Enhanced DWT for Denoising Heartbeat Signal in Non-Invasive Detection

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Enhanced DWT for Denoising Heartbeat Signal in Non-Invasive Detection
Title:
Enhanced DWT for Denoising Heartbeat Signal in Non-Invasive Detection
Journal Title:
Sensors
Publication Date:
11 March 2025
Citation:
Zhu, P., Feng, L., Yu, K., Zhang, Y., Chen, W., & Hao, J. (2025). Enhanced DWT for Denoising Heartbeat Signal in Non-Invasive Detection. Sensors, 25(6), 1743. https://doi.org/10.3390/s25061743
Abstract:
Achieving both accurate and real-time monitoring heartbeat signals by non-invasive sensing techniques is challenging due to various noise interferences. In this paper, we propose an enhanced discrete wavelet transform (DWT) method that incorporates objective denoising quality assessment metrics to determine accurate thresholds and adaptive threshold functions. Our approach begins by denoising ECG signals from various databases, introducing several types of typical noise, including additive white Gaussian (AWG) noise, baseline wandering noise, electrode motion noise, and muscle artifacts. The results show that for Gaussian white noise denoising, the enhanced DWT can achieve 1–5 dB SNR improvement compared to the traditional DWT method, while for real noise denoising, our proposed method improves the SNR tens or even hundreds of times that of the state-of-the-art denoising techniques. Furthermore, we validate the effectiveness of the enhanced DWT method by visualizing and comparing the denoising results of heartbeat signals monitored by fiber-optic micro-vibration sensors against those obtained using other denoising methods. The improved DWT enhances the quality of heartbeat signals from non-invasive sensors, thereby increasing the accuracy of cardiovascular disease diagnosis.
License type:
Attribution 4.0 International (CC BY 4.0)
Funding Info:
This work was supported in part by the Natural Science Foundation of Fujian Science and Technology Plan under Grant [2022J01824] and Xiamen Science and Technology Subsidy Project [No.2023CXY0304].
Description:
ISSN:
1424-8220