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Synchronization in the quaternionic Kuramoto model

Dynamical Systems 2024-01-23 v3 Mathematical Physics math.MP

Abstract

In this paper, we propose an NN oscillators Kuramoto model with quaternions H\mathbb{H}. In case the coupling strength is strong, a sufficient condition of synchronization is established for general N2N\geqslant 2. On the other hand, we analyze the case when the coupling strength is weak. For N=2N=2, when coupling strength is weak (below the critical coupling strength λc\lambda_c), we show that new periodic orbits emerge near each equilibrium point, and hence phase-locking state exists. This phenomenon is different from the real Kuramoto system since it is impossible to arrive at any synchronization when λ<λc\lambda<\lambda_c. We prove a theorem that states a set of closed and dense contour forms near each equilibrium point, resembling a tree's growth rings. In other words, the trajectory of phase difference lies on a 4D4D-torus surface. Therefore, this implies that the phase-locking state is Lyapunov stable but not asymptotically stable. The proof uses a new infinite buffer method (``δ/n\delta/n criterion") and a Lyapunov function argument. This has been studied both analytically and numerically. For N=3N=3, we consider the ``Lion Dance flow", the analog of Cherry flow for our model, to demonstrate that the quaternionic synchronization exists even when the coupling strength is ``super weak" (when λ/ω<0.85218915...\lambda/\omega <0.85218915...). Also, numerical evaluation reveals that when N>3N>3, the stable manifold of Lion Dance flow exists, and the number of these equilibria is N12\lfloor \frac{N-1}{2}\rfloor. Therefore, we conjecture that Lyapunov stable quaternionic synchronization always exists.

Keywords

Cite

@article{arxiv.2309.01893,
  title  = {Synchronization in the quaternionic Kuramoto model},
  author = {Ting-Yang Hsiao and Yun-Feng Lo and Winnie Wang},
  journal= {arXiv preprint arXiv:2309.01893},
  year   = {2024}
}

Comments

41 pages, 12 figures

R2 v1 2026-06-28T12:12:40.063Z