Abstract

Cardiac activity has been monitored continuously in daily life by virtue of advanced medical instruments with microelectromechanical system (MEMS) technology. Seismocardiography (SCG) has been considered to be free from the burden of measurement for cardiac activity, but it has been limited in its application in daily life. The most important issues regarding SCG are to overcome the limitations of motion artifacts due to the sensitivity of motion sensor. Although novel adaptive filters for noise cancellation have been developed, they depend on the researcher’s subjective decision. Convolutional neural networks (CNNs) can extract significant features from data automatically without a researcher’s subjective decision, so that signal processing has been recently replaced as CNNs. Thus, this study aimed to develop a novel method to enhance heart rate estimation from thoracic movement by CNNs. Thoracic movement was measured by six-axis accelerometer and gyroscope signals using a wearable sensor that can be worn by simply clipping on clothes. The dataset was collected from 30 participants (15 males, 15 females) using 12 measurement conditions according to two physical conditions (i.e., relaxed and aroused conditions), three body postures (i.e., sitting, standing, and supine), and six movement speeds (i.e., 3.2, 4.5, 5.8, 6.4, 8.5, and 10.3 km/h). The motion data (i.e., six-axis accelerometer and gyroscope) and heart rate (i.e., electrocardiogram (ECG)) were determined as the input data and labels in the dataset, respectively. The CNN model was developed based on VGG Net and optimized by testing according to network depth and data augmentation. The ensemble network of the VGG-16 without data augmentation and the VGG-19 with data augmentation was determined as optimal architecture for generalization. As a result, the proposed method showed higher accuracy than the previous SCG method using signal processing in most measurement conditions. The three main contributions are as follows: (1) the CNN model enhanced heart rate estimation with the benefits of automatic feature extraction from the data; (2) the proposed method was compared with the previous SCG method using signal processing; (3) the method was tested in 12 measurement conditions related to daily motion for a more practical application.

Highlights

  • Cardiac activity has been monitored continuously in daily life by virtue of advanced medical instruments with microelectromechanical systems (MEMS) technology

  • Thoracic movement was measured by six-axis accelerometer and gyroscope signals using a wearable sensor that can be worn by clipping on clothes

  • The three main contributions are as follows: (1) the Convolutional neural networks (CNNs) model enhanced heart rate estimation with the benefits of automatic feature extraction from the data; (2) the proposed method was compared with the previous SCG method using signal processing; (3) the method was tested in 12 measurement conditions related to daily motion for a more practical application

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Summary

Introduction

Cardiac activity has been monitored continuously in daily life by virtue of advanced medical instruments with microelectromechanical systems (MEMS) technology. The most important issues regarding SCG are to overcome the limitations of the measurement conditions according to measurement location, axis selection, and motion artifacts [2]. The limitations of measurement location and axis selection have been steadily improved in recent studies. The measurement location is related to the shape, amplitude, and clinical characteristics of the signal, so that initial SCG measurement systems have been developed to be forcibly contacted and fixed on the left side of the chest [3,4,5,6,7]. The initial SCG studies only focused on the z-axis of the accelerometer, but recent studies have explored the clinical interpretation and integration for the tri-axis of the accelerometer [4,9,10,11], the tri-axis of the gyroscope [12,13,14,15], and the six-axis of the accelerometer and gyroscope [8]

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