中文

A Majorization-Minimization with Monte Carlo Approach for Hyperparameter Estimation

数值分析 2026-05-14 v1 数值分析

摘要

We consider inverse problems with linear forward models and Gaussian priors, but with unknown hyperparameters that may arise from the model, the noise, or the specification of the prior. We model this using a hierarchical Bayes framework resulting in a posterior distribution that is non-Gaussian, in general, and challenging to sample from. Consequently, we use an empirical Bayes framework for estimating the maximum a posteriori estimate of the hyperpameters by considering the marginalized posterior distribution. However, the optimization problem is also computationally challenging due to the need for repeated evaluation of log determinants. To address this issue, we propose a Majorization-Minimization with Monte Carlo approach, which we call M3^{3}C, for hyperparameter estimation. Specifically, we replace the challenging optimization problem with a sequence of simpler ones by utilizing a majorization function (or majorant) for the log-determinant term, combined with a Monte Carlo estimator to approximate the majorant. We provide theoretical results, showing that under certain assumptions, the M3^{3}C iterates converge with high probability to a critical point of the original cost function. A variety of numerical examples are provided from seismic tomography, super-resolution imaging, and contaminant source identification.

关键词

引用

@article{arxiv.2605.13620,
  title  = {A Majorization-Minimization with Monte Carlo Approach for Hyperparameter Estimation},
  author = {Elle Buser and Julianne Chung and Hugo Díaz and Arvind K. Saibaba},
  journal= {arXiv preprint arXiv:2605.13620},
  year   = {2026}
}

备注

25 pages, 4 figures, Supplementary Material