2006-05-01
On stabilized integration for time-dependent PDEs
Publication
Publication
An integration method is discussed which has been designed totreat parabolic and hyperbolic terms explicitly and stiff reaction terms implicitly. The method is a special
two-step form of the one-step IMEX (Implicit-Explicit) RKC (Runge-Kutta-Chebyshev) method. The special two-step form is introduced with the aim of getting a non-zero
imaginary stability boundary which is zero for the one-step method. Having a non-zero imaginary stability boundary allows, for example, the integration of pure advection
equations space-discretized with centered schemes, the integration of damped or viscous wave equations, the integration of coupled sound and heat flow equations, etc.
For our class of methods it also simplifies the choice of temporal step sizes satisfying the Von Neumann stability criterion, by embedding a thin long rectangle inside the
stability region. Embedding rectangles or other tractable domains with this purpose is an idea of Wesseling
Additional Metadata | |
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CWI | |
Modelling, Analysis and Simulation [MAS] | |
Organisation | Computational Dynamics |
Sommeijer, B., & Verwer, J. (2006). On stabilized integration for time-dependent PDEs. Modelling, Analysis and Simulation [MAS]. CWI. |