Wireless interference recognition with multimodal learning
Wireless interference recognition with multimodal learning
In non-cooperative communications, malicious electromagnetic interference attacks communication systems and causes higher probability of communication disruption. In order to address the challenges posed by electromagnetic interference, the wireless interference recognition technique has emerged, which identifies the interference signals without priori information. In recent years, the success of deep learning (DL) has sparked interest in introducing DL in the field of wireless interference recognition. However, most DL-based interference identification methods improve accuracy by dramatically increasing network sizes while ignoring the important effect of network inputs. For this reason, we extensively investigate the impact of different signal transformation forms of interference (called signal modalities) on performance. The artificial features of the interference signal are also utilized as one of the refined modalities, which breaks the inherent concept that artificial features are only used in the methods of feature extraction. Convolution and transformer are combined in the extraction of different modal features. In order to reduce the complexity of transformer, a dual transformer module (DTM) is proposed. Furthermore, to overcome the imbalance of modal optimization during the training process, an adaptive gradient modulation (AGM) strategy is proposed, which leads to better convergence for the multimodal training. Finally, modal information selection mechanism (MISM) selects the most appropriate modalities for each input sample, which saves computational costs. Extensive experiments demonstrate that combining multiple interference modalities is more effective than trying different networks.
Wang, Pengyu
9a5a7248-f266-4204-964b-eff81d3c1a34
Ma, Ke
4a5144d2-9587-49fd-81e0-35b09b4e2f52
Bai, Yingshuang
9315d980-cc48-4360-99bf-c5399022162f
Sun, Chen
43e34dae-1569-4c2f-b8ce-b3690c74269c
Wang, Zhaocheng
70339538-3970-4094-bcfc-1b5111dfd8b4
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Wang, Pengyu
9a5a7248-f266-4204-964b-eff81d3c1a34
Ma, Ke
4a5144d2-9587-49fd-81e0-35b09b4e2f52
Bai, Yingshuang
9315d980-cc48-4360-99bf-c5399022162f
Sun, Chen
43e34dae-1569-4c2f-b8ce-b3690c74269c
Wang, Zhaocheng
70339538-3970-4094-bcfc-1b5111dfd8b4
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Wang, Pengyu, Ma, Ke, Bai, Yingshuang, Sun, Chen, Wang, Zhaocheng and Chen, Sheng
(2024)
Wireless interference recognition with multimodal learning.
IEEE Transactions on Wireless Communications.
(doi:10.1109/TWC.2024.3470244).
Abstract
In non-cooperative communications, malicious electromagnetic interference attacks communication systems and causes higher probability of communication disruption. In order to address the challenges posed by electromagnetic interference, the wireless interference recognition technique has emerged, which identifies the interference signals without priori information. In recent years, the success of deep learning (DL) has sparked interest in introducing DL in the field of wireless interference recognition. However, most DL-based interference identification methods improve accuracy by dramatically increasing network sizes while ignoring the important effect of network inputs. For this reason, we extensively investigate the impact of different signal transformation forms of interference (called signal modalities) on performance. The artificial features of the interference signal are also utilized as one of the refined modalities, which breaks the inherent concept that artificial features are only used in the methods of feature extraction. Convolution and transformer are combined in the extraction of different modal features. In order to reduce the complexity of transformer, a dual transformer module (DTM) is proposed. Furthermore, to overcome the imbalance of modal optimization during the training process, an adaptive gradient modulation (AGM) strategy is proposed, which leads to better convergence for the multimodal training. Finally, modal information selection mechanism (MISM) selects the most appropriate modalities for each input sample, which saves computational costs. Extensive experiments demonstrate that combining multiple interference modalities is more effective than trying different networks.
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Accepted/In Press date: 24 September 2024
e-pub ahead of print date: 7 October 2024
Identifiers
Local EPrints ID: 494986
URI: http://eprints.soton.ac.uk/id/eprint/494986
ISSN: 1536-1276
PURE UUID: ad26397d-c0d1-4d45-9bdf-987458f93c3a
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Date deposited: 24 Oct 2024 16:49
Last modified: 24 Oct 2024 16:49
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Author:
Pengyu Wang
Author:
Ke Ma
Author:
Yingshuang Bai
Author:
Chen Sun
Author:
Zhaocheng Wang
Author:
Sheng Chen
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