A Cluster Expansion Proof That The Stochastic Exponential Of A Brownian Motion Is A Martingale

Abstract

Let :R+→R+ be a smooth and continuous real function and ∈L2(R+). Let B(t) be a standard Brownian motion defined with respect to a probability space (,F,P) and where dB(t)=(t)dt and t∈R+. The process (t) is a Gaussian white noise with expectation E~(t)=0 and with covariance E~(t)(s)=δ(t-s). The Dolean-Dades stochastic exponential Z(t) is the solution to the linear stochastic differential equation describing a geometric Brownian motion such that dZ(t)=(t)Z(t)dB(t)=(t)Z(t)(t)dt. Using a cluster expansion method, and the moment and cumulant generating functions for (t), it is shown that Z(t) is a martingale. The original Novikov criteria for Z(t) being a true martingale are reproduced and exactly satisfied, namely that align EZ(t)=E(∫ot(u)dB(u) -12∫0t|(u)|2du)=1 align provided that (∫0t|(u)|2du)<∞ for all t>0. However, E[|Z(t)|p] =(12p(p-1)φ(t)), if φ(t)=∫0t|(u)|2du is monotone increasing and is a submartingale for all p>1.