B-spline neural network based multiuser MIMO-OFDM nonlinear uplink
B-spline neural network based multiuser MIMO-OFDM nonlinear uplink
Multiple-input multiple-output (MIMO) technology in conjunction with orthogonal frequency division multiplexing (OFDM) transmission is widely adopted in fifth-generation mobile networks to support multiple users. However, in these mobile communication systems, high power amplifiers (HPAs) at user terminals’ transmitters are driven into their saturation regions, which makes the multiuser frequency-selective MIMO-OFDM uplink channel nonlinear and renders the standard multiuser detection (MUD) at the base station (BS) ineffective. In this paper machine learning is employed to combat the distortions in the uplink of this multiuser frequency-selective MIMO-OFDM communication system. More specifically, a powerful complexvalued B-spline neural network (BSNN) based design is developed to simultaneously identify the system’s channel impulse response (CIR) matrix and the BSNN model for the nonlinear transmitters’ HPA together with the BSNN inversion for the nonlinear HPA at transmitters. This enables the BS to effectively implement MUD by utilizing the estimated MIMO-OFDM CIR matrix as well as to compensate for the transmitter HPAs’ saturation distortions using the estimated BSNN inversion. A simulation study is included to evaluate the effectiveness of this novel BSNN assisted design in combating multiuser and dispersive channel interference as well as nonlinear distortions for multiuser MIMOOFDM nonlinear uplink.
4030-4045
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Wang, Pengyu
9a5a7248-f266-4204-964b-eff81d3c1a34
Li, Mingkun
206a1f93-e786-4f77-b304-ca600edfbfa9
Khalaf, Emad
f8dad6b4-c9c8-4e20-b5be-62aec5625eba
Morfeq, Ali
c6be8aa2-aba9-4d2d-aae9-0056ff0ba742
Alotaibi, Naif
039035d6-edee-4e87-93b5-7c847f88e956
28 January 2026
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Wang, Pengyu
9a5a7248-f266-4204-964b-eff81d3c1a34
Li, Mingkun
206a1f93-e786-4f77-b304-ca600edfbfa9
Khalaf, Emad
f8dad6b4-c9c8-4e20-b5be-62aec5625eba
Morfeq, Ali
c6be8aa2-aba9-4d2d-aae9-0056ff0ba742
Alotaibi, Naif
039035d6-edee-4e87-93b5-7c847f88e956
Chen, Sheng, Wang, Pengyu, Li, Mingkun, Khalaf, Emad, Morfeq, Ali and Alotaibi, Naif
(2026)
B-spline neural network based multiuser MIMO-OFDM nonlinear uplink.
IEEE Transactions on Communications, 74, .
Abstract
Multiple-input multiple-output (MIMO) technology in conjunction with orthogonal frequency division multiplexing (OFDM) transmission is widely adopted in fifth-generation mobile networks to support multiple users. However, in these mobile communication systems, high power amplifiers (HPAs) at user terminals’ transmitters are driven into their saturation regions, which makes the multiuser frequency-selective MIMO-OFDM uplink channel nonlinear and renders the standard multiuser detection (MUD) at the base station (BS) ineffective. In this paper machine learning is employed to combat the distortions in the uplink of this multiuser frequency-selective MIMO-OFDM communication system. More specifically, a powerful complexvalued B-spline neural network (BSNN) based design is developed to simultaneously identify the system’s channel impulse response (CIR) matrix and the BSNN model for the nonlinear transmitters’ HPA together with the BSNN inversion for the nonlinear HPA at transmitters. This enables the BS to effectively implement MUD by utilizing the estimated MIMO-OFDM CIR matrix as well as to compensate for the transmitter HPAs’ saturation distortions using the estimated BSNN inversion. A simulation study is included to evaluate the effectiveness of this novel BSNN assisted design in combating multiuser and dispersive channel interference as well as nonlinear distortions for multiuser MIMOOFDM nonlinear uplink.
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NMUMIMOOFDM
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Accepted/In Press date: 5 January 2026
Published date: 28 January 2026
Identifiers
Local EPrints ID: 509569
URI: http://eprints.soton.ac.uk/id/eprint/509569
ISSN: 0090-6778
PURE UUID: 990b4545-69df-413b-a797-3956d74a9b7d
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Date deposited: 25 Feb 2026 17:53
Last modified: 25 Feb 2026 17:53
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Contributors
Author:
Sheng Chen
Author:
Pengyu Wang
Author:
Mingkun Li
Author:
Emad Khalaf
Author:
Ali Morfeq
Author:
Naif Alotaibi
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