Tensor-based multiscale method for diffusion problems in quasi-periodic heterogeneous media
Abstract
This paper proposes to address the issue of complexity reduction for the numerical simulation of multiscale media in a quasi-periodic setting. We consider a stationary elliptic diffusion equation defined on a domain such that is the union of cells and we introduce a two-scale representation by identifying any function defined on with a bi-variate function , where relates to the index of the cell containing the point and relates to a local coordinate in a reference cell . We introduce a weak formulation of the problem in a broken Sobolev space using a discontinuous Galerkin framework. The problem is then interpreted as a tensor-structured equation by identifying with a tensor product space of functions defined over the product set . Tensor numerical methods are then used in order to exploit approximability properties of quasi-periodic solutions by low-rank tensors.
Cite
@article{arxiv.1710.08307,
title = {Tensor-based multiscale method for diffusion problems in quasi-periodic heterogeneous media},
author = {Quentin Ayoul-Guilmard and Anthony Nouy and Christophe Binetruy},
journal= {arXiv preprint arXiv:1710.08307},
year = {2019}
}
Comments
Changed the choice of test spaces V(D) and X (with regard to regularity) and the argumentation thereof. Corrected proof of proposition 3. Corrected wrong multiplicative factor in proposition 4 and its proof (was 2 instead of 1). Added remark 6 at the end of section 2. Extended remark 7. Added references. Some minor improvements (typos, typesetting)