Local time-stepping for adaptive multiresolution using natural extension of Runge--Kutta methods
For computational scientists solving time-dependent PDEs, this method offers improved efficiency through adaptive local time-stepping, though it is an incremental improvement over existing adaptive multiresolution techniques.
The paper presents a space-time adaptive multiresolution method for evolutionary PDEs using a local time-stepping scheme based on a natural extension of Runge-Kutta methods. Numerical tests in 1D-3D show improved CPU time and memory compression compared to reference methods.
A space-time fully adaptive multiresolution method for evolutionary non-linear partial differential equations is presented introducing an improved local time-stepping method. The space discretisation is based on classical finite volumes, endowed with cell average multiresolution analysis for triggering the dynamical grid adaptation. The explicit time scheme features a natural extension of Runge--Kutta methods which allow local time-stepping while guaranteeing accuracy. The use of a compact Runge--Kutta formulation permits further memory reduction. The precision and computational efficiency of the scheme regarding CPU time and memory compression are assessed for problems in one, two and three space dimensions. As application Burgers equation, reaction-diffusion equations and the compressible Euler equations are considered. The numerical results illustrate the efficiency and superiority of the proposed local time-stepping method with respect to the reference computations.