English

Nonlinear spectral analysis: A local Gaussian approach

Methodology 2020-07-10 v4

Abstract

The spectral distribution f(ω)f(\omega) of a stationary time series {Yt}tZ\{Y_t\}_{t\in\mathbb{Z}} can be used to investigate whether or not periodic structures are present in {Yt}tZ\{Y_t\}_{t\in\mathbb{Z}}, but f(ω)f(\omega) has some limitations due to its dependence on the autocovariances γ(h)\gamma(h). For example, f(ω)f(\omega) can not distinguish white i.i.d. noise from GARCH-type models (whose terms are dependent, but uncorrelated), which implies that f(ω)f(\omega) can be an inadequate tool when {Yt}tZ\{Y_t\}_{t\in\mathbb{Z}} contains asymmetries and nonlinear dependencies. Asymmetries between the upper and lower tails of a time series can be investigated by means of the local Gaussian autocorrelations introduced in Tj{\o}stheim and Hufthammer (2013), and these local measures of dependence can be used to construct the local Gaussian spectral density presented in this paper. A key feature of the new local spectral density is that it coincides with f(ω)f(\omega) for Gaussian time series, which implies that it can be used to detect non-Gaussian traits in the time series under investigation. In particular, if f(ω)f(\omega) is flat, then peaks and troughs of the new local spectral density can indicate nonlinear traits, which potentially might discover local periodic phenomena that remain undetected in an ordinary spectral analysis.

Keywords

Cite

@article{arxiv.1708.02166,
  title  = {Nonlinear spectral analysis: A local Gaussian approach},
  author = {Lars Arne Jordanger and Dag Tjøstheim},
  journal= {arXiv preprint arXiv:1708.02166},
  year   = {2020}
}

Comments

Version 4: Major revision from version 3, with new theory/figures. 135 pages (main part 32 + appendices 103), 11 + 16 figures

R2 v1 2026-06-22T21:08:44.631Z