Model's sparse representation based on reduced mixed GMsFE basis methods

TL;DR

This paper introduces a sparse representation approach for multiscale PDE models with random inputs, utilizing reduced mixed GMsFE basis methods and sparse tensor approximation to enhance computational efficiency.

Contribution

The paper develops a novel reduced mixed GMsFE basis method that is independent of random parameters and integrates sparse tensor approximation for efficient model evaluation.

Findings

Reduced basis functions are independent of random parameters.

Sparse tensor approximation significantly accelerates online computations.

Numerical examples demonstrate high efficiency and accuracy.

Abstract

In this paper, we propose a model's sparse representation based on reduced mixed generalized multiscale finite element (GMsFE) basis methods for elliptic PDEs with random inputs. Mixed generalized multiscale finite element method (GMsFEM) is one of the accurate and efficient approaches to solve multiscale problem in a coarse grid with local mass conservation. When the inputs of the PDEs are parameterized by the random variables, the GMsFE basis functions usually depend on the random parameters. This leads to a large number degree of freedoms for the mixed GMsFEM and substantially impacts on the computation efficiency. In order to overcome the difficulty, we develop reduced mixed GMsFE basis methods such that the multiscale basis functions are independent of the random parameters and span a low-dimensional space. To this end, a greedy algorithm is used to find a set of optimal samples from a training set scattered in the parameter space. Reduced mixed GMsFE basis functions are constructed based on the optimal samples using two optimal sampling strategies: basis-oriented cross-validation and proper orthogonal decomposition. Although the dimension of the space spanned by the reduced mixed GMsFE basis functions is much smaller than the dimension of the original full order model, the online computation still depends on the number of coarse degree of freedoms. To significantly improve the online computation, we integrate the reduced mixed GMsFE basis methods with sparse tensor approximation and obtain a sparse representation for the model's outputs. The sparse representation is very efficient for evaluating the model's outputs for many instances of parameters. To illustrate the efficacy of the proposed methods, we present a few numerical examples for multsicale problems with random inputs.