The Euler-Maruyama method for SDEs with low-regularity drift

Abstract

We study the strong Lp-convergence rates of the Euler-Maruyama method for stochastic differential equations driven by Brownian motion with low-regularity drift coefficients. Specifically, the drift is assumed to be in the Lebesgue-H\"older spaces Lq([0,T]; Cbα( Rd)) with α∈(0,1) and q∈ (2/(1+α),∞]. For every p≥ 2, by using stochastic sewing and/or the It\o-Tanaka trick, we obtain the Lp-convergence rates: (1+α)/2 for q∈ [2,∞] and (1-1/q) for q∈ (2/(1+α),2). Moreover, we prove that the unique strong solution can be constructed via the Picard iteration.