Higher-order adaptive methods for exit times of It\o diffusions

Abstract

We construct a higher-order adaptive method for strong approximations of exit times of It\o stochastic differential equations (SDE). The method employs a strong It\o--Taylor scheme for simulating SDE paths, and adaptively decreases the step-size in the numerical integration as the solution approaches the boundary of the domain. These techniques turn out to complement each other nicely: adaptive time-stepping improves the accuracy of the exit time by reducing the magnitude of the overshoot of the numerical solution when it exits the domain, and higher-order schemes improve the approximation of the state of the diffusion process. We present two versions of the higher-order adaptive method. The first one uses the Milstein scheme as numerical integrator and two step-sizes for adaptive time-stepping: h when far away from the boundary and h2 when close to the boundary. The second method is an extension of the first one using the strong It\o--Taylor scheme of order 1.5 as numerical integrator and three step-sizes for adaptive time-stepping. For any >0, we prove that the strong error is bounded by O(h1-) and O(h3/2-) for the first and second method, respectively, and the expected computational cost for both methods is O(h-1 (h-1)). Theoretical results are supported by numerical examples, and we discuss the potential for extensions that improve the strong convergence rate even further.