Noise Reinforced L\'evy Processes: L\'evy-It\o Decomposition and Applications

Abstract

A step reinforced random walk is a discrete time process with memory such that at each time step, with fixed probability p ∈ (0,1), it repeats a previously performed step chosen uniformly at random while with complementary probability 1-p, it performs an independent step with fixed law. In the continuum, the main result of Bertoin in [7] states that the random walk constructed from the discrete-time skeleton of a L\'evy process for a time partition of mesh-size 1/n converges, as n ∞ in the sense of finite dimensional distributions, to a process referred to as a noise reinforced L\'evy process. Our first main result states that a noise reinforced L\'evy processes has rcll paths and satisfies a noise reinforced L\'evy It\o decomposition in terms of the noise reinforced Poisson point process of its jumps. We introduce the joint distribution of a L\'evy process and its reinforced version (, ) and show that the pair, conformed by the skeleton of the L\'evy process and its step reinforced version, converge towards (, ) as the mesh size tend to 0. As an application, we analyse the rate of growth of at the origin and identify its main features as an infinitely divisible process.