The geometry of synchronization: quantifying the coupling direction of physiological signals of stress between individuals using inter-system recurrence networks

Fred Hasselman, Luciënne den Uil, Renske Koordeman, Peter de Looff, Roy Otten
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Abstract

In the study of synchronization dynamics between interacting systems, several techniques are available to estimate coupling strength and coupling direction. Currently, there is no general ‘best’ method that will perform well in most contexts. Inter-system recurrence networks (IRN) combine auto-recurrence and cross-recurrence matrices to create a graph that represents interacting networks. The method is appealing because it is based on cross-recurrence quantification analysis, a well-developed method for studying synchronization between 2 systems, which can be expanded in the IRN framework to include N > 2 interacting networks. In this study we examine whether IRN can be used to analyze coupling dynamics between physiological variables (acceleration, blood volume pressure, electrodermal activity, heart rate and skin temperature) observed in a client in residential care with severe to profound intellectual disabilities (SPID) and their professional caregiver. Based on the cross-clustering coefficients of the IRN conclusions about the coupling direction (client or caregiver drives the interaction) can be drawn, however, deciding between bi-directional coupling or no coupling remains a challenge. Constructing the full IRN, based on the multivariate time series of five coupled processes, reveals the existence of potential feedback loops. Further study is needed to be able to determine dynamics of coupling between the different layers.
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同步的几何:用系统间递归网络量化个体间应激生理信号的耦合方向
在相互作用系统之间的同步动力学研究中,有几种技术可以用来估计耦合强度和耦合方向。目前,没有一种通用的“最佳”方法可以在大多数情况下表现良好。系统间递归网络(IRN)结合自递归矩阵和交叉递归矩阵来创建一个表示交互网络的图。该方法很有吸引力,因为它基于交叉递归量化分析,这是一种研究两个系统之间同步的成熟方法,可以在IRN框架中扩展到包括N >2相互作用的网络。在这项研究中,我们研究了IRN是否可以用于分析在重度到重度智力残疾(SPID)住院护理的客户及其专业护理人员中观察到的生理变量(加速度、血容量压、皮电活动、心率和皮肤温度)之间的耦合动力学。基于IRN的交叉聚类系数可以得出关于耦合方向(患者或护理者驱动交互)的结论,然而,决定是双向耦合还是不耦合仍然是一个挑战。基于五个耦合过程的多元时间序列构建完整的IRN,揭示了潜在反馈回路的存在。需要进一步的研究来确定不同层之间的耦合动力学。
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