Strong convergence of the Euler--Maruyama approximation for a class of L\'evy-driven SDEs

Abstract

Consider the following stochastic differential equation (SDE) dXt = b(t,Xt-) \, dt+ dLt, X0 = x, driven by a d-dimensional L\'evy process (Lt)t ≥ 0. We establish conditions on the L\'evy process and the drift coefficient b such that the Euler--Maruyama approximation converges strongly to a solution of the SDE with an explicitly given rate. The convergence rate depends on the regularity of b and the behaviour of the L\'evy measure at the origin. As a by-product of the proof, we obtain that the SDE has a pathwise unique solution. Our result covers many important examples of L\'evy processes, e.g. isotropic stable, relativistic stable, tempered stable and layered stable.