Entangled time in flocking: Multi-time-scale interaction reveals emergence of inherent noise

Entangled time in flocking: Multi-time-scale interaction reveals emergence of inherent noise

Collective behaviors that seem highly ordered and result in collective alignment, such as schooling by fish and flocking by birds, arise from seamless shuffling (such as super-diffusion) and bustling inside groups (such as Lévy walks). However, such noisy behavior inside groups appears to preclude t...

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Veröffentlicht in:PloS one 2018-04, Vol.13 (4), p.e0195988-e0195988
Hauptverfasser: Niizato, Takayuki, Murakami, Hisashi
Format: Artikel
Sprache:eng
Schlagworte:
Alignment
Analysis
Animal behavior
Biology and Life Sciences
Birds
Brownian motion
Brownian movements
Cognitive ability
Computer and Information Sciences
Diffusion
Entropy
Flocking behavior
Foraging behavior
Mathematical models
Maximum entropy
Medicine and Health Sciences
Noise
Physical Sciences
Physiological aspects
Research and Analysis Methods
Statistical modelling
Statistical models
Swarming
Three dimensional models
Two dimensional models
Zebrafish
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Murakami, Hisashi
description Collective behaviors that seem highly ordered and result in collective alignment, such as schooling by fish and flocking by birds, arise from seamless shuffling (such as super-diffusion) and bustling inside groups (such as Lévy walks). However, such noisy behavior inside groups appears to preclude the collective behavior: intuitively, we expect that noisy behavior would lead to the group being destabilized and broken into small sub groups, and high alignment seems to preclude shuffling of neighbors. Although statistical modeling approaches with extrinsic noise, such as the maximum entropy approach, have provided some reasonable descriptions, they ignore the cognitive perspective of the individuals. In this paper, we try to explain how the group tendency, that is, high alignment, and highly noisy individual behavior can coexist in a single framework. The key aspect of our approach is multi-time-scale interaction emerging from the existence of an interaction radius that reflects short-term and long-term predictions. This multi-time-scale interaction is a natural extension of the attraction and alignment concept in many flocking models. When we apply this method in a two-dimensional model, various flocking behaviors, such as swarming, milling, and schooling, emerge. The approach also explains the appearance of super-diffusion, the Lévy walk in groups, and local equilibria. At the end of this paper, we discuss future developments, including extending our model to three dimensions.
doi_str_mv 10.1371/journal.pone.0195988
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However, such noisy behavior inside groups appears to preclude the collective behavior: intuitively, we expect that noisy behavior would lead to the group being destabilized and broken into small sub groups, and high alignment seems to preclude shuffling of neighbors. Although statistical modeling approaches with extrinsic noise, such as the maximum entropy approach, have provided some reasonable descriptions, they ignore the cognitive perspective of the individuals. In this paper, we try to explain how the group tendency, that is, high alignment, and highly noisy individual behavior can coexist in a single framework. The key aspect of our approach is multi-time-scale interaction emerging from the existence of an interaction radius that reflects short-term and long-term predictions. This multi-time-scale interaction is a natural extension of the attraction and alignment concept in many flocking models. 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subjects Alignment
Analysis
Animal behavior
Biology and Life Sciences
Birds
Brownian motion
Brownian movements
Cognitive ability
Computer and Information Sciences
Diffusion
Entropy
Flocking behavior
Foraging behavior
Mathematical models
Maximum entropy
Medicine and Health Sciences
Noise
Physical Sciences
Physiological aspects
Research and Analysis Methods
Statistical modelling
Statistical models
Swarming
Three dimensional models
Two dimensional models
Zebrafish
title Entangled time in flocking: Multi-time-scale interaction reveals emergence of inherent noise
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