Predicting the Last Zero of Brownian Motion with Drift

Abstract

Given a standard Brownian motion Bμ=(Btμ)0 t T with drift μ ∈ IR and letting g denote the last zero of Bμ before T, we consider the optimal prediction problem V*=∈f0 τ T E\:|\:g-τ | where the infimum is taken over all stopping times τ of Bμ. Reducing the optimal prediction problem to a parabolic free-boundary problem and making use of local time-space calculus techniques, we show that the following stopping time is optimal: τ*=∈f t∈ [0,T] | Btμ b-(t) or Btμ b+(t) where the function t b-(t) is continuous and increasing on [0,T] with b-(T)=0, the function t b+(t) is continuous and decreasing on [0,T] with b+(T)=0, and the pair b- and b+ can be characterised as the unique solution to a coupled system of nonlinear Volterra integral equations. This also yields an explicit formula for V* in terms of b- and b+. If μ=0 then b-=-b+ and there is a closed form expression for b as shown in [10] using the method of time change from [4]. The latter method cannot be extended to the case when μ 0 and the present paper settles the remaining cases using a different approach.