English

Quantized tensor FEM for multiscale problems: diffusion problems in two and three dimensions

Numerical Analysis 2020-06-03 v1 Numerical Analysis

Abstract

Homogenization in terms of multiscale limits transforms a multiscale problem with n+1n+1 asymptotically separated microscales posed on a physical domain DRdD \subset \mathbb{R}^d into a one-scale problem posed on a product domain of dimension (n+1)d(n+1)d by introducing nn so-called "fast variables". This procedure allows to convert n+1n+1 scales in dd physical dimensions into a single-scale structure in (n+1)d(n+1)d dimensions. We prove here that both the original, physical multiscale problem and the corresponding high-dimensional, one-scale limiting problem can be efficiently treated numerically with the recently developed quantized tensor-train finite-element method (QTT-FEM). The method is based on restricting computation to sequences of nested subspaces of low dimensions (which are called tensor ranks) within a vast but generic "virtual" (background) discretization space. In the course of computation, these subspaces are computed iteratively and data-adaptively at runtime, bypassing any "offline precomputation". For the purpose of theoretical analysis, such low-dimensional subspaces are constructed analytically to bound the tensor ranks vs. error τ>0\tau>0. We consider a model linear elliptic multiscale problem in several physical dimensions and show, theoretically and experimentally, that both (i) the solution of the associated high-dimensional one-scale problem and (ii) the corresponding approximation to the solution of the multiscale problem admit efficient approximation by the QTT-FEM. These problems can therefore be numerically solved in a scale-robust fashion by standard (low-order) PDE discretizations combined with state-of-the-art general-purpose solvers for tensor-structured linear systems. We prove scale-robust exponential convergence, i.e., that QTT-FEM achieves accuracy τ\tau with the number of effective degrees of freedom scaling polynomially in logτ\log \tau.

Keywords

Cite

@article{arxiv.2006.01455,
  title  = {Quantized tensor FEM for multiscale problems: diffusion problems in two and three dimensions},
  author = {V. Kazeev and I. Oseledets and M. Rakhuba and Ch. Schwab},
  journal= {arXiv preprint arXiv:2006.01455},
  year   = {2020}
}

Comments

31 pages, 8 figures

R2 v1 2026-06-23T15:59:08.452Z