MDFEM: Multivariate decomposition finite element method for elliptic PDEs with lognormal diffusion coefficients using higher-order QMC and FEM

Abstract

We introduce the multivariate decomposition finite element method for elliptic PDEs with lognormal diffusion coefficient a=(Z) where Z is a Gaussian random field defined by an infinite series expansion Z(y) = Σj1 yj\,φj with yj(0,1) and a given sequence of functions \φj\j1. We use the MDFEM to approximate the expected value of a linear functional of the solution of the PDE which is an infinite-dimensional integral over the parameter space. The proposed algorithm uses the multivariate decomposition method (MDM) to compute the infinite-dimensional integral by a decomposition into finite-dimensional integrals, which we resolve using quasi-Monte Carlo (QMC) methods, and for which we use the finite element method (FEM) to solve different instances of the PDE. We develop higher-order quasi-Monte Carlo rules for integration over the finite-dimensional Euclidean space with respect to the Gaussian distribution by use of a truncation strategy. By linear transformations of interlaced polynomial lattice rules from the unit cube to a multivariate box of the Euclidean space we achieve higher-order convergence rates for functions belonging to a class of anchored Gaussian Sobolev spaces, taking into account the truncation error. Under appropriate conditions, the MDFEM achieves higher-order convergence rates in term of error versus cost, i.e., to achieve an accuracy of O(ε) the computational cost is O(ε-1/λ-d'/λ) = O(ε-(p*+d'/τ)/(1-p*)) where ε-1/λ and ε-d'/λ are respectively the cost of the quasi-Monte Carlo cubature and the finite element approximations, with d' = d \, (1+δ') for some δ' 0 and d the physical dimension, and 0 < p* (2+d'/τ)-1 is a parameter representing the sparsity of \φj\j1.