Strong convergence and stability of stochastic theta method for time-changed stochastic differential equations with local Lipschitz coefficients

In this paper, the stochastic theta (ST) method is investigated for a class of stochastic differential equations driven by a time-changed Brownian motion, whose coefficients are time-space-dependent and satisfy the local Lipschitz condition. It is proved that under the local Lipschitz and some additional assumptions, the ST method with $\theta\in[1/2,1]$ is strongly convergent. It is also obtained that, for all positive stepsizes, the ST method with $\theta\in[1/2,1]$ is asymptotically mean square stable under a coercivity condition. With some restrictions on the stepsize, the ST method with $\theta\in[0,1/2)$ is asymptotically mean square stable under a stronger assumption. Some numerical simulations are presented to illustrate the theoretical results.