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Main Author: Zhou, Datong
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.13587
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author Zhou, Datong
author_facet Zhou, Datong
contents We develop a mean-field theory for large, non-exchangeable particle (agent) systems where the states and interaction weights co-evolve in a coupled system of SDEs. A first main result is the establishment of the propagation of dissociatedness, a conceptual generalization of the classical propagation of chaos that accommodates the intrinsic local correlations between particles and their weights. The limiting McKean-Vlasov process is characterized by an Aldous-Hoover representation on a filtered probability space, beyond the standard one-particle law (or a family thereof). Paralleling the classical equivalence between propagation of chaos and the convergence of empirical measures to the one-particle law, we show that the propagation of dissociatedness corresponds to the convergence of the empirical structure under a distance unifying the Wasserstein distance for particles and the cut distance for weights. This quantitative stability is grounded in an adaptation of the sampling lemma from dense graph theory, analogous to the classical concentration results for empirical measures in the Wasserstein distance.
format Preprint
id arxiv_https___arxiv_org_abs_2506_13587
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Non-exchangeable mean-field theory for adaptive weights: propagation of dissociatedness and graphon sampling lemma
Zhou, Datong
Probability
Analysis of PDEs
Combinatorics
60K35, 60H10, 05C22, 05C80, 62D05, 49Q22, 60G57
We develop a mean-field theory for large, non-exchangeable particle (agent) systems where the states and interaction weights co-evolve in a coupled system of SDEs. A first main result is the establishment of the propagation of dissociatedness, a conceptual generalization of the classical propagation of chaos that accommodates the intrinsic local correlations between particles and their weights. The limiting McKean-Vlasov process is characterized by an Aldous-Hoover representation on a filtered probability space, beyond the standard one-particle law (or a family thereof). Paralleling the classical equivalence between propagation of chaos and the convergence of empirical measures to the one-particle law, we show that the propagation of dissociatedness corresponds to the convergence of the empirical structure under a distance unifying the Wasserstein distance for particles and the cut distance for weights. This quantitative stability is grounded in an adaptation of the sampling lemma from dense graph theory, analogous to the classical concentration results for empirical measures in the Wasserstein distance.
title Non-exchangeable mean-field theory for adaptive weights: propagation of dissociatedness and graphon sampling lemma
topic Probability
Analysis of PDEs
Combinatorics
60K35, 60H10, 05C22, 05C80, 62D05, 49Q22, 60G57
url https://arxiv.org/abs/2506.13587