Fast no-reference deep image dehazing

IF 2.4 4区 计算机科学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Machine Vision and Applications Pub Date : 2024-08-29 DOI:10.1007/s00138-024-01601-8
Hongyi Qin, Alexander G. Belyaev
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Abstract

This paper presents a deep learning method for image dehazing and clarification. The main advantages of the method are high computational speed and using unpaired image data for training. The method adapts the Zero-DCE approach (Li et al. in IEEE Trans Pattern Anal Mach Intell 44(8):4225–4238, 2021) for the image dehazing problem and uses high-order curves to adjust the dynamic range of images and achieve dehazing. Training the proposed dehazing neural network does not require paired hazy and clear datasets but instead utilizes a set of loss functions, assessing the quality of dehazed images to drive the training process. Experiments on a large number of real-world hazy images demonstrate that our proposed network effectively removes haze while preserving details and enhancing brightness. Furthermore, on an affordable GPU-equipped laptop, the processing speed can reach 1000 FPS for images with 2K resolution, making it highly suitable for real-time dehazing applications.

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快速无参照深度图像去毛刺
本文介绍了一种用于图像去毛刺和澄清的深度学习方法。该方法的主要优点是计算速度快,并使用非配对图像数据进行训练。该方法将 Zero-DCE 方法(Li 等人,发表于 IEEE Trans Pattern Anal Mach Intell 44(8):4225-4238, 2021)应用于图像去雾问题,并使用高阶曲线来调整图像的动态范围并实现去雾。训练所提出的去毛刺神经网络不需要配对朦胧和清晰数据集,而是利用一组损失函数,评估去毛刺图像的质量来驱动训练过程。在大量真实世界的雾霾图像上进行的实验表明,我们提出的网络能有效去除雾霾,同时保留细节并提高亮度。此外,在配备 GPU 的经济型笔记本电脑上,处理 2K 分辨率图像的速度可达 1000 FPS,因此非常适合实时去雾应用。
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来源期刊
Machine Vision and Applications
Machine Vision and Applications 工程技术-工程:电子与电气
CiteScore
6.30
自引率
3.00%
发文量
84
审稿时长
8.7 months
期刊介绍: Machine Vision and Applications publishes high-quality technical contributions in machine vision research and development. Specifically, the editors encourage submittals in all applications and engineering aspects of image-related computing. In particular, original contributions dealing with scientific, commercial, industrial, military, and biomedical applications of machine vision, are all within the scope of the journal. Particular emphasis is placed on engineering and technology aspects of image processing and computer vision. The following aspects of machine vision applications are of interest: algorithms, architectures, VLSI implementations, AI techniques and expert systems for machine vision, front-end sensing, multidimensional and multisensor machine vision, real-time techniques, image databases, virtual reality and visualization. Papers must include a significant experimental validation component.
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