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Fast and effective pseudo transfer entropy for bivariate data-driven causal inference

Riccardo Silini, Cristina Masoller

2021Scientific Reports43 citationsDOIOpen Access PDF

Abstract

Identifying, from time series analysis, reliable indicators of causal relationships is essential for many disciplines. Main challenges are distinguishing correlation from causality and discriminating between direct and indirect interactions. Over the years many methods for data-driven causal inference have been proposed; however, their success largely depends on the characteristics of the system under investigation. Often, their data requirements, computational cost or number of parameters limit their applicability. Here we propose a computationally efficient measure for causality testing, which we refer to as pseudo transfer entropy (pTE), that we derive from the standard definition of transfer entropy (TE) by using a Gaussian approximation. We demonstrate the power of the pTE measure on simulated and on real-world data. In all cases we find that pTE returns results that are very similar to those returned by Granger causality (GC). Importantly, for short time series, pTE combined with time-shifted (T-S) surrogates for significance testing strongly reduces the computational cost with respect to the widely used iterative amplitude adjusted Fourier transform (IAAFT) surrogate testing. For example, for time series of 100 data points, pTE and T-S reduce the computational time by [Formula: see text] with respect to GC and IAAFT. We also show that pTE is robust against observational noise. Therefore, we argue that the causal inference approach proposed here will be extremely valuable when causality networks need to be inferred from the analysis of a large number of short time series.

Topics & Concepts

Transfer entropyCausal inferenceComputer scienceInferenceBivariate analysisGranger causalityCausality (physics)Entropy (arrow of time)AlgorithmTime seriesData miningMachine learningEconometricsArtificial intelligenceMathematicsPrinciple of maximum entropyPhysicsQuantum mechanicsNeural dynamics and brain functionFunctional Brain Connectivity StudiesElectrochemical Analysis and Applications