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Journal of the Royal Statistical Society: Series B (Statistical Methodology)
Volume 77, Issue 2
Original Article

Dynamic functional principal components

Siegfried Hörmann

Corresponding Author

Université Libre de Bruxelles, Belgium

Address for correspondence: Siegfried Hörmann, Department of Mathematics, Université libre de Bruxelles, CP 210, Boulevard du Triomphe, B‐1050 Brussels, Belgium. E‐mail: shormann@ulb.ac.beSearch for more papers by this author
Łukasz Kidziński

Université Libre de Bruxelles, Belgium

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Marc Hallin

Université Libre de Bruxelles, Belgium

Princeton University, USA

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First published: 18 July 2014
https://doi.org/10.1111/rssb.12076
Citations: 47

Summary

We address the problem of dimension reduction for time series of functional data urn:x-wiley:13697412:media:rssb12076:rssb12076-math-0001. Such functional time series frequently arise, for example, when a continuous time process is segmented into some smaller natural units, such as days. Then each Xt represents one intraday curve. We argue that functional principal component analysis, though a key technique in the field and a benchmark for any competitor, does not provide an adequate dimension reduction in a time series setting. Functional principal component analysis indeed is a static procedure which ignores the essential information that is provided by the serial dependence structure of the functional data under study. Therefore, inspired by Brillinger's theory of dynamic principal components, we propose a dynamic version of functional principal component analysis which is based on a frequency domain approach. By means of a simulation study and an empirical illustration, we show the considerable improvement that the dynamic approach entails when compared with the usual static procedure.

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