From Lévy to Brownian: a computational model based on biological fluctuation

Theoretical studies predict that Lévy walks maximizes the chance of encountering randomly distributed targets with a low density, but Brownian walks is favorable inside a patch of targets with high density. Recently, experimental data reports that some animals indeed show a Lévy and Brownian walk mo...

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Bibliographic Details
Published in:PloS one 2011-02, Vol.6 (2), p.e16168-e16168
Main Authors: Nurzaman, Surya G, Matsumoto, Yoshio, Nakamura, Yutaka, Shirai, Kazumichi, Koizumi, Satoshi, Ishiguro, Hiroshi
Format: Article
Language:English
Subjects:
Adaptation, Biological - physiology
Animal behavior
Animals
Bacteria
Behavior, Animal - physiology
Biological models (mathematics)
Biology
Chemotactic Factors - pharmacology
Computation
Computer applications
Computer Science
Computer Simulation
Density
E coli
Ecology
Ecosystem
Effect Modifier, Epidemiologic
Engineering schools
Environment
Escherichia coli
Escherichia coli - drug effects
Escherichia coli - physiology
Feeding Behavior - physiology
Food
Food Chain
Forage
Foraging behavior
Information processing
Mathematics
Models, Biological
Motility
Movement - drug effects
Movement - physiology
Noise
Physics
Plankton
Predatory Behavior - physiology
Robots
Simulation
Stochasticity
Variation
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Summary:Theoretical studies predict that Lévy walks maximizes the chance of encountering randomly distributed targets with a low density, but Brownian walks is favorable inside a patch of targets with high density. Recently, experimental data reports that some animals indeed show a Lévy and Brownian walk movement patterns when forage for foods in areas with low and high density. This paper presents a simple, Gaussian-noise utilizing computational model that can realize such behavior. We extend Lévy walks model of one of the simplest creature, Escherichia coli, based on biological fluctuation framework. We build a simulation of a simple, generic animal to observe whether Lévy or Brownian walks will be performed properly depends on the target density, and investigate the emergent behavior in a commonly faced patchy environment where the density alternates. Based on the model, animal behavior of choosing Lévy or Brownian walk movement patterns based on the target density is able to be generated, without changing the essence of the stochastic property in Escherichia coli physiological mechanism as explained by related researches. The emergent behavior and its benefits in a patchy environment are also discussed. The model provides a framework for further investigation on the role of internal noise in realizing adaptive and efficient foraging behavior.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0016168