Functional large deviations for Stroock's approximation to a class of Gaussian processes with application to small noise diffusions
Abstract
Letting~ be a standard Poisson process, Stroock~ \cite{Stroock-1981} constructed a family of continuous processes by where , 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 , 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 and are both Lipschitz functions, and establish its Freidlin-Wentzell type LDP as . The rate function indicates a phase transition phenomenon as moves from one region to the other.
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}
}