Abstract
Target recognition is one of the most challenging tasks in synthetic aperture radar (SAR) image processing since it is highly affected by a series of pre-processing techniques which usually require sophisticated manipulation for different data and consume huge calculation resources. To alleviate this limitation, numerous deep-learning based target recognition methods are proposed, particularly combined with convolutional neural network (CNN) due to its strong capability of data abstraction and end-to-end structure. In this case, although complex pre-processing can be avoided, the inner mechanism of CNN is still unclear. Such a “black box” only tells a result but not what CNN learned from the input data, thus it is difficult for researchers to further analyze the causes of errors. Layer-wise relevance propagation (LRP) is a prevalent pixel-level rearrangement algorithm to visualize neural networks’ inner mechanism. LRP is usually applied in sparse auto-encoder with only fully-connected layers rather than CNN, but such network structure usually obtains much lower recognition accuracy than CNN. In this paper, we propose a novel LRP algorithm particularly designed for understanding CNN’s performance on SAR image target recognition. We provide a concise form of the correlation between output of a layer and weights of the next layer in CNNs. The proposed method can provide positive and negative contributions in input SAR images for CNN’s classification, viewed as a clear visual understanding of CNN’s recognition mechanism. Numerous experimental results demonstrate the proposed method outperforms common LRP.
Highlights
Synthetic aperture radar (SAR) can generate radar images with both high rangeresolution and Doppler-resolution by synthesizing a series of small aperture antennas into an equivalent large aperture antenna
We compare the performance of common Layer-wise relevance propagation (LRP) with sparse auto-encoder and the proposed method with convolutional neural network (CNN)
We proposed a new LRP method designed for CNN’s classification in synthetic aperture radar (SAR) image interpretation
Summary
Synthetic aperture radar (SAR) can generate radar images with both high rangeresolution and Doppler-resolution by synthesizing a series of small aperture antennas into an equivalent large aperture antenna. In. SAR image interpretation, target recognition is usually regarded as one of the most challenging tasks [1,3]. Target recognition can be compartmentalized into two steps: First, some pre-processing techniques will be performed on raw SAR images, such as filtering, edge detection, region of interest (ROI) extraction, and feature extraction. A classifier is used to categorize them to their corresponding class according to the divergence among extracted features [4,5]. Such complex individual procedures usually bring a huge computation burden, causing difficulty in realizing real-time application and device miniaturization
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