Paper Info
Title
Stochastic Basis Adaptation and Spatial Domain Decomposition for Partial Differential Equations with Random Coefficients.
Abstract
We present a novel uncertainty quantification approach for high-dimensional stochastic partial differential equations that reduces the computational cost of polynomial chaos methods by decomposing the computational domain into nonoverlapping subdomains and adapting the stochastic basis in each subdomain so the local solution has a lower dimensional random space representation. The local solutions are coupled using the Neumann Neumann algorithm, where we first estimate the interface solution then evaluate the interior solution in each subdomain using the interface solution as a boundary condition. The interior solutions in each subdomain are computed independently of each other, which reduces the operation count from O(N-alpha) to O(M-alpha), where N is the total number of degrees of freedom, M is the number of degrees of freedom in each subdomain, and the exponent alpha > 1 depends on the uncertainty quantification method used. In addition, the localized nature of solutions makes the proposed approach highly parallelizable. We illustrate the accuracy and efficiency of the approach for linear and nonlinear differential equations with random coefficients.
Year
DOI
Venue
2018
10.1137/16M1097134
SIAM-ASA JOURNAL ON UNCERTAINTY QUANTIFICATION
Keywords
DocType
Volume
basis adaptation,dimension reduction,domain decomposition,polynomial chaos,uncertainty quantification,Neumann-Neumann algorithm
Journal
6
Issue
ISSN
Citations 
1
2166-2525
0
PageRank 
References 
Authors
0.34
0
3
Name
Order
Citations
PageRank
Ramakrishna Tipireddy1113.07
Panos Stinis200.34
Alexandre M. Tartakovsky34513.54