Abstract
The paper describes the implementation and testing of two adaptive controllers developed for a wearable, underactuated upper extremity therapy robot – RUPERT (Robotic Upper Extremity Repetitive Trainer). The controllers developed in this study were used to implement two adaptive robotic therapy modes – the adaptive co-operative mode and the adaptive active-assist mode – that are based on two different approaches for providing robotic assistance for task practice. The adaptive active-assist mode completes therapy tasks when a subject is unable to do so voluntarily. This robotic therapy mode is a novel implementation of the idea of an active-assist therapy mode; it utilizes the measure of a subject’s motor ability, along with their real-time movement kinematics to initiate robotic assistance at the appropriate time during a movement trial. The adaptive co-operative mode, on the other hand, is based on the idea of enabling task completion instead of completing the task for the subject. Both these therapy modes were designed to adapt to a stroke subject's motor ability, and thus encourage voluntary participation from the stroke subject. The two controllers were tested on three stroke subjects practicing robot-assisted reaching movements. The results from this testing demonstrate that an underactuated wearable exoskeleton, such as RUPERT, can be used for administering robot-assisted therapy, in a manner that encourages voluntary participation from the subject undergoing therapy.
Highlights
Over the past 15 years there has been an increased interest in the use of robotic devices as tools for neurorehabilitation for the upper extremity [1,2,3,4]
The feedback controllers for implementing active-assist mode (AAM) and Adaptive cooperative mode (ACM) were developed for RUPERT and tested on three stroke survivors
This study demonstrates that an underactuated wearable exoskeleton, such as RUPERT, can be used for administering robot-assisted therapy, in a manner that encourages voluntary participation from the subject undergoing therapy
Summary
Over the past 15 years there has been an increased interest in the use of robotic devices as tools for neurorehabilitation for the upper (and the lower) extremity [1,2,3,4] The purpose of these robotic devices is to provide sensorimotor stimulation to the subject undergoing robot-assisted therapy. In a previous article [9] we had described the design and development of RUPERT III (Fig. 1), a wearable robotic exoskeleton developed by our group at the Arizona State University, and Kinetic Muscles Inc. RUPERT III (the third version of the robot) consists of four degrees-of-freedom (DOFs) – each activated by a single “McKibben” type pneumatic muscle actuator (PMA) [10]. Each DOF of the robot is instrumented with a position sensor to measure joint angle, and a pressure sensor to sense the internal PMA pressure
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