Rainfall regression from C-band Synthetic Aperture Radar using Multi-Task Generative Adversarial Networks
This work addresses rainfall estimation for remote sensing applications, but it is incremental as it builds on existing methods with specific enhancements.
The paper tackled the problem of estimating precipitation rates from Synthetic Aperture Radar (SAR) at 200-meter resolution by addressing challenges like data misalignment and scarcity in strong wind conditions, resulting in improved accuracy and performance extension to scenarios up to 15 m/s.
This paper introduces a data-driven approach to estimate precipitation rates from Synthetic Aperture Radar (SAR) at a spatial resolution of 200 meters per pixel. It addresses previous challenges related to the collocation of SAR and weather radar data, specifically the misalignment in collocations and the scarcity of rainfall examples under strong wind. To tackle these challenges, the paper proposes a multi-objective formulation, introducing patch-level components and an adversarial component. It exploits the full NEXRAD archive to look for potential co-locations with Sentinel-1 data. With additional enhancements to the training procedure and the incorporation of additional inputs, the resulting model demonstrates improved accuracy in rainfall estimates and the ability to extend its performance to scenarios up to 15 m/s.