It is possible to construct fully implicit Runge-Kutta methods like Gauß-Legendre, Radau-IA, Radau-IIA, Lobatto-IIIA, -IIIB, and -IIIC methods of arbitrary high order of convergence. The aim of this paper is to find a new adaptive time stepping for these classes which is based on the embedding technique. Adaptive time step control with embedding is well-known for Runge-Kutta methods, and therefore new embedded methods of order s-1 for the above classes of fully implicit Runge-Kutta methods are constructed. Since these fully implicit methods need the solution of a huge non-linear system of equations different approaches for non-linear equations are discussed and compared. It can be observed that non-linear solvers like the usually used simpl...
We consider the construction of semi-implicit linear multistep methods which can be applied to time ...
We address the problem of constructing high-order implicit schemes for wave equations. We considered...
International audienceThis paper studies higher order approximations of solutions of differential eq...
Strong stability preserving (SSP) time discretizations were developed for use with spatial discretiz...
International audienceThis paper introduces a new class of numerical methods for the time integratio...
AbstractThe nonlinear equations, arising in the implementation of implicit Runge-Kutta methods, may ...
Adaptive time-stepping is central to the efficient solution of initial value problems in ODEs and DA...
This paper introduces a new class of numerical methods for the time integration of evolution equatio...
This chapter describes implicit time integration methods developed by four TILDA partners for the ap...
Efficient time stepping algorithms are crucial for accurate long time simulations of nonlinear waves...
Fully implicit Runge–Kutta methods offer the possibility to use high order accurate time discretizat...
International audienceThe main purpose of the paper is to show how to use implicit-explicit (IMEX) R...
"We investigate a class of time discretization schemes called “ETD Runge Kutta methods,” where the l...
We introduce a variable step size algorithm for the pathwise numerical approximation of solutions to...
The last decades have seen a strongly increasing use of computers for modeling larger and more compl...
We consider the construction of semi-implicit linear multistep methods which can be applied to time ...
We address the problem of constructing high-order implicit schemes for wave equations. We considered...
International audienceThis paper studies higher order approximations of solutions of differential eq...
Strong stability preserving (SSP) time discretizations were developed for use with spatial discretiz...
International audienceThis paper introduces a new class of numerical methods for the time integratio...
AbstractThe nonlinear equations, arising in the implementation of implicit Runge-Kutta methods, may ...
Adaptive time-stepping is central to the efficient solution of initial value problems in ODEs and DA...
This paper introduces a new class of numerical methods for the time integration of evolution equatio...
This chapter describes implicit time integration methods developed by four TILDA partners for the ap...
Efficient time stepping algorithms are crucial for accurate long time simulations of nonlinear waves...
Fully implicit Runge–Kutta methods offer the possibility to use high order accurate time discretizat...
International audienceThe main purpose of the paper is to show how to use implicit-explicit (IMEX) R...
"We investigate a class of time discretization schemes called “ETD Runge Kutta methods,” where the l...
We introduce a variable step size algorithm for the pathwise numerical approximation of solutions to...
The last decades have seen a strongly increasing use of computers for modeling larger and more compl...
We consider the construction of semi-implicit linear multistep methods which can be applied to time ...
We address the problem of constructing high-order implicit schemes for wave equations. We considered...
International audienceThis paper studies higher order approximations of solutions of differential eq...