Constrained Brownian motion: Fluctuations away from circular and parabolic barriers

Constrained Brownian motion: Fluctuations away from circular and parabolic barriers

Patrik L. Ferrari and Herbert Spohn

Source: Ann. Probab. Volume 33, Number 4 (2005), 1302-1325.

Abstract

Motivated by the polynuclear growth model, we consider a Brownian bridge b(t) with b(±T)=0 conditioned to stay above the semicircle $c_{T}(t)=\sqrt{T^{2}-t^{2}}$ . In the limit of large T, the fluctuation scale of b(t)−c_T(t) is T^1/3 and its time-correlation scale is T^2/3. We prove that, in the sense of weak convergence of path measures, the conditioned Brownian bridge, when properly rescaled, converges to a stationary diffusion process with a drift explicitly given in terms of Airy functions. The dependence on the reference point t=τT, τ∈(−1,1), is only through the second derivative of c_T(t) at t=τT. We also prove a corresponding result where instead of the semicircle the barrier is a parabola of height T^γ, γ>1/2. The fluctuation scale is then T^(2−γ)/3. More general conditioning shapes are briefly discussed.

Primary Subjects: 60J65

Secondary Subjects: 60J60

Keywords: Conditioned Brownian bridge; limiting diffusion process

Full-text: Open access

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Links and Identifiers

Permanent link to this document: http://projecteuclid.org/euclid.aop/1120224582
Digital Object Identifier: doi:10.1214/009117905000000125
Mathematical Reviews number (MathSciNet): MR2150190
Zentralblatt MATH identifier: 1082.60071

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