异质集体运动的个体测量

Andrei V. Zvezdin, Mitchell Welch, T. Schaerf
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引用次数: 0

摘要

昆虫群、鱼群和鸟群都是我们熟悉的日常集体运动的例子。尽管这些群体由截然不同的个体组成,但它们是如何同步的,这是一个令人着迷的问题。集体运动的经典模型假设同质个体在局部相互作用,产生群体水平的模式,然后通过汇总测量进行分类,通常称为顺序参数,例如群体的对齐或旋转程度。实证和理论研究都指出了个体差异(异质性)对集体行为的重要性。为了研究个体差异如何驱动集体运动,我们需要了解不同的成员如何促成出现的集体运动现象。为此,我们需要将焦点从群体转移到个人,并引入新的措施或将群体层面的顺序参数推广到个人层面。我们研究了以下方法来研究异质群体:1)个体状态(循环、定向、随机或复合轨迹)通过对个体轨迹应用对准和铣削顺序参数得到;2)个体流动性,定义为在固定p周期内相对于群质心的移动量;3) d二切分被定义为焦点个体与其邻居之间的距离的最小CAL差,以及4)个体看到或与之相互作用的邻居的数量。利用典型的区域(斥力、取向、吸引力)等速自推进粒子模型,我们将上述措施应用于由两种不同行为类型组成的同质和异质群体,以研究多稳定性、自排序和状态转换的关键问题。我们在迟滞的背景下研究了这些问题,因为迟滞是多稳定性的自然度量,也是集体运动系统表现出集体记忆形式的趋势,其中当前出现的群体行为受到系统近期历史的影响。我们通过保留一个子群来产生异质组的滞后回路
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Individual measures for heterogeneous collective motion
: Insect swarms, fish schools and bird flocks are familiar everyday examples of collective motion. How these groups synchronize despite being made up of vastly different individuals is a fascinating question. Classical modeling of collective motion assumes homogenous individuals interacting locally to produce group-level patterns which are then classified via summary measures, usually called order parameters, such as the degree of alignment or rotation of the group. Empirical and theoretical work have pointed to the importance of individual differences (heterogeneity) driving collective behaviour. To investigate how individual differences drive collective motion, we need to understand how the different members contribute to the emergent collective motion phenomena. For this we need to shift the focus from the group to the individual and either introduce new measures or generalize the group level order parameters to the individual level. We investigated the following measures for studying heterogeneous groups: 1) the individual state (cycling, directed, random or composite trajectories) derived from applying alignment and milling order parameters to an individual’s track; 2) the individual fluidity defined as the amount of movement relative to the group centroid over a fixed p eriod; 3 ) t he d ichotomy d efined as th e lo cal di fference in he ading be tween a focal individual and its neighbours and 4) the number of neighbours an individual sees or interacts with. Using a canonical zonal (repulsion, orientation, attraction) constant speed self propelled particle model we applied the above measures to homogenous and heterogeneous groups comprised of two distinct behavioural class types to investigate key questions of multi-stability, self-sorting and state transitions. We investigated these questions in the context of hysteresis as it is a natural measure of multi-stability and the tendency of a collective motion system to exhibit a form of collective memory where current emergent group behaviour is influenced by the recent history of the system. We produced hysteresis loops for heterogeneous groups by keeping one subgroup
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