Universal order statistics for random walks & L\'evy flights

Abstract

We consider one-dimensional discrete-time random walks (RWs) of n steps, starting from x0=0, with arbitrary symmetric and continuous jump distributions f(η), including the important case of L\'evy flights. We study the statistics of the gaps k,n between the kth and (k+1)th maximum of the set of positions \x1,…,xn\. We obtain an exact analytical expression for the probability distribution Pk,n() valid for any k and n, and jump distribution f(η), which we then analyse in the large n limit. For jump distributions whose Fourier transform behaves, for small q, as f (q) 1 - |q|μ with a L\'evy index 0< μ ≤ 2, we find that, the distribution becomes stationary in the limit of n ∞, i.e. n ∞ Pk,n()=Pk(). We obtain an explicit expression for its first moment E[k], valid for any k and jump distribution f(η) with μ>1, and show that it exhibits a universal algebraic decay E[k] k1/μ-1 (1-1/μ)/π for large k. Furthermore, for μ>1, we show that in the limit of k∞ the stationary distribution exhibits a universal scaling form Pk() k1-1/μ Pμ(k1-1/μ) which depends only on the L\'evy index μ, but not on the details of the jump distribution. We compute explicitly the limiting scaling function Pμ(x) in terms of Mittag-Leffler functions. For 1< μ <2, we show that, while this scaling function captures the distribution of the typical gaps on the scale k1/μ-1, the atypical large gaps are not described by this scaling function since they occur at a larger scale of order k1/μ.