Power-law bounds for increasing subsequences in Brownian separable permutons and homogeneous sets in Brownian cographons

TL;DR

This paper establishes power-law bounds for the length of the longest increasing subsequences in permutations sampled from Brownian separable permutons and for the size of largest cliques and independent sets in related Brownian cographons, using fragmentation process analysis.

Contribution

It provides explicit power-law bounds for these combinatorial structures in Brownian permutons and cographons, extending understanding of their asymptotic behavior.

Findings

Longest increasing subsequence length scales as n^{alpha_*(p)} to n^{beta^*(p)}

Largest clique and independent set sizes follow similar power-law bounds

Bounds are supported by numerical simulations and relate to fragmentation processes

Abstract

The Brownian separable permutons are a one-parameter family -- indexed by $p\in(0,1)$ -- of universal limits of random constrained permutations. We show that for each $p\in (0,1)$, there are explicit constants $1/2 < \alpha_*(p) \leq \beta^*(p) < 1$ such that the length of the longest increasing subsequence in a random permutation of size $n$ sampled from the Brownian separable permuton is between $n^{\alpha_*(p) - o(1)}$ and $n^{\beta^*(p) + o(1)}$ with probability tending to 1 as $n\to\infty$. In the symmetric case $p=1/2$, we have $\alpha_*(p) \approx 0.812$ and $\beta^*(p)\approx 0.975$. We present numerical simulations which suggest that the lower bound $\alpha_*(p)$ is close to optimal in the whole range $p\in(0,1)$. Our results work equally well for the closely related Brownian cographons. In this setting, we show that for each $p\in (0,1)$, the size of the largest clique (resp. independent set) in a random graph on $n$ vertices sampled from the Brownian cographon is between $n^{\alpha_*(p) - o(1)}$ and $n^{\beta^*(p) + o(1)}$ (resp. $n^{\alpha_*(1-p) - o(1)}$ and $n^{\beta^*(1-p) + o(1)}$) with probability tending to 1 as $n\to\infty$. Our proofs are based on the analysis of a fragmentation process embedded in a Brownian excursion introduced by Bertoin (2002). We expect that our techniques can be extended to prove similar bounds for uniform separable permutations and uniform cographs.