Collective dynamics of self-propelled particles with variable speed

Mishra, Sudhanshu; Tunstrøm, Kolbjørn; Couzin, Iain D.; Huepe, Cristián

doi:10.1103/physreve.86.011901

Cited by 80 publications

(88 citation statements)

References 45 publications

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“…This has been shown for instance by Gautrais et al [40], who detected a change in behavioural parameters with increasing density, leading to a disordered swimming once a critical density has been reached. It is worth noting that in that particular case, the individuals may change their behaviour relative to the density [91]. This additional coupling, namely the influence of the school as a whole on the behaviour of its constituent individuals, is a topic that we may carefully consider in future investigations.…”

Section: Determining Group Size Effects and Theirmentioning

confidence: 99%

“…the school) is highly polarized [60]. This critical change in global behaviour is obtained by varying the value of a behavioural parameter such as noise [60,90], blind angle size [65], speed [91], alignment tendency [62] or a 'strategy parameter' [92], which weighs a behavioural compromise between aligning with neighbours and reacting to their direction changes. The validity of this view finds some support in the experimental work of Becco et al [93] that showed that such transition from disorder to order can be obtained by increasing the density of Tilapia fish in a shallow water arena.…”

Section: Statistical Physics Of Collective Motionmentioning

confidence: 99%

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From behavioural analyses to models of collective motion in fish schools

et al. 2012

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Fish schooling is a phenomenon of long-lasting interest in ethology and ecology, widely spread across taxa and ecological contexts, and has attracted much interest from statistical physics and theoretical biology as a case of self-organized behaviour. One topic of intense interest is the search of specific behavioural mechanisms at stake at the individual level and from which the school properties emerges. This is fundamental for understanding how selective pressure acting at the individual level promotes adaptive properties of schools and in trying to disambiguate functional properties from non-adaptive epiphenomena. Decades of studies on collective motion by means of individual-based modelling have allowed a qualitative understanding of the self-organization processes leading to collective properties at school level, and provided an insight into the behavioural mechanisms that result in coordinated motion. Here, we emphasize a set of paradigmatic modelling assumptions whose validity remains unclear, both from a behavioural point of view and in terms of quantitative agreement between model outcome and empirical data. We advocate for a specific and biologically oriented re-examination of these assumptions through experimental-based behavioural analysis and modelling.

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Section: Determining Group Size Effects and Theirmentioning

confidence: 99%

Section: Statistical Physics Of Collective Motionmentioning

confidence: 99%

From behavioural analyses to models of collective motion in fish schools

et al. 2012

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“…In recent years, a variety of efforts have been devoted to modeling the dynamic properties of swarms [15][16][17][18][19][20][21][22][23][24][25][26][27]. In 1995, Vicsek et al proposed a particularly simple but rich model [28].…”

Section: Introductionmentioning

confidence: 99%

Promoting collective motion of self-propelled agents by distance-based influence

2014

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We propose a dynamic model for a system consisting of self-propelled agents in which the influence of an agent on another agent is weighted by geographical distance. A parameter α is introduced to adjust the influence: the smaller value of α means that the closer neighbors have stronger influence on the moving direction. We find that there exists an optimal value of α, leading to the highest degree of direction consensus. The value of optimal α increases as the system size increases, while it decreases as the absolute velocity, the sensing radius and the noise amplitude increase.

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“…However, active matters in biological and physical systems have been studied theoretically and experimentally [12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28]. The kinetics of active particles moving in periodic structures could exhibit peculiar behaviors.…”

Section: Introductionmentioning

confidence: 99%

Entropic Ratchet transport of interacting active Brownian particles

Zhong

2014

The Journal of Chemical Physics

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Directed transport of interacting active (self-propelled)Brownian particles is numerically investigated in confined geometries (entropic barriers). The self-propelled velocity can break thermodynamical equilibrium and induce the directed transport. It is found that the interaction between active particles can greatly affect the ratchet transport. For attractive particles, on increasing the interaction strength, the average velocity firstly decreases to its minima, then increases, and finally decreases to zero. For repulsive particles, when the interaction is very weak, there exists a critical interaction at which the average velocity is minimal, nearly tends to zero, however, for the strong interaction, the average velocity is independent of the interaction.

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Collective dynamics of self-propelled particles with variable speed

Cited by 80 publications

References 45 publications

From behavioural analyses to models of collective motion in fish schools

From behavioural analyses to models of collective motion in fish schools

Promoting collective motion of self-propelled agents by distance-based influence

Entropic Ratchet transport of interacting active Brownian particles

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