The Euler-Maruyama Scheme for SDEs with Irregular Drift: Convergence Rates via Reduction to a Quadrature Problem

Abstract

We study the strong convergence order of the Euler-Maruyama scheme for scalar stochastic differential equations with additive noise and irregular drift. We provide a general framework for the error analysis by reducing it to a weighted quadrature problem for irregular functions of Brownian motion. Assuming Sobolev-Slobodeckij-type regularity of order ∈ (0,1) for the non-smooth part of the drift, our analysis of the quadrature problem yields the convergence order \3/4,(1+)/2\-ε for the equidistant Euler-Maruyama scheme (for arbitrarily small ε>0). The cut-off of the convergence order at 3/4 can be overcome by using a suitable non-equidistant discretization, which yields the strong convergence order of (1+)/2-ε for the corresponding Euler-Maruyama scheme.