English

Dynamical independence: discovering emergent macroscopic processes in complex dynamical systems

Adaptation and Self-Organizing Systems 2023-07-26 v2

Abstract

We introduce a notion of emergence for coarse-grained macroscopic variables associated with highly-multivariate microscopic dynamical processes, in the context of a coupled dynamical environment. Dynamical independence instantiates the intuition of an emergent macroscopic process as one possessing the characteristics of a dynamical system "in its own right", with its own dynamical laws distinct from those of the underlying microscopic dynamics. We quantify (departure from) dynamical independence by a transformation-invariant Shannon information-based measure of dynamical dependence. We emphasise the data-driven discovery of dynamically-independent macroscopic variables, and introduce the idea of a multiscale "emergence portrait" for complex systems. We show how dynamical dependence may be computed explicitly for linear systems via state-space modelling, in both time and frequency domains, facilitating discovery of emergent phenomena at all spatiotemporal scales. We discuss application of the state-space operationalisation to inference of the emergence portrait for neural systems from neurophysiological time-series data. We also examine dynamical independence for discrete- and continuous-time deterministic dynamics, with potential application to Hamiltonian mechanics and classical complex systems such as flocking and cellular automata.

Keywords

Cite

@article{arxiv.2106.06511,
  title  = {Dynamical independence: discovering emergent macroscopic processes in complex dynamical systems},
  author = {Lionel Barnett and Anil K. Seth},
  journal= {arXiv preprint arXiv:2106.06511},
  year   = {2023}
}

Comments

40 pages, 7 figures

R2 v1 2026-06-24T03:06:40.499Z