Jie Hong∗ and Xiansheng Qin∗
[1] Y.L. Wang, Z.X. Li, X.Q. Zhao, D. Wang, et al., Stroke care quality in China: Substantial improvement, and a huge challenge and opportunity, International Journal of Stroke, 12(3), 2017, 229–235. [2] A.M. Mamou and N. Saadia, A control strategy for developed lower limbs robotic rehabilitation chair, International Journal of Robotics and Automation, 32(6), 2017, 577–589. [3] S.H. Chen, W.M. Lien, W.W. Wang, G.D. Lee, e. al., Assistive control system for upper limb rehabilitation robot, IEEE Transactions on Neural Systems and Rehabilitation Engineering, 24(11), 2016, 1199–1209. [4] J.A. Blaya and H. Herr, Adaptive control of a variableimpedance ankle-foot orthosis to assist drop-foot gait, IEEE Transactions on Neural Systems and Rehabilitation Engineering, 12(1), 2004, 24–31. [5] M. Girone, G. Burdea, M. Bouzit, V. Popescu, et al., A stewart platform-based system for ankle telerehabilitation, Autonomous Robots, 10(2), 2001, 203–212. [6] S. Hesse, A. Waldner, and C. Tomelleri, Innovative gait robot for the repetitive practice of floor walking and stair climbing up and down in stroke patients, Journal of Neuroengineering and Rehabilitation, 7, 2010, 30. [7] C. Li, Z. Rusak, Y.M. Hou, C. Young, et al., Upper limb motor rehabilitation integrated with video games focusing on training fingers’ fine movements, International Journal of Robotics and Automation, 29(4), 2014, 359–368. [8] K.H. Low and Y. Yin, An integrated lower exoskeleton system towards design of a portable active orthotic device, International Journal of Robotics and Automation, 22(1), 2007, 32–43. [9] M.S. Masmoudi, N. Krichen, and M. Masmoudi, A hardwarebased implementation of a tsk fuzzy controller for a wheelchair system, International Journal of Robotics and Automation, 33(1), 2018, 12–22. [10] M. Li, G.H. Xu, J. Xie, and C.Y. Chen, A review: motor rehabilitation after stroke with control based on human intent, Proceedings of the Institution of Mechanical Engineerings, Part H: Journal of Engineering in Medicine, 232(4), 2018, 344–360. [11] J.B. Feland, J.W. Myrer, S.S. Schulthies, et al., The effect of duration of stretching of the hamstring muscle group for increasing range of motion in people aged 65 years or older, Physical Therapy, 81(5), 2001, 1110–1117. [12] J.d.R. Millan, F. Renkens, J. Mourino, and W. Gerstner, Noninvasive brain-actuated control of a mobile robot by human EEG, IEEE Transactions on Biomedical Engineering, 51(6), 2004, 1026–1033. [13] L.Z. Bi, X.A. Fan, and Y.L. Liu, EEG-based brain-controlled mobile robots: a survey, IEEE Transactions on HumanMachine Systems, 43(2), 2013, 161–176. [14] K. Tanaka, K. Matsunaga, and H.O. Wang, Electroencephalogram-based control of an electric wheelchair, IEEE Transactions on Robotics, 21(4), 2005, 762–766. [15] G. Purtscheller and F.H.L. da Silva. Event-related EEG/MEG synchronization and desynchronization: basic principles, Clinical Neurophysiology, 110(11), 1999, 1842–1857. 350
Important Links:
Go Back