Lie Meets Network Dynamics: Exact Macroscopic Reductions (Finite Systems)
Abstract
We establish a unified framework for exact dimensional reductions in network dynamical systems using Lie-Scheffers theory.
For network dynamical systems with \emph{mean-field Lie-Scheffers structure}, we prove that networks of $n$ nodes with local dimension $d$ can be exactly reduced from $ n d $ dimensions to a fixed macroscopic system of dimension $ m d $, where $m$ is the number of fundamental solutions required by the nodal dynamics.
Crucially, the superposition principle resulting from the Lie-algebraic structure allows the mean-field coupling to be expressed explicitly in terms of the macroscopic variables, yielding a \emph{closed} self-consistent system independent of network size.
This reduction collapses the high-dimensional network flow onto invariant manifolds parameterized by $ \gamma = d(n-m) $ independent constants of motion.
Our framework rigorously explains known reductions and provides a \emph{systematic method to discover new ones}.
We illustrate the theory with ensembles of Riccati equations (encompassing the Kuramoto model and Theta neuron model), quasi-linear ODEs, and generalized Bernoulli equations, explicitly deriving the macroscopic flows and conserved quantities for each case.
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