Exponential Stability of Numerical Solutions to Stochastic Age-Dependent Population Equations with Poisson Jumps
The main aim of this paper is to investigate the exponential stability of the Euler method for a stochastic age-dependent population equations with Poisson random measures. It is proved that the Euler scheme is exponentially stable in mean square sense. An example is given for illustration.
[1] J.H.Pollard, On the use of the direct matrix product in analyzing certain
stochastic population model, Biometrika. 53(1966), 397-415.
[2] Q.M.Zhang, W.A.Liu, Z.K.Nie, Existence, uniqueness and exponential
stability for stochastic age-dependent population, Appl. Math. Comput.
154(2004), 183-201.
[3] Li Ronghua, Meng Hongbing, Chang Qin, Convergence of numerical
solutions to stochastic age-dependent population equations. J. Comput.
Appl. Math. 193(2006), 109-120.
[4] W.K. Pang, Li Ronghua, Liu Ming, Exponential stability of numerical
solutions to stochastic age-dependent population equations. Appl. Math.
Comput. 183(2006), 152-159.
[5] Ronghua Li, W.K. Pang, Qinghe Wang. Numerical analysis for stochastic
age-dependent population equations with Poisson jumps. J. Math. Anal.
Appl, 327(2007), 1214-1224.
[6] Wang L, Wang X, Convergence of the semi-implicit Euler method for
stochastic age-dependent population equations with Poisson jumps. Appl.
Math. Model. 34(2010), 2034-2043.
[7] D. J. Higham, X. Mao, C.Yuan, Almost Sure and Moment Exponential
Stability in the Numerical Simulation of Stochastic Differential Equations.
SIAM. J. Numer. Anal, vol. 45, 2007, pp. 592-609.
[8] Xuerong Mao, Exponential stability of equidistant EulerCMaruyama
approximations of stochastic differential delay equations J. Comput. Appl.
Math. 200, 2007, 297-316
[9] D.J.Higham, X.Mao, and A.M.Stuart, Exponential Mean-Square Stability
of Numerical Solutions to Stochastic Differential Equations, LMS J.
Comput. Math, 6(2003), 297-313.
[10] N.Ikeda and S.Watanable, Stochastic Differential Equations and diffusion
processes, North-Holland/ Kodansha Amsterdam. Oxford. New York.
1989.
[1] J.H.Pollard, On the use of the direct matrix product in analyzing certain
stochastic population model, Biometrika. 53(1966), 397-415.
[2] Q.M.Zhang, W.A.Liu, Z.K.Nie, Existence, uniqueness and exponential
stability for stochastic age-dependent population, Appl. Math. Comput.
154(2004), 183-201.
[3] Li Ronghua, Meng Hongbing, Chang Qin, Convergence of numerical
solutions to stochastic age-dependent population equations. J. Comput.
Appl. Math. 193(2006), 109-120.
[4] W.K. Pang, Li Ronghua, Liu Ming, Exponential stability of numerical
solutions to stochastic age-dependent population equations. Appl. Math.
Comput. 183(2006), 152-159.
[5] Ronghua Li, W.K. Pang, Qinghe Wang. Numerical analysis for stochastic
age-dependent population equations with Poisson jumps. J. Math. Anal.
Appl, 327(2007), 1214-1224.
[6] Wang L, Wang X, Convergence of the semi-implicit Euler method for
stochastic age-dependent population equations with Poisson jumps. Appl.
Math. Model. 34(2010), 2034-2043.
[7] D. J. Higham, X. Mao, C.Yuan, Almost Sure and Moment Exponential
Stability in the Numerical Simulation of Stochastic Differential Equations.
SIAM. J. Numer. Anal, vol. 45, 2007, pp. 592-609.
[8] Xuerong Mao, Exponential stability of equidistant EulerCMaruyama
approximations of stochastic differential delay equations J. Comput. Appl.
Math. 200, 2007, 297-316
[9] D.J.Higham, X.Mao, and A.M.Stuart, Exponential Mean-Square Stability
of Numerical Solutions to Stochastic Differential Equations, LMS J.
Comput. Math, 6(2003), 297-313.
[10] N.Ikeda and S.Watanable, Stochastic Differential Equations and diffusion
processes, North-Holland/ Kodansha Amsterdam. Oxford. New York.
1989.
@article{"International Journal of Engineering, Mathematical and Physical Sciences:50007", author = "Mao Wei", title = "Exponential Stability of Numerical Solutions to Stochastic Age-Dependent Population Equations with Poisson Jumps", abstract = "The main aim of this paper is to investigate the exponential stability of the Euler method for a stochastic age-dependent population equations with Poisson random measures. It is proved that the Euler scheme is exponentially stable in mean square sense. An example is given for illustration.
", keywords = "Stochastic age-dependent population equations, poisson random measures, numerical solutions, exponential stability.", volume = "5", number = "7", pages = "936-6", }
