Robust Bayesian attention belief network for radar work mode recognition
Robust Bayesian attention belief network for radar work mode recognition
Understanding and analyzing radar work modes play a key role in electronic support measure system. Many classifiers, for example those based on convolutional neural network (CNN) and recurrent neural network (RNN), are available for recognizing radar work modes as well as emitter types from their waveform parameters. However, the performance of these methods may suffer significantly when confronting different types of signal degradation, e.g., measurement error, lost pulse and spurious pulse. To tackle this issue, we in this paper develop a Bayesian attention belief network (BABNet) based on Bayesian neural networks in which the probability distribution over weights can help to enhance the model robustness for corrupted data. In particular, we adopt pre-trained CNN as the Bayesian inference prior. This not only accelerates the convergence speed, but also avoids the training process getting stuck in bad local minima. Meanwhile, instead of using RNNs which are difficult to be implemented in parallel, the combination of padding operation and attention module in the proposed BABNet enables CNN, as the backbone, to process sequential data with variable length. Extensive experiments are conducted to demonstrate the recognition capability and robustness of the BABNet in different environments.
Attention mechanism, Bayesian neural network, Pulse descriptor word, Radar work mode, Recognition, Robustness
Du, Mingyang
d42b1519-40d9-476a-b2a3-2b9f6c63d46a
Zhong, Ping
fbe3680c-9259-4868-80f6-33d810f1c646
Cai, Xiaohao
de483445-45e9-4b21-a4e8-b0427fc72cee
Bi, Daping
7d0942b5-14a9-4e09-b709-416fa34f31a2
Jing, Aiqi
c303e8cf-3555-4b90-aa8a-fab8803280f5
12 December 2022
Du, Mingyang
d42b1519-40d9-476a-b2a3-2b9f6c63d46a
Zhong, Ping
fbe3680c-9259-4868-80f6-33d810f1c646
Cai, Xiaohao
de483445-45e9-4b21-a4e8-b0427fc72cee
Bi, Daping
7d0942b5-14a9-4e09-b709-416fa34f31a2
Jing, Aiqi
c303e8cf-3555-4b90-aa8a-fab8803280f5
Du, Mingyang, Zhong, Ping, Cai, Xiaohao, Bi, Daping and Jing, Aiqi
(2022)
Robust Bayesian attention belief network for radar work mode recognition.
Digital Signal Processing: A Review Journal, 133.
(doi:10.1016/j.dsp.2022.103874).
Abstract
Understanding and analyzing radar work modes play a key role in electronic support measure system. Many classifiers, for example those based on convolutional neural network (CNN) and recurrent neural network (RNN), are available for recognizing radar work modes as well as emitter types from their waveform parameters. However, the performance of these methods may suffer significantly when confronting different types of signal degradation, e.g., measurement error, lost pulse and spurious pulse. To tackle this issue, we in this paper develop a Bayesian attention belief network (BABNet) based on Bayesian neural networks in which the probability distribution over weights can help to enhance the model robustness for corrupted data. In particular, we adopt pre-trained CNN as the Bayesian inference prior. This not only accelerates the convergence speed, but also avoids the training process getting stuck in bad local minima. Meanwhile, instead of using RNNs which are difficult to be implemented in parallel, the combination of padding operation and attention module in the proposed BABNet enables CNN, as the backbone, to process sequential data with variable length. Extensive experiments are conducted to demonstrate the recognition capability and robustness of the BABNet in different environments.
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More information
e-pub ahead of print date: 7 December 2022
Published date: 12 December 2022
Keywords:
Attention mechanism, Bayesian neural network, Pulse descriptor word, Radar work mode, Recognition, Robustness
Identifiers
Local EPrints ID: 491694
URI: http://eprints.soton.ac.uk/id/eprint/491694
ISSN: 1051-2004
PURE UUID: 57f5a0bc-3b88-4e7e-8822-bf19ef09298d
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Date deposited: 03 Jul 2024 16:02
Last modified: 11 Jul 2024 02:06
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Contributors
Author:
Mingyang Du
Author:
Ping Zhong
Author:
Xiaohao Cai
Author:
Daping Bi
Author:
Aiqi Jing
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