Knowledge and data dual-driven channel estimation and feedback for ultra-massive MIMO systems under hybrid field beam squint effect
Knowledge and data dual-driven channel estimation and feedback for ultra-massive MIMO systems under hybrid field beam squint effect
Acquiring accurate channel state information (CSI) at an access point (AP) is challenging for wideband millimeter wave (mmWave) ultra-massive multiple-input and multiple-output (UMMIMO) systems, due to the high-dimensional channel matrices, hybrid near- and far- field channel feature, beam squint effects, and imperfect hardware constraints, such as low-resolution analogto- digital converters, and in-phase and quadrature imbalance. To overcome these challenges, this paper proposes an efficient downlink channel estimation (CE) and CSI feedback approach based on knowledge and data dual-driven deep learning (DL) networks. Specifically, we first propose a data-driven residual neural network de-quantizer (ResNet-DQ) to pre-process the received pilot signals at user equipment (UEs), where the noise and distortion brought by imperfect hardware can be mitigated. A knowledge-driven generalized multiple measurement vector learned approximate message passing (GMMV-LAMP) network is then developed to jointly estimate the channels by exploiting the approximately same physical angle shared by different subcarriers. In particular, two wideband redundant dictionaries (WRDs) are proposed such that the measurement matrices of the GMMV-LAMP network can accommodate the farfield and near-field beam squint effect, respectively. Finally, we propose an encoder at the UEs and a decoder at the AP by a data-driven CSI residual network (CSI-ResNet) to compress the CSI matrix into a low-dimensional quantized bit vector for feedback, thereby reducing the feedback overhead substantially. Simulation results show that the proposed knowledge and data dual-driven approach outperforms conventional downlink CE and CSI feedback methods, especially in the case of low signal-to-noise ratios.
CSI feedback, Ultra-massive multiple input multiple output (UM-MIMO), channel estimation, hybrid near- and far- field channels, knowledge and data dual-driven, orthogonal frequency division multiplexing (OFDM)
11240-11259
Wang, Kuiyu
05cdbd6e-0073-4ffa-8a94-bbae81d4b768
Gao, Zhen
e0ab17e4-5297-4334-8b64-87924feb7876
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Ning, Boyu
c937b43d-c96a-43b8-a020-4ac5d9275de3
Chen, Gaojie
aa435aa8-ff8b-4751-8817-189b10356b91
Su, Yu
b733417e-bb9e-44e7-aae9-62eaef7a0e5f
Wang, Zhaocheng
70339538-3970-4094-bcfc-1b5111dfd8b4
Poor, H. Vincent
2ce6442b-62db-47b3-8d8e-484e7fad51af
12 September 2024
Wang, Kuiyu
05cdbd6e-0073-4ffa-8a94-bbae81d4b768
Gao, Zhen
e0ab17e4-5297-4334-8b64-87924feb7876
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Ning, Boyu
c937b43d-c96a-43b8-a020-4ac5d9275de3
Chen, Gaojie
aa435aa8-ff8b-4751-8817-189b10356b91
Su, Yu
b733417e-bb9e-44e7-aae9-62eaef7a0e5f
Wang, Zhaocheng
70339538-3970-4094-bcfc-1b5111dfd8b4
Poor, H. Vincent
2ce6442b-62db-47b3-8d8e-484e7fad51af
Wang, Kuiyu, Gao, Zhen, Chen, Sheng, Ning, Boyu, Chen, Gaojie, Su, Yu, Wang, Zhaocheng and Poor, H. Vincent
(2024)
Knowledge and data dual-driven channel estimation and feedback for ultra-massive MIMO systems under hybrid field beam squint effect.
IEEE Transactions on Wireless Communications, 23 (9), .
(doi:10.1109/TWC.2024.3380638).
Abstract
Acquiring accurate channel state information (CSI) at an access point (AP) is challenging for wideband millimeter wave (mmWave) ultra-massive multiple-input and multiple-output (UMMIMO) systems, due to the high-dimensional channel matrices, hybrid near- and far- field channel feature, beam squint effects, and imperfect hardware constraints, such as low-resolution analogto- digital converters, and in-phase and quadrature imbalance. To overcome these challenges, this paper proposes an efficient downlink channel estimation (CE) and CSI feedback approach based on knowledge and data dual-driven deep learning (DL) networks. Specifically, we first propose a data-driven residual neural network de-quantizer (ResNet-DQ) to pre-process the received pilot signals at user equipment (UEs), where the noise and distortion brought by imperfect hardware can be mitigated. A knowledge-driven generalized multiple measurement vector learned approximate message passing (GMMV-LAMP) network is then developed to jointly estimate the channels by exploiting the approximately same physical angle shared by different subcarriers. In particular, two wideband redundant dictionaries (WRDs) are proposed such that the measurement matrices of the GMMV-LAMP network can accommodate the farfield and near-field beam squint effect, respectively. Finally, we propose an encoder at the UEs and a decoder at the AP by a data-driven CSI residual network (CSI-ResNet) to compress the CSI matrix into a low-dimensional quantized bit vector for feedback, thereby reducing the feedback overhead substantially. Simulation results show that the proposed knowledge and data dual-driven approach outperforms conventional downlink CE and CSI feedback methods, especially in the case of low signal-to-noise ratios.
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Accepted/In Press date: 11 March 2024
e-pub ahead of print date: 29 March 2024
Published date: 12 September 2024
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Publisher Copyright:
IEEE
Keywords:
CSI feedback, Ultra-massive multiple input multiple output (UM-MIMO), channel estimation, hybrid near- and far- field channels, knowledge and data dual-driven, orthogonal frequency division multiplexing (OFDM)
Identifiers
Local EPrints ID: 487983
URI: http://eprints.soton.ac.uk/id/eprint/487983
ISSN: 1536-1276
PURE UUID: d76bc57b-d4e2-4f7d-866f-2553c07e0b5d
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Date deposited: 12 Mar 2024 17:39
Last modified: 13 Sep 2024 16:31
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Contributors
Author:
Kuiyu Wang
Author:
Zhen Gao
Author:
Sheng Chen
Author:
Boyu Ning
Author:
Gaojie Chen
Author:
Yu Su
Author:
Zhaocheng Wang
Author:
H. Vincent Poor
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