Low rank tensor approximation of singularly perturbed partial differential equations in one dimension
Metadata only
Date
2020-09Type
- Report
ETH Bibliography
yes
Altmetrics
Abstract
We derive rank bounds on the quantized tensor train (QTT) compressed approximation of singularly perturbed reaction diffusion partial differential equations (PDEs) in one dimension. Specifically, we show that, independently of the scale of the singular perturbation parameter, a numerical solution with accuracy 0<ϵ<1 can be represented in QTT format with a number of parameters that depends only polylogarithmically on ϵ. In other words, QTT compressed solutions converge exponentially to the exact solution, with respect to a root of the number of parameters. We also verify the rank bound estimates numerically, and overcome known stability issues of the QTT based solution of PDEs by adapting a preconditioning strategy to obtain stable schemes at all scales. We find, therefore, that the QTT based strategy is a rapidly converging algorithm for the solution of singularly perturbed PDEs, which does not require prior knowledge on the scale of the singular perturbation and on the shape of the boundary layers. Show more
Publication status
publishedExternal links
Journal / series
SAM Research ReportVolume
Publisher
Seminar for Applied Mathematics, ETH ZurichSubject
Singular perturbation; low rank tensor approximation; tensor train; exponential convergenceOrganisational unit
03435 - Schwab, Christoph / Schwab, Christoph
More
Show all metadata
ETH Bibliography
yes
Altmetrics