Abstract
As one of the most common adverse weather phenomena, haze has caused detrimental effects on many computer vision systems. To eliminate the effect of haze, in the field of image processing, image dehazing has been studied intensively, and many advanced dehazing algorithms have been proposed. Physical model-based and deep learning-based methods are two competitive methods for single image dehazing, but it is still a challenging problem to achieve fidelity and effectively dehazing simultaneously in real hazy scenes. In this work, a mixed iterative model is proposed, which combines a physical model-based method with a learning-based method to restore high-quality clear images, and it has good performance in maintaining natural attributes and completely removing haze. Unlike previous studies, we first divide the image into different regions according to the density of haze to accurately calculate the atmospheric light for restoring haze-free images. Then, dark channel prior and DehazeNet are used to jointly estimate the transmission to promote the final clear haze-free image that is more similar to the real scene. Finally, a numerical iterative strategy is employed to further optimize the atmospheric light and transmission. Extensive experiments demonstrate that our method outperforms existing state-of-the-art methods on synthetic datasets and real-world datasets. Moreover, to indicate the universality of the proposed method, we further apply it to the remote sensing datasets, which can also produce visually satisfactory results.
Highlights
Due to the absorption and scattering of suspended particles in the atmosphere, images taken in haze, fog, and smoke have low contrast and poor visibility
Based on the dark channel prior (DCP), we introduce a single-image numerical iterative dehazing method for single-image defogging [17], which can effectively remove the fog from hazy images, preserve the detail of the image and maintain fidelity
The single-image numerical iterative dehazing method we proposed in [17] is dependent on local physical features; it can remove most of the haze in images and restore appropriate brightness and color levels while maintaining the physical characteristics
Summary
Due to the absorption and scattering of suspended particles in the atmosphere, images taken in haze, fog, and smoke have low contrast and poor visibility. Hazy images can severely affect the performance of surveillance systems, remote sensing imaging, and computer vision tasks that depend on image quality. The single-image defogging method can recover a haze-free image from a low-quality foggy scene. According to the physical process of hazy image formation [1], a hazy image is described as: IðxÞ 1⁄4 JðxÞtðxÞ þ Að1 À tðxÞÞ; ð1Þ.
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