Exponential or Power Law? How to Select a Stable Distribution of Probability in a Physical System

Exponential or Power Law? How to Select a Stable Distribution of Probability in a Physical System

A mapping of non-extensive statistical mechanics with non-additivity parameter q ≠ 1 into Gibbs’ statistical mechanics exists (E. Vives, A. Planes, PRL 88 2, 020601 (2002)) which allows generalization to q ≠ 1 both of Einstein’s formula for fluctuations and of the ’general evolution...

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Main Author: Andrea Di Vita
Format: Article
Language:English
Published: MDPI AG 2017-11-01
Series:Proceedings
Subjects:
non-extensive thermodynamics
non-equilibrium thermodynamics
probability distribution
power laws
nonlinear Fokker-Planck equation
discrete maps
Online Access:https://www.mdpi.com/2504-3900/2/4/156
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spelling doaj-b4910b9f3ab240609552833c2d92849e2020-11-25T02:26:19ZengMDPI AGProceedings2504-39002017-11-012415610.3390/ecea-4-05009ecea-4-05009Exponential or Power Law? How to Select a Stable Distribution of Probability in a Physical SystemAndrea Di Vita0D.I.C.C.A., Università di Genova, Via Montallegro 1, 16145 Genova, ItalyA mapping of non-extensive statistical mechanics with non-additivity parameter q ≠ 1 into Gibbs’ statistical mechanics exists (E. Vives, A. Planes, PRL 88 2, 020601 (2002)) which allows generalization to q ≠ 1 both of Einstein’s formula for fluctuations and of the ’general evolution criterion’ (P. Glansdorff, I. Prigogine, Physica 30 351 (1964)), an inequality involving the time derivatives of thermodynamical quantities. Unified thermodynamic description of relaxation to stable states with either Boltzmann ( q = 1 ) or power-law ( q ≠ 1 ) distribution of probabilities of microstates follows. If a 1D (possibly nonlinear) Fokker-Planck equation describes relaxation, then generalized Einstein’s formula predicts whether the relaxed state exhibits a Boltzmann or a power law distribution function. If this Fokker-Planck equation is associated to the stochastic differential equation obtained in the continuous limit from a 1D, autonomous, discrete, noise-affected map, then we may ascertain if a a relaxed state follows a power-law statistics—and with which exponent—by looking at both map dynamics and noise level, without assumptions concerning the (additive or multiplicative) nature of the noise and without numerical computation of the orbits. Results agree with the simulations (J. R. Sánchez, R. Lopez-Ruiz, EPJ 143.1 (2007): 241–243) of relaxation leading to a Pareto-like distribution function.https://www.mdpi.com/2504-3900/2/4/156non-extensive thermodynamicsnon-equilibrium thermodynamicsprobability distributionpower lawsnonlinear Fokker-Planck equationdiscrete maps
collection DOAJ
language English
format Article
sources DOAJ
author Andrea Di Vita
spellingShingle Andrea Di Vita
Exponential or Power Law? How to Select a Stable Distribution of Probability in a Physical System
Proceedings
non-extensive thermodynamics
non-equilibrium thermodynamics
probability distribution
power laws
nonlinear Fokker-Planck equation
discrete maps
author_facet Andrea Di Vita
author_sort Andrea Di Vita
title Exponential or Power Law? How to Select a Stable Distribution of Probability in a Physical System
title_short Exponential or Power Law? How to Select a Stable Distribution of Probability in a Physical System
title_full Exponential or Power Law? How to Select a Stable Distribution of Probability in a Physical System
title_fullStr Exponential or Power Law? How to Select a Stable Distribution of Probability in a Physical System
title_full_unstemmed Exponential or Power Law? How to Select a Stable Distribution of Probability in a Physical System
title_sort exponential or power law? how to select a stable distribution of probability in a physical system
publisher MDPI AG
series Proceedings
issn 2504-3900
publishDate 2017-11-01
description A mapping of non-extensive statistical mechanics with non-additivity parameter q ≠ 1 into Gibbs’ statistical mechanics exists (E. Vives, A. Planes, PRL 88 2, 020601 (2002)) which allows generalization to q ≠ 1 both of Einstein’s formula for fluctuations and of the ’general evolution criterion’ (P. Glansdorff, I. Prigogine, Physica 30 351 (1964)), an inequality involving the time derivatives of thermodynamical quantities. Unified thermodynamic description of relaxation to stable states with either Boltzmann ( q = 1 ) or power-law ( q ≠ 1 ) distribution of probabilities of microstates follows. If a 1D (possibly nonlinear) Fokker-Planck equation describes relaxation, then generalized Einstein’s formula predicts whether the relaxed state exhibits a Boltzmann or a power law distribution function. If this Fokker-Planck equation is associated to the stochastic differential equation obtained in the continuous limit from a 1D, autonomous, discrete, noise-affected map, then we may ascertain if a a relaxed state follows a power-law statistics—and with which exponent—by looking at both map dynamics and noise level, without assumptions concerning the (additive or multiplicative) nature of the noise and without numerical computation of the orbits. Results agree with the simulations (J. R. Sánchez, R. Lopez-Ruiz, EPJ 143.1 (2007): 241–243) of relaxation leading to a Pareto-like distribution function.
topic non-extensive thermodynamics
non-equilibrium thermodynamics
probability distribution
power laws
nonlinear Fokker-Planck equation
discrete maps
url https://www.mdpi.com/2504-3900/2/4/156
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