Adaptive Symlet filter based on ECG baseline wander removal

Q3 Engineering

Serbian Journal of Electrical Engineering Pub Date : 2020-01-01 DOI:10.2298/sjee2002187n

A. Nahar

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引用次数: 2

Abstract

In this paper, proposed a new approach of combining the hybrid soft computing technique called Adaptive Symlet Wavelet Transform (ASWT) filter. The baseline wanders (BW) noise removal from an ECG signals to minimize distortion of the S-T segment of the ECG signal specially that have high sampling frequencies. Therefore, when using Symlet Wavelet Transform (SWT) to analysis the ECG signal can cause problems to analysis, exclusively when examining the content of the ECG signal at low-frequency such as S-T segment. The corresponding frequency components of the approximation coefficients at level number seven are (0-3.9) Hz. Since the BW frequency is below 0.5 Hz and ST segment frequency between (0.67-4) Hz. The adaptive filter with a unity reference signal used to remove the BW noise below 0.5 Hz from the lowest level of the approximation coefficient of the decomposed ECG signal. The denoising output from adaptive filter and the output from SWT (the other detail coefficients) will use as an input to ISWT for reconstruction ECG signals with the remove BW signal. This method represents a very effective filter for BW noise removal, as it does not need for any computation process of reference point.

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基于心电基线漂移去除的自适应Symlet滤波

本文提出了一种结合混合软计算技术的自适应小波变换滤波方法。从心电信号中去除基线漂移(BW)噪声，以尽量减少心电信号S-T段的失真，特别是在高采样频率的情况下。因此，在使用Symlet小波变换(SWT)对心电信号进行分析时，只对S-T段等低频心电信号的内容进行检测，会给分析带来问题。7级近似系数对应的频率分量为(0-3.9)Hz。由于BW频率在0.5 Hz以下，ST段频率在(0.67-4)Hz之间。采用统一参考信号的自适应滤波器，从分解后的心电信号的近似系数最低处去除0.5 Hz以下的BW噪声。自适应滤波器的去噪输出和SWT(其他细节系数)的输出将用作ISWT的输入，用于用去除BW信号重建心电信号。该方法不需要任何参考点的计算过程，是一种非常有效的去噪滤波方法。

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

Serbian Journal of Electrical Engineering Energy-Energy Engineering and Power Technology

CiteScore

1.30

自引率

0.00%

发文量

审稿时长

25 weeks

期刊介绍： The main aims of the Journal are to publish peer review papers giving results of the fundamental and applied research in the field of electrical engineering. The Journal covers a wide scope of problems in the following scientific fields: Applied and Theoretical Electromagnetics, Instrumentation and Measurement, Power Engineering, Power Systems, Electrical Machines, Electrical Drives, Electronics, Telecommunications, Computer Engineering, Automatic Control and Systems, Mechatronics, Electrical Materials, Information Technologies, Engineering Mathematics, etc.