English

Wiener Guided DIP for Unsupervised Blind Image Deconvolution

Computer Vision and Pattern Recognition 2021-12-21 v1

Abstract

Blind deconvolution is an ill-posed problem arising in various fields ranging from microscopy to astronomy. The ill-posed nature of the problem requires adequate priors to arrive to a desirable solution. Recently, it has been shown that deep learning architectures can serve as an image generation prior during unsupervised blind deconvolution optimization, however often exhibiting a performance fluctuation even on a single image. We propose to use Wiener-deconvolution to guide the image generator during optimization by providing it a sharpened version of the blurry image using an auxiliary kernel estimate starting from a Gaussian. We observe that the high-frequency artifacts of deconvolution are reproduced with a delay compared to low-frequency features. In addition, the image generator reproduces low-frequency features of the deconvolved image faster than that of a blurry image. We embed the computational process in a constrained optimization framework and show that the proposed method yields higher stability and performance across multiple datasets. In addition, we provide the code.

Keywords

Cite

@article{arxiv.2112.10271,
  title  = {Wiener Guided DIP for Unsupervised Blind Image Deconvolution},
  author = {Gustav Bredell and Ertunc Erdil and Bruno Weber and Ender Konukoglu},
  journal= {arXiv preprint arXiv:2112.10271},
  year   = {2021}
}
R2 v1 2026-06-24T08:23:53.925Z