TY - JOUR
T1 - Joint demosaicking and denoising benefits from a two-stage training strategy
AU - GUO, Yu
AU - JIN, Qiyu
AU - MOREL, Jean-Michel
AU - ZENG, Tieyong
AU - FACCIOLO, Gabriele
N1 - Y. Guo and Q. Jin are very grateful to Professor Guoqing Chen for helpful comments and suggestions. The authors are also grateful to the reviewers for their valuable comments and remarks.
PY - 2023/12/15
Y1 - 2023/12/15
N2 - Image demosaicking and denoising are the first two key steps of the color image production pipeline. The classical processing sequence has for a long time consisted of applying denoising first, and then demosaicking. Applying the operations in this order leads to oversmoothing and checkerboard effects. Yet, it was difficult to change this order, because once the image is demosaicked, the statistical properties of the noise are dramatically changed and hard to handle by traditional denoising models. In this paper, we address this problem by a hybrid machine learning method. We invert the traditional color filter array (CFA) processing pipeline by first demosaicking and then denoising. Our demosaicking algorithm, trained on noiseless images, combines a traditional method and a residual convolutional neural network (CNN). This first stage retains all known information, which is the key point to obtain faithful final results. The noisy demosaicked image is then passed through a second CNN restoring a noiseless full-color image. This pipeline order completely avoids checkerboard effects and restores fine image detail. Although CNNs can be trained to solve jointly demosaicking–denoising end-to-end, we find that this two-stage training performs better and is less prone to failure. It is shown experimentally to improve on the state of the art, both quantitatively and in terms of visual quality.
AB - Image demosaicking and denoising are the first two key steps of the color image production pipeline. The classical processing sequence has for a long time consisted of applying denoising first, and then demosaicking. Applying the operations in this order leads to oversmoothing and checkerboard effects. Yet, it was difficult to change this order, because once the image is demosaicked, the statistical properties of the noise are dramatically changed and hard to handle by traditional denoising models. In this paper, we address this problem by a hybrid machine learning method. We invert the traditional color filter array (CFA) processing pipeline by first demosaicking and then denoising. Our demosaicking algorithm, trained on noiseless images, combines a traditional method and a residual convolutional neural network (CNN). This first stage retains all known information, which is the key point to obtain faithful final results. The noisy demosaicked image is then passed through a second CNN restoring a noiseless full-color image. This pipeline order completely avoids checkerboard effects and restores fine image detail. Although CNNs can be trained to solve jointly demosaicking–denoising end-to-end, we find that this two-stage training performs better and is less prone to failure. It is shown experimentally to improve on the state of the art, both quantitatively and in terms of visual quality.
KW - Convolutional neural networks
KW - Demosaicking
KW - Denoising
KW - Pipeline
KW - Residual
UR - https://www.scopus.com/pages/publications/85161049765
U2 - 10.1016/j.cam.2023.115330
DO - 10.1016/j.cam.2023.115330
M3 - Journal Article (refereed)
AN - SCOPUS:85161049765
SN - 0377-0427
VL - 434
JO - Journal of Computational and Applied Mathematics
JF - Journal of Computational and Applied Mathematics
M1 - 115330
ER -