English

Mean-field approximation for networks with synchrony-driven adaptive coupling

Neurons and Cognition 2024-08-01 v1

Abstract

Synaptic plasticity is a key component of neuronal dynamics, describing the process by which the connections between neurons change in response to experiences. In this study, we extend a network model of θ\theta-neuron oscillators to include a realistic form of adaptive plasticity. In place of the less tractable spike-timing-dependent plasticity, we employ recently validated phase-difference-dependent plasticity rules, which adjust coupling strengths based on the relative phases of θ\theta-neuron oscillators. We investigate two approaches for implementing this plasticity: pairwise coupling strength updates and global coupling strength updates. A mean-field approximation of the system is derived and we investigate its validity through comparison with the θ\theta-neuron simulations across various stability states. The synchrony of the system is examined using the Kuramoto order parameter. A bifurcation analysis, by means of numerical continuation and the calculation of maximal Lyapunov exponents, reveals interesting phenomena, including bistability and evidence of period-doubling and boundary crisis routes to chaos, that would otherwise not exist in the absence of adaptive coupling.

Keywords

Cite

@article{arxiv.2407.21393,
  title  = {Mean-field approximation for networks with synchrony-driven adaptive coupling},
  author = {Niamh Fennelly and Alannah Neff and Renaud Lambiotte and Andrew Keane and Áine Byrne},
  journal= {arXiv preprint arXiv:2407.21393},
  year   = {2024}
}
R2 v1 2026-06-28T17:59:00.973Z