Abstract
This paper presents a novel kinematic reconstruction of the human arm chain with five degrees of freedom and the estimation of the shoulder location during rehabilitation therapy assisted by end-effector robotic devices. This algorithm is based on the pseudoinverse of the Jacobian through the acceleration of the upper arm, measured using an accelerometer, and the orientation of the shoulder, estimated with a magnetic angular rate and gravity (MARG) device. The results show a high accuracy in terms of arm joints and shoulder movement with respect to the real arm measured through an optoelectronic system. Furthermore, the range of motion (ROM) of 50 healthy subjects is studied from two different trials, one trying to avoid shoulder movements and the second one forcing them. Moreover, the shoulder movement in the second trial is also estimated accurately. Besides the fact that the posture of the patient can be corrected during the exercise, the therapist could use the presented algorithm as an objective assessment tool. In conclusion, the joints’ estimation enables a better adjustment of the therapy, taking into account the needs of the patient, and consequently, the arm motion improves faster.
Highlights
Robot-aided neuro-rehabilitation therapies have become an interesting field in the robotics area
This paper presents a kinematic reconstruction algorithm of human arm joints assuming a simplified model with five DoFs
The necessary devices to estimate the arm joints are: the end-effector robot; an accelerometer placed onto the upper arm and a magnetic angular rate and gravity (MARG) device placed onto the shoulder
Summary
Robot-aided neuro-rehabilitation therapies have become an interesting field in the robotics area. There are several devices, such as exoskeletons, prosthesis or end-effector configuration robots, developed for this purpose [1,2]. They are able to help and assist the shortcomings of human beings. Post-stroke patients usually lose limb mobility due to the impairment in motor activity. Rehabilitation in this field takes an important role when it comes to improving the motor and proprioceptive activity [3,4]. End-effector configuration robots are the most common devices used in these therapies They are adapted to and easy to use by patients with different diseases
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