Heart Rate Monitoring During Physical Exercise From Photoplethysmography Using Neural Network

Photoplethysmography (PPG) signals have been widely used for heart rate (HR) monitoring. Compared to the electrocardiogram, PPG signals can be easily collected with wearable devices such as smart watches at a lower cost. However, the PPG signals are often contaminated by the motion artifact (MA) and noises, which greatly deteriorate the signal quality and pose significant challenges on HR monitoring. In this article, a new algorithm, using the spectral subtraction and the neural network (NN), is developed for accurate HR tracking in the presence of MA and noises. Specifically, the spectral component of MA is estimated from the acceleration (ACC) signals and then removed from the spectra of PPG. In addition, an NN model is developed based on new features extracted from ACC signals to identify the relationship between the ACC and HR variations in consecutive time windows. Such information is further used as a reference to select the spectral peak corresponding to the actual HR. A postprocessing algorithm is used to correct misidentified HR and to improve the accuracy. The NN-based algorithm is validated using the 2015 IEEE Signal Processing Cup Dataset. Our algorithm achieves an average absolute error of 1.03 beats per minutes (BPM) (standard deviation: 1.82 BPM), which outperforms previously reported works in the literature.

[1]  Yuan-Ting Zhang,et al.  Robust heart beat detection from photoplethysmography interlaced with motion artifacts based on Empirical Mode Decomposition , 2012, Proceedings of 2012 IEEE-EMBS International Conference on Biomedical and Health Informatics.

[2]  Suiren Wan,et al.  SFST: A robust framework for heart rate monitoring from photoplethysmography signals during physical activities , 2017, Biomed. Signal Process. Control..

[3]  Fei Wang,et al.  SVM-Based Spectral Analysis for Heart Rate from Multi-Channel WPPG Sensor Signals , 2017, Sensors.

[4]  P. Eilers A perfect smoother. , 2003, Analytical chemistry.

[5]  Andriy Temko,et al.  Accurate Heart Rate Monitoring During Physical Exercises Using PPG , 2017, IEEE Transactions on Biomedical Engineering.

[6]  Alexander J. Casson,et al.  Towards Photoplethysmography-Based Estimation of Instantaneous Heart Rate During Physical Activity , 2017, IEEE Transactions on Biomedical Engineering.

[7]  Takashi Sato,et al.  PARHELIA: Particle Filter-Based Heart Rate Estimation From Photoplethysmographic Signals During Physical Exercise , 2018, IEEE Transactions on Biomedical Engineering.

[8]  Zhilin Zhang,et al.  TROIKA: A General Framework for Heart Rate Monitoring Using Wrist-Type Photoplethysmographic Signals During Intensive Physical Exercise , 2014, IEEE Transactions on Biomedical Engineering.

[9]  S. Julius,et al.  Elevated Heart Rate: A Major Risk Factor for Cardiovascular Disease , 2004, Clinical and experimental hypertension.

[10]  Zhilin Zhang,et al.  Photoplethysmography-Based Heart Rate Monitoring in Physical Activities via Joint Sparse Spectrum Reconstruction , 2015, IEEE Transactions on Biomedical Engineering.

[11]  Zhilin Zhang,et al.  Combining Nonlinear Adaptive Filtering and Signal Decomposition for Motion Artifact Removal in Wearable Photoplethysmography , 2016, IEEE Sensors Journal.

[12]  Marimuthu Palaniswami,et al.  Ensemble Empirical Mode Decomposition With Principal Component Analysis: A Novel Approach for Extracting Respiratory Rate and Heart Rate From Photoplethysmographic Signal , 2018, IEEE Journal of Biomedical and Health Informatics.

[13]  J. Lee,et al.  Wearable Multichannel Photoplethysmography Framework for Heart Rate Monitoring During Intensive Exercise , 2018, IEEE Sensors Journal.

[14]  E. Hari Krishna,et al.  Evaluation of wavelets for reduction of motion artifacts in photoplethysmographic signals , 2010, 10th International Conference on Information Science, Signal Processing and their Applications (ISSPA 2010).

[15]  Sun K. Yoo,et al.  Motion artifact reduction in photoplethysmography using independent component analysis , 2006, IEEE Transactions on Biomedical Engineering.