Abstract
This work describes a domain embedding technique between two nonmatching meshes used for generating realizations of spatially correlated random fields with applications to large-scale sampling-based uncertainty quantification. The goal is to apply the multilevel Monte Carlo (MLMC) method for the quantification of output uncertainties of PDEs with random input coefficients on general and unstructured computational domains. We propose a highly scalable, hierarchical sampling method to generate realizations of a Gaussian random field on a given unstructured mesh by solving a reaction–diffusion PDE with a stochastic right-hand side. The stochastic PDE is discretized using the mixed finite element method on an embedded domain with a structured mesh, and then, the solution is projected onto the unstructured mesh. This work describes implementation details on how to efficiently transfer data from the structured and unstructured meshes at coarse levels, assuming that this can be done efficiently on the finest level. We investigate the efficiency and parallel scalability of the technique for the scalable generation of Gaussian random fields in three dimensions. An application of the MLMC method is presented for quantifying uncertainties of subsurface flow problems. We demonstrate the scalability of the sampling method with nonmatching mesh embedding, coupled with a parallel forward model problem solver, for large-scale 3D MLMC simulations with up to 1.9·109 unknowns.
Original language | English (US) |
---|---|
Article number | e2146 |
Journal | Numerical Linear Algebra with Applications |
Volume | 25 |
Issue number | 3 |
DOIs | |
State | Published - May 2018 |
Keywords
- H(div) problems
- mixed finite elements
- multilevel methods
- multilevel Monte Carlo
- nonmatching meshes
- PDE sampler
- PDEs with random input data
- uncertainty quantification
ASJC Scopus subject areas
- Algebra and Number Theory
- Applied Mathematics