Feynman-Kac representation for the parabolic Anderson model driven by fractional noise

Abstract

We consider the parabolic Anderson model driven by fractional noise: ∂∂ tu(t,x)= u(t,x)+ u(t,x)∂∂ tW(t,x) x∈Zd\;,\; t≥ 0\,, where >0 is a diffusion constant, is the discrete Laplacian defined by f(x)= 12dΣ|y-x|=1(f(y)-f(x)), and \W(t,x)\;;\;t≥0\x ∈ Zd is a family of independent fractional Brownian motions with Hurst parameter H∈(0,1), indexed by Zd. We make sense of this equation via a Stratonovich integration obtained by approximating the fractional Brownian motions with a family of Gaussian processes possessing absolutely continuous sample paths. We prove that the Feynman-Kac representation equation u(t,x)=Ex[uo(X(t)) ∫0t W(ds, X(t-s))]\,, equation is a mild solution to this problem. Here uo(y) is the initial value at site y∈Zd, \X(t)\;;\;t≥0\ is a simple random walk with jump rate , started at x ∈ Zd and independent of the family \W(t,x)\;;\;t≥0\x∈Zd and Ex is expectation with respect to this random walk. We give a unified argument that works for any Hurst parameter H∈ (0,1).