Abstract
In a hazy environment, visibility is reduced and objects are difficult to identify. For this reason, many dehazing techniques have been proposed to remove the haze. Especially, in the case of the atmospheric scattering model estimation-based method, there is a problem of distortion when inaccurate models are estimated. We present a novel residual-based dehazing network model to overcome the performance limitation in an atmospheric scattering model-based method. More specifically, the proposed model adopted the gate fusion network that generates the dehazed results using a residual operator. To further reduce the divergence between the clean and dehazed images, the proposed discriminator distinguishes dehazed results and clean images, and then reduces the statistical difference via adversarial learning. To verify each element of the proposed model, we hierarchically performed the haze removal process in an ablation study. Experimental results show that the proposed method outperformed state-of-the-art approaches in terms of peak signal-to-noise ratio (PSNR), structural similarity index measure (SSIM), international commission on illumination cie delta e 2000 (CIEDE2000), and mean squared error (MSE). It also gives subjectively high-quality images without color distortion or undesired artifacts for both synthetic and real-world hazy images.
Highlights
Outdoor images are degraded by various atmospheric particles such as haze and dust
Since it is hard to estimate the accurate transmission in Equation (1), we propose a novel residual-based dehazing method that does not use the transmission map
To train the proposed model, Adam optimizer was used with learning rate (10)−4 for combined Ll1 and VGG16 loss ( Ll1 + Lvgg ) and (10)−6 for adversarial loss ( L adv(G), L adv( D) )
Summary
Outdoor images are degraded by various atmospheric particles such as haze and dust. Haze reduces the visibility of the image and disturbs the clarity of distant objects because of the effect of light scattering by particles in the air. Dehazing techniques were based on mathematical optimization. Huang et al proposed a visibility restoration (VR) technique using color correlation based on the gray world assumption and transmission map based on depth estimation [1]. Proposed a Markov random field-based graph cut and belief propagation method to remove haze without using geometrical information [2]. Qu et al presented a dehazing method based on a local consistent Markov random field framework [5].
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