Involuntary movement during haptics-enabled robotic rehabilitation: Analysis and control design

In this paper, a safety concern arising from pathological tremors in patients interacting with haptics-enabled rehabilitation robots is analyzed and the issue of tremor amplification for assistive/coordinative robotic rehabilitation is investigated. In order to deal with this issue, a control architecture is proposed to dissipate the extra energy of the system and guarantee its stability and safety of the patient. For this purpose, (a) first, a multilayer adaptive filter is proposed to estimate high-frequency components of hand motions (corresponding to involuntary movements); (b) then a resistive force field is generated and applied by the robot to attenuate the tremor; and (c) simultaneously the residual low-frequency voluntary actions are amplified/coordinated to deliver appropriate therapy. Stability analysis and a stabilization scheme are developed to guarantee safe interaction regardless of variations in the patient´s dynamics and tremor kinematics. The ultimate goal is to make it possible for patients with pathological tremors to take advantage of non-passive robotic assistive/coordinative therapy. This would not be possible using conventional systems due to the possibility of tremor amplification. Experimental results are presented.