High-dimensional permutons: theory and applications
Abstract
Permutons, which are probability measures on the unit square with uniform marginals, are the natural scaling limits for sequences of (random) permutations. We introduce a -dimensional generalization of these measures for all , which we call -dimensional permutons, and extend -- from the two-dimensional setting -- the theory to prove convergence of sequences of (random) -dimensional permutations to (random) -dimensional permutons. Building on this new theory, we determine the random high-dimensional permuton limits for two natural families of high-dimensional permutations. First, we determine the -dimensional permuton limit for Schnyder wood permutations, which bijectively encode planar triangulations decorated by triples of spanning trees known as Schnyder woods. Second, we identify the -dimensional permuton limit for -separable permutations, a pattern-avoiding class of -dimensional permutations generalizing ordinary separable permutations. Both high-dimensional permuton limits are random and connected to previously studied universal 2-dimensional permutons, such as the Brownian separable permutons and the skew Brownian permutons, and share interesting connections with objects arising from random geometry, including the continuum random tree, Schramm--Loewner evolutions, and Liouville quantum gravity surfaces.
Keywords
Cite
@article{arxiv.2412.19730,
title = {High-dimensional permutons: theory and applications},
author = {Jacopo Borga and Andrew Lin},
journal= {arXiv preprint arXiv:2412.19730},
year = {2025}
}
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