DG²-TCR: An Adaptive Clouds Removal Network for Optical Remote Sensing Images Using SAR-Driven Dual-Flow Fusion Guidance

Clouds in optical remote sensing images significantly limit image utilization. Traditional cloud removal methods using single or multi-temporal data sources struggle to ensure reliable reconstruction for thick cloud (TKC) areas. Synthetic aperture radar (SAR) images are increasingly used to recover information obscured by clouds, but their performance in cloud-obscured regions is unstable. Therefore, an adaptive cloud removal network for remote sensing images, named DG²-TCR, is proposed based on SAR-driven dual-flow fusion guidance (DFG). DG²-TCR uses SAR and optical remote sensing imagery (ORSI) to construct DFG, including local spatial-spectral feature reconstruction (LSSFR) flow and global texture feature compensation (GTFC). LSSFR, driven by ORSI and SAR, efficiently extracts useful features in noncloud areas and focuses on local information reconstruction using the designed spatial-spectral features inference reconstruction block (SSIRB). Based on SAR images, GTFC guides the compensation of global texture information. DFG can adaptively extract features and reconstruct missing information from local and global scales. The public SEN12MS-CR-TS dataset is divided into four sub-datasets with different coverage to evaluate the recovering capability in varying clouds. Experiments show that the peak signal-to-noise ratio (PSNR), structural similarity index (SSIM), root mean square error (RMSE), Fréchet inception distance (FID), and normalized cross correlation (NCC) indicator values on four sub-datasets and the SIMLE-CR datasets are better than the seven comparison methods. Furthermore, the ablation experiments show that the generalization and robustness of this proposed method on images with different cloud coverage are better than other comparison methods. Therefore, DG²-TCR can reliably recover information on cloud occlusions with various coverage and thickness, which is significant for cloud removal in practical applications.