Discrete Feynman-Kac approximation for parabolic Anderson model using random walks

Abstract

In this paper, we introduce a natively positive approximation method based on the Feynman-Kac representation using random walks, to approximate the solution to the one-dimensional parabolic Anderson model of Skorokhod type, with either a flat or a Dirac delta initial condition. Assuming the driving noise is a fractional Brownian sheet with Hurst parameters H ≥ 12 and H* ≥ 12 in time and space, respectively, we also provide an error analysis of the proposed method. The error in Lp () norm is of order \[ O (h12[(2H + H* - 1) 1] - ε), \] where h > 0 is the step size in time (resp. h in space), and ε > 0 can be chosen arbitrarily small. This error order matches the H\"older continuity of the solution in time with a correction order ε, making it `almost' optimal. Furthermore, these results provide a quantitative framework for convergence of the partition function of directed polymers in Gaussian environments to the parabolic Anderson model.

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