Holographic MIMO aided integrated user-centric cell-free terrestrial and non-terrestrial networks
Holographic MIMO aided integrated user-centric cell-free terrestrial and non-terrestrial networks
With the rapid growth of global communication demand, the limitations of traditional terrestrial networks (TNs) in terms of their coverage, reliability and resource utilization efficiency are becoming increasingly apparent. To address these challenges, this paper proposes a holographic multiple-input multiple-output (MIMO) user-centric cell-free integrated terrestrial and non-terrestrial network (TN-NTN). The proposed architecture is promising to achieve seamless global coverage, high spectral efficiency and robust performance in dynamic multi-user scenarios by combining holographic beamforming, distributed access points (APs) and satellite-ground collaboration. Based on the proposed holographic MIMO assisted user-centric cell-free TN-NTN, first we present the associated channel estimation and time synchronization methods conceived for these dynamic environments, and use statistical modeling as well as distributed optimization techniques for improving the adaptability and synchronization accuracy of the system. Then, we analyze the hybrid beamforming design proposed for this architecture, which combines holographic and digital beamforming for optimizing both signal directionality and interference suppression. We harness statistical modeling and real-time feedback for prompt dynamic adaptation to the violently fluctuating channel conditions. We demonstrate that our system significantly outperforms traditional TN-NTNs in terms of its spectral efficiency and system adaptability. We conclude with the challenges faced by practical hardware limitations, time synchronization and resource allocation, and propose promising future research directions such as hardware optimization, quantum enhanced security, and advanced modulation.
Li, Qingchao
504bc1ac-445e-4750-93ab-6ebe01591c9a
El-Hajjar, Mohammed
3a829028-a427-4123-b885-2bab81a44b6f
Li, Kunlun
412d655a-669d-4a41-9d7e-797649a845ed
Feng, Xinyu
97113942-6f1f-40f1-a55f-ae45e7fa615a
Xu, Chao
5710a067-6320-4f5a-8689-7881f6c46252
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Li, Qingchao
504bc1ac-445e-4750-93ab-6ebe01591c9a
El-Hajjar, Mohammed
3a829028-a427-4123-b885-2bab81a44b6f
Li, Kunlun
412d655a-669d-4a41-9d7e-797649a845ed
Feng, Xinyu
97113942-6f1f-40f1-a55f-ae45e7fa615a
Xu, Chao
5710a067-6320-4f5a-8689-7881f6c46252
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
Li, Qingchao, El-Hajjar, Mohammed, Li, Kunlun, Feng, Xinyu, Xu, Chao and Hanzo, Lajos
(2025)
Holographic MIMO aided integrated user-centric cell-free terrestrial and non-terrestrial networks.
IEEE Network.
(doi:10.1109/MNET.2025.3580451).
Abstract
With the rapid growth of global communication demand, the limitations of traditional terrestrial networks (TNs) in terms of their coverage, reliability and resource utilization efficiency are becoming increasingly apparent. To address these challenges, this paper proposes a holographic multiple-input multiple-output (MIMO) user-centric cell-free integrated terrestrial and non-terrestrial network (TN-NTN). The proposed architecture is promising to achieve seamless global coverage, high spectral efficiency and robust performance in dynamic multi-user scenarios by combining holographic beamforming, distributed access points (APs) and satellite-ground collaboration. Based on the proposed holographic MIMO assisted user-centric cell-free TN-NTN, first we present the associated channel estimation and time synchronization methods conceived for these dynamic environments, and use statistical modeling as well as distributed optimization techniques for improving the adaptability and synchronization accuracy of the system. Then, we analyze the hybrid beamforming design proposed for this architecture, which combines holographic and digital beamforming for optimizing both signal directionality and interference suppression. We harness statistical modeling and real-time feedback for prompt dynamic adaptation to the violently fluctuating channel conditions. We demonstrate that our system significantly outperforms traditional TN-NTNs in terms of its spectral efficiency and system adaptability. We conclude with the challenges faced by practical hardware limitations, time synchronization and resource allocation, and propose promising future research directions such as hardware optimization, quantum enhanced security, and advanced modulation.
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Accepted/In Press date: 14 June 2025
e-pub ahead of print date: 17 June 2025
Identifiers
Local EPrints ID: 503381
URI: http://eprints.soton.ac.uk/id/eprint/503381
ISSN: 0890-8044
PURE UUID: b67d5881-9802-46c5-bd00-8b741f702d65
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Date deposited: 30 Jul 2025 16:30
Last modified: 11 Sep 2025 03:45
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