Brownian motion: the hyperbolic number setting

Abstract

The purpose of this paper is to define normal Gaussian variables in the setting of hyperbolic probabilities, and introduce an associated Brownian motion, when both the index and the values of the process lie in the real algebra H of hyperbolic numbers. In Hida's white noise space, we construct two probability measures (say P1 and P2), and associate to them two families of N(0,1) variables (Zn)n∈ N0 (independent with respect to P1) and (Wn)n∈ N0 (independent with respect to P2). An important feature is that the Zn and Wm need not be mutually independent either with respect to P1 or P2. An hyperbolic normal Gaussian variable is constructed (in non-degenerate cases) from two classical Gaussian variables and the hyperbolic Brownian motion is, in general, composed from two copies of the classical Brownian motion. Using the associated Gelfand triples we also compute the derivative of the hyperbolic Brownian motion as a stochastic distribution. The argument extends to the H-valued fractional Brownian motion, and more generally to a wide family of H-valued stationary-increment second order processes.