English

Analog Forecasting with Dynamics-Adapted Kernels

Data Analysis, Statistics and Probability 2016-03-09 v3

Abstract

Analog forecasting is a nonparametric technique introduced by Lorenz in 1969 which predicts the evolution of states of a dynamical system (or observables defined on the states) by following the evolution of the sample in a historical record of observations which most closely resembles the current initial data. Here, we introduce a suite of forecasting methods which improve traditional analog forecasting by combining ideas from kernel methods developed in harmonic analysis and machine learning and state-space reconstruction for dynamical systems. A key ingredient of our approach is to replace single-analog forecasting with weighted ensembles of analogs constructed using local similarity kernels. The kernels used here employ a number of dynamics-dependent features designed to improve forecast skill, including Takens' delay-coordinate maps (to recover information in the initial data lost through partial observations) and a directional dependence on the dynamical vector field generating the data. Mathematically, our approach is closely related to kernel methods for out-of-sample extension of functions, and we discuss alternative strategies based on the Nystr\"om method and the multiscale Laplacian pyramids technique. We illustrate these techniques in applications to forecasting in a low-order deterministic model for atmospheric dynamics with chaotic metastability, and interannual-scale forecasting in the North Pacific sector of a comprehensive climate model. We find that forecasts based on kernel-weighted ensembles have significantly higher skill than the conventional approach following a single analog.

Keywords

Cite

@article{arxiv.1412.3831,
  title  = {Analog Forecasting with Dynamics-Adapted Kernels},
  author = {Zhizhen Zhao and Dimitrios Giannakis},
  journal= {arXiv preprint arXiv:1412.3831},
  year   = {2016}
}

Comments

submitted to Nonlinearity

R2 v1 2026-06-22T07:28:31.903Z