Electrocardiogram Signal Compression Using Deep Convolutional Autoencoder with Constant Error and Flexible Compression Rate

IF 5.6 4区 医学 Q1 ENGINEERING, BIOMEDICAL Irbm Pub Date : 2024-09-06 DOI:10.1016/j.irbm.2024.100859
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Abstract

Objectives

Electrocardiogram (ECG) signals are beneficial for diagnosing cardiac diseases. The cardiac patients' life quality likely increases with continuous or long-period recording and monitoring of ECG signals, leading to better and early diagnosis of disease and heart attacks. However, continuous ECG recording necessitates high data rates and storage, which means high costs. Therefore, ECG compression is a handy concept that facilitates continuous monitoring of ECG signals. Deep neural networks open up new horizons for compression and also for ECG compression by providing high compression rates and quality. Although they bring constant compression ratios with better average quality, the compression quality of individual samples is not guaranteed, which may lead to misdiagnoses. This study aims to investigate the effect of compression quality on the diagnoses and to develop a deep neural network-based compression strategy that guarantees a quality-bound in return for varying compression ratios.

Materials and methods

The effect of the compression quality on the arrhythmia diagnoses is tested by comparing the performance of the deep learning-based ECG classifier on the original ECG recordings and the distorted recordings using a lossy compression algorithm with different compression error levels. Then, a compression error upper limit is calculated in terms of normalized percent root mean square difference (PRDN) error, which also coincides with the findings of the previous studies in the literature. Lastly, to enable deep learning in ECG compression, a single encoder-multi-decoder convolutional autoencoder architecture, and multiple quantization levels are proposed to guarantee a desired upper limit on the error rate.

Results

The efficiency of the proposed method is demonstrated on a popular benchmark data set for ECG compression methods using a transfer learning approach. The PRDN error is fixed to various values, and the average compression rates are reported. An average of 13.019:1 compression is achieved for a 10% PRDN error rate, assessed as a fair quality threshold for reconstruction error. It has also been shown that the compression model has a runtime that can be run in real-time on wearable devices such as commercial smartwatches.

Conclusion

This study proposes a deep learning-based ECG compression algorithm that guarantees a desired upper limit on the compression error. This model may facilitate an eHealth solution for continuous monitoring of ECG signals of individuals, especially cardiac patients.

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使用具有恒定误差和灵活压缩率的深度卷积自动编码器压缩心电图信号
目的心电图(ECG)信号有利于诊断心脏疾病。连续或长期记录和监测心电信号可提高心脏病患者的生活质量,从而更好地及早诊断疾病和心脏病发作。然而,连续心电图记录需要很高的数据传输率和存储量,这意味着高昂的成本。因此,心电图压缩是一个方便的概念,有助于对心电图信号进行连续监测。深度神经网络通过提供高压缩率和高质量,为压缩和心电图压缩开辟了新天地。虽然深度神经网络能带来恒定的压缩率和更好的平均质量,但单个样本的压缩质量却无法保证,这可能会导致误诊。本研究旨在研究压缩质量对诊断的影响,并开发一种基于深度神经网络的压缩策略,在不同的压缩率下保证质量上限。材料与方法通过比较基于深度学习的心电图分类器在原始心电图记录和使用有损压缩算法的失真记录上的性能,以及不同的压缩误差水平,测试压缩质量对心律失常诊断的影响。然后,根据归一化均方根差值(PRDN)误差计算出压缩误差上限,这也与之前文献中的研究结果相吻合。最后,为了在心电图压缩中实现深度学习,提出了单编码器-多解码器卷积自动编码器架构和多量化级别,以保证达到所需的误差率上限。PRDN 误差被固定为不同的值,并报告了平均压缩率。在 PRDN 误差率为 10% 的情况下,平均压缩率为 13.019:1,这被认为是重建误差的合理质量阈值。研究还表明,该压缩模型的运行时间可在商用智能手表等可穿戴设备上实时运行。 结论 本研究提出了一种基于深度学习的心电图压缩算法,它能保证压缩误差达到理想的上限。该模型可为电子医疗解决方案提供便利,用于持续监测个人(尤其是心脏病患者)的心电图信号。
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
Irbm
Irbm ENGINEERING, BIOMEDICAL-
CiteScore
10.30
自引率
4.20%
发文量
81
审稿时长
57 days
期刊介绍: IRBM is the journal of the AGBM (Alliance for engineering in Biology an Medicine / Alliance pour le génie biologique et médical) and the SFGBM (BioMedical Engineering French Society / Société française de génie biologique médical) and the AFIB (French Association of Biomedical Engineers / Association française des ingénieurs biomédicaux). As a vehicle of information and knowledge in the field of biomedical technologies, IRBM is devoted to fundamental as well as clinical research. Biomedical engineering and use of new technologies are the cornerstones of IRBM, providing authors and users with the latest information. Its six issues per year propose reviews (state-of-the-art and current knowledge), original articles directed at fundamental research and articles focusing on biomedical engineering. All articles are submitted to peer reviewers acting as guarantors for IRBM''s scientific and medical content. The field covered by IRBM includes all the discipline of Biomedical engineering. Thereby, the type of papers published include those that cover the technological and methodological development in: -Physiological and Biological Signal processing (EEG, MEG, ECG…)- Medical Image processing- Biomechanics- Biomaterials- Medical Physics- Biophysics- Physiological and Biological Sensors- Information technologies in healthcare- Disability research- Computational physiology- …
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