Research on gait recognition and prediction based on optimized machine learning algorithm_Journal of Biomedical Engineering

Authors：

GAO Jingwei ¹ ,  MA Chao ¹ , SU Hong ¹ , WANG Shaohong ¹ , XU Xiaoli ¹ , YAO Jie ²

1. Key Laboratory of Modern Measurement and Control Technology, Ministry of Education Beijing Information Science and Technology University, Beijing 100192, P. R. China;
2. School of Biological Science and Medical Engineering, Beihang University, Beijing 100191, P. R. China;

Corresponding author：

MA Chao, Email: mach2006@126.com

Keywords：

Neural network; Immune particle swarm algorithm; Gated recurrent unit; Gait prediction

DOI：

10.7507/1001-5515.202106072

Video：

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Aiming at the problems of individual differences in the asynchrony process of human lower limbs and random changes in stride during walking, this paper proposes a method for gait recognition and prediction using motion posture signals. The research adopts an optimized gated recurrent unit (GRU) network algorithm based on immune particle swarm optimization (IPSO) to establish a network model that takes human body posture change data as the input, and the posture change data and accuracy of the next stage as the output, to realize the prediction of human body posture changes. This paper first clearly outlines the process of IPSO's optimization of the GRU algorithm. It collects human body posture change data of multiple subjects performing flat-land walking, squatting, and sitting leg flexion and extension movements. Then, through comparative analysis of IPSO optimized recurrent neural network (RNN), long short-term memory (LSTM) network, GRU network classification and prediction, the effectiveness of the built model is verified. The test results show that the optimized algorithm can better predict the changes in human posture. Among them, the root mean square error (RMSE) of flat-land walking and squatting can reach the accuracy of 10⁻³, and the RMSE of sitting leg flexion and extension can reach the accuracy of 10⁻². The R² value of various actions can reach above 0.966. The above research results show that the optimized algorithm can be applied to realize human gait movement evaluation and gait trend prediction in rehabilitation treatment, as well as in the design of artificial limbs and lower limb rehabilitation equipment, which provide a reference for future research to improve patients' limb function, activity level, and life independence ability.

Citation： GAO Jingwei, MA Chao, SU Hong, WANG Shaohong, XU Xiaoli, YAO Jie. Research on gait recognition and prediction based on optimized machine learning algorithm. Journal of Biomedical Engineering, 2022, 39(1): 103-111. doi: 10.7507/1001-5515.202106072 Copy

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14.	Hochreiter S, Schmidhuber J. Long short-term memory. Neural Comput, 1997, 9(8): 1735-1780.
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16.	Zebin T, Sperrin M, Peek N, et al. Human activity recognition from inertial sensor time-series using batch normalized deep LSTM recurrent networks//2018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC). Hawaii, USA: IEEE Xplore, 2018: 18-21.
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21.	王永华, 杨欣毅, 李本威, 等. 基于免疫粒子群算法的涡扇发动机性能仿真. 机械工程学报, 2013, 49(12): 153-160.

1. Weber L M, Stein J. The use of robots in stroke rehabilitation: a narrative review. Neurorehabilitation, 2018, 43(1): 99-110.
2. Huang M E, Millier L A, Lipschutz R, et al. Rehabilitation and prosthetic restoration in lower limb amputation// Braddom RL, Philadelphia, Saunders, Physical Medicine and Rehabilitation, 2011: 277-316.
3. Nizamis K, Stienen A H, Kamper D G, et al. Transferrable expertise from bionic arms to robotic exoskeletons: perspectives for stroke and duchenne muscular dystrophy. IEEE Trans Med Robot Bionics, 2019, 1(2): 88-96.
4. Gassert R, Dietz V. Rehabilitation robots for the treatment of sensorimotor deficits: a neurophysiological perspective. J Neuroeng Rehabil, 2018, 15(1): 46-61.
5. Hobbs B, Artemiadis P. A review of robot-assisted lower-limb stroke therapy: unexplored paths and future directions in gait rehabilitation. Front Neurorobot, 2020, 14: 19.
6. 谢峥, 王明江, 黄武龙, 等. 基于实时步态分析的行走辅助外骨骼机器人系统. 生物医学工程学杂志, 2017, 34(2): 265-270.
7. Mazzoleni S, Duret C, Grosmaire A G, et al. Combining upper limb robotic rehabilitation with other therapeutic approaches after stroke: current status, rationale, and challenges. Biomed Res Int, 2017, 2017: 8905637.
8. 班朝, 任国营, 王斌锐, 等. 基于IMU的机器人姿态自适应EKF测量算法研究. 仪器仪表学报, 2020, 41(2): 33-39.
9. Tagliamonte N L, Valentini S, Sudano A, et al. Switching assistance for exoskeletons during cyclic motions. Frontiers in Neurorobotics, 2019, 13(1): 41-54.
10. Tanghe K, De Groote F, Lefeber D, et al. Gait trajectory and event prediction from state estimation for exoskeletons during gait. IEEE Trans Neural Syst Rehabil Eng, 2020, 28(1): 211-220.
11. Pan Chengtang, Chang C C, Sun Peiyuan, et al. Development of multi-axis motor control systems for lower limb robotic exoskeleton. J Med Biol Eng, 2019, 39(5): 752-763.
12. Yun Y, Kim H C, Shin S Y, et al. Statistical method for prediction of gait kinematics with Gaussian process regression. J Biomech, 2014, 47(1): 186-192.
13. Melo N B, Dorea C E, Alsina P J, et al. Joint trajectory generator for powered orthosis based on gait modelling using PCA and FFT. Robotica International Journal of Information Education & Research in Robotics & Artificial Intelligence, 2018, 36(1): 395-407.
14. Hochreiter S, Schmidhuber J. Long short-term memory. Neural Comput, 1997, 9(8): 1735-1780.
15. Su B, Gutierrez F, Elena M. Gait trajectory and gait phase prediction based on an LSTM network. Sensors (Basel), 2020, 20(24): 238-255.
16. Zebin T, Sperrin M, Peek N, et al. Human activity recognition from inertial sensor time-series using batch normalized deep LSTM recurrent networks//2018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC). Hawaii, USA: IEEE Xplore, 2018: 18-21.
17. Ma X, Liu Y, Song Q, et al. Continuous estimation of knee joint angle based on surface electromyography using a long short-term memory neural network and time-advanced feature. Sensors, 2020, 20(17): 4966.
18. Su B, Smith C, Gutierrez F E. Gait phase recognition using deep convolutional neural network with inertial measurement units. Biosensors, 2020, 10(9): 109.
19. Zhou Zikang, Liang Binghong, Huang Guowei, et al. Individualized gait generation for rehabilitation robots based on recurrent neural networks. IEEE Trans Neural Syst Rehabil Eng, 2021, 29: 273-281.
20. Nakagome S, Luu T P, He Y, et al. An empirical comparison of neural networks and machine learning algorithms for EEG gait decoding. Scientific Reports, 2020, 10(1): 4372.
21. 王永华, 杨欣毅, 李本威, 等. 基于免疫粒子群算法的涡扇发动机性能仿真. 机械工程学报, 2013, 49(12): 153-160.

Journal of Biomedical Engineering

Research on gait recognition and prediction based on optimized machine learning algorithm

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