Weighted Sub-fractional Brownian Motion Process: Properties and Generalizations

Abstract

In this paper, we present several path properties, simulations, inferences, and generalizations of the weighted sub-fractional Brownian motion. A primary focus is on the derivation of the covariance function Rf,b(s,t) for the weighted sub-fractional Brownian motion, defined as: equation* Rf,b(s,t) = 11-b ∫0s t f(r) [(s-r)b + (t-r)b - (t+s-2r)b] dr, equation* where f:R+ R+ is a measurable function and b∈ [0,1)(1,2]. This covariance function Rf,b(s,t) is used to define the centered Gaussian process ζt,f,b, which is the weighted sub-fractional Brownian motion. Furthermore, if there is a positive constant c and a ∈ (-1,∞) such that 0 ≤ f(u) ≤ c ua on [0,T] for some T>0. Then, for b ∈ (0,1), ζt,f,b exhibits infinite variation and zero quadratic variation, making it a non-semi-martingale. On the other hand, for b ∈ (1,2], ζt,f,b is a continuous process of finite variation and thus a semi-martingale and for b=0 the process ζt,f,0 is a square integrable continuous martingale. We also provide inferential studies using maximum likelihood estimation and perform simulations comparing various numerical methods for their efficiency in computing the finite-dimensional distributions of ζt,f,b. Additionally, we extend the weighted sub-fractional Brownian motion to Rd by defining new covariance structures for measurable, bounded sets in Rd. Finally, we define a stochastic integral with respect to ζt,f,b and introduce both the weighted sub-fractional Ornstein-Uhlenbeck process and the geometric weighted sub-fractional Brownian motion.