Related papers: Guided Frequency Loss for Image Restoration

Guided Frequency Loss for Image Restoration

URL: http://arxiv.org/abs/2309.15563v2
Date: Sun, 22 Oct 2023 06:36:41 GMT
Title: Guided Frequency Loss for Image Restoration
Authors: Bilel Benjdira, Anas M. Ali, Anis Koubaa
Abstract summary: We propose the Guided Frequency Loss (GFL), which helps the model to learn in a balanced way the image's frequency content alongside the spatial content. It aggregates three major components that work in parallel to enhance learning efficiency. We found that the GFL loss improved the PSNR metric in most implemented experiments.
Score: 0.9821874476902969
License: http://creativecommons.org/licenses/by-nc-nd/4.0/
Abstract: Image Restoration has seen remarkable progress in recent years. Many generative models have been adapted to tackle the known restoration cases of images. However, the interest in benefiting from the frequency domain is not well explored despite its major factor in these particular cases of image synthesis. In this study, we propose the Guided Frequency Loss (GFL), which helps the model to learn in a balanced way the image's frequency content alongside the spatial content. It aggregates three major components that work in parallel to enhance learning efficiency; a Charbonnier component, a Laplacian Pyramid component, and a Gradual Frequency component. We tested GFL on the Super Resolution and the Denoising tasks. We used three different datasets and three different architectures for each of them. We found that the GFL loss improved the PSNR metric in most implemented experiments. Also, it improved the training of the Super Resolution models in both SwinIR and SRGAN. In addition, the utility of the GFL loss increased better on constrained data due to the less stochasticity in the high frequencies' components among samples.

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