Phase oscillators with global sinusoidal coupling evolve by Mobius group action
Abstract
Systems of N identical phase oscillators with global sinusoidal coupling are known to display low-dimensional dynamics. Although this phenomenon was first observed about 20 years ago, its underlying cause has remained a puzzle. Here we expose the structure working behind the scenes of these systems, by proving that the governing equations are generated by the action of the Mobius group, a three-parameter subgroup of fractional linear transformations that map the unit disc to itself. When there are no auxiliary state variables, the group action partitions the N-dimensional state space into three-dimensional invariant manifolds (the group orbits). The N-3 constants of motion associated with this foliation are the N-3 functionally independent cross ratios of the oscillator phases. No further reduction is possible, in general; numerical experiments on models of Josephson junction arrays suggest that the invariant manifolds often contain three-dimensional regions of neutrally stable chaos.
Cite
@article{arxiv.0904.1680,
title = {Phase oscillators with global sinusoidal coupling evolve by Mobius group action},
author = {Seth A. Marvel and Renato E. Mirollo and Steven H. Strogatz},
journal= {arXiv preprint arXiv:0904.1680},
year = {2015}
}
Comments
13 pages, 3 figures