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Time Window Determination for Inference of Time-Varying Dynamics: Application to Cardiorespiratory Interaction

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Time Window Determination for Inference of Time-Varying Dynamics: Application to Cardiorespiratory Interaction. / Lukarski, D.; Ginovska, M.; Spasevska, H. et al.
In: Frontiers in Physiology, Vol. 11, 341, 28.04.2020.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

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Lukarski D, Ginovska M, Spasevska H, Stankovski T. Time Window Determination for Inference of Time-Varying Dynamics: Application to Cardiorespiratory Interaction. Frontiers in Physiology. 2020 Apr 28;11:341. doi: 10.3389/fphys.2020.00341

Author

Lukarski, D. ; Ginovska, M. ; Spasevska, H. et al. / Time Window Determination for Inference of Time-Varying Dynamics : Application to Cardiorespiratory Interaction. In: Frontiers in Physiology. 2020 ; Vol. 11.

Bibtex

@article{b18d9a20dce843ec957464dafec337c3,
title = "Time Window Determination for Inference of Time-Varying Dynamics: Application to Cardiorespiratory Interaction",
abstract = "Interacting dynamical systems abound in nature, with examples ranging from biology and population dynamics, through physics and chemistry, to communications and climate. Often their states, parameters and functions are time-varying, because such systems interact with other systems and the environment, exchanging information and matter. A common problem when analysing time-series data from dynamical systems is how to determine the length of the time window for the analysis. When one needs to follow the time-variability of the dynamics, or the dynamical parameters and functions, the time window needs to be resolved first. We tackled this problem by introducing a method for adaptive determination of the time window for interacting oscillators, as modeled and scaled for the cardiorespiratory interaction. By investigating a system of coupled phase oscillators and utilizing the Dynamical Bayesian Inference method, we propose a procedure to determine the time window and the propagation parameter of the covariance matrix. The optimal values are determined so that the inferred parameters follow the dynamics of the actual ones and at the same time the error of the inference represented by the covariance matrix is minimal. The effectiveness of the methodology is presented on a system of coupled limit-cycle oscillators and on the cardiorespiratory interaction. Three cases of cardiorespiratory interaction were considered—measurement with spontaneous free breathing, one with periodic sine breathing and one with a-periodic time-varying breathing. The results showed that the cardiorespiratory coupling strength and similarity of form of coupling functions have greater values for slower breathing, and this variability follows continuously the change of the breathing frequency. The method can be applied effectively to other time-varying oscillatory interactions and carries important implications for analysis of general dynamical systems.",
keywords = "time-series analysis, dynamical systems, dynamical Bayesian inference, coupled oscillators, coupling functions",
author = "D. Lukarski and M. Ginovska and H. Spasevska and T. Stankovski",
year = "2020",
month = apr,
day = "28",
doi = "10.3389/fphys.2020.00341",
language = "English",
volume = "11",
journal = "Frontiers in Physiology",
issn = "1664-042X",
publisher = "Frontiers Media S.A.",

}

RIS

TY - JOUR

T1 - Time Window Determination for Inference of Time-Varying Dynamics

T2 - Application to Cardiorespiratory Interaction

AU - Lukarski, D.

AU - Ginovska, M.

AU - Spasevska, H.

AU - Stankovski, T.

PY - 2020/4/28

Y1 - 2020/4/28

N2 - Interacting dynamical systems abound in nature, with examples ranging from biology and population dynamics, through physics and chemistry, to communications and climate. Often their states, parameters and functions are time-varying, because such systems interact with other systems and the environment, exchanging information and matter. A common problem when analysing time-series data from dynamical systems is how to determine the length of the time window for the analysis. When one needs to follow the time-variability of the dynamics, or the dynamical parameters and functions, the time window needs to be resolved first. We tackled this problem by introducing a method for adaptive determination of the time window for interacting oscillators, as modeled and scaled for the cardiorespiratory interaction. By investigating a system of coupled phase oscillators and utilizing the Dynamical Bayesian Inference method, we propose a procedure to determine the time window and the propagation parameter of the covariance matrix. The optimal values are determined so that the inferred parameters follow the dynamics of the actual ones and at the same time the error of the inference represented by the covariance matrix is minimal. The effectiveness of the methodology is presented on a system of coupled limit-cycle oscillators and on the cardiorespiratory interaction. Three cases of cardiorespiratory interaction were considered—measurement with spontaneous free breathing, one with periodic sine breathing and one with a-periodic time-varying breathing. The results showed that the cardiorespiratory coupling strength and similarity of form of coupling functions have greater values for slower breathing, and this variability follows continuously the change of the breathing frequency. The method can be applied effectively to other time-varying oscillatory interactions and carries important implications for analysis of general dynamical systems.

AB - Interacting dynamical systems abound in nature, with examples ranging from biology and population dynamics, through physics and chemistry, to communications and climate. Often their states, parameters and functions are time-varying, because such systems interact with other systems and the environment, exchanging information and matter. A common problem when analysing time-series data from dynamical systems is how to determine the length of the time window for the analysis. When one needs to follow the time-variability of the dynamics, or the dynamical parameters and functions, the time window needs to be resolved first. We tackled this problem by introducing a method for adaptive determination of the time window for interacting oscillators, as modeled and scaled for the cardiorespiratory interaction. By investigating a system of coupled phase oscillators and utilizing the Dynamical Bayesian Inference method, we propose a procedure to determine the time window and the propagation parameter of the covariance matrix. The optimal values are determined so that the inferred parameters follow the dynamics of the actual ones and at the same time the error of the inference represented by the covariance matrix is minimal. The effectiveness of the methodology is presented on a system of coupled limit-cycle oscillators and on the cardiorespiratory interaction. Three cases of cardiorespiratory interaction were considered—measurement with spontaneous free breathing, one with periodic sine breathing and one with a-periodic time-varying breathing. The results showed that the cardiorespiratory coupling strength and similarity of form of coupling functions have greater values for slower breathing, and this variability follows continuously the change of the breathing frequency. The method can be applied effectively to other time-varying oscillatory interactions and carries important implications for analysis of general dynamical systems.

KW - time-series analysis

KW - dynamical systems

KW - dynamical Bayesian inference

KW - coupled oscillators

KW - coupling functions

U2 - 10.3389/fphys.2020.00341

DO - 10.3389/fphys.2020.00341

M3 - Journal article

VL - 11

JO - Frontiers in Physiology

JF - Frontiers in Physiology

SN - 1664-042X

M1 - 341

ER -