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Autori principali: Caputo, Pietro, Chen, Zongchen, Parisi, Daniel
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2503.19419
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author Caputo, Pietro
Chen, Zongchen
Parisi, Daniel
author_facet Caputo, Pietro
Chen, Zongchen
Parisi, Daniel
contents We derive entropy factorization estimates for spin systems using the stochastic localization approach proposed by Eldan and Chen-Eldan, which, in this context, is equivalent to the renormalization group approach developed independently by Bauerschmidt, Bodineau, and Dagallier. The method provides approximate Shearer-type inequalities for the corresponding Gibbs measure at sufficiently high temperature, without restrictions on the degree of the underlying graph. For Ising systems, these are shown to hold up to the critical tree-uniqueness threshold, including polynomial bounds at the critical point, with optimal $O(\sqrt n)$ constants for the Curie-Weiss model at criticality. In turn, these estimates imply tight mixing time bounds for arbitrary block dynamics or Gibbs samplers, improving over existing results. Moreover, we establish new tensorization statements for the Shearer inequality asserting that if a system consists of weakly interacting but otherwise arbitrary components, each of which satisfies an approximate Shearer inequality, then the whole system also satisfies such an estimate.
format Preprint
id arxiv_https___arxiv_org_abs_2503_19419
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Factorizations of relative entropy using stochastic localization
Caputo, Pietro
Chen, Zongchen
Parisi, Daniel
Probability
Information Theory
Functional Analysis
We derive entropy factorization estimates for spin systems using the stochastic localization approach proposed by Eldan and Chen-Eldan, which, in this context, is equivalent to the renormalization group approach developed independently by Bauerschmidt, Bodineau, and Dagallier. The method provides approximate Shearer-type inequalities for the corresponding Gibbs measure at sufficiently high temperature, without restrictions on the degree of the underlying graph. For Ising systems, these are shown to hold up to the critical tree-uniqueness threshold, including polynomial bounds at the critical point, with optimal $O(\sqrt n)$ constants for the Curie-Weiss model at criticality. In turn, these estimates imply tight mixing time bounds for arbitrary block dynamics or Gibbs samplers, improving over existing results. Moreover, we establish new tensorization statements for the Shearer inequality asserting that if a system consists of weakly interacting but otherwise arbitrary components, each of which satisfies an approximate Shearer inequality, then the whole system also satisfies such an estimate.
title Factorizations of relative entropy using stochastic localization
topic Probability
Information Theory
Functional Analysis
url https://arxiv.org/abs/2503.19419