The Properties of Fractional Gaussian Process and Their Applications

Abstract

The process (Gt)t∈[0,T] is referred to as a fractional Gaussian process if the first-order partial derivative of the difference between its covariance function and that of the fractional Brownian motion (BHt)t∈[0,T ] is a normalized bounded variation function. We quantify the relation between the associated reproducing kernel Hilbert space of (G) and that of (BH). Seven types of Gaussian processes with non-stationary increments in the literature belong to it. In the context of applications, we demonstrate that the Gladyshev's theorem holds for this process, and we provide Berry-Ess\'een upper bounds associated with the statistical estimations of the ergodic fractional Ornstein-Uhlenbeck process driven by it. The second application partially builds upon the idea introduced in BBES 23, where they assume that (G) has stationary increments. Additionally, we briefly discuss a variant of this process where the covariance structure is not entirely linked to that of the fractional Brownian motion.