A Stochastic Iteratively Regularized Gauss-Newton Method
Abstract
This work focuses on developing and motivating a stochastic version of a wellknown inverse problem methodology. Specifically, we consider the iteratively regularized Gauss-Newton method, originally proposed by Bakushinskii for infinite-dimensional problems. Recent work have extended this method to handle sequential observations, rather than a single instance of the data, demonstrating notable improvements in reconstruction accuracy. In this paper, we further extend these methods to a stochastic framework through mini-batching, introducing a new algorithm, the stochastic iteratively regularized Gauss-Newton method (SIRGNM). Our algorithm is designed through the use randomized sketching. We provide an analysis for the SIRGNM, which includes a preliminary error decomposition and a convergence analysis, related to the residuals. We provide numerical experiments on a 2D elliptic PDE example. This illustrates the effectiveness of the SIRGNM, through maintaining a similar level of accuracy while reducing on the computational time.
Cite
@article{arxiv.2409.12381,
title = {A Stochastic Iteratively Regularized Gauss-Newton Method},
author = {El Houcine Bergou and Neil K. Chada and Youssef Diouane},
journal= {arXiv preprint arXiv:2409.12381},
year = {2024}
}
Comments
23 pages