Mayfly Optimization with Deep Belief Network-Based Automated COVID-19 Cough Classification Using Biological Audio Signals

IF 1.1 4区计算机科学 Q3 COMPUTER SCIENCE, CYBERNETICS

Cybernetics and Systems Pub Date : 2023-01-20 DOI:10.1080/01969722.2023.2166244

G. Ayappan, S. Anila

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引用次数: 0

Abstract

Abstract The outbreak of the COVID-19 pandemic has made widespread testing a need for controlling the disease. Numerous recent investigations have shown that many people with COVID-19 show no outward signs of illness. As a result, these patients are more likely to unwittingly spread the virus because they will not take a COVID-19 test. In order to get tested, patients will need to travel to a lab, putting others at risk of exposure. Recent studies have shown that people with COVID-19 who are asymptomatic have distinctive coughs and breathing patterns compared to the general population. This prompted the study of cough and breath sounds in COVID-19 patients as a means of differentiating them from those of non-COVID lung infection patients and the general population. In this article, we present a robust, efficient, and extensible method for identifying symptomatic patterns in biological audio signals. Cough digitized audio files are subjected to spectral analysis via a stationary wavelet transform (SWT). The proposed model employs ADASYN technique to handle the class imbalance problem. Also, features like Mel-frequency cepstral coefficients (MFCCs), log frame energies, zero crossing rate (ZCR), and kurtosis are extracted. For classification process, deep belief network (DBN) model is utilized. Finally, mayfly optimization (MFO) algorithm is exploited for optimal hyper-parameter tuning of the DBN model. The experimental validation of the proposed model takes place using open access dataset. Proposed method is compared with other methods in terms accuracy, specificity, sensitivity, F1-Score, precision and recall. The experimental outcomes demonstrated the betterment of the proposed model over other recent state of art approaches.

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基于生物音频信号的基于深度信念网络的新型冠状病毒咳嗽自动分类的蜉蝣优化

摘要2019冠状病毒病(COVID-19)大流行的爆发使得广泛检测成为控制疾病的需要。最近的许多调查表明，许多COVID-19患者没有表现出疾病的外在迹象。因此，这些患者更有可能在不知不觉中传播病毒，因为他们不会接受COVID-19检测。为了进行检测，患者需要前往实验室，将其他人置于暴露的风险之中。最近的研究表明，与普通人群相比，无症状的COVID-19患者咳嗽和呼吸模式不同。这促使研究人员对COVID-19患者的咳嗽和呼吸音进行研究，以将其与非COVID-19肺部感染患者和一般人群区分开来。在本文中，我们提出了一种鲁棒、高效和可扩展的方法来识别生物音频信号中的症状模式。通过平稳小波变换(SWT)对数字化音频文件进行频谱分析。该模型采用ADASYN技术来处理类不平衡问题。此外，还提取了mel频率倒谱系数(MFCCs)、对数帧能量、零交叉率(ZCR)和峰度等特征。在分类过程中，采用深度信念网络(DBN)模型。最后，利用蜉蝣优化(MFO)算法对DBN模型进行超参数优化。利用开放获取数据集对所提出的模型进行了实验验证。并在准确度、特异度、灵敏度、F1-Score、精密度、召回率等方面与其他方法进行比较。实验结果表明，所提出的模型优于其他最新的技术方法。

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来源期刊

Cybernetics and Systems 工程技术-计算机：控制论

CiteScore

4.30

自引率

5.90%

发文量

审稿时长

>12 weeks

期刊介绍： Cybernetics and Systems aims to share the latest developments in cybernetics and systems to a global audience of academics working or interested in these areas. We bring together scientists from diverse disciplines and update them in important cybernetic and systems methods, while drawing attention to novel useful applications of these methods to problems from all areas of research, in the humanities, in the sciences and the technical disciplines. Showing a direct or likely benefit of the result(s) of the paper to humankind is welcome but not a prerequisite. We welcome original research that: -Improves methods of cybernetics, systems theory and systems research- Improves methods in complexity research- Shows novel useful applications of cybernetics and/or systems methods to problems in one or more areas in the humanities- Shows novel useful applications of cybernetics and/or systems methods to problems in one or more scientific disciplines- Shows novel useful applications of cybernetics and/or systems methods to technical problems- Shows novel applications in the arts