English

An Approximation Scheme for Reflected Stochastic Differential Equations

Probability 2011-06-29 v1

Abstract

In this paper we consider the Stratonovich reflected stochastic differential equation dXt=σ(Xt)dWt+b(Xt)dt+dLtdX_t=\sigma(X_t)\circ dW_t+b(X_t)dt+dL_t in a bounded domain \O\O which satisfies conditions, introduced by Lions and Sznitman, which are specified below. Letting WtNW^N_t be the NN-dyadic piecewise linear interpolation of WtW_t what we show is that one can solve the reflected ordinary differential equation X˙tN=σ(XtN)W˙tN+b(XtN)+L˙tN\dot X^N_t=\sigma(X^N_t)\dot W^N_t+b(X^N_t)+\dot L^N_t and that the distribution of the pair (XtN,LtN)(X^N_t,L^N_t) converges weakly to that of (Xt,Lt)(X_t,L_t). Hence, what we prove is a distributional version for reflected diffusions of the famous result of Wong and Zakai. Perhaps the most valuable contribution made by our procedure derives from the representation of X˙tN\dot X^N_t in terms of a projection of W˙tN\dot W_t^N. In particular, we apply our result in hand to derive some geometric properties of coupled reflected Brownian motion in certain domains, especially those properties which have been used in recent work on the "hot spots" conjecture for special domain.

Keywords

Cite

@article{arxiv.1008.3428,
  title  = {An Approximation Scheme for Reflected Stochastic Differential Equations},
  author = {Lawrence Christopher Evans and Daniel W. Stroock},
  journal= {arXiv preprint arXiv:1008.3428},
  year   = {2011}
}

Comments

26 pages, 4 figures

R2 v1 2026-06-21T16:03:08.822Z