Wang JW, Liu RX (2005) Combined finite volume-finite element method for shallow water equations. Computers &, Fluids 34(10), 1199-1222. [In English]
Web link:http://dx.doi.org/10.1016/j.compfluid.2004.09.008
Keywords:
approximate riemann solvers, shock-capturing schemes, godunov-type, scheme, unstructured meshes, 2-dimensional flow, channel, model,
Abstract: This paper is concerned with solving the viscous and inviscid shallow water equations. The numerical method is based on second-order finite volume-finite element (FV-FE) discretization: the convective inviscid terms of the shallow water equations are computed by a finite volume method, while the diffusive viscous terms are computed with a finite element method. The method is implemented on unstructured meshes. The inviscid fluxes are evaluated with the approximate Riemann solver coupled with a second-order upwind reconstruction. Herein, the Roe and the Osher approximate Riemann solvers are used respectively and a comparison between them is made. Appropriate limiters are used to suppress spurious oscillations and the performance of three different limiters is assessed. Moreover, the second-order conforming piecewise linear finite elements are used. The second-order TVD Runge-Kutta method is applied to the time integration. Verification of the method for the full viscous system and the inviscid equations is carried out. By solving an advection-diffusion problem, the performance assessment for the FV-FE method, the full finite volume method, and the discontinuous Galerkin method is presented. (c) 2004 Elsevier Ltd. All rights reserved.