Lower limb joint contact forces and ground reaction forces analysis based on Azure Kinect motion capture_Journal of Biomedical Engineering

Authors：

PENG Yinghu ¹ , WANG Lin ^1,2 , CHEN Zhenxian ³ , DANG Xiaodong ³ , CHEN Fei ⁴ ,  LI Guanglin ¹

1. CAS Key Laboratory of Human-Machine Intelligence-Synergy Systems, Shenzhen Institutes of Advanced Technology, Chinese Academy of Sciences, Shenzhen, Guangdong 518055, P. R. China;
2. Shenzhen Intelligent Lower Limb Rehabilitation Engineering Research Center, Shenzhen, Guangdong 518055, P. R. China;
3. School of Mechanical Engineering, Chang’an University, Xi’an 710064, P. R. China;
4. Department of Biomedical Engineering, Faculty of Engineering, Hong Kong Polytechnic University, Hong Kong SAR, 999077, P. R. China;

Corresponding author：

LI Guanglin, Email: gl.li@siat.ac.cn

Keywords：

Lower limb joint contact forces; Azure Kinect motion capture; Ground reaction forces; Musculoskeletal multibody dynamics; Gait

DOI：

10.7507/1001-5515.202311040

Video：

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Traditional gait analysis systems are typically complex to operate, lack portability, and involve high equipment costs. This study aims to establish a musculoskeletal dynamics calculation process driven by Azure Kinect. Building upon the full-body model of the Anybody musculoskeletal simulation software and incorporating a foot-ground contact model, the study utilized Azure Kinect-driven skeletal data from depth videos of 10 participants. The in-depth videos were prepossessed to extract keypoint of the participants, which were then adopted as inputs for the musculoskeletal model to compute lower limb joint angles, joint contact forces, and ground reaction forces. To validate the Azure Kinect computational model, the calculated results were compared with kinematic and kinetic data obtained using the traditional Vicon system. The forces in the lower limb joints and the ground reaction forces were normalized by dividing them by the body weight. The lower limb joint angle curves showed a strong correlation with Vicon results (mean ρ values: 0.78 ~ 0.92) but with root mean square errors as high as 5.66°. For lower limb joint force prediction, the model exhibited root mean square errors ranging from 0.44 to 0.68, while ground reaction force root mean square errors ranged from 0.01 to 0.09. The established musculoskeletal dynamics model based on Azure Kinect shows good prediction capabilities for lower limb joint forces and vertical ground reaction forces, but some errors remain in predicting lower limb joint angles.

Citation： PENG Yinghu, WANG Lin, CHEN Zhenxian, DANG Xiaodong, CHEN Fei, LI Guanglin. Lower limb joint contact forces and ground reaction forces analysis based on Azure Kinect motion capture. Journal of Biomedical Engineering, 2024, 41(4): 751-757, 765. doi: 10.7507/1001-5515.202311040 Copy

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2.	Delp S L, Anderson F C, Arnold A S, et al. OpenSim: open-source software to create and analyze dynamic simulations of movement. IEEE Trans Biomed Eng, 2007, 54(11): 1940-1950..
3.	Windolf M, Götzen N, Morlock M. Systematic accuracy and precision analysis of video motion capturing systems—exemplified on the Vicon-460 system. J Biomech, 2008, 41(12): 2776-2780..
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7.	Latorre J, Colomer C, Alcañiz M, et al. Gait analysis with the Kinect v2: normative study with healthy individuals and comprehensive study of its sensitivity, validity, and reliability in individuals with stroke. J Neuroeng Rehabilitation, 2019, 16: 1-11..
8.	Skals S, Rasmussen K P, Bendtsen K M, et al. A musculoskeletal model driven by dual Microsoft Kinect Sensor data. Multibody Syst Dyn, 2017, 41: 297-316..
9.	Albert J A, Owolabi V, Gebel A, et al. Evaluation of the pose tracking performance of the azure kinect and kinect v2 for gait analysis in comparison with a gold standard: A pilot study. Sensors, 2020, 20(18): 5104..
10.	Latorre J, Llorens R, Colomer C, et al. Reliability and comparison of Kinect-based methods for estimating spatiotemporal gait parameters of healthy and post-stroke individuals. J Biomech, 2018, 72: 268-273..
11.	彭迎虎, 陈瑱贤, 胡家渝, 等. 人体足地接触模型的步速适用性. 医用生物力学, 2019, 34(5): 514-521..
12.	Fluit R, Andersen M S, Kolk S, et al. Prediction of ground reaction forces and moments during various activities of daily living. J Biomech, 2014, 47(10): 2321-2329..
13.	Yeung L-F, Yang Z, Cheng K C-C, et al. Effects of camera viewing angles on tracking kinematic gait patterns using Azure Kinect, Kinect v2 and Orbbec Astra Pro v2. Gait Posture, 2021, 87: 19-26..
14.	Peng Y, Wong D W-C, Wang Y, et al. Immediate effects of medially posted insoles on lower limb joint contact forces in adult acquired flatfoot: a pilot study. Int J Environ Res Public Health, 2020, 17(7): 2226..
15.	Komaris D-S, Perez-Valero E, Jordan L, et al. Effects of segment masses and cut-off frequencies on the estimation of vertical ground reaction forces in running. J Biomech, 2020, 99: 109552..
16.	Peng Y, Zhang Z, Gao Y, et al. Concurrent prediction of ground reaction forces and moments and tibiofemoral contact forces during walking using musculoskeletal modelling. Med Eng Phys, 2018, 52: 31-40..
17.	Sprague M A, Geers T L. Spectral elements and field separation for an acoustic fluid subject to cavitation. J Comput Phys, 2003, 184(1): 149-162..
18.	Ashburner J. SPM: a history. Neuroimage, 2012, 62(2): 791-800..
19.	Needham L, Evans M, Cosker D P, et al. The accuracy of several pose estimation methods for 3D joint centre localisation. Sci Rep, 2021, 11(1): 20673..

1. Damsgaard M, Rasmussen J, Christensen S T, et al. Analysis of musculoskeletal systems in the AnyBody Modeling System. Simul Model Pract Theory, 2006, 14(8): 1100-1111..
2. Delp S L, Anderson F C, Arnold A S, et al. OpenSim: open-source software to create and analyze dynamic simulations of movement. IEEE Trans Biomed Eng, 2007, 54(11): 1940-1950..
3. Windolf M, Götzen N, Morlock M. Systematic accuracy and precision analysis of video motion capturing systems—exemplified on the Vicon-460 system. J Biomech, 2008, 41(12): 2776-2780..
4. Topley M, Richards J G. A comparison of currently available optoelectronic motion capture systems. J Biomech, 2020, 106: 109820..
5. Andersen M S, Damsgaard M, MacWilliams B, et al. A computationally efficient optimisation-based method for parameter identification of kinematically determinate and over-determinate biomechanical systems. Comput Methods Biomech Biomed Engin, 2010, 13(2): 171-183..
6. Herda L, Fua P, Plänkers R, et al. Using skeleton-based tracking to increase the reliability of optical motion capture. Hum Mov Sci, 2001, 20(3): 313-341..
7. Latorre J, Colomer C, Alcañiz M, et al. Gait analysis with the Kinect v2: normative study with healthy individuals and comprehensive study of its sensitivity, validity, and reliability in individuals with stroke. J Neuroeng Rehabilitation, 2019, 16: 1-11..
8. Skals S, Rasmussen K P, Bendtsen K M, et al. A musculoskeletal model driven by dual Microsoft Kinect Sensor data. Multibody Syst Dyn, 2017, 41: 297-316..
9. Albert J A, Owolabi V, Gebel A, et al. Evaluation of the pose tracking performance of the azure kinect and kinect v2 for gait analysis in comparison with a gold standard: A pilot study. Sensors, 2020, 20(18): 5104..
10. Latorre J, Llorens R, Colomer C, et al. Reliability and comparison of Kinect-based methods for estimating spatiotemporal gait parameters of healthy and post-stroke individuals. J Biomech, 2018, 72: 268-273..
11. 彭迎虎, 陈瑱贤, 胡家渝, 等. 人体足地接触模型的步速适用性. 医用生物力学, 2019, 34(5): 514-521..
12. Fluit R, Andersen M S, Kolk S, et al. Prediction of ground reaction forces and moments during various activities of daily living. J Biomech, 2014, 47(10): 2321-2329..
13. Yeung L-F, Yang Z, Cheng K C-C, et al. Effects of camera viewing angles on tracking kinematic gait patterns using Azure Kinect, Kinect v2 and Orbbec Astra Pro v2. Gait Posture, 2021, 87: 19-26..
14. Peng Y, Wong D W-C, Wang Y, et al. Immediate effects of medially posted insoles on lower limb joint contact forces in adult acquired flatfoot: a pilot study. Int J Environ Res Public Health, 2020, 17(7): 2226..
15. Komaris D-S, Perez-Valero E, Jordan L, et al. Effects of segment masses and cut-off frequencies on the estimation of vertical ground reaction forces in running. J Biomech, 2020, 99: 109552..
16. Peng Y, Zhang Z, Gao Y, et al. Concurrent prediction of ground reaction forces and moments and tibiofemoral contact forces during walking using musculoskeletal modelling. Med Eng Phys, 2018, 52: 31-40..
17. Sprague M A, Geers T L. Spectral elements and field separation for an acoustic fluid subject to cavitation. J Comput Phys, 2003, 184(1): 149-162..
18. Ashburner J. SPM: a history. Neuroimage, 2012, 62(2): 791-800..
19. Needham L, Evans M, Cosker D P, et al. The accuracy of several pose estimation methods for 3D joint centre localisation. Sci Rep, 2021, 11(1): 20673..

Journal of Biomedical Engineering

Lower limb joint contact forces and ground reaction forces analysis based on Azure Kinect motion capture

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