Sparse approximation of multilinear problems with applications to kernel-based methods in UQ
Abstract
We provide a framework for the sparse approximation of multilinear problems and show that several problems in uncertainty quantification fit within this framework. In these problems, the value of a multilinear map has to be approximated using approximations of different accuracy and computational work of the arguments of this map. We propose and analyze a generalized version of Smolyak's algorithm, which provides sparse approximation formulas with convergence rates that mitigate the curse of dimension that appears in multilinear approximation problems with a large number of arguments. We apply the general framework to response surface approximation and optimization under uncertainty for parametric partial differential equations using kernel-based approximation. The theoretical results are supplemented by numerical experiments.
Cite
@article{arxiv.1609.00246,
title = {Sparse approximation of multilinear problems with applications to kernel-based methods in UQ},
author = {Fabio Nobile and Raul Tempone and Soeren Wolfers},
journal= {arXiv preprint arXiv:1609.00246},
year = {2018}
}