Open AccessEstimating eigenvalues of dynamical systems from time series with applications to predicting cardiac alternans
Author(s) -
Adam Petrie,
Xiaopeng Zhao
Publication year - 2012
Publication title -
proceedings of the royal society a mathematical physical and engineering sciences
Language(s) - English
Resource type - Journals
eISSN - 1471-2946
pISSN - 1364-5021
DOI - 10.1098/rspa.2012.0098
Subject(s) - eigenvalues and eigenvectors , stability (learning theory) , mathematics , series (stratigraphy) , ventricular fibrillation , cardiac electrophysiology , statistical physics , computer science , physics , cardiology , medicine , paleontology , electrophysiology , quantum mechanics , machine learning , biology
The stability of a dynamical system can be indicated by eigenvalues of its underlying mathematical model. However, eigenvalue analysis of a complicated system (e.g. the heart) may be extremely difficult because full models may be intractable or unavailable. We develop data-driven statistical techniques, which are independent of any underlying dynamical model, that use principal components and maximum-likelihood methods to estimate the dominant eigenvalues and their standard errors from the time series of one or a few measurable quantities, e.g. transmembrane voltages in cardiac experiments. The techniques are applied to predicting cardiac alternans that is characterized by an eigenvalue approaching −1. Cardiac alternans signals a vulnerability to ventricular fibrillation, the leading cause of death in the USA.
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