Related papers: Towards a General-Purpose Zero-Shot Synthetic Low-Light Image and Video Pipeline

Towards a General-Purpose Zero-Shot Synthetic Low-Light Image and Video Pipeline

URL: http://arxiv.org/abs/2504.12169v1
Date: Wed, 16 Apr 2025 15:19:11 GMT
Title: Towards a General-Purpose Zero-Shot Synthetic Low-Light Image and Video Pipeline
Authors: Joanne Lin, Crispian Morris, Ruirui Lin, Fan Zhang, David Bull, Nantheera Anantrasirichai,
Abstract summary: We propose a new Degradation Estimation Network (DEN) which synthetically generates realistic standard RGB (sRGB) noise without the requirement for camera metadata.<n>We evaluate our proposed synthetic pipeline using various methods trained on its synthetic data for typical low-light tasks including synthetic noise replication, video enhancement, and object detection.
Score: 3.811151974338892
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Low-light conditions pose significant challenges for both human and machine annotation. This in turn has led to a lack of research into machine understanding for low-light images and (in particular) videos. A common approach is to apply annotations obtained from high quality datasets to synthetically created low light versions. In addition, these approaches are often limited through the use of unrealistic noise models. In this paper, we propose a new Degradation Estimation Network (DEN), which synthetically generates realistic standard RGB (sRGB) noise without the requirement for camera metadata. This is achieved by estimating the parameters of physics-informed noise distributions, trained in a self-supervised manner. This zero-shot approach allows our method to generate synthetic noisy content with a diverse range of realistic noise characteristics, unlike other methods which focus on recreating the noise characteristics of the training data. We evaluate our proposed synthetic pipeline using various methods trained on its synthetic data for typical low-light tasks including synthetic noise replication, video enhancement, and object detection, showing improvements of up to 24\% KLD, 21\% LPIPS, and 62\% AP$_{50-95}$, respectively.

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