Cross-Frequency Attention and Color Contrast Constraint for Remote Sensing Dehazing

Current deep learning-based methods for remote sensing image dehazing have developed rapidly, yet they still commonly struggle to simultaneously preserve fine texture details and restore accurate colors. The fundamental reason lies in the insufficient modeling of high-frequency information that captures structural details, as well as the lack of effective constraints for color restoration. To address the insufficient modeling of global high-frequency information, we first develop an omni-directional high-frequency feature in painting mechanism that leverages the wavelet transform to extract multi-directional high-frequency components. While maintaining the advantage of linear complexity, it models global long-range texture dependencies through cross-frequency perception. Then, to further strengthen local high-frequency representation, we design a high-frequency prompt attention module that dynamically injects wavelet-domain optimized high-frequency features as cross-level guidance signals, significantly enhancing the model's capability in edge sharpness restoration and texture detail reconstruction. Further, to alleviate the problem of inaccurate color restoration, we propose a color contrast loss function based on the HSV color space, which explicitly models the statistical distribution differences of brightness and saturation in hazy regions, guiding the model to generate dehazed images with consistent colors and natural visual appearance. Finally, extensive experiments on multiple benchmark datasets demonstrate that the proposed method outperforms existing approaches in both texture detail restoration and color consistency. Further results and code are available at: https://github.com/fyxnl/C4RSD.