Discrete Razumikhin-type technique and stability of the Euler-Maruyama method to stochastic functional differential equations

B. Liu; C. T. H. Baker; C. Zhang; D. J. Higham; D. J. Higham; F. Wu; F. Wu; F. Wu; Fuke Wu; J. K. Hale; K. Burrage; K. Burrage; Peter E. Kloeden; S. Pang; S. Zhang; T. Caraballo; X. Mao; X. Mao; X. Mao; Xuerong Mao; Y. Saito; Y. Saito

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Discrete Razumikhin-type technique and stability of the Euler-Maruyama method to stochastic functional differential equations

Authors: B. Liu
C. T. H. Baker
C. Zhang
D. J. Higham
D. J. Higham
F. Wu
F. Wu
F. Wu
Fuke Wu
J. K. Hale
K. Burrage
K. Burrage
Peter E. Kloeden
S. Pang
S. Zhang
T. Caraballo
X. Mao
X. Mao
X. Mao
Xuerong Mao
Y. Saito
Y. Saito
Publication date: 1 January 2013
Publisher: 'American Institute of Mathematical Sciences (AIMS)'
Doi

Abstract

A discrete stochastic Razumikhin-type theorem is established to investigate whether the Euler--Maruyama (EM) scheme can reproduce the moment exponential stability of exact solutions of stochastic functional differential equations (SFDEs). In addition, the Chebyshev inequality and the Borel-Cantelli lemma are applied to show the almost sure stability of the EM approximate solutions of SFDEs. To show our idea clearly, these results are used to discuss stability of numerical solutions of two classes of special SFDEs, including stochastic delay differential equations (SDDEs) with variable delay and stochastically perturbed equations