Single Image Dehazing Based on Two-Stream Convolutional Neural Network

Jun Meng, Yuanyuan Li, Huahua Liang, You Ma
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引用次数: 22

Abstract

Objective The haze weather environment leads to the deterioration of the visual effect of the image, and it is difficult to carry out the work of the advanced vision task. Therefore, dehazing the haze image is an important step before the execution of the advanced vision task. Traditional dehazing algorithms achieve image dehazing by improving image brightness and contrast or constructing artificial priors such as color attenuation priors and dark channel priors, but the effect is unstable when dealing with complex scenes. In the method based on convolutional neural network, the image dehazing network of the encoding and decoding structure does not consider the difference before and after the dehazing image, and the image spatial information is lost in the encoding stage. In order to overcome these problems, this paper proposes a novel end-to-end two-stream convolutional neural network for single image dehazing. Method The network model is composed of a spatial information feature stream and a high-level semantic feature stream. The spatial information feature stream retains the detailed information of the dehazing image, and the high-level semantic feature stream extracts the multi-scale structural features of the dehazing image. A spatial information auxiliary module is designed between the feature streams. This module uses the attention mechanism to construct a unified expression of different types of information, and realizes the gradual restoration of the clear image with the semantic information auxiliary spatial information in the dehazing network. A parallel residual twicing module is proposed, which performs dehazing on the difference information of features at different stages to improve the model’s ability to discriminate haze images. Result The peak signal-to-noise ratio and structural similarity are used to quantitatively evaluate the similarity between the dehazing results of each algorithm and the original image. The structure similarity and peak signal-to-noise ratio of the method in this paper reached 0.852 and 17.557dB on the Hazerd dataset, which were higher than all comparison algorithms. On the SOTS dataset, the indicators are 0.955 and 27.348dB, which are sub-optimal results. In experiments with real haze images, this method can also achieve excellent visual restoration effects.
基于双流卷积神经网络的单图像去雾
目的雾霾天气环境导致图像视觉效果恶化,难以开展高级视觉任务的工作。因此,对雾霾图像进行去雾处理是执行高级视觉任务前的重要步骤。传统的去雾算法通过提高图像亮度和对比度或构建颜色衰减先验和暗通道先验等人工先验来实现图像去雾,但在处理复杂场景时效果不稳定。在基于卷积神经网络的方法中,编码和解码结构的图像去雾网络没有考虑图像去雾前后的差异,在编码阶段丢失了图像空间信息。为了克服这些问题,本文提出了一种新的端到端双流卷积神经网络用于单幅图像去雾。方法网络模型由空间信息特征流和高级语义特征流组成。空间信息特征流保留去雾图像的详细信息,高级语义特征流提取去雾图像的多尺度结构特征。在特征流之间设计了空间信息辅助模块。该模块利用注意机制构建不同类型信息的统一表达,在消雾网络中通过语义信息辅助空间信息实现清晰图像的逐步恢复。提出了一种并行残差二次处理模块,对不同阶段特征的差异信息进行去雾处理,提高模型对雾霾图像的识别能力。结果利用峰值信噪比和结构相似度定量评价各算法去雾结果与原始图像的相似度。本文方法在Hazerd数据集上的结构相似度和峰值信噪比分别达到0.852和17.557dB,均高于所有比较算法。在SOTS数据集上,指标分别为0.955和27.348dB,属于次优结果。在对真实雾霾图像的实验中,该方法也能达到很好的视觉恢复效果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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