Study on a quantitative analysis method for pulse signal by modelling its waveform in time and space domain_Journal of Biomedical Engineering

Authors：

CHOU Yongxin ^1,4 ,  ZHANG Aihua ² , LIU Jicheng ¹ , LIN Jiajun ³ , HUANG Xufeng ⁴

1. School of Electrical and Automatic Engineering, Changshu Institute of Technology, Suzhou, Jiangsu 215500, P.R.China;
2. College of Electrical and Information Engineering, Lanzhou University of Technology, Lanzhou 730050, P.R.China;
3. School of Information Science and Engineering, East China University of Science and Technology, Shanghai 200237, P.R.China;
4. The East China Science and Technology Research Institute of Changshu Co., Ltd, Suzhou, Jiangsu 215500, P.R.China;

Corresponding author：

ZHANG Aihua, Email: zhangaihua@lut.cn

Keywords：

pulse signal; analytical modeling in the time-space domain; pulse to pulse interval; pulse waveform; quantitative analysis

DOI：

10.7507/1001-5515.201904024

Video：

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Abstract Full text Figures/Tables Video References Cited by

In order to quantitatively analyze the morphology and period of pulse signals, a time-space analytical modeling and quantitative analysis method for pulse signals were proposed. Firstly, according to the production mechanism of the pulse signal, the pulse space-time analytical model was built after integrating the period and baseline of pulse signal into the analytical model, and the model mathematical expression and its 12 parameters were obtained for pulse wave quantification. Then, the model parameters estimation process based on the actual pulse signal was presented, and the optimization method, constraints and boundary conditions in parameter estimation were given. The spatial-temporal analytical modeling method was applied to the pulse waves of healthy subjects from the international standard physiological signal sub-database Fantasia of the PhysioNet in open-source, and we derived some changes in heartbeat rhythm and hemodynamic generated by aging and gender difference from the analytical models. The model parameters were employed as the input of some machine learning methods, e.g. random forest and probabilistic neural network, to classify the pulse waves by age and gender, and the results showed that random forest has the best classification performance with Kappa coefficients over 98%. Therefore, the space-time analytical modeling method proposed in this study can effectively quantify and analyze the pulse signal, which provides a theoretical basis and technical framework for some related applications based on pulse signals.

Citation： CHOU Yongxin, ZHANG Aihua, LIU Jicheng, LIN Jiajun, HUANG Xufeng. Study on a quantitative analysis method for pulse signal by modelling its waveform in time and space domain. Journal of Biomedical Engineering, 2020, 37(1): 61-70, 79. doi: 10.7507/1001-5515.201904024 Copy

1.	Sorelli M, Perrella A, Bocchi L. Detecting vascular age using the analysis of peripheral pulse. IEEE Trans Biomed Eng, 2018, 65(12): 2742-2750.
2.	Nathan V, Jafari R. Particle filtering and sensor fusion for robust heart rate monitoring using wearable sensors. IEEE J Biomed Health Inform, 2018, 22(6): 1834-1846.
3.	Hernando A, Pelaez-Coca M D, Lozano M T, et al. Autonomic nervous system measurement in hyperbaric environments using ECG and PPG signals. IEEE J Biomed Health Inform, 2019, 23(1): 132-142.
4.	Sun Yu, Thakor N. Photoplethysmography revisited: from contact to noncontact, from point to imaging. IEEE Trans Biomed Eng, 2016, 63(3): 463-477.
5.	漆宇晟, 张爱华, 马玉润. 日常无监督状态下的脉率变异性提取方法研究. 生物医学工程学杂志, 2019, 36(2): 1-8.
6.	孙薇, 唐宁, 江贵平. 脉搏波信号特征点识别与预处理方法研究. 生物医学工程学杂志, 2015, 32(1): 197-201.
7.	Manning T S, Shykoff B E, Izzo J L. Validity and reliability of diastolic pulse contour analysis (windkessel model) in humans. Hypertension, 2002, 39(5): 963-968.
8.	Jiang X, Wei S, Ji J, et al. Modeling radial artery pressure waveforms using curve fitting: comparison of four types of fitting functions. Artery Res, 2018, 23: 56-62.
9.	He Dianning, Wang Lu, Fan Xiaobing, et al. A new mathematical model of wrist pulse waveforms characterizes patients with cardiovascular disease - a pilot study. Med Eng Phys, 2017, 48(SI): 142-149.
10.	Sološenko A, Petrėnas A, Marozas V, et al. Modeling of the photoplethysmogram during atrial fibrillation. Comput Biol Med, 2017, 81(2017): 130-138.
11.	Liu C, Zheng D, Murray A, et al. Modeling carotid and radial artery pulse pressure waveforms by curve fitting with Gaussian functions. Biomedical Signal Processing and Control, 2013, 8(5): 449-454.
12.	Couceiro R, Carvalho P, Paiva R P, et al. Assessment of cardiovascular function from multi-Gaussian fitting of a finger photoplethysmogram. Physiol Meas, 2015, 36(9): 1801-1825.
13.	Sun Bin, Wang Chengchao, Chen Xiaohui, et al. PPG signal motion artifacts correction algorithm based on feature estimation. Optik (Stuttg), 2019, 176(2019): 337-349.
14.	Paradkar N, Chowdhury S R. Cardiac arrhythmia detection using photoplethysmography// IEEE Engineering in Medicine and Biology Society, Jeju Island, Korea: IEEE, 2017: 113-116.
15.	Alqudah A M. An enhanced method for real-time modelling of cardiac related bio-signals using Gaussian mixtures. J Med Eng Technol, 2017, 41(8): 600-611.
16.	Yang Chenxi, Tang Sunli, Tavassolian N. Utilizing gyroscopes towards the automatic annotation of seismocardiograms. IEEE Sens J, 2017, 17(7): 2129-2136.
17.	张爱华, 丑永新. 动态脉搏信号的采集与处理. 中国医疗器械杂志, 2012, 36(2): 79-84.
18.	Teng Y D, Ge L, Chou Y X. A novel abnormal segments detection method for photopletysmography signal// 2018 37th Chinese Control Conference (CCC), Wuhan: IEEE, 2018: 4113-4117.
19.	刘增丁, 陈骥, 汤敏芳. 基于波形时域特征和动态差分阈值的脉搏波传导时间检测算法. 生物医学工程学杂志, 2017, 34(3): 329-334.
20.	丑永新, 张爱华, 欧继青, 等. 基于手机的动态脉率变异性信号提取与分析. 中国医疗器械杂志, 2015, 39(5): 313-317.
21.	Martin-Martinez D, Casaseca-de-La-Higuera P, Martin-Fernandez M, et al. Stochastic modeling of the PPG signal: a synthesis-by-analysis approach with applications. IEEE Trans Biomed Eng, 2013, 60(9): 2432-2441.
22.	Goldberger A L, Amaral L A, Glass L, et al. PhysioBank, PhysioToolkit, and PhysioNet: components of a new research resource for complex physiologic signals. Circulation, 2000, 101(23): e215-e220.
23.	Islam M S, Khreich W, Hamou-Lhadj A. Anomaly detection techniques based on Kappa-Pruned ensembles. IEEE Transactions on Reliability, 2018, 67(1): 212-229.

1. Sorelli M, Perrella A, Bocchi L. Detecting vascular age using the analysis of peripheral pulse. IEEE Trans Biomed Eng, 2018, 65(12): 2742-2750.
2. Nathan V, Jafari R. Particle filtering and sensor fusion for robust heart rate monitoring using wearable sensors. IEEE J Biomed Health Inform, 2018, 22(6): 1834-1846.
3. Hernando A, Pelaez-Coca M D, Lozano M T, et al. Autonomic nervous system measurement in hyperbaric environments using ECG and PPG signals. IEEE J Biomed Health Inform, 2019, 23(1): 132-142.
4. Sun Yu, Thakor N. Photoplethysmography revisited: from contact to noncontact, from point to imaging. IEEE Trans Biomed Eng, 2016, 63(3): 463-477.
5. 漆宇晟, 张爱华, 马玉润. 日常无监督状态下的脉率变异性提取方法研究. 生物医学工程学杂志, 2019, 36(2): 1-8.
6. 孙薇, 唐宁, 江贵平. 脉搏波信号特征点识别与预处理方法研究. 生物医学工程学杂志, 2015, 32(1): 197-201.
7. Manning T S, Shykoff B E, Izzo J L. Validity and reliability of diastolic pulse contour analysis (windkessel model) in humans. Hypertension, 2002, 39(5): 963-968.
8. Jiang X, Wei S, Ji J, et al. Modeling radial artery pressure waveforms using curve fitting: comparison of four types of fitting functions. Artery Res, 2018, 23: 56-62.
9. He Dianning, Wang Lu, Fan Xiaobing, et al. A new mathematical model of wrist pulse waveforms characterizes patients with cardiovascular disease - a pilot study. Med Eng Phys, 2017, 48(SI): 142-149.
10. Sološenko A, Petrėnas A, Marozas V, et al. Modeling of the photoplethysmogram during atrial fibrillation. Comput Biol Med, 2017, 81(2017): 130-138.
11. Liu C, Zheng D, Murray A, et al. Modeling carotid and radial artery pulse pressure waveforms by curve fitting with Gaussian functions. Biomedical Signal Processing and Control, 2013, 8(5): 449-454.
12. Couceiro R, Carvalho P, Paiva R P, et al. Assessment of cardiovascular function from multi-Gaussian fitting of a finger photoplethysmogram. Physiol Meas, 2015, 36(9): 1801-1825.
13. Sun Bin, Wang Chengchao, Chen Xiaohui, et al. PPG signal motion artifacts correction algorithm based on feature estimation. Optik (Stuttg), 2019, 176(2019): 337-349.
14. Paradkar N, Chowdhury S R. Cardiac arrhythmia detection using photoplethysmography// IEEE Engineering in Medicine and Biology Society, Jeju Island, Korea: IEEE, 2017: 113-116.
15. Alqudah A M. An enhanced method for real-time modelling of cardiac related bio-signals using Gaussian mixtures. J Med Eng Technol, 2017, 41(8): 600-611.
16. Yang Chenxi, Tang Sunli, Tavassolian N. Utilizing gyroscopes towards the automatic annotation of seismocardiograms. IEEE Sens J, 2017, 17(7): 2129-2136.
17. 张爱华, 丑永新. 动态脉搏信号的采集与处理. 中国医疗器械杂志, 2012, 36(2): 79-84.
18. Teng Y D, Ge L, Chou Y X. A novel abnormal segments detection method for photopletysmography signal// 2018 37th Chinese Control Conference (CCC), Wuhan: IEEE, 2018: 4113-4117.
19. 刘增丁, 陈骥, 汤敏芳. 基于波形时域特征和动态差分阈值的脉搏波传导时间检测算法. 生物医学工程学杂志, 2017, 34(3): 329-334.
20. 丑永新, 张爱华, 欧继青, 等. 基于手机的动态脉率变异性信号提取与分析. 中国医疗器械杂志, 2015, 39(5): 313-317.
21. Martin-Martinez D, Casaseca-de-La-Higuera P, Martin-Fernandez M, et al. Stochastic modeling of the PPG signal: a synthesis-by-analysis approach with applications. IEEE Trans Biomed Eng, 2013, 60(9): 2432-2441.
22. Goldberger A L, Amaral L A, Glass L, et al. PhysioBank, PhysioToolkit, and PhysioNet: components of a new research resource for complex physiologic signals. Circulation, 2000, 101(23): e215-e220.
23. Islam M S, Khreich W, Hamou-Lhadj A. Anomaly detection techniques based on Kappa-Pruned ensembles. IEEE Transactions on Reliability, 2018, 67(1): 212-229.

Journal of Biomedical Engineering

Study on a quantitative analysis method for pulse signal by modelling its waveform in time and space domain

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