Approximation of the ergodic measure of SDEs with singular drift by Euler-Maruyama scheme

Abstract

We study the approximation of the ergodic measure of the following stochastic differential equation (SDE) on Rd: eqnarraye:SDEE d Xt &=& (b1(Xt)+b2(Xt)) d t+σ(Xt) d Wt, eqnarray where Wt is a d-dimensional standard Brownian motion, and b1: Rd Rd, b2: Rd Rd and σ: Rd Rd× d are the functions to be specified in Assumption 2.1 below. In particular, b1 satisfies b1∈ L∞(Rd) L1(Rd) or b1 ∈ Cbα(Rd) with α∈ (0,1), which makes the standard numerical schemes not work or fail to give a good convergence rate. In order to overcome these two difficulties, we first apply a Zvonkin's transform to SDE and obtain a new SDE which has coefficients with nice properties and admits a unique ergodic measure μ, then discretize the new equation by Euler-Maruyama scheme to approximate μ, and finally use the inverse Zvonkin's transform to get an approximation of the ergodic measure of SDE, denoted by μ. Our approximation method is inspired by Xie and Zhang [22]. The proof of our main result is based on the method of introducing a stationary Markov chain, a key ingredient in this method is establishing the regularity of a Poisson equation, which is done by combining the classical PDE local regularity and a nice extension trick introduced by Gurvich [10].