English

Synchronization on circles and spheres with nonlinear interactions

Optimization and Control 2026-01-28 v2 Machine Learning Dynamical Systems

Abstract

We consider the dynamics of nn points on a sphere in Rd\mathbb{R}^d (d2d \geq 2) which attract each other according to a function φ\varphi of their inner products. When φ\varphi is linear (φ(t)=t\varphi(t) = t), the points converge to a common value (i.e., synchronize) in various connectivity scenarios: this is part of classical work on Kuramoto oscillator networks. When φ\varphi is exponential (φ(t)=eβt\varphi(t) = e^{\beta t}), these dynamics correspond to a limit of how idealized transformers process data, as described by Geshkovski et al. (2025). Accordingly, they ask whether synchronization occurs for exponential φ\varphi. The answer depends on the dimension dd. In the context of consensus for multi-agent control, Markdahl et al. (2018) show that for d3d \geq 3 (spheres), if the interaction graph is connected and φ\varphi is increasing and convex, then the system synchronizes. We give a separate proof of this result. What is the situation on circles (d=2d=2)? First, we show that φ\varphi being increasing and convex is no longer sufficient (even for complete graphs). Then we identify a new condition under which we do have synchronization on the circle (namely, if the Taylor coefficients of φ\varphi' are decreasing). As a corollary, this provide synchronization for exponential φ\varphi with β(0,1]\beta \in (0, 1]. The proofs are based on nonconvex landscape analysis.

Keywords

Cite

@article{arxiv.2405.18273,
  title  = {Synchronization on circles and spheres with nonlinear interactions},
  author = {Christopher Criscitiello and Quentin Rebjock and Andrew D. McRae and Nicolas Boumal},
  journal= {arXiv preprint arXiv:2405.18273},
  year   = {2026}
}

Comments

30 pages, 1 figure

R2 v1 2026-06-28T16:44:00.657Z