Abstract
To explore a method to predict ECG signals in body area networks (BANs), we propose a hybrid prediction method for ECG signals in this paper. The proposed method combines variational mode decomposition (VMD), phase space reconstruction (PSR), and a radial basis function (RBF) neural network to predict an ECG signal. To reduce the nonstationarity and randomness of the ECG signal, we use VMD to decompose the ECG signal into several intrinsic mode functions (IMFs) with finite bandwidth, which is helpful to improve the prediction accuracy. The input parameters of the RBF neural network affect the prediction accuracy and computational burden. We employ PSR to optimize input parameters of the RBF neural network. To evaluate the prediction performance of the proposed method, we carry out many simulation experiments on ECG data from the MIT-BIH Arrhythmia Database. The experimental results show that the root mean square error (RMSE) and mean absolute error (MAE) of the proposed method are of 10−3 magnitude, while the RMSE and MAE of some competitive prediction methods are of 10−2 magnitude. Compared with other several prediction methods, our method obviously improves the prediction accuracy of ECG signals.
Highlights
ECG signals are very important for doctors to diagnose diverse kinds of heart diseases
(c) We propose a novel prediction method for ECG signals based on variational mode decomposition (VMD), phase space reconstruction (PSR), and a radial basis function (RBF) neural network
Based on the study of ECG prediction, this paper proposes a hybrid method of ECG signal prediction based on VMD, PSR, and a RBF neural network
Summary
ECG signals are very important for doctors to diagnose diverse kinds of heart diseases. It is of significance to predict ECG signals accurately. Accurate prediction of ECG signals can help doctors know the patient’s condition in advance, while it can reduce the energy consumption of sensors in body area networks (BANs). How to reduce the energy consumption and prolong the lifetime of such sensors is a challenge. Prediction can reduce the volume of transmitted data [2], reducing the energy consumption of the sensor. In BANs, there are many physiological signals, such as the ECG, body temperature, and blood pressure. If these physiological signals can be accurately predicted from the past and current data, the amount of data transmission and the energy consumption of the sensor will be greatly reduced
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