Authors: Christopher Spiewak, M. R. Islam, Mohammad Arifur Rahaman, Mohammad H. Rahman, Roger Smith, Maarouf Saad

Abstract:

For those who have lost the ability to move their hand, going through repetitious motions with the assistance of a therapist is the main method of recovery. We have been developed a robotic assistive device to rehabilitate the hand motions in place of the traditional therapy. The developed assistive device (RAD-HR) is comprised of four degrees of freedom enabling basic movements, hand function, and assists in supporting the hand during rehabilitation. We used a nonlinear computed torque control technique to control the RAD-HR. The accuracy of the controller was evaluated in simulations (MATLAB/Simulink environment). To see the robustness of the controller external disturbance as modelling uncertainty (±10% of joint torques) were added in each joints.

Keywords: Biorobotics, rehabilitation, nonlinear control, robotic assistive device, exoskeleton.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1125743

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References:

[1] D. Mozaffarian, E. J. Benjamin, A. S. Go, D. K. Arnett, M. J. Blaha, M. Cushman, S. R. Das, S. de Ferranti, J. P. Després, H. J. Fullerton, and V. J. Howard, “Heart Disease and Stroke Statistics—2016 Update A Report from the American Heart Association,” Circulation, CIR-0000000000000350, 2015.
[2] “Paralysis,” Stroke.org, 2014. (Online). Available at: http://www.stroke.org/we-can-help/survivors/stroke-recovery/post-stroke-conditions/physical/paralysis. (Accessed: 06-Mar-2016).
[3] S. Masiero, A. Celia, G. Rosati, and M. Armani, “Robotic-assisted rehabilitation of the upper limb after acute stroke,” Archives of physical medicine and rehabilitation, vol. 88, no. 2, pp. 142-9, 2007.
[4] P. S. Lum, C.G. Burgar, P. C. Shor, M. Majmundar, and M. Van der Loos, "Robot-Assisted Movement Training Compared with Conventional Therapy Techniques for the Rehabilitation of Upper-Limb Motor Function After Stroke," Archives of Physical Medicine and Rehabilitation, vol. 83, no. 7, pp. 952-959, 2002.
[5] G. R. Romer, H. J. Stuyt, and A. Peters, "Cost-savings and economic benefits due to the assistive robotic manipulator (ARM)," in 9th International Conference on Rehabilitation Robotics, ICORR, 2005, pp. 201-204.
[6] A.D. Winter, Biomechanics and Motor Control of Human Movements, 2nd ed., University of Waterloo Press, Canada, 1992.
[7] J. J. Craig, Introduction to Robotics Mechanics and Control, 3rd ed.: Pearson Prentice Hall, 2004.
[8] N. P. Hamilton, Kinesiology: Scientific basis of human motion. Brown & Benchmark, 2011.
[9] D. J. Magee, J. E. Zachazewski, and W. S. Quillen, Pathology and intervention in musculoskeletal rehabilitation. Elsevier Health Sciences, 2008.
[10] M H. Rahman, M. Saad., J-P Kenné, and P. S. Archambault (2013). "Control of an Exoskeleton Robot Arm with Sliding Mode Exponential Reaching Law." International Journal of Control, Automation, and Systems ,201, vol. 11 no 1: pp 92-104.
[11] Chen M, SK Ho, HF Zhou, PMK Pang, XL Hu, Ng DTW, Tong KY:Interactive rehabilitation robot for hand function training. In Proc. IEEE International Conference on Rehabilitation Robotics ICORR.Kyoto, Japan; 2009:777–780.
[12] M. H. Rahman, M. J. Rahman, O. L. Cristobal, M. Saad, J. P. Kenné and P. S. Archambault " Development of a whole arm wearable robotic exoskeleton for rehabilitation and to assist upper limb movements." Robotica CJO 2014, doi:10.1017/S0263574714000034.