English

Detecting Model Misspecification in Bayesian Inverse Problems via Variational Gradient Descent

Methodology 2026-04-09 v2 Computation

Abstract

Bayesian inference is optimal when the statistical model is well-specified, while outside this setting Bayesian inference can catastrophically fail; accordingly a wealth of post-Bayesian methodologies have been proposed. Predictively oriented (PrO) approaches lift the statistical model PθP_\theta to an (infinite) mixture model Pθ  dQ(θ)\int P_\theta \; \mathrm{d}Q(\theta) and fit this predictive distribution via minimising an entropy-regularised objective functional. In the well-specified setting one expects the mixing distribution QQ to concentrate around the true data-generating parameter in the large data limit, while such singular concentration will typically not be observed if the model is misspecified. Our contribution is to demonstrate that one can empirically detect model misspecification by comparing the standard Bayesian posterior to the PrO `posterior' QQ. To operationalise this, we present an efficient numerical algorithm based on variational gradient descent. A simulation study, and a more detailed case study involving a Bayesian inverse problem in seismology, confirm that model misspecification can be automatically detected using this framework.

Keywords

Cite

@article{arxiv.2512.01667,
  title  = {Detecting Model Misspecification in Bayesian Inverse Problems via Variational Gradient Descent},
  author = {Qingyang Liu and Matthew A. Fisher and Zheyang Shen and Xuebin Zhao and Katherine Tant and Andrew Curtis and Chris. J. Oates},
  journal= {arXiv preprint arXiv:2512.01667},
  year   = {2026}
}

Comments

Expanded section on hypothesis testing with new theoretical support

R2 v1 2026-07-01T08:03:44.358Z