Emergent Field-Driven Robot Swarm States

We present an ecology-inspired form of active matter consisting of a robot swarm. Each robot moves over a planar dynamic resource environment represented by a large light-emitting diode array in search of maximum light intensity; the robots deplete (dim) locally by their presence the local light intensity and seek maximum light intensity. Their movement is directed along the steepest local light intensity gradient; we call this emergent symmetry breaking motion field drive. We show there emerge dynamic and spatial transitions similar to gas, crystalline, liquid, glass, and jammed states as a function of robot density, resource consumption rates, and resource recovery rates. Paradoxically the nongas states emerge from smooth, flat resource landscapes, not rough ones, and each state can directly move to a glassy state if the resource recovery rate is slow enough, at any robot density.

Automated summary

The study introduces an ecology-inspired form of active matter consisting of a robot swarm that moves to search for maximum light intensity in a resource environment, resulting in dynamic and spatial transitions influenced by robot density, resource consumption rates, and resource recovery rates. These transitions can lead to different states such as gas, crystalline, liquid, glass, and jammed, with non-gas states emerging from smooth, flat resource landscapes and the potential for direct movement to a glassy state under certain conditions.