Towards the Mechatronic Development of a New Upper-Limb Exoskeleton (SAMA)

Abdelbar, M.; Mohamed, I.; Abdellatif, A.; Hegaze, Moutaz M.

doi:10.3390/designs6050080

Cited by 5 publications

(2 citation statements)

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“…The Robot Operating System (ROS) is widely used in the design of the control systems of exoskeleton devices [17][18][19][20][21][22]. In [19], the authors present a new design of the robot's control software based on the ROS (Robot Operating System) platform to realize the basic rehabilitation training of the patient's shoulder.…”

Section: Introductionmentioning

confidence: 99%

“…In [19], the authors present a new design of the robot's control software based on the ROS (Robot Operating System) platform to realize the basic rehabilitation training of the patient's shoulder. Moreover, a new framework has been developed for rapid prototyping based on the integration between MATLAB-Simulink and the Robot Operating System (ROS) environment [20]. This framework allows robust position and torque control of the exoskeleton and real-time monitoring.…”

Section: Introductionmentioning

confidence: 99%

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RETRACTED: A Newly-Designed Wearable Robotic Hand Exoskeleton Controlled by EMG Signals and ROS Embedded Systems

Abdallah

Bouteraa

2023

Robotics

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One of the most difficult parts of stroke therapy is hand mobility recovery. Indeed, stroke is a serious medical disorder that can seriously impair hand and locomotor movement. To improve hand function in stroke patients, new medical technologies, such as various wearable devices and rehabilitation therapies, are being developed. In this study, a new design of electromyography (EMG)-controlled 3D-printed hand exoskeleton is presented. The exoskeleton was created to help stroke victims with their gripping abilities. Computer-aided design software was used to create the device’s 3D architecture, which was then printed using a polylactic acid filament. For online classifications, the performance of two classifiers—the support vector machine (SVM) and the K-near neighbor (KNN)—was compared. The Robot Operating System (ROS) connects all the various system nodes and generates the decision for the hand exoskeleton. The selected classifiers had high accuracy, reaching up to 98% for online classification performed with healthy subjects. These findings imply that the new wearable exoskeleton, which could be controlled in accordance with the subjects’ motion intentions, could aid in hand rehabilitation for a wider motion range and greater dexterity.

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