High-order Tensor-Train Finite Volume Method for Shallow Water Equations
Abstract
In this paper, we introduce a high-order tensor-train (TT) finite volume method for the Shallow Water Equations (SWEs). We present the implementation of the order Upwind and the order Upwind and WENO reconstruction schemes in the TT format. It is shown in detail that the linear upwind schemes can be implemented by directly manipulating the TT cores while the WENO scheme requires the use of TT cross interpolation for the nonlinear reconstruction. In the development of numerical fluxes, we directly compute the flux for the linear SWEs without using TT rounding or cross interpolation. For the nonlinear SWEs where the TT reciprocal of the shallow water layer thickness is needed for fluxes, we develop an approximation algorithm using Taylor series to compute the TT reciprocal. The performance of the TT finite volume solver with linear and nonlinear reconstruction options is investigated under a physically relevant set of validation problems. In all test cases, the TT finite volume method maintains the formal high-order accuracy of the corresponding traditional finite volume method. In terms of speed, the TT solver achieves up to 124x acceleration of the traditional full-tensor scheme.
Keywords
Cite
@article{arxiv.2408.03483,
title = {High-order Tensor-Train Finite Volume Method for Shallow Water Equations},
author = {Mustafa Engin Danis and Duc P. Truong and Derek DeSantis and Mark Petersen and Kim O. Rasmussen and Boian S. Alexandrov},
journal= {arXiv preprint arXiv:2408.03483},
year = {2024}
}