English

A robust GMRES algorithm in Tensor Train format

Distributed, Parallel, and Cluster Computing 2022-10-27 v1

Abstract

We consider the solution of linear systems with tensor product structure using a GMRES algorithm. In order to cope with the computational complexity in large dimension both in terms of floating point operations and memory requirement, our algorithm is based on low-rank tensor representation, namely the Tensor Train format. In a backward error analysis framework, we show how the tensor approximation affects the accuracy of the computed solution. With the bacwkward perspective, we investigate the situations where the (d+1)(d+1)-dimensional problem to be solved results from the concatenation of a sequence of dd-dimensional problems (like parametric linear operator or parametric right-hand side problems), we provide backward error bounds to relate the accuracy of the (d+1)(d+1)-dimensional computed solution with the numerical quality of the sequence of dd-dimensional solutions that can be extracted form it. This enables to prescribe convergence threshold when solving the (d+1)(d+1)-dimensional problem that ensures the numerical quality of the dd-dimensional solutions that will be extracted from the (d+1)(d+1)-dimensional computed solution once the solver has converged. The above mentioned features are illustrated on a set of academic examples of varying dimensions and sizes.

Keywords

Cite

@article{arxiv.2210.14533,
  title  = {A robust GMRES algorithm in Tensor Train format},
  author = {Olivier Coulaud and Luc Giraud and Martina Iannacito},
  journal= {arXiv preprint arXiv:2210.14533},
  year   = {2022}
}
R2 v1 2026-06-28T04:32:03.887Z