The number of people with abnormal gait in China has been increasing for years. Compared with traditional methods, lower limb rehabilitation robots which address problems such as longstanding human guidance may cause fatigue, and the training is lacking scientific and intuitive monitoring data. However, typical rigid rehabilitation robots are always meeting drawbacks like the enormous weight, the limitation of joint movement,and low comfort. The purpose of this research is to design a cable-driven flexible exoskeleton robot to assist in rehabilitation training of patients who have abnormal gait due to low-level hemiplegia or senility. The system consists of a PC terminal, a Raspberry Pi, and the actuator structure. Monitoring and training are realized through remote operation and interactive interface simultaneously. We designed an integrated and miniaturized driving control box. Inside the box, two driving cables on customized pulley-blocks with different radii can retract/release by one motor after transmitting the target position to the Raspberry Pi from the PC. The force could be transferred to the flexible suit to aid hip flexion and ankle plantar flexion. Furthermore, the passive elastic structure was intended to assist ankle dorsiflexion. We also adopted the predictable admittance controller,which uses the Prophet algorithm to predict the changes in the next five gait cycles from the current ankle angular velocity and obtain the ideal force curve through a functional relationship. The admittance controller can realize the desired force following. Finally, we finished the performance test and the human-subject experiment.Experimental data indicate that the exoskeleton can meet the basic demand of multi-joint assistance and improve abnormal postures. Meanwhile, it can increase the range of joint rotation and eliminate asymmetrical during walking.
XU Ziwei (徐子薇), XIE Le (谢叻)
. Cable-Driven Flexible Exoskeleton Robot for Abnormal Gait Rehabilitation[J]. Journal of Shanghai Jiaotong University(Science), 2022
, 27(2)
: 231
-239
.
DOI: 10.1007/s12204-021-2403-4
[1] Office of the Leading Group of the State Council. Major figures on 2020 population census of China [M].Beijing: China Statistic Press, 2021.
[2] PIRKER W, KATZENSCHLAGER R. Gait disorders in adults and the elderly people: A clinical guide [J].Wiener Klinische Wochenschrift, 2017, 129: 81-95.
[3] CHAO B, LIU J, WANG Y, et al. Stroke prevention and control in China: Achievements, challenges and responses [J]. Chinese Circulation Journal, 2019, 34(7): 625-631 (in Chinese).
[4] FIGUEIREDO J, SANTOS C P, MORENO J C. Automatic recognition of gait patterns in human motor disorders using machine learning: A review [J]. Medical Engineering & Physics, 2018, 53: 1-12.
[5] MORRIS M E, HUXHAM F E, MCGINLEY J, et al.Gait disorders and gait rehabilitation in Parkinson’s disease [J]. Advances in Neurology, 2001, 87: 347-361.
[6] KARAVAS N C, TSAGARAKIS N G, CALDWELL D G. Design, modeling and control of a series elastic actuator for an assistive knee exoskeleton [C]//2012 4th IEEE RAS and EMBS International Conference on Biomedical Robotics and Biomechatronics. Rome:IEEE, 2012: 1813-1819.
[7] SAWICKI G S, KHAN N S. A simple model to estimate plantarflexor muscle-tendon mechanics and energetics during walking with elastic ankle exoskeletons[J]. IEEE Transactions on Biomedical Engineering,2016, 63(5): 914-923.
[8] AWAD L N, BAE J, O’DONNELL, et al. A soft robotic exosuit improves walking in patients after stroke[J]. Science Translational Medicine, 2017, 9(400):eaai9084.
[9] SCHMIDT K, RIENER R. MAXX: mobility assisting textile exoskeleton that exploits neural control synergies [M]//Converging clinical and engineering research on neurorehabilitation II. Cham: Springer, 2017: 539-543.
[10] BARTENBACH V, SCHMIDT K, NAEF M, et al.Concept of a soft exosuit for the support of leg function in rehabilitation [C]//2015 IEEE/RAS-EMBS International Conference on Rehabilitation Robotics (ICORR 2015). Singapore: IEEE, 2015: 125-130.
[11] JIA J, WANG W, JIN A, et al. A soft lower limb power-assisted exoskeleton: CN 108992313A [P]. 2018-12-14 (in Chinese).
[12] DOLLAR A M, HERR H. Lower extremity exoskeletons and active orthoses: Challenges and state-of-theart [J]. IEEE Transactions on Robotics, 2008, 24(1):144-158.
[13] TAYLOR S J, LETHAM B. Forecasting at scale [J].The American Statistician, 2018, 72(1): 37-45.
[14] GRIMMER M, QUINLIVAN B T, LEE S, et al. Comparison of the human-exosuit interaction using ankle moment and ankle positive power inspired walking assistance [J]. Journal of Biomechanics, 2019, 83: 76-84.
[15] LIU D F, TANG Z Y, PEI Z C. Swing motion control of lower extremity exoskeleton based on admittance method [J]. Journal of Beijing University of Aeronautics and Astronautics, 2015,41(6): 1019-1025(in Chinese).
[16] OTT C, MUKHERJEE R, NAKAMURA Y. Unified impedance and admittance control [C]// 2010 IEEE International Conference on Robotics and Automation.Anchorage: IEEE, 2010: 554-561.
[17] FEI S, XIAO A. Motor speed control with MFAC optimized by genetic algorithm [J]. Mechanical Engineering & Automation, 2016 (1): 10-12 (in Chinese).
[18] ZHUMH, YANG C J, YANGW, et al. A Kinect-based motion capture method for assessment of lower extremity exoskeleton [M]//Wearable sensors and robots.Springer: Singapore, 2017: 481-494.
[19] ROY G, BHUIYA A, MUKHERJEE A, et al. Kinect camera based gait data recording and analysis for assistive robotics: An alternative to goniometer based measurement technique [J]. Procedia Computer Science,2018, 133: 763-771.
