Wave-shape oscillatory model for nonstationary periodic time series analysis

IF 1.7 Q2 MATHEMATICS, APPLIED Foundations of data science (Springfield, Mo.) Pub Date : 2020-07-13 DOI:10.3934/FODS.2021009
Yu-Ting Lin, John Malik, Hau‐Tieng Wu
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引用次数: 17

Abstract

The oscillations observed in many time series, particularly in biomedicine, exhibit morphological variations over time. These morphological variations are caused by intrinsic or extrinsic changes to the state of the generating system, henceforth referred to as dynamics. To model these time series (including and specifically pathophysiological ones) and estimate the underlying dynamics, we provide a novel wave-shape oscillatory model. In this model, time-dependent variations in cycle shape occur along a manifold called the wave-shape manifold. To estimate the wave-shape manifold associated with an oscillatory time series, study the dynamics, and visualize the time-dependent changes along the wave-shape manifold, we apply the well-established diffusion maps (DM) algorithm to the set of all observed oscillations. We provide a theoretical guarantee on the dynamical information recovered by the DM algorithm under the proposed model. Applying the proposed model and algorithm to arterial blood pressure (ABP) signals recorded during general anesthesia leads to the extraction of nociception information. Applying the wave-shape oscillatory model and the DM algorithm to cardiac cycles in the electrocardiogram (ECG) leads to ectopy detection and a new ECG-derived respiratory signal, even when the subject has atrial fibrillation.
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非平稳周期时间序列分析的波形振荡模型
在许多时间序列中观察到的振荡,特别是在生物医学中,表现出随时间的形态学变化。这些形态变化是由发电系统状态的内在或外在变化引起的,下文称为动力学。为了对这些时间序列(包括,特别是病理生理序列)进行建模并估计潜在的动力学,我们提供了一个新的波形振荡模型。在这个模型中,周期形状随时间的变化沿着一个称为波形流形的流形发生。为了估计与振荡时间序列相关的波形流形,研究动力学,并可视化沿波形流形的随时间变化,我们将公认的扩散图(DM)算法应用于所有观测到的振荡集。我们为DM算法在所提出的模型下恢复动态信息提供了理论保证。将所提出的模型和算法应用于全麻期间记录的动脉血压(ABP)信号,可以提取伤害感受信息。将波形振荡模型和DM算法应用于心电图(ECG)中的心动周期会导致异位检测和新的ECG衍生的呼吸信号,即使受试者患有心房颤动。
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