Deep Adaptive Denoising Auto-Encoder Networks for ECG Noise Cancellation via Time-Frequency Domain

2022 Asia-Pacific Signal and Information Processing Association Annual Summit and Conference (APSIPA ASC) Pub Date : 2022-11-07 DOI:10.23919/APSIPAASC55919.2022.9980058

Amir Mohammadisrab, Poorya Aghaomidi, Jalil Mazloum, M. Akbarzadeh, M. Orooji, N. Mokari, H. Yanikomeroglu

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Abstract

In this paper, we study the performance of a deep adaptive denoising auto-encoder network (DeepADAENet) for electrocardiogram (ECG) signal noise cancelation in the time-frequency domain for practical use cases. In order to achieve a higher resolution in distinguishing the noise from valuable data, the fractional Stockwell transform (FrST) is exploited to convert the ECG to the time-frequency image. The magnitude of the time-frequency version of the ECG is noise-canceled using DeepADAENet. Then, inverse FrST is utilized to return the denoised time-frequency ECG into the time domain. Furthermore, we use the MIT-BID Apnea-ECG database (APNEA-ECG) for preparing the dataset due to various physiologies and records compared with other ECG databases. Moreover, muscle artifacts (MA), baseline wander (BW), and electrode motion (EM) from the MIT-BID Noise Stress Test Database (NSTDB) are utilized to make noisy this clean dataset. The ECG signals recorded by non-clinical devices contain more noise than clinical recording. Accordingly, by changing the coefficient and frequency of noise resources, we attempt to close the simulated noisy signal to reality. Results reveal the excellent performance of DeepADAENet compared with similar work in terms of signal-to-noise ratio (SNR), root mean square error (RMSE), and percent root mean square difference (PRD).

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基于时频域心电降噪的深度自适应自编码器网络

在本文中，我们研究了一种深度自适应降噪自编码器网络(DeepADAENet)在实际用例中用于心电图(ECG)信号噪声消除的时频域性能。为了从有价值的数据中获得更高的分辨噪声，利用分数阶斯托克韦尔变换(FrST)将心电信号转换为时频图像。使用DeepADAENet对ECG的时频幅值进行噪声消除。然后利用逆first st将去噪后的时频心电信号返回到时域。此外，与其他ECG数据库相比，我们使用MIT-BID呼吸暂停-ECG数据库(Apnea-ECG)来准备数据集，因为它具有各种生理和记录。此外，利用MIT-BID噪声压力测试数据库(NSTDB)中的肌肉伪像(MA)、基线漂移(BW)和电极运动(EM)对这个干净的数据集进行噪声处理。非临床设备记录的心电信号比临床记录的噪声更大。因此，我们试图通过改变噪声源的系数和频率，使模拟的噪声信号接近真实。结果表明，与同类算法相比，DeepADAENet在信噪比(SNR)、均方根误差(RMSE)和均方根差(PRD)百分比方面表现优异。

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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2022 Asia-Pacific Signal and Information Processing Association Annual Summit and Conference (APSIPA ASC)

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