Path-conservative central-upwind schemes for nonconservative hyperbolic systems

Castro Díaz, Manuel Jesús; Kurganov, Alexander; Morales de Luna, Tomás

doi:10.1051/m2an/2018077

Castro Díaz, Manuel Jesús ¹ ; Kurganov, Alexander ¹ ; Morales de Luna, Tomás ¹

ESAIM: Mathematical Modelling and Numerical Analysis , Tome 53 (2019) no. 3, pp. 959-985.

Suite au passage du modèle économique de la revue en S20, le texte intégral des articles des années 2019 et 2020 est accessible uniquement sur le site de l'éditeur et est réservé aux abonnés.

Résumé

We develop path-conservative central-upwind schemes for nonconservative one-dimensional hyperbolic systems of nonlinear partial differential equations. Such systems arise in a variety of applications and the most challenging part of their numerical discretization is a robust treatment of nonconservative product terms. Godunov-type central-upwind schemes were developed as an efficient, highly accurate and robust ``black-box’’ solver for hyperbolic systems of conservation and balance laws. They were successfully applied to a large number of hyperbolic systems including several nonconservative ones. To overcome the difficulties related to the presence of nonconservative product terms, several special techniques were proposed. However, none of these techniques was sufficiently robust and thus the applicability of the original central-upwind schemes was rather limited. In this paper, we rewrite the central-upwind schemes in the form of path-conservative schemes. This helps us (i) to show that the main drawback of the original central-upwind approach was the fact that the jump of the nonconservative product terms across cell interfaces has never been taken into account and (ii) to understand how the nonconservative products should be discretized so that their influence on the numerical solution is accurately taken into account. The resulting path-conservative central-upwind scheme is a new robust tool for both conservative and nonconservative hyperbolic systems. We apply the new scheme to the Saint-Venant system with discontinuous bottom topography and two-layer shallow water system. Our numerical results illustrate the good performance of the new path-conservative central-upwind scheme, its robustness and ability to achieve very high resolution.

MR Zbl

DOI : 10.1051/m2an/2018077

Classification : 76M12, 65M08, 35L65, 35L67, 86-08
Mots-clés : Nonconservative hyperbolic systems of PDEs, Saint-Venant system, two-layer shallow water equations, central-upwind scheme, path-conservative scheme, well-balanced scheme

Affiliations des auteurs :

Castro Díaz, Manuel Jesús ¹ ; Kurganov, Alexander ¹ ; Morales de Luna, Tomás ¹

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     title = {Path-conservative central-upwind schemes for nonconservative hyperbolic systems},
     journal = {ESAIM: Mathematical Modelling and Numerical Analysis },
     pages = {959--985},
     publisher = {EDP-Sciences},
     volume = {53},
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Castro Díaz, Manuel Jesús; Kurganov, Alexander; Morales de Luna, Tomás. Path-conservative central-upwind schemes for nonconservative hyperbolic systems. ESAIM: Mathematical Modelling and Numerical Analysis , Tome 53 (2019) no. 3, pp. 959-985. doi : 10.1051/m2an/2018077. http://archive.numdam.org/articles/10.1051/m2an/2018077/

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