颜色恒定性
人工智能
计算机科学
水准点(测量)
计算机视觉
反射率
噪音(视频)
图像(数学)
模式识别(心理学)
过程(计算)
一致性(知识库)
组分(热力学)
降噪
图像处理
图像复原
深度学习
亮度
图像增强
噪声测量
无监督学习
编码(集合论)
人工神经网络
作者
Jia Liu,Yu Luo,Guanghui Yue,Jie Ling,Liang Liao,Chia-Wen Lin,Guangtao Zhai,Wei Zhou
标识
DOI:10.1109/tip.2026.3652021
摘要
Recently, incorporating Retinex theory with unfolding networks has attracted increasing attention in the low-light image enhancement field. However, existing methods have two limitations, i.e., ignoring the modeling of the physical prior of Retinex theory and relying on a large amount of paired data. To advance this field, we propose a novel self-supervised unfolding network, named S2UNet, for the LIE task. Specifically, we formulate a novel optimization model based on the principle that content-consistent images under different illumination should share the same reflectance. The model simultaneously decomposes two illumination-different images into a shared reflectance component and two independent illumination components. Due to the absence of the normal-light image, we process the low-light image with gamma correction to create the illumination-different image pair. Then, we translate this model into a multi-stage unfolding network, in which each stage alternately optimizes the shared reflectance component and the respective illumination components of the two images. During progressive multi-stage optimization, the network inherently encodes the reflectance consistency prior by jointly estimating an optimal reflectance across varying illumination conditions. Finally, considering the presence of noise in low-light images and to suppress noise amplification, we propose a self-supervised denoising mechanism. Extensive experiments on nine benchmark datasets demonstrate that our proposed S2UNet outperforms state-of-the-art unsupervised methods in terms of both quantitative metrics and visual quality, while achieving competitive performance compared to supervised methods. The source code will be available at https://github.com/J-Liu-DL/S2UNet.
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