Related papers: Radar Signal Recognition through Self-Supervised Learning and Domain Adaptation

Radar Signal Recognition through Self-Supervised Learning and Domain Adaptation

URL: http://arxiv.org/abs/2501.03461v2
Date: Tue, 14 Jan 2025 04:53:30 GMT
Title: Radar Signal Recognition through Self-Supervised Learning and Domain Adaptation
Authors: Zi Huang, Simon Denman, Akila Pemasiri, Clinton Fookes, Terrence Martin,
Abstract summary: We introduce a self-supervised learning (SSL) method to enhance radar signal recognition in environments with limited RF samples and labels. Specifically, we investigate pre-training masked autoencoders (MAE) on baseband in-phase and quadrature (I/Q) signals from various RF domains. Results show that our lightweight self-supervised ResNet model with domain adaptation achieves up to a 17.5% improvement in 1-shot classification accuracy.
Score: 48.265859815346985
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Abstract: Automatic radar signal recognition (RSR) plays a pivotal role in electronic warfare (EW), as accurately classifying radar signals is critical for informing decision-making processes. Recent advances in deep learning have shown significant potential in improving RSR performance in domains with ample annotated data. However, these methods fall short in EW scenarios where annotated RF data are scarce or impractical to obtain. To address these challenges, we introduce a self-supervised learning (SSL) method which utilises masked signal modelling and RF domain adaption to enhance RSR performance in environments with limited RF samples and labels. Specifically, we investigate pre-training masked autoencoders (MAE) on baseband in-phase and quadrature (I/Q) signals from various RF domains and subsequently transfer the learned representation to the radar domain, where annotated data are limited. Empirical results show that our lightweight self-supervised ResNet model with domain adaptation achieves up to a 17.5% improvement in 1-shot classification accuracy when pre-trained on in-domain signals (i.e., radar signals) and up to a 16.31% improvement when pre-trained on out-of-domain signals (i.e., comm signals), compared to its baseline without SSL. We also provide reference results for several MAE designs and pre-training strategies, establishing a new benchmark for few-shot radar signal classification.

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