English

Functional large deviations for Stroock's approximation to a class of Gaussian processes with application to small noise diffusions

Probability 2022-06-06 v1

Abstract

Letting~N={N(t),t0}N=\left\{N(t), t\geq0\right\} be a standard Poisson process, Stroock~ \cite{Stroock-1981} constructed a family of continuous processes by Θϵ(t)=0tθϵ(r)dr,     0t1,\Theta_{\epsilon}(t)=\int_0^t\theta_{\epsilon}(r)dr, \ \ \ \ \ 0 \le t \le 1, where θϵ(r)=1ϵ(1)N(ϵ2r)\theta_{\epsilon}(r)=\frac{1}{\epsilon}(-1)^{N(\epsilon^{-2}r)}, and proved that it weakly converges to a standard Brownian motion under the continuous function topology. We establish the functional large deviations principle (LDP) for the approximations of a class of Gaussian processes constructed by integrals over Θϵ(t)\Theta_{\epsilon}(t), and find the explicit form for rate function. As an application, we consider the following (non-Markovian) stochastic differential equation \begin{equation*} \begin{aligned} X^{\epsilon}(t) &=x_{0}+\int^{t}_{0}b(X^{\epsilon}(s))ds+\lambda(\epsilon)\int^{t}_{0}\sigma(X^{\epsilon}(s))d\Theta_{\epsilon}(s), \end{aligned} \end{equation*} where bb and σ\sigma are both Lipschitz functions, and establish its Freidlin-Wentzell type LDP as ϵ0\epsilon \rightarrow 0. The rate function indicates a phase transition phenomenon as λ(ϵ)\lambda(\epsilon) moves from one region to the other.

Keywords

Cite

@article{arxiv.2206.01351,
  title  = {Functional large deviations for Stroock's approximation to a class of Gaussian processes with application to small noise diffusions},
  author = {Hui Jiang and Lihu Xu and Qingshan Yang},
  journal= {arXiv preprint arXiv:2206.01351},
  year   = {2022}
}
R2 v1 2026-06-24T11:37:50.128Z