Deep learning assisted adaptive index modulation for mmWave communications with channel estimation
Deep learning assisted adaptive index modulation for mmWave communications with channel estimation
The efficiency of link adaptation in wireless communications relies greatly on the accuracy of channel knowledge and transmission mode selection. In this paper, a novel deep learning based link adaptation framework is proposed for the orthogonal frequency-division multiplexing (OFDM) systems with compressed-sensing-assisted index modulation, termed as OFDM-CSIM, communicating over millimeter-wave (mmWave) channels. To achieve link adaptation, a novel multi-layer sparse Bayesian learning (SBL) algorithm is proposed for accurately and instantaneously providing the required channel state information. Meanwhile, a deep neural networks (DNN)-assisted adaptive modulation algorithm is proposed to choose the best possible transmission mode to maximize the achievable throughput. Simulation results show that the proposed multi-layer SBL algorithm enables more accurate channel estimation than the conventional techniques. The DNN-based adaptive modulator is capable of achieving a higher throughput than the learning-assisted solution based on the k nearest neighbor (k-NN) algorithm, and also the classic average signal-to-noise ratio (SNR)-based solutions. Moreover, analysis shows that both the multi-layer SBL algorithm and the DNN-assisted adaptive modulator achieve better performance than their respective conventional counterparts while at a significantly lower computational complexity cost.
Adaptive modulation, OFDM, channel estimation, machine learning, mmWave, neural networks, sparse Bayesian learning
9186-9201
Liu, Haochen
280c47ba-6330-47b5-b5cd-2ca84878ce0a
Zhang, Yaoyuan
6b05d076-c3a9-4e38-90cb-bb89c5ccf265
Zhang, Xiaoyu
ea1ec5dd-5b9f-4ba9-b420-c05e771a5ae3
El-Hajjar, Mohammed
3a829028-a427-4123-b885-2bab81a44b6f
Yang, Lie-Liang
ae425648-d9a3-4b7d-8abd-b3cfea375bc7
1 September 2022
Liu, Haochen
280c47ba-6330-47b5-b5cd-2ca84878ce0a
Zhang, Yaoyuan
6b05d076-c3a9-4e38-90cb-bb89c5ccf265
Zhang, Xiaoyu
ea1ec5dd-5b9f-4ba9-b420-c05e771a5ae3
El-Hajjar, Mohammed
3a829028-a427-4123-b885-2bab81a44b6f
Yang, Lie-Liang
ae425648-d9a3-4b7d-8abd-b3cfea375bc7
Liu, Haochen, Zhang, Yaoyuan, Zhang, Xiaoyu, El-Hajjar, Mohammed and Yang, Lie-Liang
(2022)
Deep learning assisted adaptive index modulation for mmWave communications with channel estimation.
IEEE Transactions on Vehicular Technology, 71 (9), .
(doi:10.1109/TVT.2022.3181825).
Abstract
The efficiency of link adaptation in wireless communications relies greatly on the accuracy of channel knowledge and transmission mode selection. In this paper, a novel deep learning based link adaptation framework is proposed for the orthogonal frequency-division multiplexing (OFDM) systems with compressed-sensing-assisted index modulation, termed as OFDM-CSIM, communicating over millimeter-wave (mmWave) channels. To achieve link adaptation, a novel multi-layer sparse Bayesian learning (SBL) algorithm is proposed for accurately and instantaneously providing the required channel state information. Meanwhile, a deep neural networks (DNN)-assisted adaptive modulation algorithm is proposed to choose the best possible transmission mode to maximize the achievable throughput. Simulation results show that the proposed multi-layer SBL algorithm enables more accurate channel estimation than the conventional techniques. The DNN-based adaptive modulator is capable of achieving a higher throughput than the learning-assisted solution based on the k nearest neighbor (k-NN) algorithm, and also the classic average signal-to-noise ratio (SNR)-based solutions. Moreover, analysis shows that both the multi-layer SBL algorithm and the DNN-assisted adaptive modulator achieve better performance than their respective conventional counterparts while at a significantly lower computational complexity cost.
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paper
- Accepted Manuscript
More information
Accepted/In Press date: 10 June 2022
Published date: 1 September 2022
Keywords:
Adaptive modulation, OFDM, channel estimation, machine learning, mmWave, neural networks, sparse Bayesian learning
Identifiers
Local EPrints ID: 467311
URI: http://eprints.soton.ac.uk/id/eprint/467311
ISSN: 0018-9545
PURE UUID: bce34c09-8756-42bb-9380-e844a571f711
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Date deposited: 05 Jul 2022 17:04
Last modified: 18 Apr 2024 01:59
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Contributors
Author:
Haochen Liu
Author:
Yaoyuan Zhang
Author:
Xiaoyu Zhang
Author:
Mohammed El-Hajjar
Author:
Lie-Liang Yang
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