Skip to content

Latest commit

 

History

History
26 lines (15 loc) · 2.13 KB

README.md

File metadata and controls

26 lines (15 loc) · 2.13 KB

deSpeckNet: Generalizing Deep Learning Based SAR Image Despeckling.

Deep learning (DL) has proven to be a suitable approach for despeckling synthetic aperture radar (SAR) images. So far, most DL models are trained to reduce speckle that follows a particular distribution, either using simulated noise or a specific set of real SAR images, limiting the applicability of these methods for real SAR images with unknown noise statistics. In this article,we present a DL method, deSpeckNet, 1 that estimates the speckle noise distribution and the despeckled image simultaneously.Since it does not depend on a specific noise model, deSpeckNet generalizes well across SAR acquisitions in a variety of landcover conditions. We evaluated the performance of deSpeckNet onsingle polarized Sentinel-1 images acquired in Indonesia, The Democratic Republic of Congo, and The Netherlands, a single polarized ALOS-2/PALSAR-2 image acquired in Japan and an Iceye X2 image acquired in Germany. In all cases, deSpeckNet was able to effectively reduce speckle and restore the images in high quality with respect to the state of the art.

Architecture

drawing1 drawing_finetune

The articles pre-print is available on https://arxiv.org/pdf/2012.03066.pdf

The base models used to tune the models to the respective test images is in the models folder.

Usage

To train a model, run train_despecknet_DAG.m or train_despecknet_DAG_TV.m to train a model. To test a pre-trained model, please run, test_despecknet_DAG.m.

Dependencies

These codes requires MatconvNet to be installed and configured for GPU. Matconvnet can be downloaded and installation instructions can be found here.

Reference

If you use these scripts please cite our paper as: Mullissa, A.G., Marcos, D., Tuia,D., Herold, M., Reiche, J.,~deSpeckNet: Generalizing Deep Learning Based SAR Image Despeckling, IEEE Transactions on Geoscience and Remote Sensing, 2020.