Heart rate extraction algorithm based on adaptive heart rate search model_Journal of Biomedical Engineering

Authors：

MENG Ronghao ¹ ,  LI Zhuoshi ¹ ,  YU Helong ¹ , NIU Qichao ²

1. Jilin Agricultural University, Changchun 130000, P. R. China;
2. Institute of Flexible Electronics Technology of THU. Zhejiang, Jiaxing, Zhejiang 314000, P. R. China;

Corresponding author：

LI Zhuoshi, Email: lizs323@163.com; YU Helong, Email: yuhelong@jlau.edu.cn

Keywords：

Photoplethysmography; Self-adaptive heart rate separation model; Acceleration signal; Strong motion noise

DOI：

10.7507/1001-5515.202101091

Video：

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Abstract Full text Figures/Tables Video References Cited by

Photoplethysmography (PPG) is a non-invasive technique to measure heart rate at a lower cost, and it has been recently widely used in smart wearable devices. However, as PPG is easily affected by noises under high-intensity movement, the measured heart rate in sports has low precision. To tackle the problem, this paper proposed a heart rate extraction algorithm based on self-adaptive heart rate separation model. The algorithm firstly preprocessed acceleration and PPG signals, from which cadence and heart rate history were extracted respectively. A self-adaptive model was made based on the connection between the extracted information and current heart rate, and to output possible domain of the heart rate accordingly. The algorithm proposed in this article removed the interference from strong noises by narrowing the domain of real heart rate. From experimental results on the PPG dataset used in 2015 IEEE Signal Processing Cup, the average absolute error on 12 training sets was 1.12 beat per minute (bpm) (Pearson correlation coefficient: 0.996; consistency error: −0.184 bpm). The average absolute error on 10 testing sets was 3.19 bpm (Pearson correlation coefficient: 0.990; consistency error: 1.327 bpm). From experimental results, the algorithm proposed in this paper can effectively extract heart rate information under noises and has the potential to be put in usage in smart wearable devices.

Citation： MENG Ronghao, LI Zhuoshi, YU Helong, NIU Qichao. Heart rate extraction algorithm based on adaptive heart rate search model. Journal of Biomedical Engineering, 2022, 39(3): 516-526. doi: 10.7507/1001-5515.202101091 Copy

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14.	Zhang Z, Pi Z, Liu B. TROIKA: A general framework for heart rate monitoring using wrist-type photoplethysmographic signals during intensive physical exercise. IEEE Trans Biomed Eng, 2015, 62(2): 522-531.
15.	王岚, 彭敏, 周清峰. 基于自适应双阈值的计步算法. 计算机应用研究, 2020, 37(6): 1741-1744, 1773.
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17.	Zhang Z. Photoplethysmography-based heart rate monitoring in physical activities via joint sparse spectrum reconstruction. IEEE Trans Biomed Eng, 2015, 62(8): 1902-1910.
18.	Arunkumar K R, Bhaskar M. CASINOR: Combination of adaptive filters using single noise reference signal for heart rate estimation from PPG signals. Signal Image Video Process, 2020, 14: 1507-1515.
19.	Fujita Y, Hiromoto M, Sato T. PARHELIA: Particle filter-based heart rate estimation from photoplethysmographic signals during physical exercise. IEEE Trans Biomed Eng, 2018, 65(1): 189-198.
20.	Zhang Y S, Liu B Y, Zhang Z L. Combining ensemble empirical mode decomposition with spectrum subtraction technique for heart rate monitoring using wrist-type photoplethysmography. Biomed Signal Process Control, 2015, 21(1): 119-125.

1. 吴学思. 心率在心血管疾病中的意义. 中华内科杂志, 2006(7): 601-602.
2. Foroozan F. 基于MUSIC的算法利用腕上PPG信号提供按需心率估算. 中国电子商情(基础电子), 2018(4): 22-24.
3. 洋洋, 陈小惠, 王保强, 等. 脉搏信号中有效信号识别与特征提取方法研究. 电子测量与仪器学报, 2016, 30(1): 126-132.
4. 陈暘. 基于PPG的去运动伪影及心率估计方法研究. 成都: 电子科技大学, 2019.
5. Kajita M, Hara S. Motion artifact canceling PPG heart rate sensor based on an adaptive filter algorithm with variable tap length// Annu Int Conf IEEE Eng Med Biol Soc (EMBC). Montreal: EMBC, 2020: 4410-4413.
6. Shao Hanyu, Chen Xiaohui. Motion artifact detection and reduction in PPG signals based on statistics analysis//第29届中国控制与决策会议论文集. 重庆: IEEE, 2017: 1351-1356.
7. Zhang Z, Rao B D. Sparse signal recovery with temporally correlated source vectors using sparse Bayesian learning. IEEE J Sel Topics Signal Process, 2011, 5(5): 912-926.
8. 徐菁, 朱敏. 基于三轴加速度信号的心率修正算法. 计算机应用与软件, 2017, 34(12): 289-294.
9. Su SW, Huang S, Wang L, et al. Optimizing heart rate regulation for safe exercise. Ann Biomed Eng, 2010, 38(3): 758-768.
10. Girard C, Ibeas A, Vilanova R. Robust discrete-time linear control of heart rate during treadmill exercise// 2016 24th Iranian Conference on Electrical Engineering. Shirazi: ICEE, 2016: 1113-1118.
11. Temko A. Accurate heart rate monitoring during physical exercises using PPG. IEEE Trans Biomed Eng, 2017, 64(9): 2016-2024.
12. Lv Xueying, Wang Yitian, Deng Jjunyi, et al. Improved particle swarm optimization algorithm based on last-eliminated principle and enhanced information sharing. Comput Intell Neurosci, 2018, 2018: 5025672.
13. Esmaeili A, Ibeas A. Particie Swarm Optimization modelling of the heart rate response in treadmill exercise// 2016 20th International Conference on System Theory Control and Computing. Sinaia: ICSTCC, 2016: 613-618.
14. Zhang Z, Pi Z, Liu B. TROIKA: A general framework for heart rate monitoring using wrist-type photoplethysmographic signals during intensive physical exercise. IEEE Trans Biomed Eng, 2015, 62(2): 522-531.
15. 王岚, 彭敏, 周清峰. 基于自适应双阈值的计步算法. 计算机应用研究, 2020, 37(6): 1741-1744, 1773.
16. Cheng T M, Savkin A V, Celler B G, et al. Nonlinear modeling and control of human heart rate response during exercise with various work load intensities. IEEE Trans Biomed Eng, 2008, 55(11): 2499-2508.
17. Zhang Z. Photoplethysmography-based heart rate monitoring in physical activities via joint sparse spectrum reconstruction. IEEE Trans Biomed Eng, 2015, 62(8): 1902-1910.
18. Arunkumar K R, Bhaskar M. CASINOR: Combination of adaptive filters using single noise reference signal for heart rate estimation from PPG signals. Signal Image Video Process, 2020, 14: 1507-1515.
19. Fujita Y, Hiromoto M, Sato T. PARHELIA: Particle filter-based heart rate estimation from photoplethysmographic signals during physical exercise. IEEE Trans Biomed Eng, 2018, 65(1): 189-198.
20. Zhang Y S, Liu B Y, Zhang Z L. Combining ensemble empirical mode decomposition with spectrum subtraction technique for heart rate monitoring using wrist-type photoplethysmography. Biomed Signal Process Control, 2015, 21(1): 119-125.

Journal of Biomedical Engineering

Heart rate extraction algorithm based on adaptive heart rate search model

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