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Complex-valued Gaussian Process Regression for Time Series Analysis

Machine Learning 2017-12-08 v2

Abstract

The construction of synthetic complex-valued signals from real-valued observations is an important step in many time series analysis techniques. The most widely used approach is based on the Hilbert transform, which maps the real-valued signal into its quadrature component. In this paper, we define a probabilistic generalization of this approach. We model the observable real-valued signal as the real part of a latent complex-valued Gaussian process. In order to obtain the appropriate statistical relationship between its real and imaginary parts, we define two new classes of complex-valued covariance functions. Through an analysis of simulated chirplets and stochastic oscillations, we show that the resulting Gaussian process complex-valued signal provides a better estimate of the instantaneous amplitude and frequency than the established approaches. Furthermore, the complex-valued Gaussian process regression allows to incorporate prior information about the structure in signal and noise and thereby to tailor the analysis to the features of the signal. As a example, we analyze the non-stationary dynamics of brain oscillations in the alpha band, as measured using magneto-encephalography.

Keywords

Cite

@article{arxiv.1611.10073,
  title  = {Complex-valued Gaussian Process Regression for Time Series Analysis},
  author = {Luca Ambrogioni and Eric Maris},
  journal= {arXiv preprint arXiv:1611.10073},
  year   = {2017}
}
R2 v1 2026-06-22T17:09:08.759Z