Entropy-complexity analysis in some globally-coupled systems

Antoine M. Chrisment; Marie Christine Firpo

doi:10.1016/j.physa.2016.05.009

Entropy-complexity analysis in some globally-coupled systems

Antoine M. Chrisment, Marie Christine Firpo

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

Abstract

Globally-coupled N-body systems are well known to possess an intricate dynamics. When N is large, collective effects may drastically lower the effective dimension of the dynamics breaking the conditions on ergodicity necessary for the applicability of statistical mechanics. These problems are here illustrated and discussed through an entropy-complexity analysis of the repulsive Hamiltonian mean-field model. Using a Poincaré section of the mean-field time series provides a natural sampling time in the entropy-complexity treatment. This approach is shown to single-out the out-of-equilibrium dynamical features and to uncover a transition of the system dynamics from low-energy non-Boltzmann quasi-stationary states to high-energy stochastic-like behavior.

Original language	English
Pages (from-to)	162-173
Number of pages	12
Journal	Physica A: Statistical Mechanics and its Applications
Volume	460
DOIs	https://doi.org/10.1016/j.physa.2016.05.009
Publication status	Published - 15 Oct 2016

Keywords

Deterministic chaos
Long-range interacting systems
Mean-field models
Quasi-stationary states
Stochasticity

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10.1016/j.physa.2016.05.009

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title = "Entropy-complexity analysis in some globally-coupled systems",

abstract = "Globally-coupled N-body systems are well known to possess an intricate dynamics. When N is large, collective effects may drastically lower the effective dimension of the dynamics breaking the conditions on ergodicity necessary for the applicability of statistical mechanics. These problems are here illustrated and discussed through an entropy-complexity analysis of the repulsive Hamiltonian mean-field model. Using a Poincar{\'e} section of the mean-field time series provides a natural sampling time in the entropy-complexity treatment. This approach is shown to single-out the out-of-equilibrium dynamical features and to uncover a transition of the system dynamics from low-energy non-Boltzmann quasi-stationary states to high-energy stochastic-like behavior.",

keywords = "Deterministic chaos, Long-range interacting systems, Mean-field models, Quasi-stationary states, Stochasticity",

author = "Chrisment, \{Antoine M.\} and Firpo, \{Marie Christine\}",

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doi = "10.1016/j.physa.2016.05.009",

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T1 - Entropy-complexity analysis in some globally-coupled systems

AU - Chrisment, Antoine M.

AU - Firpo, Marie Christine

PY - 2016/10/15

Y1 - 2016/10/15

N2 - Globally-coupled N-body systems are well known to possess an intricate dynamics. When N is large, collective effects may drastically lower the effective dimension of the dynamics breaking the conditions on ergodicity necessary for the applicability of statistical mechanics. These problems are here illustrated and discussed through an entropy-complexity analysis of the repulsive Hamiltonian mean-field model. Using a Poincaré section of the mean-field time series provides a natural sampling time in the entropy-complexity treatment. This approach is shown to single-out the out-of-equilibrium dynamical features and to uncover a transition of the system dynamics from low-energy non-Boltzmann quasi-stationary states to high-energy stochastic-like behavior.

AB - Globally-coupled N-body systems are well known to possess an intricate dynamics. When N is large, collective effects may drastically lower the effective dimension of the dynamics breaking the conditions on ergodicity necessary for the applicability of statistical mechanics. These problems are here illustrated and discussed through an entropy-complexity analysis of the repulsive Hamiltonian mean-field model. Using a Poincaré section of the mean-field time series provides a natural sampling time in the entropy-complexity treatment. This approach is shown to single-out the out-of-equilibrium dynamical features and to uncover a transition of the system dynamics from low-energy non-Boltzmann quasi-stationary states to high-energy stochastic-like behavior.

KW - Deterministic chaos

KW - Long-range interacting systems

KW - Mean-field models

KW - Quasi-stationary states

KW - Stochasticity

U2 - 10.1016/j.physa.2016.05.009

DO - 10.1016/j.physa.2016.05.009

M3 - Article

AN - SCOPUS:84970963273

SN - 0378-4371

VL - 460

SP - 162

EP - 173

JO - Physica A: Statistical Mechanics and its Applications

JF - Physica A: Statistical Mechanics and its Applications

ER -

Entropy-complexity analysis in some globally-coupled systems

Abstract

Keywords

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