The Vicsek-Kuramoto model in collective dynamics: macroscopic equations and pattern formation

TL;DR

This paper derives macroscopic equations from an individual-based model combining Vicsek and Kuramoto dynamics, revealing pattern formation and synchronization phenomena in collective motion.

Contribution

It introduces a new macroscopic model derived from a combined Vicsek-Kuramoto individual-based model, capturing complex collective behaviors.

Findings

Macroscopic equations successfully reproduce emergent patterns.

Numerical simulations show rotating clusters and traveling waves.

The model demonstrates synchronization and pattern formation in collective dynamics.

Abstract

In this work, we investigate an individual-based model (IBM) for self-propelled agents interacting locally on a plane. Agents are characterized by their position, the angle determining their direction of motion, and their angular velocity. The dynamics combine features of the well-known Vicsek and Kuramoto models, which describe collective dynamics and synchronization, respectively. The evolution of the directions of motion follows a Vicsek model, where agents align their orientations with the mean orientation of their neighbors, subject to some noise. Similarly, the angular velocities relax towards the average angular velocity of the neighboring agents, also subject to noise. From the IBM we derive the corresponding kinetic equation in the limit of a large number of agents and formally obtain the macroscopic equations through a macroscopic (hydrodynamic) limit. Numerical simulations of the IBM reveal a variety of patterns, including rotating clusters, traveling orientation waves, and globally synchronized rotational motion. A qualitative comparison with simulations of the macroscopic system show the ability of the macroscopic model to reproduce some emergent behavior of the IBM.