AbstractThis paper considers the use of continuously embedded Runge-Kutta-Sarafyan methods for the solution of delay differential equations. It discusses simple ways to improve the error estimation and step size selection strategies for delay solvers based on Sarafyan methods. Numerical results are given which demonstrate the manner in which these estimates improve the accuracy of the solvers in a natural way
In this paper, initial value problems of first order delay differential equations (DDEs) are solved ...
In this paper a new method for the numerical computation of characteristic roots for linear autonomo...
AbstractStability properties of numerical methods for delay differential equations are considered. S...
AbstractThe use of continuously imbedded Runge–Kutta–Sarafyan methods for the solution of ordinary d...
Introduction to delay differential equations (DDEs) and their examples are presented. The General fo...
This paper presents numerical solution for Delay Differential Equations systems to identify frequent...
This thesis describes the implementation of one-step block methods of Runge-Kutta type for solving s...
In this paper, the numerical solution of delay differential equations using a predictor-corrector sc...
AbstractThis work examines the performance of explicit, adaptive, Runge-Kutta based algorithms for s...
This work examines the performance of explicit, adaptive, Runge-Kutta based algorithms for solving d...
This thesis describes the implementation of one step block methods of Runge-Kutta type for solving f...
Continuous Runge-Kutta methods have many applications including the numerical solution of delay diff...
In this paper we used three embedded diagonally implicit Runge-Kutta methods to solve a standard set...
AbstractThe effect of the local approximation error on the stepsize control at one-step methods, whi...
We discuss the practical determination of stability regions when various fixed-stepsize Runge-Kutta ...
In this paper, initial value problems of first order delay differential equations (DDEs) are solved ...
In this paper a new method for the numerical computation of characteristic roots for linear autonomo...
AbstractStability properties of numerical methods for delay differential equations are considered. S...
AbstractThe use of continuously imbedded Runge–Kutta–Sarafyan methods for the solution of ordinary d...
Introduction to delay differential equations (DDEs) and their examples are presented. The General fo...
This paper presents numerical solution for Delay Differential Equations systems to identify frequent...
This thesis describes the implementation of one-step block methods of Runge-Kutta type for solving s...
In this paper, the numerical solution of delay differential equations using a predictor-corrector sc...
AbstractThis work examines the performance of explicit, adaptive, Runge-Kutta based algorithms for s...
This work examines the performance of explicit, adaptive, Runge-Kutta based algorithms for solving d...
This thesis describes the implementation of one step block methods of Runge-Kutta type for solving f...
Continuous Runge-Kutta methods have many applications including the numerical solution of delay diff...
In this paper we used three embedded diagonally implicit Runge-Kutta methods to solve a standard set...
AbstractThe effect of the local approximation error on the stepsize control at one-step methods, whi...
We discuss the practical determination of stability regions when various fixed-stepsize Runge-Kutta ...
In this paper, initial value problems of first order delay differential equations (DDEs) are solved ...
In this paper a new method for the numerical computation of characteristic roots for linear autonomo...
AbstractStability properties of numerical methods for delay differential equations are considered. S...