Re-iterated multiscale model reduction using the GMsFEM

TL;DR

This paper extends the GMsFEM by applying iterative multiscale basis construction to improve efficiency in complex heterogeneous media, demonstrating its effectiveness through numerical experiments.

Contribution

It introduces a re-iterated multiscale basis construction method for GMsFEM, enabling better handling of problems without scale separation and high contrast.

Findings

Effective multiscale basis functions constructed iteratively

Improved accuracy in heterogeneous media simulations

Adaptive strategies enhance computational efficiency

Abstract

Numerical homogenization and multiscale finite element methods construct effective properties on a coarse grid by solving local problems and extracting the average effective properties from these local solutions. In some cases, the solutions of local problems can be expensive to compute due to scale disparity. In this setting, one can basically apply a homogenization or multiscale method re-iteratively to solve for the local problems. This process is known as re-iterated homogenization and has many variations in the numerical context. Though the process seems to be a straightforward extension of two-level process, it requires some careful implementation and the concept development for problems without scale separation and high contrast. In this paper, we consider the Generalized Multiscale Finite Element Method (GMsFEM) and apply it iteratively to construct its multiscale basis functions. The main idea of the GMsFEM is to construct snapshot functions and then extract multiscale basis functions (called offline space) using local spectral decompositions in the snapshot spaces. The extension of this construction to several levels uses snapshots and offline spaces interchangebly to achieve this goal. At each coarse-grid scale, we assume that the offline space is a good approximation of the solution and use all possible offline functions or randomization as boundary conditions and solve the local problems in the offline space at the previous (finer) level, to construct snapshot space. We present an adaptivity strategy and show numerical results for flows in heterogeneous media and in perforated domains.