Abstract
BackgroundElectrocardiographic (ECG) monitors have been widely used for diagnosing cardiac arrhythmias for decades. However, accurate analysis of ECG signals is difficult and time-consuming work because large amounts of beats need to be inspected. In order to enhance ECG beat classification, machine learning and deep learning methods have been studied. However, existing studies have limitations in model rigidity, model complexity, and inference speed.ObjectiveTo classify ECG beats effectively and efficiently, we propose a baseline model with recurrent neural networks (RNNs). Furthermore, we also propose a lightweight model with fused RNN for speeding up the prediction time on central processing units (CPUs).MethodsWe used 48 ECGs from the MIT-BIH (Massachusetts Institute of Technology-Beth Israel Hospital) Arrhythmia Database, and 76 ECGs were collected with S-Patch devices developed by Samsung SDS. We developed both baseline and lightweight models on the MXNet framework. We trained both models on graphics processing units and measured both models’ inference times on CPUs.ResultsOur models achieved overall beat classification accuracies of 99.72% for the baseline model with RNN and 99.80% for the lightweight model with fused RNN. Moreover, our lightweight model reduced the inference time on CPUs without any loss of accuracy. The inference time for the lightweight model for 24-hour ECGs was 3 minutes, which is 5 times faster than the baseline model.ConclusionsBoth our baseline and lightweight models achieved cardiologist-level accuracies. Furthermore, our lightweight model is competitive on CPU-based wearable hardware.
Highlights
Arrhythmia refers to any change causing the heart to beat too fast or slow, or erratically [1], and can lead to sudden death or critical adverse outcomes such as embolic stroke [2]
We trained both models on graphics processing units and measured both models’ inference times on central processing unit (CPU)
Our models achieved overall beat classification accuracies of 99.72% for the baseline model with recurrent neural networks (RNNs) and 99.80% for the lightweight model with fused RNN
Summary
Background Arrhythmia refers to any change causing the heart to beat too fast or slow, or erratically [1], and can lead to sudden death or critical adverse outcomes such as embolic stroke [2]. One of the most widely used diagnostic methods for detecting arrhythmia is electrocardiographic (ECG) monitoring. ECG monitoring is a simple and noninvasive method for recording electrical activities of the heart by using electrodes placed on http://medinform.jmir.org/2020/3/e17037/ XSLFO RenderX. Despite improvements to measuring ECGs and patient comfort, it is still difficult to diagnose arrhythmias because identification of abnormal ECG patterns from large amounts of recorded ECGs is not trivial. An ECG record, measured for 24 hours in patients with a heart rate of 80 bpm, consists of 110,000 beats. It takes at least 2 hours for an expert to analyze this 24-hour ECG signal. Existing studies have limitations in model rigidity, model complexity, and inference speed
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