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Time-series forecasting using manifold learning, radial basis function interpolation, and geometric harmonics

Panagiotis G. Papaioannou, Ronen Talmon, Ioannis G. Kevrekidis, Constantinos Siettos

2022Chaos An Interdisciplinary Journal of Nonlinear Science26 citationsDOIOpen Access PDF

Abstract

We address a three-tier numerical framework based on nonlinear manifold learning for the forecasting of high-dimensional time series, relaxing the "curse of dimensionality" related to the training phase of surrogate/machine learning models. At the first step, we embed the high-dimensional time series into a reduced low-dimensional space using nonlinear manifold learning (local linear embedding and parsimonious diffusion maps). Then, we construct reduced-order surrogate models on the manifold (here, for our illustrations, we used multivariate autoregressive and Gaussian process regression models) to forecast the embedded dynamics. Finally, we solve the pre-image problem, thus lifting the embedded time series back to the original high-dimensional space using radial basis function interpolation and geometric harmonics. The proposed numerical data-driven scheme can also be applied as a reduced-order model procedure for the numerical solution/propagation of the (transient) dynamics of partial differential equations (PDEs). We assess the performance of the proposed scheme via three different families of problems: (a) the forecasting of synthetic time series generated by three simplistic linear and weakly nonlinear stochastic models resembling electroencephalography signals, (b) the prediction/propagation of the solution profiles of a linear parabolic PDE and the Brusselator model (a set of two nonlinear parabolic PDEs), and (c) the forecasting of a real-world data set containing daily time series of ten key foreign exchange rates spanning the time period 3 September 2001-29 October 2020.

Topics & Concepts

Autoregressive modelMathematicsKrigingAlgorithmSeries (stratigraphy)Applied mathematicsNonlinear systemNonlinear dimensionality reductionRadial basis functionTime seriesComputer scienceMathematical optimizationArtificial intelligenceMachine learningArtificial neural networkDimensionality reductionPhysicsBiologyEconometricsQuantum mechanicsPaleontologyNeural Networks and ApplicationsNeural dynamics and brain functionGaussian Processes and Bayesian Inference