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Single Trajectory Nonparametric Learning of Nonlinear Dynamics

Machine Learning 2022-02-22 v2 Optimization and Control Machine Learning

Abstract

Given a single trajectory of a dynamical system, we analyze the performance of the nonparametric least squares estimator (LSE). More precisely, we give nonasymptotic expected l2l^2-distance bounds between the LSE and the true regression function, where expectation is evaluated on a fresh, counterfactual, trajectory. We leverage recently developed information-theoretic methods to establish the optimality of the LSE for nonparametric hypotheses classes in terms of supremum norm metric entropy and a subgaussian parameter. Next, we relate this subgaussian parameter to the stability of the underlying process using notions from dynamical systems theory. When combined, these developments lead to rate-optimal error bounds that scale as T1/(2+q)T^{-1/(2+q)} for suitably stable processes and hypothesis classes with metric entropy growth of order δq\delta^{-q}. Here, TT is the length of the observed trajectory, δR+\delta \in \mathbb{R}_+ is the packing granularity and q(0,2)q\in (0,2) is a complexity term. Finally, we specialize our results to a number of scenarios of practical interest, such as Lipschitz dynamics, generalized linear models, and dynamics described by functions in certain classes of Reproducing Kernel Hilbert Spaces (RKHS).

Keywords

Cite

@article{arxiv.2202.08311,
  title  = {Single Trajectory Nonparametric Learning of Nonlinear Dynamics},
  author = {Ingvar Ziemann and Henrik Sandberg and Nikolai Matni},
  journal= {arXiv preprint arXiv:2202.08311},
  year   = {2022}
}
R2 v1 2026-06-24T09:41:39.374Z