Stability analysis of numerical methods for ordinary diierential equations is motivated by the question \for what choices of stepsize does the numerical method reproduce the characteristics of the test equation?" We study a linear test equation with a multiplicative noise term, and consider mean-square and asymptotic stability of a stochastic version of the Theta Method. We extend some mean-square stability results in Saito and Mit-sui, SIAM. In particular, we show that an extension of the deterministic A-stability property holds. We also plot mean-square stability regions for the case where the test equation has real parameters. For asymptotic stability, we show that the issue reduces to nding the expected value of a parametrized random variable. We combine analytical and numerical techniques to get insights into the stability properties. For a variant of the method that has been proposed in the literature we obtain precise analytic expressions for the asymptotic stability region. This allows us to prove a number of results. The technique introduced is widely applicable, and we use it to show that a fully implicit method suggested by Kloeden and Platen has an asymptotic stability extension of the deterministic A-stability property. We also use the approach to explain some numerical results reported in Milstein, Platen and Schurz,
[1]
R. Spigler,et al.
Convergence and stability of implicit runge-kutta methods for systems with multiplicative noise
,
1993
.
[2]
Peter D. Drummond,et al.
Computer simulations of multiplicative stochastic differential equations
,
1991
.
[3]
A. Hayes.
Mathematica: A system for doing mathematics by computer
,
1993,
The Mathematical Gazette.
[4]
P. Kloeden,et al.
Higher-order implicit strong numerical schemes for stochastic differential equations
,
1992
.
[5]
E. Platen,et al.
Balanced Implicit Methods for Stiff Stochastic Systems
,
1998
.
[6]
W. P. Petersen,et al.
A General Implicit Splitting for Stabilizing Numerical Simulations of Itô Stochastic Differential Equations
,
1998
.
[7]
R. Spigler,et al.
A-stability of Runge-Kutta methods for systems with additive noise
,
1992
.