Abstract
AbstractHyperbolic systems of conservation laws in multiple spatial dimensions display features absent in the one-dimensional case, such as involutions and non-trivial stationary states. These features need to be captured by numerical methods without excessive grid refinement. The active flux method is an extension of the finite volume scheme with additional point values distributed along the cell boundary. For the equations of linear acoustics, an exact evolution operator can be used for the update of these point values. It incorporates all multi-dimensional information. The active flux method is stationarity preserving, i.e., it discretizes all the stationary states of the PDE. This paper demonstrates the experimental evidence for the discrete stationary states of the active flux method and shows the evolution of setups towards a discrete stationary state.
Publisher
Springer Science and Business Media LLC
Reference14 articles.
1. Barsukow, W.: The active flux scheme for nonlinear problems. submitted to J. Sci. Comp. (2019)
2. Barsukow, W.: Stationarity preserving schemes for multi-dimensional linear systems. Math. Comput. 88(318), 1621–1645 (2019)
3. Barsukow, W., Edelmann, P.V.F., Klingenberg, C., Miczek, F., Röpke, F.K.: A numerical scheme for the compressible low-Mach number regime of ideal fluid dynamics. J. Sci. Comput. 72(2), 623–646 (2017)
4. Barsukow, W., Hohm, J., Klingenberg, C., Roe, P.L.: The active flux scheme on Cartesian grids and its low Mach number limit. J. Sci. Comput. 81(1), 594–622 (2019)
5. Barsukow, W., Klingenberg, C.: Exact solution and a truly multidimensional Godunov scheme for the acoustic equations. arXiv: 2004.04217 (2020)
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2 articles.
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