbers of transmitting elements at each search layer, and RHS elements are densely packed, significant mutual coupling effects may arise. To mitigate this, we propose two element activation strategies: centered activation and sparse activation based on different RHS element positioning patterns within the hierarchical beam training framework. Furthermore, we design a practical beam training approach tailored to a hybrid digital–holographic architecture, optimized through an alternating algorithm that accounts for both binary and coupled amplitude-phase hardware constraints on RHS meta-elements. Simulation results demonstrate strong robustness under various hardware and channel state information (CSI) imperfections, achieving performance close to that of fully digital systems. Finally, we further analyse the asymptotic orthogonality of near-field beam focusing vectors under different RHS surface geometries. The results show that rectangular surfaces offer superior beam orthogonality for beams steered in the same direction but located at different distances.
Dong, Yinuo
b769741e-45bc-4884-8d3b-4e64848029cd
Li, Qingchao
504bc1ac-445e-4750-93ab-6ebe01591c9a
Ng, Soon Xin
e19a63b0-0f12-4591-ab5f-554820d5f78c
El-Hajjar, Mohammed
3a829028-a427-4123-b885-2bab81a44b6f
Dong, Yinuo
b769741e-45bc-4884-8d3b-4e64848029cd
Li, Qingchao
504bc1ac-445e-4750-93ab-6ebe01591c9a
Ng, Soon Xin
e19a63b0-0f12-4591-ab5f-554820d5f78c
El-Hajjar, Mohammed
3a829028-a427-4123-b885-2bab81a44b6f
Dong, Yinuo, Li, Qingchao, Ng, Soon Xin and El-Hajjar, Mohammed
(2025)
Near-field hierarchical beam training for reconfigurable holographic surfaces.
IEEE Transactions on Communications.
(doi:10.1109/TCOMM.2025.3618668).
Abstract
Reconfigurable holographic surfaces (RHS) are expected to play a key role in future mobile networks. However, the substantial increase in antenna aperture and operating frequency brings new challenges for near-field communication. We propose a near-field multi-user 3D hierarchical beam training scheme tailored for RHS-based multi-input multi-output (MIMO) systems, supporting both near-field and far-field user deployment, while considering hardware constraints. Since the hierarchical beam training scheme involves activating varying numbers of transmitting elements at each search layer, and RHS elements are densely packed, significant mutual coupling effects may arise. To mitigate this, we propose two element activation strategies: centered activation and sparse activation based on different RHS element positioning patterns within the hierarchical beam training framework. Furthermore, we design a practical beam training approach tailored to a hybrid digital–holographic architecture, optimized through an alternating algorithm that accounts for both binary and coupled amplitude-phase hardware constraints on RHS meta-elements. Simulation results demonstrate strong robustness under various hardware and channel state information (CSI) imperfections, achieving performance close to that of fully digital systems. Finally, we further analyse the asymptotic orthogonality of near-field beam focusing vectors under different RHS surface geometries. The results show that rectangular surfaces offer superior beam orthogonality for beams steered in the same direction but located at different distances.
Text
main
- Accepted Manuscript
More information
Accepted/In Press date: 29 September 2025
e-pub ahead of print date: 7 October 2025
Identifiers
Local EPrints ID: 506380
URI: http://eprints.soton.ac.uk/id/eprint/506380
ISSN: 0090-6778
PURE UUID: e21b159a-58dc-4dc9-9261-5521e355660c
Catalogue record
Date deposited: 05 Nov 2025 17:47
Last modified: 06 Nov 2025 02:45
Export record
Altmetrics
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
