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Beamspace channel estimation via PARAFAC decomposition for RIS assisted millimeter-wave multiuser MISO communications

Beamspace channel estimation via PARAFAC decomposition for RIS assisted millimeter-wave multiuser MISO communications
Beamspace channel estimation via PARAFAC decomposition for RIS assisted millimeter-wave multiuser MISO communications
The reconfigurable intelligent surface (RIS) with massive low-cost passive reflecting elements integrated on a planar surface has the ability to favourably reconfigure the wireless propagation environment, thereby significantly improving the performance of wireless communication networks. In this work, we consider uplink (UL) channel estimation for the RIS assisted millimeter-wave multiuser multiple-input single-output beamspace system where the base station (BS) is equipped with lens antenna array. This channel state information (CSI) estimation task is extremely challenging for two reasons. First, the BS only has limited number of radio frequency chains but the size of beamspace channel is very large. Second, the number of passive components in the RIS is abundance but they lack signal processing capabilities. By exploiting the parallel factor (PARAFAC) decomposition of the received signals, we derive an iterative estimation algorithm, called unitary approximate message passing (UAMP), to accurately estimate the channels between the BS and the RIS as well as the channels between the RIS and the users. To guide the selection of the system parameters, we provide the uniqueness conditions for our PARAFAC decomposition based channel estimation. To theoretically verify the efficiency of our UAMP algorithm, the Cram´er-Rao bound (CRB) of the estimation is also derived. Besides, we investigate the achievable downlink (DL) sum rate for the channel estimation obtained by the proposed algorithm by using the maximum power beam selection, the optimized phase shift matrix and the zero forcing precoding. Extensive simulation results demonstrate the excellent mean squared error (MSE) performance of our UAMP estimation algorithm. In particular, for sufficiently high UL signal-to-noise ratio, the MSE of our channel estimation reaches the CRB. Simulation results also show that the DL sum rate achieved by the estimated CSI is very close to that obtained by the perfect CSI. Theoretical analysis and simulation results thus validate the effectiveness and reliability of our beamspace channel estimation approach.
Cramér-Rao bound, PARAFAC, Reconfigurable intelligent surface, beamspace, channel estimation, downlink sum rate, lens antenna array, millimeter-wave, Cramér-Rao bound
0018-9545
7594-7609
Guo, Xinying
4c93cc91-7ace-4d5d-989c-ff2803355fd1
Xie, Zongyuan
bfbc19b7-329a-4833-831b-25364c3736d9
Zhang, Jiankang
c6c025b3-6576-4f9d-be95-57908e61fa88
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Zhu, Chunhua
a17f1ca7-43ca-4c4f-a11f-98084bc4cb81
Guo, Xinying
4c93cc91-7ace-4d5d-989c-ff2803355fd1
Xie, Zongyuan
bfbc19b7-329a-4833-831b-25364c3736d9
Zhang, Jiankang
c6c025b3-6576-4f9d-be95-57908e61fa88
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Zhu, Chunhua
a17f1ca7-43ca-4c4f-a11f-98084bc4cb81

Guo, Xinying, Xie, Zongyuan, Zhang, Jiankang, Chen, Sheng and Zhu, Chunhua (2025) Beamspace channel estimation via PARAFAC decomposition for RIS assisted millimeter-wave multiuser MISO communications. IEEE Transactions on Vehicular Technology, 74 (5), 7594-7609. (doi:10.1109/TVT.2024.3522365).

Record type: Article

Abstract

The reconfigurable intelligent surface (RIS) with massive low-cost passive reflecting elements integrated on a planar surface has the ability to favourably reconfigure the wireless propagation environment, thereby significantly improving the performance of wireless communication networks. In this work, we consider uplink (UL) channel estimation for the RIS assisted millimeter-wave multiuser multiple-input single-output beamspace system where the base station (BS) is equipped with lens antenna array. This channel state information (CSI) estimation task is extremely challenging for two reasons. First, the BS only has limited number of radio frequency chains but the size of beamspace channel is very large. Second, the number of passive components in the RIS is abundance but they lack signal processing capabilities. By exploiting the parallel factor (PARAFAC) decomposition of the received signals, we derive an iterative estimation algorithm, called unitary approximate message passing (UAMP), to accurately estimate the channels between the BS and the RIS as well as the channels between the RIS and the users. To guide the selection of the system parameters, we provide the uniqueness conditions for our PARAFAC decomposition based channel estimation. To theoretically verify the efficiency of our UAMP algorithm, the Cram´er-Rao bound (CRB) of the estimation is also derived. Besides, we investigate the achievable downlink (DL) sum rate for the channel estimation obtained by the proposed algorithm by using the maximum power beam selection, the optimized phase shift matrix and the zero forcing precoding. Extensive simulation results demonstrate the excellent mean squared error (MSE) performance of our UAMP estimation algorithm. In particular, for sufficiently high UL signal-to-noise ratio, the MSE of our channel estimation reaches the CRB. Simulation results also show that the DL sum rate achieved by the estimated CSI is very close to that obtained by the perfect CSI. Theoretical analysis and simulation results thus validate the effectiveness and reliability of our beamspace channel estimation approach.

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e-pub ahead of print date: 25 December 2024
Published date: 25 May 2025
Keywords: Cramér-Rao bound, PARAFAC, Reconfigurable intelligent surface, beamspace, channel estimation, downlink sum rate, lens antenna array, millimeter-wave, Cramér-Rao bound
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Identifiers

Local EPrints ID: 497565
URI: http://eprints.soton.ac.uk/id/eprint/497565
DOI: doi:10.1109/TVT.2024.3522365
ISSN: 0018-9545
PURE UUID: 40c00626-3c5e-48cf-8c49-257e30b7da9d

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Date deposited: 27 Jan 2025 17:59
Last modified: 29 Aug 2025 16:59

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Contributors

Author: Xinying Guo
Author: Zongyuan Xie
Author: Jiankang Zhang
Author: Sheng Chen
Author: Chunhua Zhu

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