Exponential Distribution for the Occurrence of Rare Patterns in Gibbsian Random Fields

M. Abadi; J. R. Chazottes; F. Redig; E. Verbitskiy

doi:10.1007/s00220-004-1041-7

Exponential Distribution for the Occurrence of Rare Patterns in Gibbsian Random Fields

M. Abadi
, J. R. Chazottes
, F. Redig
, E. Verbitskiy

Research output: Contribution to journal › Article › peer-review

Abstract

We study the distribution of the occurrence of rare patterns in sufficiently mixing Gibbs random fields on the lattice ℤ^d, d ≥ 2. A typical example is the high temperature Ising model. This distribution is shown to converge to an exponential law as the size of the pattern diverges. Our analysis not only provides this convergence but also establishes a precise estimate of the distance between the exponential law and the distribution of the occurrence of finite patterns. A similar result holds for the repetition of a rare pattern. We apply these results to the fluctuation properties of occurrence and repetition of patterns: We prove a central limit theorem and a large deviation principle.

Original language	English
Pages (from-to)	269-294
Number of pages	26
Journal	Communications in Mathematical Physics
Volume	246
Issue number	2
DOIs	https://doi.org/10.1007/s00220-004-1041-7
Publication status	Published - 1 Apr 2004

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abstract = "We study the distribution of the occurrence of rare patterns in sufficiently mixing Gibbs random fields on the lattice ℤd, d ≥ 2. A typical example is the high temperature Ising model. This distribution is shown to converge to an exponential law as the size of the pattern diverges. Our analysis not only provides this convergence but also establishes a precise estimate of the distance between the exponential law and the distribution of the occurrence of finite patterns. A similar result holds for the repetition of a rare pattern. We apply these results to the fluctuation properties of occurrence and repetition of patterns: We prove a central limit theorem and a large deviation principle.",

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AU - Abadi, M.

AU - Chazottes, J. R.

AU - Redig, F.

AU - Verbitskiy, E.

PY - 2004/4/1

Y1 - 2004/4/1

N2 - We study the distribution of the occurrence of rare patterns in sufficiently mixing Gibbs random fields on the lattice ℤd, d ≥ 2. A typical example is the high temperature Ising model. This distribution is shown to converge to an exponential law as the size of the pattern diverges. Our analysis not only provides this convergence but also establishes a precise estimate of the distance between the exponential law and the distribution of the occurrence of finite patterns. A similar result holds for the repetition of a rare pattern. We apply these results to the fluctuation properties of occurrence and repetition of patterns: We prove a central limit theorem and a large deviation principle.

AB - We study the distribution of the occurrence of rare patterns in sufficiently mixing Gibbs random fields on the lattice ℤd, d ≥ 2. A typical example is the high temperature Ising model. This distribution is shown to converge to an exponential law as the size of the pattern diverges. Our analysis not only provides this convergence but also establishes a precise estimate of the distance between the exponential law and the distribution of the occurrence of finite patterns. A similar result holds for the repetition of a rare pattern. We apply these results to the fluctuation properties of occurrence and repetition of patterns: We prove a central limit theorem and a large deviation principle.

UR - https://www.scopus.com/pages/publications/2142684462

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SP - 269

EP - 294

JO - Communications in Mathematical Physics

JF - Communications in Mathematical Physics

IS - 2

ER -

Exponential Distribution for the Occurrence of Rare Patterns in Gibbsian Random Fields

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