基于储层计算框架中的多分形分析的心脏异常鉴别方法

Basab Bijoy Purkayastha;Shovan Barma
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引用次数: 0

摘要

本研究针对不同类型的心律失常提出了一种基于多分形频谱的多类分类技术,这些心律失常与心脏的不规则性和/或复杂动态有关。事实上,在不同的心脏状态下,这种动态的复杂程度是不同的。当然,这种心脏动态的生理反应可以通过分析不同通道的心电图(ECG)信号来区分。早期基于心电图的心律失常鉴别研究将心脏视为一个黑盒系统,分析大多围绕时域统计平均值或频谱分析进行。这些工作忽略了一个关键参数,即时间局部不规则性的存在,这种不规则性与不同类型的心律失常密切相关,并在分析信号时导致信号动态系统的振幅和形状发生微妙变化。因此,在这项工作中,我们提出了一种基于多分形分析的新方法来对不同类型的心脏状况进行分类。在此,我们采用动态系统方法,计算了心电信号嵌入式相空间结构的多分形频谱。为了减轻计算负担,我们通过回波状态网络来完成分类任务。为了进行验证,我们考虑了三个知名数据集(绍兴市人民医院数据集、PTB 诊断心电图数据库 v1.0.0 和 2017 PhysioNet/CinC Challenge 数据集)。结果和分析表明,所提方法的准确率最高可达 96%,明显高于其他方法。此外,在多通道心电图分析中还评估了通道/导联的最佳数量。结果和分析表明,该模型能有效地从心电图中对各类心脏疾病进行分类。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Discrimination of Cardiac Abnormalities Based on Multifractal Analysis in Reservoir Computing Framework
This study proposes a multiclass classification technique based on multifractal spectra for different types of cardiac arrhythmias which are associated with irregularity and/or complex dynamics of the heart. Indeed, the degree of complexity of such dynamics is diverse for different states of cardiac condition. Certainly, such physiological responses of the heart dynamics can be discriminated by analyzing electrocardiogram (ECG) signals through different channels. Earlier, ECG-based works for discriminating cardiac arrhythmias consider the heart as a black box system and the analysis is mostly surrounded with time domain statistical averages or spectral analysis. The works ignore one of the key parameters, i.e., the presence of time-localized irregularities which are strongly associated with different kinds of arrhythmias and contribute to subtle variations in the amplitude and shape of the signal dynamical system while analyzing the signal. Therefore, in this work, we proposed a new method based on multifractal analysis to classify different kinds of cardiac conditions. Here, we followed the dynamical systems approach and computed the multifractal spectrum of the embedded phase space structure of the ECG signal. We performed the classification task by an echo state network to reduce the computational burden. For validation, three well-known datasets (Shaoxing Peoples’ Hospital dataset, PTB diagnostic ECG database v1.0.0, and 2017 PhysioNet/CinC Challenge dataset) have been considered. The results and analysis show that the proposed method can achieve a maximum accuracy of up to 96%, which is significantly high. Further, an optimum number of channels/leads has also been evaluated in multichannel ECG analysis. The result and analysis reveal that the effectiveness of the model in classifying various categories of cardiac disorders from ECG.
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