Paper Info
Title
An adaptive stochastic Galerkin tensor train discretization for randomly perturbed domains.
Abstract
A linear PDE problem for randomly perturbed domains is considered in an adaptive Galerkin framework. The perturbation of the domain's boundary is described by a vector valued random field depending on a countable number of random variables in an affine way. The corresponding Karhunen-Loeve expansion is approximated by the pivoted Cholesky decomposition based on a prescribed covariance function. The examined high dimensional Galerkin system follows from the domain mapping approach, transferring the randomness from the domain to the diffusion coefficient and the forcing. In order to make this computationally feasible, the representation makes use of the modern tensor train format for the implicit compression of the problem. Moreover, an a posteriori error estimator is presented, which allows for the problem-dependent iterative refinement of all discretization parameters and the assessment of the achieved error reduction. The proposed approach is demonstrated in numerical benchmark problems.
Year
DOI
Venue
2020
10.1137/19M1246080
SIAM-ASA JOURNAL ON UNCERTAINTY QUANTIFICATION
Keywords
DocType
Volume
partial differential equations with random coefficients,random domain,tensor train,uncertainty quantification,adaptive methods,low-rank
Journal
8
Issue
ISSN
Citations 
3
2166-2525
0
PageRank 
References 
Authors
0.34
15
3
Name
Order
Citations
PageRank
Martin Eigel1104.00
Manuel Marschall220.71
Michael Multerer300.34