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Deriving pairwise transfer entropy from network structure and motifs

Leonardo Novelli, Fatihcan M. Atay, Jürgen Jost, Joseph T. Lizier

2020Proceedings of the Royal Society A Mathematical Physical and Engineering Sciences20 citationsDOIOpen Access PDF

Abstract

Transfer entropy (TE) is an established method for quantifying directed statistical dependencies in neuroimaging and complex systems datasets. The pairwise (or bivariate) TE from a source to a target node in a network does not depend solely on the local source-target link weight, but on the wider network structure that the link is embedded in. This relationship is studied using a discrete-time linearly coupled Gaussian model, which allows us to derive the TE for each link from the network topology. It is shown analytically that the dependence on the directed link weight is only a first approximation, valid for weak coupling. More generally, the TE increases with the in-degree of the source and decreases with the in-degree of the target, indicating an asymmetry of information transfer between hubs and low-degree nodes. In addition, the TE is directly proportional to weighted motif counts involving common parents or multiple walks from the source to the target, which are more abundant in networks with a high clustering coefficient than in random networks. Our findings also apply to Granger causality, which is equivalent to TE for Gaussian variables. Moreover, similar empirical results on random Boolean networks suggest that the dependence of the TE on the in-degree extends to nonlinear dynamics.

Topics & Concepts

Pairwise comparisonGaussianMathematicsEntropy (arrow of time)Transfer entropyClustering coefficientRandom walkComplex networkStatistical physicsCluster analysisAsymmetryEntropy estimationLink (geometry)Information theoryNetwork structureNonlinear systemTopology (electrical circuits)Node (physics)Discrete mathematicsProbability and statisticsBoolean networkAlgorithmTransfer (computing)Computer scienceHomogeneity (statistics)SymmetrizationStochastic block modelRandomnessTheoretical computer scienceComplex systemNetwork theoryFunctional Brain Connectivity StudiesNeural dynamics and brain functionStatistical Mechanics and Entropy