Spectral Network Principle for Frequency Synchronization in Repulsive Laser Networks

TL;DR

This paper introduces a spectral principle based on eigenvalues of a complex matrix to predict frequency synchronization in heterogeneous laser networks with repulsive coupling, revealing how network topology influences synchronization.

Contribution

It presents a novel spectral approach for predicting synchronization thresholds in repulsive laser networks and demonstrates its applicability beyond laser models to Kuramoto networks.

Findings

Eigenvalue gap controls synchronization threshold

Full bipartite networks optimize synchronization

Local rings and all-to-all networks hinder synchronization

Abstract

Network synchronization of lasers is critical for reaching high-power levels and for effective optical computing. Yet, the role of network topology for the frequency synchronization of lasers is not well understood. Here, we report our significant progress toward solving this critical problem for networks of heterogeneous laser model oscillators with repulsive coupling. We discover a general approximate principle for predicting the onset of frequency synchronization from the spectral knowledge of a complex matrix representing a combination of the signless Laplacian induced by repulsive coupling and a matrix associated with intrinsic frequency detuning. We show that the gap between the two smallest eigenvalues of the complex matrix generally controls the coupling threshold for frequency synchronization. In stark contrast with Laplacian networks, we demonstrate that local rings and all-to-all networks prevent frequency synchronization, whereas full bipartite networks have optimal synchronization properties. Beyond laser models, we show that, with a few exceptions, the spectral principle can be applied to repulsive Kuramoto networks. Our results may provide guidelines for optimal designs of scalable laser networks capable of achieving reliable synchronization.