Smooth approximation of stochastic differential equations

Abstract

Consider an It\o process X satisfying the stochastic differential equation dX=a(X)\,dt+b(X)\,dW where a,b are smooth and W is a multidimensional Brownian motion. Suppose that Wn has smooth sample paths and that Wn converges weakly to W. A central question in stochastic analysis is to understand the limiting behavior of solutions Xn to the ordinary differential equation dXn=a(Xn)\,dt+b(Xn)\,dWn. The classical Wong--Zakai theorem gives sufficient conditions under which Xn converges weakly to X provided that the stochastic integral ∫ b(X)\,dW is given the Stratonovich interpretation. The sufficient conditions are automatic in one dimension, but in higher dimensions the correct interpretation of ∫ b(X)\,dW depends sensitively on how the smooth approximation Wn is chosen. In applications, a natural class of smooth approximations arise by setting Wn(t)=n-1/2∫0ntvφs\,ds where φt is a flow (generated, e.g., by an ordinary differential equation) and v is a mean zero observable. Under mild conditions on φt, we give a definitive answer to the interpretation question for the stochastic integral ∫ b(X)\,dW. Our theory applies to Anosov or Axiom A flows φt, as well as to a large class of nonuniformly hyperbolic flows (including the one defined by the well-known Lorenz equations) and our main results do not require any mixing assumptions on φt. The methods used in this paper are a combination of rough path theory and smooth ergodic theory.