Navigating the swarm: Deep neural networks command emergent behaviours

Dongjo Kim, Jeongsu Lee, Ho-Young Kim
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Abstract

Interacting individuals in complex systems often give rise to coherent motion exhibiting coordinated global structures. Such phenomena are ubiquitously observed in nature, from cell migration, bacterial swarms, animal and insect groups, and even human societies. Primary mechanisms responsible for the emergence of collective behavior have been extensively identified, including local alignments based on average or relative velocity, non-local pairwise repulsive-attractive interactions such as distance-based potentials, interplay between local and non-local interactions, and cognitive-based inhomogeneous interactions. However, discovering how to adapt these mechanisms to modulate emergent behaviours remains elusive. Here, we demonstrate that it is possible to generate coordinated structures in collective behavior at desired moments with intended global patterns by fine-tuning an inter-agent interaction rule. Our strategy employs deep neural networks, obeying the laws of dynamics, to find interaction rules that command desired collective structures. The decomposition of interaction rules into distancing and aligning forces, expressed by polynomial series, facilitates the training of neural networks to propose desired interaction models. Presented examples include altering the mean radius and size of clusters in vortical swarms, timing of transitions from random to ordered states, and continuously shifting between typical modes of collective motions. This strategy can even be leveraged to superimpose collective modes, resulting in hitherto unexplored but highly practical hybrid collective patterns, such as protective security formations. Our findings reveal innovative strategies for creating and controlling collective motion, paving the way for new applications in robotic swarm operations, active matter organisation, and for the uncovering of obscure interaction rules in biological systems.
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为蜂群导航深度神经网络指挥突发行为
复杂系统中相互作用的个体往往会产生连贯的运动,表现出协调的整体结构。这种现象在自然界中随处可见,从细胞迁移、细菌群、动物和昆虫群体,甚至人类社会。导致集体行为产生的主要机制已被广泛确认,包括基于平均速度或相对速度的局部排列、非局部成对冲动-吸引相互作用(如基于距离的电位)、局部和非局部相互作用之间的相互作用以及基于认知的非均质相互作用。然而,如何调整这些机制以调节萌发行为仍然是一个难题。在这里,我们证明了通过微调代理间的交互规则,有可能在所需的时刻产生具有预期全局模式的集体行为协调结构。我们的策略是利用服从动力学规律的深度神经网络,找到能够指挥所需集体结构的交互规则。将交互规则分解为由多项式序列表示的距离力和对齐力,有助于训练神经网络,从而提出所需的交互模型。展示的例子包括改变涡旋虫群的主题半径和集群大小、从随机状态过渡到有序状态的时间,以及在典型的集体运动模式之间不断转换。这种策略甚至可以用来叠加集体模式,从而形成迄今为止尚未探索过但却非常实用的混合集体模式,例如保护性安全编队。我们的发现揭示了创造和控制集体运动的创新策略,为机器人蜂群操作、主动物质组织以及揭示生物系统中模糊的相互作用规则等新应用铺平了道路。
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