Record Statistics for Multiple Random Walks

Abstract

We study the statistics of the number of records Rn,N for N identical and independent symmetric discrete-time random walks of n steps in one dimension, all starting at the origin at step 0. At each time step, each walker jumps by a random length drawn independently from a symmetric and continuous distribution. We consider two cases: (I) when the variance σ2 of the jump distribution is finite and (II) when σ2 is divergent as in the case of L\'evy flights with index 0 < μ < 2. In both cases we find that the mean record number <Rn,N> grows universally as αN n for large n, but with a very different behavior of the amplitude αN for N > 1 in the two cases. We find that for large N, αN ≈ 2 N independently of σ2 in case I. In contrast, in case II, the amplitude approaches to an N-independent constant for large N, αN ≈ 4/π, independently of 0<μ<2. For finite σ2 we argue, and this is confirmed by our numerical simulations, that the full distribution of (Rn,N/n - 2 N) N converges to a Gumbel law as n ∞ and N ∞. In case II, our numerical simulations indicate that the distribution of Rn,N/n converges, for n ∞ and N ∞, to a universal nontrivial distribution, independently of μ. We discuss the applications of our results to the study of the record statistics of 366 daily stock prices from the Standard & Poors 500 index.