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Continuity Scaling: A Rigorous Framework for Detecting and Quantifying Causality Accurately

Ying Xiong, Siyang Leng, Huanfei Ma, Qing Nie, Ying‐Cheng Lai, Wei Lin

2022Research31 citationsDOIOpen Access PDF

Abstract

Data-based detection and quantification of causation in complex, nonlinear dynamical systems is of paramount importance to science, engineering, and beyond. Inspired by the widely used methodology in recent years, the cross-map-based techniques, we develop a general framework to advance towards a comprehensive understanding of dynamical causal mechanisms, which is consistent with the natural interpretation of causality. In particular, instead of measuring the smoothness of the cross-map as conventionally implemented, we define causation through measuring the scaling law for the continuity of the investigated dynamical system directly. The uncovered scaling law enables accurate, reliable, and efficient detection of causation and assessment of its strength in general complex dynamical systems, outperforming those existing representative methods. The continuity scaling-based framework is rigorously established and demonstrated using datasets from model complex systems and the real world.

Topics & Concepts

CausationCausality (physics)Dynamical systems theoryScalingComputer scienceComplex systemNonlinear systemSmoothnessInterpretation (philosophy)Scaling lawTheoretical computer scienceStatistical physicsData miningArtificial intelligenceMathematicsPhysicsEpistemologyQuantum mechanicsGeometryPhilosophyProgramming languageMathematical analysisProtein Structure and DynamicsComplex Systems and Time Series AnalysisNeural dynamics and brain function
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