Multilevel Hierarchical Decomposition of Finite Element White Noise with Application to Multilevel Markov Chain Monte Carlo
Hillary R. Fairbanks, Umberto Villa, and Panayot S. Vassilevski
TL;DR
This paper introduces a scalable hierarchical multilevel PDE-based method for generating Gaussian random fields, optimized for integration into multilevel MCMC algorithms, with theoretical validation and numerical demonstrations.
Contribution
A novel hierarchical decomposition approach for white noise in PDEs enabling efficient multilevel Gaussian field generation within MCMC frameworks.
Findings
Method is computationally scalable across multiple levels.
Successfully integrated into a four-level MCMC algorithm.
Numerical results confirm efficiency and feasibility.
Abstract
In this work we develop a new hierarchical multilevel approach to generate Gaussian random field realizations in an algorithmically scalable manner that is well-suited to incorporate into multilevel Markov chain Monte Carlo (MCMC) algorithms. This approach builds off of other partial differential equation (PDE) approaches for generating Gaussian random field realizations; in particular, a single field realization may be formed by solving a reaction-diffusion PDE with a spatial white noise source function as the righthand side. While these approaches have been explored to accelerate forward uncertainty quantification tasks, e.g. multilevel Monte Carlo, the previous constructions are not directly applicable to multilevel MCMC frameworks which build fine scale random fields in a hierarchical fashion from coarse scale random fields. Our new hierarchical multilevel method relies on a…
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