Universality of rank-ordering distributions in the arts and sciences

Searching for generic behaviors has been one of the driving forces leading to a deep understanding and classification of diverse phenomena. Usually a starting point is the development of a phenomenology based on observations. Such is the case for power law distributions encountered in a wealth of si...

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Bibliographic Details
Published in:PloS one 2009-03, Vol.4 (3), p.e4791-e4791
Main Authors: Martínez-Mekler, Gustavo, Alvarez Martínez, Roberto, Beltrán del Río, Manuel, Mansilla, Ricardo, Miramontes, Pedro, Cocho, Germinal
Format: Article
Language:English
Subjects:
Algorithms
Analysis
Animals
Bibliometrics
Biodiversity
Cats
Codon
Computational Biology/Systems Biology
Dictionaries
E coli
Ecosystems
Escherichia coli
Geophysics
Humans
Impact factors
Laws, regulations and rules
Mathematics/Nonlinear Dynamics
Mathematics/Statistics
Music
Mutation
Natural Science Disciplines - statistics & numerical data
Nature
Neurosciences
Phenomenology
Physics
Physics/Interdisciplinary Physics
Plants
Power law
Probabilistic models
Probability distribution functions
Random variables
Social networks
Social organization
Statistical analysis
Statistical Distributions
Zipf's Law
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Summary:Searching for generic behaviors has been one of the driving forces leading to a deep understanding and classification of diverse phenomena. Usually a starting point is the development of a phenomenology based on observations. Such is the case for power law distributions encountered in a wealth of situations coming from physics, geophysics, biology, lexicography as well as social and financial networks. This finding is however restricted to a range of values outside of which finite size corrections are often invoked. Here we uncover a universal behavior of the way in which elements of a system are distributed according to their rank with respect to a given property, valid for the full range of values, regardless of whether or not a power law has previously been suggested. We propose a two parameter functional form for these rank-ordered distributions that gives excellent fits to an impressive amount of very diverse phenomena, coming from the arts, social and natural sciences. It is a discrete version of a generalized beta distribution, given by f(r) = A(N+1-r)(b)/r(a), where r is the rank, N its maximum value, A the normalization constant and (a, b) two fitting exponents. Prompted by our genetic sequence observations we present a growth probabilistic model incorporating mutation-duplication features that generates data complying with this distribution. The competition between permanence and change appears to be a relevant, though not necessary feature. Additionally, our observations mainly of social phenomena suggest that a multifactorial quality resulting from the convergence of several heterogeneous underlying processes is an important feature. We also explore the significance of the distribution parameters and their classifying potential. The ubiquity of our findings suggests that there must be a fundamental underlying explanation, most probably of a statistical nature, such as an appropriate central limit theorem formulation.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0004791