On the performance of the Euler-Maruyama scheme for multidimensional SDEs with discontinuous drift coefficient

Abstract

We study strong approximation of d-dimensional stochastic differential equations (SDEs) with a discontinuous drift coefficient. More precisely, we essentially assume that the drift coefficient is piecewise Lipschitz continuous with an exceptional set Θ⊂ Rd that is an orientable C4-hypersurface of positive reach, the diffusion coefficient is assumed to be Lipschitz continuous and, in a neighborhood of Θ, both coefficients are bounded and the diffusion coefficient has a non-degenerate portion orthogonal to Θ. In recent years, a number of results have been proven in the literature for strong approximation of such SDEs and, in particular, the performance of the Euler-Maruyama scheme was studied. For d=1 and finite Θ it was shown that the Euler-Maruyama scheme achieves an Lp-error rate of at least 1/2 for all p≥ 1 as in the classical case of Lipschitz continuous coefficients. For d>1, it was only known so far, that the Euler-Maruyama scheme achieves an L2-error rate of at least 1/4- if, additionally, the coefficients μ and σ are globally bounded. In this article, we prove that in the above setting the Euler-Maruyama scheme in fact achieves an Lp-error rate of at least 1/2- for all d∈N and all p≥ 1. The proof of this result is based on the well-known approach of transforming such an SDE into an SDE with globally Lipschitz continuous coefficients, a new Itô formula for a class of functions which are not globally C2 and a detailed analysis of the expected total time that the actual position of the time-continuous Euler-Maruyama scheme and its position at the preceding time point on the underlying grid are on 'different sides' of the hypersurface Θ.