Mathias Casiulis, Eden Arbel, Yoav Lahini, Stefano Martiniani, Naomi Oppenheimer, Matan Yah Ben Zion
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A geometric condition for robot-swarm cohesion and cluster-flock transition
We present a geometric design rule for size-controlled clustering of
self-propelled particles. Active particles that tend to rotate under an
external force have an intrinsic signed-parameter with units of curvature,
which we term curvity, derivable from first principles. Robot experiments and
numerical simulations show that the properties of the individual robot alone --
radius and curvity -- control pair-cohesion in a binary system as well as the
stability of flocking and clustering in a swarm. Our results have applications
in meta-materials and embodied decentralized control.
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