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Learning Beyond Experience: Generalizing to Unseen State Space with Reservoir Computing

Machine Learning 2025-10-30 v2 Dynamical Systems Chaotic Dynamics Computational Physics

Abstract

Machine learning techniques offer an effective approach to modeling dynamical systems solely from observed data. However, without explicit structural priors -- built-in assumptions about the underlying dynamics -- these techniques typically struggle to generalize to aspects of the dynamics that are poorly represented in the training data. Here, we demonstrate that reservoir computing -- a simple, efficient, and versatile machine learning framework often used for data-driven modeling of dynamical systems -- can generalize to unexplored regions of state space without explicit structural priors. First, we describe a multiple-trajectory training scheme for reservoir computers that supports training across a collection of disjoint time series, enabling effective use of available training data. Then, applying this training scheme to multistable dynamical systems, we show that RCs trained on trajectories from a single basin of attraction can achieve out-of-domain generalization by capturing system behavior in entirely unobserved basins.

Keywords

Cite

@article{arxiv.2506.05292,
  title  = {Learning Beyond Experience: Generalizing to Unseen State Space with Reservoir Computing},
  author = {Declan A. Norton and Yuanzhao Zhang and Michelle Girvan},
  journal= {arXiv preprint arXiv:2506.05292},
  year   = {2025}
}

Comments

18 pages, 12 figures. Updated to include results with RC generalization to unseen segregated and asymmetric basins of attraction and unseen chaotic attractors

R2 v1 2026-07-01T03:02:02.358Z