MambaDS: Near-Surface Meteorological Field Downscaling With Topography Constrained Selective State-Space Modeling

In an era of frequent extreme weather and global warming, obtaining precise, fine-grained near-surface weather forecasts is increasingly essential for human activities. Downscaling (DS), a crucial task in meteorological forecasting and remote sensing, enables the reconstruction of high-resolution meteorological states for target regions from global-scale forecast results. Previous downscaling methods, inspired by convolutional neural network (CNN) and Transformer-based super-resolution (SR) models, lacked tailored designs for meteorology and encountered structural limitations. Notably, they failed to efficiently integrate topography, a crucial prior to the downscaling process. In this article, we address these limitations by pioneering the selective state-space model (SSM) into the meteorological field downscaling and propose a novel model called MambaDS. This model retains the advantages of Mamba in long-range dependency modeling and linear computational complexity while enhancing the learning ability of multivariate correlation. In addition, by designing an efficient topography constraint layer, this prior information can be used more efficiently than ever before. Through extensive experiments in both China mainland and the continental United States (CONUS), we validated that our proposed MambaDS achieves state-of-the-art (SOTA) results in three different types of meteorological field downscaling settings.