English

Bernstein-von Mises theorems and uncertainty quantification for linear inverse problems

Statistics Theory 2020-01-20 v4 Statistics Theory

Abstract

We consider the statistical inverse problem of recovering an unknown function ff from a linear measurement corrupted by additive Gaussian white noise. We employ a nonparametric Bayesian approach with standard Gaussian priors, for which the posterior-based reconstruction of ff corresponds to a Tikhonov regulariser fˉ\bar f with a reproducing kernel Hilbert space norm penalty. We prove a semiparametric Bernstein-von Mises theorem for a large collection of linear functionals of ff, implying that semiparametric posterior estimation and uncertainty quantification are valid and optimal from a frequentist point of view. The result is applied to study three concrete examples that cover both the mildly and severely ill-posed cases: specifically, an elliptic inverse problem, an elliptic boundary value problem and the heat equation. For the elliptic boundary value problem, we also obtain a nonparametric version of the theorem that entails the convergence of the posterior distribution to a prior-independent infinite-dimensional Gaussian probability measure with minimal covariance. As a consequence, it follows that the Tikhonov regulariser fˉ\bar f is an efficient estimator of ff, and we derive frequentist guarantees for certain credible balls centred at fˉ\bar{f}.

Keywords

Cite

@article{arxiv.1811.04058,
  title  = {Bernstein-von Mises theorems and uncertainty quantification for linear inverse problems},
  author = {Matteo Giordano and Hanne Kekkonen},
  journal= {arXiv preprint arXiv:1811.04058},
  year   = {2020}
}

Comments

34 pages, to appear in SIAM/ASA Journal on Uncertainty Quantification (JUQ)

R2 v1 2026-06-23T05:10:46.863Z