Abstract
We construct temporal networks from time series via unfolding the temporal information into an additional topological dimension of the networks. Thus, we are able to introduce memory entropy analysis to unravel the memory effect within the considered signal. We find distinct patterns in the entropy growth rate of the aggregate network at different memory scales for time series with different dynamics ranging from white noise, 1/f noise, autoregressive process, periodic to chaotic dynamics. Interestingly, for a chaotic time series, an exponential scaling emerges in the memory entropy analysis. We demonstrate that the memory exponent can successfully characterize bifurcation phenomenon, and differentiate the human cardiac system in healthy and pathological states. Moreover, we show that the betweenness preference analysis of these temporal networks can further characterize dynamical systems and separate distinct electrocardiogram recordings. Our work explores the memory effect and betweenness preference in temporal networks constructed from time series data, providing a new perspective to understand the underlying dynamical systems.
Highlights
That the memory exponent is capable of detecting and characterizing bifurcation phenomena
We find that the memory effect can accurately differentiate various types of time series including white noise, 1/f noise, AR model, periodic and chaotic time series
An exponential scaling behavior emerges for a chaotic signal and the memory exponent is in good agreement with the largest Lyapunov exponent
Summary
That the memory exponent is capable of detecting and characterizing bifurcation phenomena. Application to human electrocardiogram (ECG) data during sinus rhythm (SR), ventricular fibrillation (VF), and ventricular tachycardia (VT) shows that such a memory exponent can accurately characterize and classify the healthy and pathological state of the heart. We find that the betweenness preference analysis can further explore the essential difference among distinct chaotic systems and differentiate the human cardiac system under distinct states (i.e., SR, VF, and VT)
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