SAR Target Recognition Based on Task-Driven Domain Adaptation Using Simulated Data

Synthetic aperture radar (SAR) images are highly susceptible to imaging conditions. However, the majority of deep learning (DL) models in SAR automatic target recognition (ATR) adopt enhanced network structures similar to those in dealing with optical image classification tasks, which is obviously unreasonable since the huge gap of the imaging conditions between training and testing data severely deteriorates the recognition performance. The main idea of the framework is to introduce SAR imaging condition information into the DL training stage to eliminate domain discrepancies between training and testing data. Based on this framework, we propose a task-driven domain adaptation (TDDA) transfer learning method, which can alleviate the degradation of recognition caused by the variance of depression angle between training and testing data. In order to introduce the prior imaging information into the method, simulated SAR data is first obtained by adding a simulated object radar reflectivity to a terrain model of individual point scatters using the known training and testing SAR imaging parameters. Then a domain confusion metric and a supervised classification loss are calculated on simulated data and source training data, respectively, to learn a representation that is semantically meaningful and domain invariant. Comparative experiments on the moving and stationary target acquisition and recognition (MSTAR) dataset demonstrate that the proposed method can obtain better recognition performance than the other methods.