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Quasi-synchronous random access for massive MIMO-based LEO satellite constellations

Quasi-synchronous random access for massive MIMO-based LEO satellite constellations
Quasi-synchronous random access for massive MIMO-based LEO satellite constellations
Low earth orbit (LEO) satellite constellation-enabled communication networks are expected to be an important part of many Internet of Things (IoT) deployments due to their unique advantage of providing seamless global coverage. In this paper, we investigate the random access problem in massive multiple-input multiple-output-based LEO satellite systems, where the multi-satellite cooperative processing mechanism is considered. Specifically, at edge satellite nodes, we conceive a training sequence padded multi-carrier system to overcome the issue of imperfect synchronization, where the training sequence is utilized to detect the devices' activity and estimate their channels. Considering the inherent sparsity of terrestrial-satellite links and the sporadic traffic feature of IoT terminals, we utilize the orthogonal approximate message passing-multiple measurement vector algorithm to estimate the delay coefficients and user terminal activity. To further utilize the structure of the receive array, a two-dimensional estimation of signal parameters via rotational invariance technique is performed for enhancing channel estimation. Finally, at the central server node, we propose a majority voting scheme to enhance activity detection by aggregating backhaul information from multiple satellites. Moreover, multi-satellite cooperative linear data detection and multi-satellite cooperative Bayesian dequantization data detection are proposed to cope with perfect and quantized backhaul, respectively. Simulation results verify the effectiveness of our proposed schemes in terms of channel estimation, activity detection, and data detection for quasi-synchronous random access in satellite systems.
Channel estimation, Delays, Internet of Things, Low earth orbit satellites, Satellite constellations, Satellites, Servers, Signal processing algorithms, low earth orbit satellite, massive multiple-input multiple-output, random access
1558-0008
1702-1722
Ying, Keke
3ee038e3-bf6b-4af3-9338-edb6a32bba73
Gao, Zhen
e0ab17e4-5297-4334-8b64-87924feb7876
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Zhou, Mingyu
c01d04ef-2a7e-4a1b-9167-14fbd58bc3b1
Zheng, Dezhi
da0121e5-27b5-4e40-ac8b-ec8b10160fce
Chatzinotas, Symeon
e349eceb-5716-490e-900b-563e347746f7
Ottersten, Bjorn
166b00b5-0970-4549-9f9b-6eeeb1ecd65a
Poor, H. Vincent
2ce6442b-62db-47b3-8d8e-484e7fad51af
Ying, Keke
3ee038e3-bf6b-4af3-9338-edb6a32bba73
Gao, Zhen
e0ab17e4-5297-4334-8b64-87924feb7876
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Zhou, Mingyu
c01d04ef-2a7e-4a1b-9167-14fbd58bc3b1
Zheng, Dezhi
da0121e5-27b5-4e40-ac8b-ec8b10160fce
Chatzinotas, Symeon
e349eceb-5716-490e-900b-563e347746f7
Ottersten, Bjorn
166b00b5-0970-4549-9f9b-6eeeb1ecd65a
Poor, H. Vincent
2ce6442b-62db-47b3-8d8e-484e7fad51af

Ying, Keke, Gao, Zhen, Chen, Sheng, Zhou, Mingyu, Zheng, Dezhi, Chatzinotas, Symeon, Ottersten, Bjorn and Poor, H. Vincent (2023) Quasi-synchronous random access for massive MIMO-based LEO satellite constellations. IEEE Journal on Selected Areas of Communications, 41 (6), 1702-1722. (doi:10.1109/JSAC.2023.3273699).

Record type: Article

Abstract

Low earth orbit (LEO) satellite constellation-enabled communication networks are expected to be an important part of many Internet of Things (IoT) deployments due to their unique advantage of providing seamless global coverage. In this paper, we investigate the random access problem in massive multiple-input multiple-output-based LEO satellite systems, where the multi-satellite cooperative processing mechanism is considered. Specifically, at edge satellite nodes, we conceive a training sequence padded multi-carrier system to overcome the issue of imperfect synchronization, where the training sequence is utilized to detect the devices' activity and estimate their channels. Considering the inherent sparsity of terrestrial-satellite links and the sporadic traffic feature of IoT terminals, we utilize the orthogonal approximate message passing-multiple measurement vector algorithm to estimate the delay coefficients and user terminal activity. To further utilize the structure of the receive array, a two-dimensional estimation of signal parameters via rotational invariance technique is performed for enhancing channel estimation. Finally, at the central server node, we propose a majority voting scheme to enhance activity detection by aggregating backhaul information from multiple satellites. Moreover, multi-satellite cooperative linear data detection and multi-satellite cooperative Bayesian dequantization data detection are proposed to cope with perfect and quantized backhaul, respectively. Simulation results verify the effectiveness of our proposed schemes in terms of channel estimation, activity detection, and data detection for quasi-synchronous random access in satellite systems.

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Accepted/In Press date: 7 April 2023
e-pub ahead of print date: 11 May 2023
Published date: 1 June 2023
Additional Information: Funding Information: The work of Zhen Gao was supported in part by the Natural Science Foundation of China (NSFC) under Grant 62071044 and Grant U2001210, in part by the Shandong Province Natural Science Foundation under Grant ZR2022YQ62, and in part by the Beijing Nova Program. The work of H. Vincent Poor was supported by the National Science Foundation of United States under Grant CNS-2128448. Publisher Copyright: © 1983-2012 IEEE.
Keywords: Channel estimation, Delays, Internet of Things, Low earth orbit satellites, Satellite constellations, Satellites, Servers, Signal processing algorithms, low earth orbit satellite, massive multiple-input multiple-output, random access
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Identifiers

Local EPrints ID: 476813
URI: http://eprints.soton.ac.uk/id/eprint/476813
DOI: doi:10.1109/JSAC.2023.3273699
ISSN: 1558-0008
PURE UUID: 5ff78768-6b7e-4f30-9828-9089b48115e3

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Date deposited: 16 May 2023 16:59
Last modified: 17 Mar 2024 01:55

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Contributors

Author: Keke Ying
Author: Zhen Gao
Author: Sheng Chen
Author: Mingyu Zhou
Author: Dezhi Zheng
Author: Symeon Chatzinotas
Author: Bjorn Ottersten
Author: H. Vincent Poor

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