Abstract In this paper, we concern stability of numerical methods applied to stochastic delay integro-differential equations. For linear stochastic delay integro-differential equations, it is shown that the mean-square stability is derived by the split-step backward Euler method without any restriction on step-size, while the Euler–Maruyama method could reproduce the mean-square stability under a step-size constraint. We also confirm the mean-square stability of the split-step backward Euler method for nonlinear stochastic delay integro-differential equations. The numerical experiments further verify the theoretical results
The exponential stability of numerical methods to stochastic differential equations (SDEs) has been ...
In this paper, we discuss the stability of stochastic type differential equations through obtaining ...
The aim of this talk is the analysis of various stability issues for numerical methods designed to s...
the split-step backward Euler (SSBE) method for linear stochastic delay integro-differential equatio...
AbstractIn this paper, the numerical approximation of solutions of linear stochastic delay different...
This paper is concerned with the numerical solution of stochastic delay differential equations. The ...
AbstractThe paper deals with convergence and stability of the semi-implicit Euler method for a linea...
AbstractOne concept of the stability of a solution of an evolutionary equation relates to the sensit...
none3siIn this paper, we introduce a split-step theta Milstein (SSTM) method for n-dimensional stoch...
AbstractThis paper deals with the adapted Milstein method for solving linear stochastic delay differ...
AbstractOur aim is to study under what conditions the exact and numerical solution (based on equidis...
This paper is devoted to investigate the mean square stability of semiimplicit Milstein scheme in ap...
AbstractIn a very recent paper, Baker and Buckwar [Exponential stability in pth mean of solutions, a...
Abstract As a particular expression of stochastic delay differential equations, stochastic pantograp...
An efficient numerical method is presented to analyze the moment stability and stationary behavior o...
The exponential stability of numerical methods to stochastic differential equations (SDEs) has been ...
In this paper, we discuss the stability of stochastic type differential equations through obtaining ...
The aim of this talk is the analysis of various stability issues for numerical methods designed to s...
the split-step backward Euler (SSBE) method for linear stochastic delay integro-differential equatio...
AbstractIn this paper, the numerical approximation of solutions of linear stochastic delay different...
This paper is concerned with the numerical solution of stochastic delay differential equations. The ...
AbstractThe paper deals with convergence and stability of the semi-implicit Euler method for a linea...
AbstractOne concept of the stability of a solution of an evolutionary equation relates to the sensit...
none3siIn this paper, we introduce a split-step theta Milstein (SSTM) method for n-dimensional stoch...
AbstractThis paper deals with the adapted Milstein method for solving linear stochastic delay differ...
AbstractOur aim is to study under what conditions the exact and numerical solution (based on equidis...
This paper is devoted to investigate the mean square stability of semiimplicit Milstein scheme in ap...
AbstractIn a very recent paper, Baker and Buckwar [Exponential stability in pth mean of solutions, a...
Abstract As a particular expression of stochastic delay differential equations, stochastic pantograp...
An efficient numerical method is presented to analyze the moment stability and stationary behavior o...
The exponential stability of numerical methods to stochastic differential equations (SDEs) has been ...
In this paper, we discuss the stability of stochastic type differential equations through obtaining ...
The aim of this talk is the analysis of various stability issues for numerical methods designed to s...