Optimal matching under size priority

TL;DR

This paper introduces a new concept of optimal matchings in large random graphs with atomless weights, proving their existence, uniqueness, and convergence properties, and analyzing their structural correlations.

Contribution

It generalizes the theory of maximal weight matchings to include size constraints and establishes convergence and correlation decay results for these optimal matchings.

Findings

Existence and uniqueness of optimal matchings on unimodular trees.

Convergence of finite graph matchings to the optimal infinite-tree matching.

Explicit formulas for asymptotic densities of edges in all or none of the optimal matchings.

Abstract

Past studies on the local limit of maximal weight matchings in edge-weighted large random graphs rely fundamentally on the assumption that the weights are atomless, which ensures that the maximal weight matching is unique. This excludes de facto maximal size matchings that correspond to equal edge-weights. In this work, we overcome this difficulty by assigning i.i.d.~atomless weights to edges and choosing the maximal size matching that maximises the weight. We call these doubly constrained matchings \emph{optimal matchings}. The natural generalisation of optimal matchings for infinite unimodular random graphs are unimodular matchings of maximal density at the root that maximise the expected weight at the root when it is matched. For unimodular Bienaym\'e-Galton-Watson (UBGW) trees and for a broad class of weight distributions, we show existence and uniqueness in law of such matchings. We also prove that if a sequence of finite random weighted graphs converges locally to an UBGW tree with i.i.d.~weights, then there exists a sequence of matchings on the finite graphs that converges locally to the optimal matching on the limiting tree. Finally, we identify a regime, depending only on the offspring distribution of the limiting tree, in which correlations between edge states in the optimal matching decay exponentially with their graph distance. In this regime, we strengthen the previous convergence to the convergence of optimal matchings of the finite graphs. As a by-product, we can explicitly compute the asymptotic densities of edges that belong to all maximal-density matchings, and of edges that belong to none.