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Variational Inference for Computational Imaging Inverse Problems

Machine Learning 2020-08-24 v3 Computer Vision and Pattern Recognition Machine Learning

Abstract

Machine learning methods for computational imaging require uncertainty estimation to be reliable in real settings. While Bayesian models offer a computationally tractable way of recovering uncertainty, they need large data volumes to be trained, which in imaging applications implicates prohibitively expensive collections with specific imaging instruments. This paper introduces a novel framework to train variational inference for inverse problems exploiting in combination few experimentally collected data, domain expertise and existing image data sets. In such a way, Bayesian machine learning models can solve imaging inverse problems with minimal data collection efforts. Extensive simulated experiments show the advantages of the proposed framework. The approach is then applied to two real experimental optics settings: holographic image reconstruction and imaging through highly scattering media. In both settings, state of the art reconstructions are achieved with little collection of training data.

Keywords

Cite

@article{arxiv.1904.06264,
  title  = {Variational Inference for Computational Imaging Inverse Problems},
  author = {Francesco Tonolini and Jack Radford and Alex Turpin and Daniele Faccio and Roderick Murray-Smith},
  journal= {arXiv preprint arXiv:1904.06264},
  year   = {2020}
}

Comments

29+15 Pages

R2 v1 2026-06-23T08:38:01.403Z