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Bibliographic Details
Main Authors: Dubois, Juliette, Herty, Michael, Müller, Siegfried
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.04868
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author Dubois, Juliette
Herty, Michael
Müller, Siegfried
author_facet Dubois, Juliette
Herty, Michael
Müller, Siegfried
contents A method for the uncertainty quantification of nonlinear hyperbolic conservation laws with many uncertain parameters is presented. The method combines stochastic finite volume methods and tensor trains in a novel way: the dimensions of physical space and time are kept as full tensors, while all stochastic dimensions are compressed together into a tensor train. The resulting hybrid format has one tensor train for each spatial cell and each time step. The MUSCL scheme is adapted to the proposed hybrid format, and its feasibility is demonstrated through several test cases. For the scalar Burgers' equation, we conduct a convergence study and compare the results with those obtained using the full tensor train format with three stochastic parameters. The equation is then solved for an increasing number of stochastic dimensions.For systems of conservation laws, we focus on the Euler equations. A parameter study and a comparison with the full tensor train format are carried out for the Sod shock tube problem. As a more complex application, we investigate the Shu-Osher problem, which involves intricate wave interactions. The presented method opens new avenues for integrating uncertainty quantification with established numerical schemes for hyperbolic conservation laws.
format Preprint
id arxiv_https___arxiv_org_abs_2502_04868
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle High-dimensional stochastic finite volumes using the tensor train format
Dubois, Juliette
Herty, Michael
Müller, Siegfried
Numerical Analysis
65M08, 65M75, 35R60
A method for the uncertainty quantification of nonlinear hyperbolic conservation laws with many uncertain parameters is presented. The method combines stochastic finite volume methods and tensor trains in a novel way: the dimensions of physical space and time are kept as full tensors, while all stochastic dimensions are compressed together into a tensor train. The resulting hybrid format has one tensor train for each spatial cell and each time step. The MUSCL scheme is adapted to the proposed hybrid format, and its feasibility is demonstrated through several test cases. For the scalar Burgers' equation, we conduct a convergence study and compare the results with those obtained using the full tensor train format with three stochastic parameters. The equation is then solved for an increasing number of stochastic dimensions.For systems of conservation laws, we focus on the Euler equations. A parameter study and a comparison with the full tensor train format are carried out for the Sod shock tube problem. As a more complex application, we investigate the Shu-Osher problem, which involves intricate wave interactions. The presented method opens new avenues for integrating uncertainty quantification with established numerical schemes for hyperbolic conservation laws.
title High-dimensional stochastic finite volumes using the tensor train format
topic Numerical Analysis
65M08, 65M75, 35R60
url https://arxiv.org/abs/2502.04868