Add to ORKGFractional-step methods are a popular and powerful divide-and-conquer approach for the numerical solution of differential equations. When the integrators of the fractional steps are Runge--Kutta methods, such methods can be written as generalized additive Runge--Kutta (GARK) methods, and thus the representation and analysis of such methods can be done through the GARK framework. We show how the general Butcher tableau representation and linear stability of such methods are related to the coefficients of the splitting method, the individual sub-integrators, and the order in which they are applied. We use this framework to explain some observations in the literature about fractional-step methods such as the choice of sub-integrators, the orde...
We consider a class of additive Runge-Kutta methods, which include most of the classical alternating...
A comprehensive linear stability analysis of splitting methods is carried out by means of a 2 × 2 ma...
Summary. The explicit two-step Runge-Kutta (TSRK) formulas for the numerical so lution of ordinary d...
Abstract. An important requirement of numerical me-thods for the integration of nonlinear sti ® init...
An important requirement of numerical methods for the integration of nonlinear stiff initial value p...
AbstractWe study the consistency for general additive Runge–Kutta methods in the integration of line...
Fractional Step Runge–Kutta–Nyströ (FSRKN) methods have been revealed to be an excellent option to i...
summary:The explicit two-step Runge-Kutta (TSRK) formulas for the numerical solution of ordinary dif...
Diagonally split Runge-Kutta (DSRK) time discretization methods are a class of implicit time-steppin...
In this article, we demonstrate through specific examples that the evolution of the size of the abso...
In this technical note a general procedure is described to construct internally consistent splittin...
In this article, we demonstrate through specific examples that the evolution of the size of the abso...
The effective numerical integration of evolutionary problems arising from real-life applications req...
AbstractA new family of linearly implicit fractional step methods is proposed and analysed in this p...
It is well known that, in the numerical resolution of linear time dependent coefficient parabolic pr...
We consider a class of additive Runge-Kutta methods, which include most of the classical alternating...
A comprehensive linear stability analysis of splitting methods is carried out by means of a 2 × 2 ma...
Summary. The explicit two-step Runge-Kutta (TSRK) formulas for the numerical so lution of ordinary d...
Abstract. An important requirement of numerical me-thods for the integration of nonlinear sti ® init...
An important requirement of numerical methods for the integration of nonlinear stiff initial value p...
AbstractWe study the consistency for general additive Runge–Kutta methods in the integration of line...
Fractional Step Runge–Kutta–Nyströ (FSRKN) methods have been revealed to be an excellent option to i...
summary:The explicit two-step Runge-Kutta (TSRK) formulas for the numerical solution of ordinary dif...
Diagonally split Runge-Kutta (DSRK) time discretization methods are a class of implicit time-steppin...
In this article, we demonstrate through specific examples that the evolution of the size of the abso...
In this technical note a general procedure is described to construct internally consistent splittin...
In this article, we demonstrate through specific examples that the evolution of the size of the abso...
The effective numerical integration of evolutionary problems arising from real-life applications req...
AbstractA new family of linearly implicit fractional step methods is proposed and analysed in this p...
It is well known that, in the numerical resolution of linear time dependent coefficient parabolic pr...
We consider a class of additive Runge-Kutta methods, which include most of the classical alternating...
A comprehensive linear stability analysis of splitting methods is carried out by means of a 2 × 2 ma...
Summary. The explicit two-step Runge-Kutta (TSRK) formulas for the numerical so lution of ordinary d...