Estimation of interaction strength and direction from short and noisy time series
- 29 October 2003
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review E
- Vol. 68 (4) , 046209
- https://doi.org/10.1103/physreve.68.046209
Abstract
A technique for determination of character and intensity of interaction between the elements of complex systems based on reconstruction of model equations for phase dynamics is extended to the case of short and noisy time series. Corrections, which eliminate systematic errors of the estimates, and expressions for confidence intervals are derived. Analytic results are presented for a particular case of linear uncoupled systems, and their validity for a much wider range of situations is demonstrated with numerical examples. The technique should be useful for the analysis of nonstationary processes in real time, including the situations of significant noise and restrictions on the observation time.This publication has 26 references indexed in Scilit:
- Event synchronization: A simple and fast method to measure synchronicity and time delay patternsPhysical Review E, 2002
- Identification of coupling direction: Application to cardiorespiratory interactionPhysical Review E, 2002
- Performance of different synchronization measures in real data: A case study on electroencephalographic signalsPhysical Review E, 2002
- Detecting direction of coupling in interacting oscillatorsPhysical Review E, 2001
- Generalized synchronization versus phase synchronizationPhysical Review E, 2000
- Fundamentals of synchronization in chaotic systems, concepts, and applicationsChaos: An Interdisciplinary Journal of Nonlinear Science, 1997
- Experimental observation of phase synchronizationPhysical Review E, 1996
- Generalized Synchronization, Predictability, and Equivalence of Unidirectionally Coupled Dynamical SystemsPhysical Review Letters, 1996
- Phase Synchronization of Chaotic OscillatorsPhysical Review Letters, 1996
- Generalized synchronization of chaos in directionally coupled chaotic systemsPhysical Review E, 1995