Abstract
Synthetic aperture radar (SAR) automatic target recognition (ATR) technology is one of the research hotspots in the field of image cognitive learning. Inspired by the human cognitive process, experts have designed convolutional neural network (CNN)-based SAR ATR methods. However, the performance of CNN significantly deteriorates when the labeled samples are insufficient. To effectively utilize the unlabeled samples, we present a novel semi-supervised CNN method. In the training process of our method, the information contained in the unlabeled samples is integrated into the loss function of CNN. Specifically, we first utilize CNN to obtain the class probabilities of the unlabeled samples. Thresholding processing is performed to optimize the class probabilities so that the reliability of the unlabeled samples is improved. Afterward, the optimized class probabilities are used to calculate the scatter matrices of the linear discriminant analysis (LDA) method. Finally, the loss function of CNN is modified by the scatter matrices. We choose ten types of targets from the Moving and Stationary Target Acquisition and Recognition (MSTAR) dataset. The experimental results show that the recognition accuracy of our method is significantly higher than other semi-supervised methods. It has been proved that our method can effectively improve the SAR ATR accuracy when labeled samples are insufficient.
Highlights
MethodsTo effectively utilize the unlabelled samples, a semi-supervised convolutional neural network (CNN) method is proposed in this paper
Synthetic Aperture Radar (SAR) has been widely used due to its high resolution and penetrating ability [1,2,3]
The class probabilities are utilized to control the impact of the unlabelled samples
Summary
The average training time of our method is 2.53sec/epoch, much less than that of the semi-supervised ladder network. The reason is that the structure of the ladder network is complex than that of the CNN used in our method. The average training time of the Pi model and temporal ensembling model is less than that of our method. This is because the Pi and temporal ensembling models utilize the CNN to predict the labels of the unlabelled samples. Our method can effectively maintain the reliability of the unlabelled samples. The computation complexity of our method is increased, the recognition accuracy is improved
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