Records, drift, and the longest increasing subsequence of biased Gaussian random walks

Abstract

The longest increasing subsequence (LIS) of a random walk has been studied mainly for zero-mean, symmetric step increments. We numerically investigate the LIS of biased Gaussian random walks, with unit-variance increments and positive drift μp = Φ-1(p), where p = P(ξ>0). In contrast with the symmetric case, we find that for every fixed p>1/2 the mean LIS length grows linearly, Ln(p) a(p)n, with a(p) increasing from 0 at p=1/2 to 1 as p 1. The record count is also linear, with coefficient λ(p) fixed by Spitzer's formula for the ascending ladder epoch, and the LIS becomes increasingly aligned with this record skeleton as p grows. At the symmetric point p=1/2, the record skeleton collapses to the Sparre Andersen n scale, while the LIS returns to the finite-variance nn regime. Near this limit the record rate has the closed-form small-drift slope λ(μp) 2\,μp, whereas the excess a(μp)-λ(μp) vanishes more slowly than linearly in the drift, although our data do not resolve a single power law. The empirical distribution of Ln also changes across this point, from lognormal-like at p=1/2 to Gaussian-like for every sampled p>1/2.