Each image acquisition setup leads to its own camera-specific image characteristics degrading the image quality. In learning-based perception algorithms, characteristics occurring during the application phase, but absent in the training data, lead to a domain gap impeding the performance. Previously, pixel-level domain adaptation through unpaired learning of the pristine-to-distorted mapping function has been proposed. In this work, we propose shallow discriminator architectures to address limitations of these approaches. We show that a smaller receptive field size improves learning of unknown image distortions by more accurately reproducing local distortion characteristics at a low network complexity. In a domain adaptation setup for instance segmentation, we achieve mean average precision increases over previous methods of up to 0.15 for individual distortions and up to 0.16 for camera-specific image characteristics in a simplified camera model. In terms of number of parameters, our approach matches the complexity of one state of the art method while reducing complexity by a factor of 20 compared to another, demonstrating superior efficiency without compromising performance.
@article{arxiv.2511.10424,
title = {Domain Adaptation for Camera-Specific Image Characteristics using Shallow Discriminators},
author = {Maximiliane Gruber and Jürgen Seiler and André Kaup},
journal= {arXiv preprint arXiv:2511.10424},
year = {2026}
}
Comments
5 pages, 7 figures, accepted for International Conference on Visual Communications and Image Processing (VCIP) 2025