How Do Cultural Classes Emerge from Assimilation and Distinction? An Extension of the Cucker-Smale Flocking Model

Kang, Jeong‐han; Ha, Seung‐Yeal; Kang, Kyungkeun; Jeong, Eun-Hee

doi:10.1080/0022250x.2011.629063

Cited by 19 publications

(10 citation statements)

References 29 publications

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“…The C-S model with weight ψ cs was introduced in 2007 by Cucker and Smale in [12] and was in some sense based on the paper by Viscek [36] from 1995 in which a model of flocking was introduced, such that each particle adjusted it's velocity with respect to the avarage velocity of it's neighbors. Since then existence, uniqueness, asymptotics and stability for alignment models similar to C-S (both in continuous and discrete cases) were extensively studied, both from physical and biological point of view [13] - [16], [30], [33] - [35] and from more theoretical point of view [1,2], [4] - [11], [17] - [25], [29,31]. A nice and thorough study of the C-S flocking model with a bounded communication weight can be found in [28], where the interplay between dicrete and continuous model is studied with measure valued solutions of the Vlasov type equation (1.3) or in [26], where the authors present a new, simple aproach to the problem of existence and asymptotics.…”

Section: Smooth Communication Weightmentioning

confidence: 99%

Existence of piecewise weak solutions of a discrete Cucker–Smale's flocking model with a singular communication weight

Peszek

2014

Journal of Differential Equations

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Section: Smooth Communication Weightmentioning

confidence: 99%

Existence of piecewise weak solutions of a discrete Cucker–Smale's flocking model with a singular communication weight

Peszek

2014

Journal of Differential Equations

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“…In particular, an unexpected application was proposed by Perea, Gómez and Elosegui [27] who suggested to use the C-S flocking mechanism [11] in the formation of spacecrafts for the Darwin space mission. Recently, the C-S flocking mechanism was also applied to the modeling of emergent cultural classes in sociology and the stochastic volatility in financial markets [1], [15], [21].…”

Section: Introductionmentioning

confidence: 99%

On the Cucker-Smale flocking with alternating leaders

2015

Quart. Appl. Math.

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We study the emergent flocking behavior in a group of Cucker-Smale flocking agents under rooted leadership with alternating leaders. It is well known that the network topology regulates the emergent behaviors of flocks. All existing results on the Cucker-Smale model with leader-follower topologies assume a fixed leader during temporal evolution process. The rooted leadership is the most general topology taking a leadership. Motivated by collective behaviors observed in the flocks of birds, swarming fishes and potential engineering applications, we consider the rooted leadership with alternating leaders; that is, at each time slice there is a leader but it can be switched among the agents from time to time. We will provide several sufficient conditions leading to the asymptotic flocking among the Cucker-Smale agents under rooted leadership with alternating leaders.

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“…4 This emergence of cultural diversity as an outcome of local consenses has been recently simulated using several agent-based models to capture more nuanced collective motions of multi-agent systems. 4,24,35 Among them, our interest lies in the first-order Cucker-Smale-type model 33 introduced for the emergence of cultural classes in human society due to assimilations and distinctions between agents. Other agent-based models for cultural diversity specify the rules of interactions between agents using verbal statements rather than mathematical equations and do not admit analytic proofs as opposed to simulation results.…”

Section: Introductionmentioning

confidence: 99%

“…33 to study the emergence of cultural classes, when both assimilation and distinction between agents are present in the dynamics, and the formation of clustering was numerically observed. Although the original Cucker-Smale model and its variants (see Refs.…”

Section: Introductionmentioning

confidence: 99%

Emergence of Multi-Cluster Configurations From Attractive and Repulsive Interactions

Jeong

Kang

et al. 2012

Math. Models Methods Appl. Sci.

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We discuss a first-order Cucker-Smale-type consensus model with attractive and repulsive interactions and present upper and lower bound estimates on the number of asymptotic point-clusters depending on the relative ranges of interactions and coupling strength. When the number of agents approaches infinity, we introduce a scalar conservation law with a non-local flux for a macroscopic description. We show that the corresponding conservation law admits a classical solution for sufficiently smooth initial data, which illustrates the shock avoidance effect due to the non-locality of the interactions. We also study the dynamics of special Dirac-Comb-type solutions consisting of two and three point-clusters.There have been many previous literature on the opinion formation. 2,7,14,15,21,22,26,32,36,40,42,44 However most of these models deal with symmetric interactions or only attractive interactions. For the symmetric and all-to-all interactions c(j, i) = c(i, j), the first moment of ζ i is conserved along the dynamics of (1.1), hence the standard global analysis tools, e.g. energy or Lyapunov estimates in Refs. 18, 19 and 29, can be employed to establish the asymptotic emergence of synchronized opinion groups, whereas for the non-symmetric and repulsive interactions, the first moment of ζ i is not conserved, hence the aforementioned standard tools are not applicable. We instead estimate the difference L i := ζ i+1 − ζ i directly using the system (1.1) and study the asymptotic behavior of L i .The novelty of this paper is threefold. First, we consider non-symmetric communication weights which simultaneously include the positive coupling (assimilation) and negative coupling (repulsion or distinction). Most available literature [14][15][16]18,19,27,[29][30][31]37 on the consensus problem deals with symmetric coupling such as attractive mean-field coupling, finite-range interaction coupling, and the nearest neighbor coupling such as toda lattice, etc. However when the communication weights are not symmetric, the first moment of information under consideration is no longer conserved, which greatly complicates the rigorous analysis. As far as we know, there is no rigorous mathematical results for non-symmetric coupling. We address this non-symmetric difficulty via detailed estimate of the evolution of immediate distance between neighbors.Secondly, as was mentioned at the opening of this paper, global diversity due to local synchronization recently attracted attention in various disciplines, and we aim to provide a succinct quantification of its mechanisms. We first formalize the non-symmetric communication weight (1.3) using the range and relative strengths between attractive and repulsive interactions and then provide quantitative estimates on the number of asymptotic synchronized clusters (see Definition 4.1). From a mathematical viewpoint, there has been no systematic approach to analyze flocking models with attractive and repulsive interactions. Most existing analytical results 18,19,29,31 deal with mean-field coupling. ...

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How Do Cultural Classes Emerge from Assimilation and Distinction? An Extension of the Cucker-Smale Flocking Model

Cited by 19 publications

References 29 publications

Existence of piecewise weak solutions of a discrete Cucker–Smale's flocking model with a singular communication weight

Existence of piecewise weak solutions of a discrete Cucker–Smale's flocking model with a singular communication weight

On the Cucker-Smale flocking with alternating leaders

Emergence of Multi-Cluster Configurations From Attractive and Repulsive Interactions

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