Abstract

In this paper, a new Region-based Convolutional Neural Networks (RCNN) method is proposed for target recognition in large scene synthetic aperture radar (SAR) images. To locate and recognize the targets in SAR images, there are three steps in the traditional procedure: detection, discrimination, classification and recognition. Each step is supposed to provide optimal processing results for the next step, but this is difficult to implement in real-life applications because of speckle noise and inefficient connection among these procedures. To solve this problem, the RCNN is applied to large scene SAR target recognition, which can detect the objects while recognizing their classes based on its regression method and the sharing network structure. However, size of the input images to RCNN is limited so that the classification could be accomplished, which leads to a problem that RCNN is not able to handle the large scene SAR images directly. Thus, before the RCNN, a fast sliding method is proposed to segment the scene image into sub-images with suitable size and avoid dividing targets into different sub-images. After the RCNN, candidate regions on different slices are predicted. To locate targets on large scene SAR images from these candidate regions on small slices, the Non-maximum Suppression between Regions (NMSR) is proposed, which could find the most proper candidate region among all the overlapped regions. Experiments on 1476 × 1784 simulated MSTAR images of simple scenes and complex scenes show that the proposed method can recognize all targets with the best accuracy and fastest speed, and outperform the other methods, such as constant false alarm rate (CFAR) detector + support vector machine (SVM), Visual Attention+SVM, and Sliding-RCNN.

Highlights

  • Spaceborne and airborne synthetic aperture radar (SAR) is able to operate in all-weather all-time conditions to generate high resolution SAR images; SAR has been widely used both in military and civil fields

  • In order to evaluate the accuracy of candidate regions generated by the region proposal network in our CNN network, an untrained slice of T72 in Moving and Stationary Target Acquisition and Recognition (MSTAR) data set is used as test sample, as Figure 10 shows

  • Inspired by great success of deep convolutional neural networks, methods of DCNN are applied to SAR image interpretation to extract features automatically, and a method to integrate detection and recognition of large scene SAR images based on non-maximum suppression between regions (NMSR) is proposed in this paper

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Summary

Introduction

Spaceborne and airborne synthetic aperture radar (SAR) is able to operate in all-weather all-time conditions to generate high resolution SAR images; SAR has been widely used both in military and civil fields. In the past few years, most researchers just focused on one part of these three stages, put forward theories such as scene segmentation, target discrimination, feature extraction, classifier design and so on These theories and algorithms just out-perform in specific operating conditions, which makes them not able to be applied universally. A reliable and universal system requires effective connection between detection and recognition, so End-to-End models were proposed [7,8], and apply robust trainable classifiers, such as Adaboost and support vector machine (SVM) [9,10,11] to realize SAR ATR. Liu proposed Single Shot MultiBox Detector (SSD), which was a compromise in accuracy and speed between Faster R-CNN and YOLO [16] Inspired by these advanced methods, many researchers tried to introduce deep learning methods into the field of SAR target detection and recognition to solve problems in End-to-End models.

SAR Target Recognition Based on Region-Based Convolutional Neural Networks
Fast Sliding
Convolutional Layer
Activation Function
Pooling Layer
Softmax Classification
Region Proposal
Loss Function
Ncls i
Non-Maximum Suppression between Regions
Experiments
Accuracy of Detection and Recognition
Anti-Noise Performance
Performance of Region Proposal Network and Non-Maximum Suppression
Detection and Recognition Performance on Large Scene Images
Comparison Experiments on Complex Background Image
Analysis on Detection and Recognition Accuracy
Analysis on Anti-Noise Performance
Analysis on Detection and Recognition Performance of Large Scene Images
Findings
Analysis on Comparison Experiments
Conclusions

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