# Synchronization of phase oscillators on the hierarchical lattice

**Authors:** Diego Garlaschelli, Frank den Hollander, Janusz Meylahn, Benthen, Zeegers

arXiv: 1703.02535 · 2019-07-29

## TL;DR

This paper investigates how phase oscillators on a hierarchical lattice synchronize, revealing a separation of time scales and universality classes, with a focus on a renormalized mean-field Kuramoto model affected by hierarchical interactions.

## Contribution

It introduces a hierarchical mean-field framework for oscillator synchronization, proposing a renormalization approach and classifying universality classes based on interaction parameters.

## Key findings

- Identification of three universality classes for synchronization levels.
- Development of a renormalization transformation for hierarchical scales.
- Analysis of a simplified renormalization transformation with partial validation.

## Abstract

Synchronization of neurons forming a network with a hierarchical structure is essential for the brain to be able to function optimally. In this paper we study synchronization of phase oscillators on the most basic example of such a network, namely, the hierarchical lattice. Each site of the lattice carries an oscillator that is subject to noise. Pairs of oscillators interact with each other at a strength that depends on their hierarchical distance, modulated by a sequence of interaction parameters. We look at block averages of the oscillators on successive hierarchical scales, which we think of as block communities. In the limit as the number of oscillators per community tends to infinity, referred to as the hierarchical mean-field limit, we find a separation of time scales, i.e., each block community behaves like a single oscillator evolving on its own time scale. We argue that the evolution of the block communities is given by a renormalized mean-field noisy Kuramoto equation, with a synchronization level that depends on the hierarchical scale of the block community. We find three universality classes for the synchronization levels on successive hierarchical scales, characterized in terms of the sequence of interaction parameters.   What makes our model specifically challenging is the non-linearity of the interaction betweenthe oscillators. The main results of our paper therefore come in three parts: (I) a conjecture about the nature of the renormalisation transformation connecting successive hierarchical scales; (II) a truncation approximation that leads to a simplified renormalization transformation; (III) a rigorous analysis of the simplified renormalization transformation. We provide compelling arguments in support of (I) and (II), but a full verification remains an open problem.

## Full text

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## Figures

17 figures with captions in the complete paper: https://tomesphere.com/paper/1703.02535/full.md

## References

20 references — full list in the complete paper: https://tomesphere.com/paper/1703.02535/full.md

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Source: https://tomesphere.com/paper/1703.02535