Abstract
Detection of the temporal reversibility of a given process is an interesting time series analysis scheme that enables the useful characterisation of processes and offers an insight into the underlying processes generating the time series. Reversibility detection measures have been widely employed in the study of ecological, epidemiological and physiological time series. Further, the time reversal of given data provides a promising tool for analysis of causality measures as well as studying the causal properties of processes. In this work, the recently proposed Compression-Complexity Causality (CCC) measure (by the authors) is shown to be free of the assumption that the "cause precedes the effect", making it a promising tool for causal analysis of reversible processes. CCC is a data-driven interventional measure of causality (second rung on the Ladder of Causation) that is based on Effort-to-Compress (ETC), a well-established robust method to characterize the complexity of time series for analysis and classification. For the detection of the temporal reversibility of processes, we propose a novel measure called the Compressive Potential based Asymmetry Measure. This asymmetry measure compares the probability of the occurrence of patterns at different scales between the forward-time and time-reversed process using ETC. We test the performance of the measure on a number of simulated processes and demonstrate its effectiveness in determining the asymmetry of real-world time series of sunspot numbers, digits of the transcedental number and heart interbeat interval variability.
Highlights
When simulated data or data recorded from real world processes are present with us, it is possible for us to create an imaginary process exhibiting the reverse dynamics of the original process
We report the results of the two performed analyses: causality testing of coupled time-reversed processes and testing of the proposed temporal asymmetry measure on simulations as well as real-world time series
Along with Compression-Complexity Causality (CCC), we demonstrate the behavior of the two most widely used causality measures, Transfer Entropy (TE) and Granger Causality (GC)
Summary
When simulated data or data recorded from real world processes are present with us, it is possible for us to create an imaginary process exhibiting the reverse dynamics of the original process. Researchers, primarily in the field of time series analysis, have widely deployed this technique to determine the time-reversibility/irreversibility of a given process. Statistical time reversibility or time symmetry implies that statistical properties of given time series remain invariant regardless of the direction of time. Time irreversibility is a common feature of non equilibrium systems [1,2,3] as well as systems driven by non-conservative forces [4]. This has been widely observed in time series obtained from ecological, epidemiological and physiological systems. Some examples include time series recordings of measles outbreak [5,6], annual phytoplankton bloom [6], and electroencephalographic recordings of normal [7]
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