Add to ORKGAn integration method is discussed which has been designed to treat 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 siz...
We study the numerical time integration of a class of viscous wave equations by means of Runge–Kutta...
textabstractThe Fortran 90 program IRKC is intended for the time integration of partial differential...
This paper constructs highly accurate and efficient time integration methods for the solution of tra...
Dedicated to Professor Piet Wesseling for his numerous contributions in the ¯eld of numerical mathem...
An integration method based on Runge–Kutta–Chebyshev (RKC) methods is discussed which has been desig...
Numerical methods for parabolic PDEs have been studied for many years. A great deal of the research ...
In many applications, the governing PDE to be solved numerically will contain a stiff component. Whe...
AbstractThe FORTRAN program RKC is intended for the time integration of parabolic partial differenti...
AbstractBased on the simplest well-known integration rules (such as the forward Euler scheme and the...
The Fortran 90 code IRKC is intended for the time integration of systems of partial differential equ...
This article is devoted to the construction of a new class of semi-Lagrangian (SL) schemes with impl...
The original explicit Runge-Kutta-Chebyshev (RKC) method is a stabilized second-order integration me...
textabstractThe {sc fortran program {sc rkc is intended for the time integration of parabolic partia...
AbstractThe Fortran 90 code IRKC is intended for the time integration of systems of partial differen...
The numerical time step integrations of PDEs are mainly carried out by the finite difference method ...
We study the numerical time integration of a class of viscous wave equations by means of Runge–Kutta...
textabstractThe Fortran 90 program IRKC is intended for the time integration of partial differential...
This paper constructs highly accurate and efficient time integration methods for the solution of tra...
Dedicated to Professor Piet Wesseling for his numerous contributions in the ¯eld of numerical mathem...
An integration method based on Runge–Kutta–Chebyshev (RKC) methods is discussed which has been desig...
Numerical methods for parabolic PDEs have been studied for many years. A great deal of the research ...
In many applications, the governing PDE to be solved numerically will contain a stiff component. Whe...
AbstractThe FORTRAN program RKC is intended for the time integration of parabolic partial differenti...
AbstractBased on the simplest well-known integration rules (such as the forward Euler scheme and the...
The Fortran 90 code IRKC is intended for the time integration of systems of partial differential equ...
This article is devoted to the construction of a new class of semi-Lagrangian (SL) schemes with impl...
The original explicit Runge-Kutta-Chebyshev (RKC) method is a stabilized second-order integration me...
textabstractThe {sc fortran program {sc rkc is intended for the time integration of parabolic partia...
AbstractThe Fortran 90 code IRKC is intended for the time integration of systems of partial differen...
The numerical time step integrations of PDEs are mainly carried out by the finite difference method ...
We study the numerical time integration of a class of viscous wave equations by means of Runge–Kutta...
textabstractThe Fortran 90 program IRKC is intended for the time integration of partial differential...
This paper constructs highly accurate and efficient time integration methods for the solution of tra...