Abstract
The monogenic signal, which is defined as a linear combination of a signal and its Riesz-transformed one, provides a great opportunity for synthetic aperture radar (SAR) image recognition. However, the incredibly large number of components at different scales may result in too much of a burden for onboard computation. There is great information redundancy in monogenic signals because components at some scales are less discriminative or even have negative impact on classification. In addition, the heterogeneity of the three types of components will lower the quality of decision-making. To solve the problems above, a scale selection method, based on a weighted multi-task joint sparse representation, is proposed. A scale selection model is designed and the Fisher score is presented to measure the discriminative ability of components at each scale. The components with high Fisher scores are concatenated to three component-specific features, and an overcomplete dictionary is built. Meanwhile, the scale selection model produces the weight vector. The three component-specific features are then fed into a multi-task joint sparse representation classification framework. The final decision is made in terms of accumulated weighted reconstruction error. Experiments on the Moving and Stationary Target Acquisition and Recognition (MSTAR) dataset have proved the effectiveness and superiority of our method.
Highlights
Synthetic aperture radar (SAR) automatic target recognition (ATR) is becoming increasingly important as the development of radar technology continues [1]
The Moving and Stationary Target Acquisition and Recognition (MSTAR) public database is used to evaluate the performance of the proposed method
The azimuth angles of SAR imagery are from 0◦ to 360◦ and adjacent angle intervals are from 1◦ to 2◦
Summary
Synthetic aperture radar (SAR) automatic target recognition (ATR) is becoming increasingly important as the development of radar technology continues [1]. The decomposed operation is usually used for high-dimensional signal analysis and processing. This decoupling strategy makes it possible to deal with many problems in the field of image processing, especially when the traditional pixel intensity can not be treated as a reliable feature in the classification field. The monogenic signal has the ability to capture broad spectral information, which is useful for SAR image recognition. The monogenic signal has provided a new viewpoint and method in the field of low-level image processing, due to its ability to provide local features of the phase-vector and attenuation in scale space. The application of the monogenic signal has been extended into the field of pattern recognition as research continues. In [11], the texture and motion information which is extracted from the monogenic signal is used for facial expression recognition
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