A noise-robust Koopman spectral analysis of an intermittent dynamics method for complex systems: a case study in pathophysiological processes of obstructive sleep apnea

IF 1.5 Q3 HEALTH CARE SCIENCES & SERVICES

IISE Transactions on Healthcare Systems Engineering Pub Date : 2022-10-28 DOI:10.1080/24725579.2022.2141379

Phat K. Huynh, Arveity Setty, Trung Le, Trung Q Le

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引用次数: 2

Abstract

Abstract Koopman operator theory and the Hankel alternative view of the Koopman (HAVOK) model have been widely used to investigate the chaotic dynamics in complex systems. Although the statistics of intermittent dynamics have been evaluated in the HAVOK model, they are not adequate to characterize intermittent forcing. In this paper, we propose a novel method to characterize the intermittent phases, chaotic bursts, and local spectral-temporal properties of various intermittent dynamics modes using spectral decomposition and wavelet analysis. To validate our methods, we compared the sensitivity to noise level and sampling period of the HAVOK and our proposed method in the Lorenz system. Our results show that the prediction accuracy of lobe switching and the intermittent forcing identifiability were highly sensitive to the sampling rate. While it is possible to maintain the desired accuracy in high noise-level cases with an appropriately selected rank in the HAVOK model, our proposed method is demonstrated to be more robust. To show the applicability of our proposed method, obstructive sleep apnea—a complex pathological disorder—was selected as a case study. The results show a strong association between active forcing and the hypopnea-apnea events. Our proposed method has been demonstrated to be a promising data-driven method to provide key insights into the dynamics of complex systems.

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复杂系统间歇动力学方法的噪声鲁棒库普曼谱分析:阻塞性睡眠呼吸暂停的病理生理过程的案例研究

摘要库普曼算子理论和库普曼模型的Hankel替代观(HAVOK)已被广泛用于研究复杂系统中的混沌动力学。虽然HAVOK模式已经评估了间歇性动力学的统计数据，但它们不足以表征间歇性强迫。在本文中，我们提出了一种利用谱分解和小波分析来表征各种间歇动力学模式的间歇相位、混沌爆发和局部频谱-时间特性的新方法。为了验证我们的方法，我们在Lorenz系统中比较了HAVOK和我们提出的方法对噪声水平和采样周期的灵敏度。结果表明，波瓣切换的预测精度和间歇强迫辨识度对采样率高度敏感。虽然在HAVOK模型中使用适当选择的秩可以在高噪声水平的情况下保持所需的精度，但我们提出的方法被证明更具鲁棒性。为了证明我们提出的方法的适用性，阻塞性睡眠呼吸暂停-一种复杂的病理障碍-被选为个案研究。结果显示，主动强迫与低呼吸-呼吸暂停事件之间有很强的联系。我们提出的方法已被证明是一种有前途的数据驱动方法，可以为复杂系统的动力学提供关键见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IISE Transactions on Healthcare Systems Engineering Social Sciences-Safety Research

CiteScore

3.10

自引率

0.00%

发文量

期刊介绍： IISE Transactions on Healthcare Systems Engineering aims to foster the healthcare systems community by publishing high quality papers that have a strong methodological focus and direct applicability to healthcare systems. Published quarterly, the journal supports research that explores: · Healthcare Operations Management · Medical Decision Making · Socio-Technical Systems Analysis related to healthcare · Quality Engineering · Healthcare Informatics · Healthcare Policy We are looking forward to accepting submissions that document the development and use of industrial and systems engineering tools and techniques including: · Healthcare operations research · Healthcare statistics · Healthcare information systems · Healthcare work measurement · Human factors/ergonomics applied to healthcare systems Research that explores the integration of these tools and techniques with those from other engineering and medical disciplines are also featured. We encourage the submission of clinical notes, or practice notes, to show the impact of contributions that will be published. We also encourage authors to collect an impact statement from their clinical partners to show the impact of research in the clinical practices.