English

Energy-based models for inverse imaging problems

Image and Video Processing 2025-09-17 v2

Abstract

In this chapter we provide a thorough overview of the use of energy-based models (EBMs) in the context of inverse imaging problems. EBMs are probability distributions modeled via Gibbs densities p(x)expE(x)p(x) \propto \exp{-E(x)} with an appropriate energy functional EE. Within this chapter we present a rigorous theoretical introduction to Bayesian inverse problems that includes results on well-posedness and stability in the finite-dimensional and infinite-dimensional setting. Afterwards we discuss the use of EBMs for Bayesian inverse problems and explain the most relevant techniques for learning EBMs from data. As a crucial part of Bayesian inverse problems, we cover several popular algorithms for sampling from EBMs, namely the Metropolis-Hastings algorithm, Gibbs sampling, Langevin Monte Carlo, and Hamiltonian Monte Carlo. Moreover, we present numerical results for the resolution of several inverse imaging problems obtained by leveraging an EBM that allows for the explicit verification of those properties that are needed for valid energy-based modeling.

Keywords

Cite

@article{arxiv.2507.12432,
  title  = {Energy-based models for inverse imaging problems},
  author = {Andreas Habring and Martin Holler and Thomas Pock and Martin Zach},
  journal= {arXiv preprint arXiv:2507.12432},
  year   = {2025}
}

Comments

Fixed various typos, improved readability, added link to code repository

R2 v1 2026-07-01T04:04:40.889Z