English

Coupling Asymmetry Optimizes Collective Dynamics over Multiplex Networks

Physics and Society 2023-10-17 v3 Disordered Systems and Neural Networks

Abstract

Networks are often interconnected, with one system wielding greater influence over another. However, the effects of such asymmetry on self-organized phenomena (e.g., consensus and synchronization) are not well understood. Here, we study collective dynamics using a generalized graph Laplacian for multiplex networks containing layers that are asymmetrically coupled. We explore the nonlinear effects of coupling asymmetry on the convergence rate toward a collective state, finding that asymmetry induces one or more optima that maximally accelerate convergence. When a faster and a slower system are coupled, depending on their relative timescales, their optimal coupling is either cooperative (network layers mutually depend on one another) or non-cooperative (one network directs another without a reciprocated influence). It is often optimal for the faster system to more-strongly influence the slower one, yet counter-intuitively, the opposite can also be true. As an application, we model collective decision-making for a human-AI system in which a social network is supported by an AI-agent network, finding that a cooperative optimum requires that these two networks operate on a sufficiently similar timescale. More broadly, our work highlights the optimization of coupling asymmetry and timescale balancing as fundamental concepts for the design of collective behavior over interconnected systems.

Keywords

Cite

@article{arxiv.2106.13127,
  title  = {Coupling Asymmetry Optimizes Collective Dynamics over Multiplex Networks},
  author = {Zhao Song and Dane Taylor},
  journal= {arXiv preprint arXiv:2106.13127},
  year   = {2023}
}

Comments

18 pages, 11 figures

R2 v1 2026-06-24T03:33:58.507Z