English

Increasing subsequences of random walks

Probability 2016-09-28 v3

Abstract

Given a sequence of nn real numbers {Si}in\{S_i\}_{i\leq n}, we consider the longest weakly increasing subsequence, namely i1<i2<<iLi_1<i_2<\dots <i_L with SikSik+1S_{i_k} \leq S_{i_{k+1}} and LL maximal. When the elements SiS_i are i.i.d. uniform random variables, Vershik and Kerov, and Logan and Shepp proved that EL=(2+o(1))n\mathbb{E} L=(2+o(1)) \sqrt{n}. We consider the case when {Si}in\{S_i\}_{i\leq n} is a random walk on R\mathbb{R} with increments of mean zero and finite (positive) variance. In this case, it is well known (e.g., using record times) that the length of the longest increasing subsequence satisfies ELcn\mathbb{E} L\geq c\sqrt{n}. Our main result is an upper bound ELn1/2+o(1)\mathbb{E} L\leq n^{1/2 + o(1)}, establishing the leading asymptotic behavior. If {Si}in\{S_i\}_{i\leq n} is a simple random walk on Z\mathbb{Z}, we improve the lower bound by showing that ELcnlogn\mathbb{E} L \geq c\sqrt{n} \log{n}. We also show that if {Si}\{\mathbf{S}_i\} is a simple random walk in Z2\mathbb{Z}^2, then there is a subsequence of {Si}in\{\mathbf{S}_i\}_{i\leq n} of expected length at least cn1/3cn^{1/3} that is increasing in each coordinate. The above one-dimensional result yields an upper bound of n1/2+o(1)n^{1/2 + o(1)}. The problem of determining the correct exponent remains open.

Keywords

Cite

@article{arxiv.1407.2860,
  title  = {Increasing subsequences of random walks},
  author = {Omer Angel and Richárd Balka and Yuval Peres},
  journal= {arXiv preprint arXiv:1407.2860},
  year   = {2016}
}

Comments

18 pages, 2 figures

R2 v1 2026-06-22T05:00:53.730Z