Nonparametric forecasting of low-dimensional dynamical systems
Abstract
This letter presents a non-parametric modeling approach for forecasting stochastic dynamical systems on low-dimensional manifolds. The key idea is to represent the discrete shift maps on a smooth basis which can be obtained by the diffusion maps algorithm. In the limit of large data, this approach converges to a Galerkin projection of the semigroup solution to the underlying dynamics on a basis adapted to the invariant measure. This approach allows one to quantify uncertainties (in fact, evolve the probability distribution) for non-trivial dynamical systems with equation-free modeling. We verify our approach on various examples, ranging from an inhomogeneous anisotropic stochastic differential equation on a torus, the chaotic Lorenz three-dimensional model, and the Ni\~{n}o-3.4 data set which is used as a proxy of the El-Ni\~{n}o Southern Oscillation.
Cite
@article{arxiv.1411.5069,
title = {Nonparametric forecasting of low-dimensional dynamical systems},
author = {Tyrus Berry and Dimitrios Giannakis and John Harlim},
journal= {arXiv preprint arXiv:1411.5069},
year = {2015}
}
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