English

A robust and stable numerical scheme for a depth-averaged Euler system

Numerical Analysis 2015-09-15 v3

Abstract

We propose an efficient numerical scheme for the resolution of a non-hydrostatic Saint-Venant type model. The model is a shallow water type approximation of the incompressbile Euler system with free surface and slightly differs from the Green-Naghdi model. The numerical approximation relies on a kinetic interpretation of the model and a projection-correction type scheme. The hyperbolic part of the system is approximated using a kinetic based finite volume solver and the correction step implies to solve an elliptic problem involving the non-hydrostatic part of the pressure. We prove the numerical scheme satisfies properties such as positivity, well-balancing and a fully discrete entropy inequality. The numerical scheme is confronted with various time-dependent analytical solutions. Notice that the numerical procedure remains stable when the water depth tends to zero.

Keywords

Cite

@article{arxiv.1506.03316,
  title  = {A robust and stable numerical scheme for a depth-averaged Euler system},
  author = {N. Aissiouene and M. -O. Bristeau and E. Godlewski and J. Sainte-Marie},
  journal= {arXiv preprint arXiv:1506.03316},
  year   = {2015}
}
R2 v1 2026-06-22T09:51:02.568Z