Phase Synchronization in Random Geometric Graphs on the 2D Sphere
Abstract
The Kuramoto model is a classical nonlinear ODE system designed to study synchronization phenomena. Each equation represents the phase of an oscillator and the coupling between them is determined by a graph. There is an increasing interest in understanding the relation between the graph topology and the spontaneous synchronization of the oscillators. Abdalla, Bandeira and Invernizzi considered random geometric graphs on the -dimensional sphere and proved that the system synchronizes with high probability as long as the mean number of neighbors and the dimension go to infinity. They posed the question about the behavior when is small. In this paper, we prove that synchronization holds for random geometric graphs on the two-dimensional sphere, with high probability as the number of nodes goes to infinity, as long as the initial conditions converge to a smooth function. We conjecture a similar behavior for more general simply-connected closed Riemannian manifolds but we expect global synchronization to fail if the manifold is not simply-connected, as was shown in [11] and suggested in [9].
Cite
@article{arxiv.2504.01151,
title = {Phase Synchronization in Random Geometric Graphs on the 2D Sphere},
author = {Cecilia De Vita and Pablo Groisman and Ruojun Huang},
journal= {arXiv preprint arXiv:2504.01151},
year = {2025}
}