Analysis and classification of arrhythmia types using improved firefly optimization algorithm and autoencoder model

IF 0.6 Q4 COMPUTER SCIENCE, THEORY & METHODS Multiagent and Grid Systems Pub Date : 2023-06-08 DOI:10.3233/mgs-230022
Mala Sinnoor, Shanthi Kaliyil Janardhan
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引用次数: 0

Abstract

In the present scenario, Electrocardiogram (ECG) is an effective non-invasive clinical tool, which reveals the functionality and rhythm of the heart. The non-stationary nature of ECG signal, noise existence, and heartbeat abnormality makes it difficult for clinicians to diagnose arrhythmia. The most of the existing models concentrate only on classification accuracy. In this manuscript, an automated model is introduced that concentrates on arrhythmia type classification using ECG signals, and also focuses on computational complexity and time. After collecting the signals from the MIT-BIH database, the signal transformation and decomposition are performed by Multiscale Local Polynomial Transform (MLPT) and Ensemble Empirical Mode Decomposition (EEMD). The decomposed ECG signals are given to the feature extraction phase for extracting features. The feature extraction phase includes six techniques: standard deviation, zero crossing rate, mean curve length, Hjorth parameters, mean Teager energy, and log energy entropy. Next, the feature dimensionality reduction and arrhythmia classification are performed utilizing the improved Firefly Optimization Algorithm and autoencoder. The selection of optimal feature vectors by the improved Firefly Optimization Algorithm reduces the computational complexity to linear and consumes computational time of 18.23 seconds. The improved Firefly Optimization Algorithm and autoencoder model achieved 98.96% of accuracy in the arrhythmia type classification, which is higher than the comparative models.
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基于改进萤火虫优化算法和自编码器模型的心律失常类型分析与分类
在目前的情况下,心电图(ECG)是一种有效的无创临床工具,它可以显示心脏的功能和节律。心电信号的非平稳性、噪声的存在和心跳异常给临床医生诊断心律失常带来了困难。现有的大多数模型只关注分类精度。本文介绍了一种利用心电信号进行心律失常类型分类的自动模型,并着重于计算复杂度和时间。从MIT-BIH数据库中采集信号后,采用多尺度局部多项式变换(MLPT)和集成经验模态分解(EEMD)对信号进行变换和分解。将分解后的心电信号送入特征提取阶段进行特征提取。特征提取阶段包括六种技术:标准差、过零率、平均曲线长度、Hjorth参数、平均Teager能量和对数能量熵。其次,利用改进的萤火虫优化算法和自编码器进行特征降维和心律失常分类。改进的萤火虫优化算法选择最优特征向量,将计算复杂度降低到线性,计算时间为18.23秒。改进的萤火虫优化算法和自编码器模型在心律失常类型分类中准确率达到98.96%,高于对比模型。
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来源期刊
Multiagent and Grid Systems
Multiagent and Grid Systems COMPUTER SCIENCE, THEORY & METHODS-
CiteScore
1.50
自引率
0.00%
发文量
13
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