Abstract

Remarkable effectiveness has been demonstrated by deep neural networks in the despeckling task for Synthetic Aperture Radar (SAR) images. However, blurring and loss of fine details can result from many despeckling models due to up-sampling and mean square error (MSE) loss. Additionally, existing degradation models and prior information are ignored by existing despeckling models, which directly learn the mapping from degraded to clear images. To address these issues, an optimization algorithm for the SAR despeckling task based on the integral-Newton method is proposed in this article. Then, a prior-driven despeckling network is proposed, which can automatically capture the implicit priors in SAR images to replace traditional manually-made priors. Furthermore, to make the network focus more on learning the structural prior information of images, a structure-preserving loss function based on MSE and the Canny edge detection operator is designed, which improves the detail of the network retention ability and speeds up convergence. Outstanding results on both simulated datasets and real SAR images are achieved by the proposed method, as shown by a large number of experimental results. Moreover, significant advantages of the proposed method both visually and quantitatively are revealed by comparison with classical and state-of-the-art despeckling algorithms.