A geometric interpretation of the transition density of a symmetric L\'evy Process

Abstract

We study for a class of symmetric L\'evy processes with state space the transition density pt(x) in terms of two one-parameter families of metrics, (dt)t>0 and (δt)t>0. The first family of metrics describes the diagonal term pt(0); it is induced by the characteristic exponent of the L\'evy process by dt(x,y)=t(x-y). The second and new family of metrics δt relates to t through the formula (-δt2(x,y)) = [e-tpt(0)](x-y) where denotes the Fourier transform. Thus we obtain the following "Gaussian" representation of the transition density: pt(x)=pt(0) e-δt2(x,0) where pt(0) corresponds to a volume term related to t and where an "exponential" decay is governed by δt2. This gives a complete and new geometric, intrinsic interpretation of pt(x).