This article presents a wearable lower extremity exoskeleton (LEE) designed to augment the ability of a human to walk while carrying payloads. The ultimate goal of the current research is to design and control a wearable power-assisted system that integrates a human’s intellect as the control command. The system in this work consists of an inner exoskeleton and an outer exoskeleton. The inner system measures the movements of the human and controls the outer system, which follows the human movements and supports the payload. A special foot-unit was designed to measure the zero moment points (ZMPs) of the human and the exoskeleton simultaneously. Using the measured human ZMP as the reference, the exoskeleton’s ZMP is controlled by trunk compensation to achieve stable walking. A COTS program, xPC Target, together with toolboxes from MATLAB, were used as a real-time operating system and integrated development environment, and real-time locomotion control of the exoskeleton was successfully implemented in this environment. Finally, some walking experimental results, by virtue of the ZMP control for the inner and outer exoskeletons, show that the stable walking can be achieved.

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Traditional shoulder therapy techniques involve the physical therapist controlling and measuring forces on the patient’s arm to work particular muscles. The imprecise nature of this leads to inconsistent exercises and inaccurate measurements of patient progress. Some research has shown that robotic devices can be valuable in a physical therapy setting, but most of these mechanisms do not have enough degrees of freedom in the shoulder joint to be useful in shoulder therapy, nor are they able to apply forces along the arm limbs. Based upon the shortcomings of traditional physical therapy robots and low force exoskeletons designed for virtual reality applications, requirements were generated for a robotic arm exoskeleton designed specifically for rehabilitation. Various kinematic designs were explored and compared until a final design emerged. Options for actuation were discussed, and the selection process for actuator components was detailed. Sensors were addressed in their role in the control and safety architecture. A mechanical analysis was performed on the final design to determine various properties, such as torque output, range of motion, and frequency response. Finally, a list of future work was compiled based on the final design’s deficiencies.

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BWSTT has become an accepted standard of care in gait rehabilitation methods. This type of locomotor training has many functional benefits, but the physical labor costs are considerable. To reduce therapist effort and improve the repeatability of locomotor training, three groups have developed commercially available robotic devices for assisted stepping. The purpose of these robotic devices is to augment locomotor rehabilitation by decreasing therapist manual assistance, increasing the amount of stepping practice, while decreasing therapist effort. Current clinical studies have yielded positive and promising results in locomotor rehabilitation inpatients with neurologic impairments of stroke or SCI. The potential benefits from robotic technology are significant for clinical use and research. As further research is conducted, rehabilitation therapists and patient outcomes will be able to contribute to the development of current and future technologies.

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Exoskeleton system which is to assist the motion of physically weak persons such as disabled, injured and elderly persons is discussed in this paper. The proposed exoskeletons are controlled basically based on the electromoyogram (EMG) signals. And a mind model is constructed to identify person’s mind for predicting or estimating person’s behavior. The proposed mind model is installed in an exoskeleton power assistive system named IAE for walking aid. The neural-network is also be used in this system to help learning. The on-line learning adjustment algorithm based on multi-sensor that are fixed on the robot is designed which makes the locomotion stable and adaptable.

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The design of a prosthetic device for patients who have suffered loss of muscular control of the hand is described. The authors present some preliminary design considerations, with emphasis on the sensing and actuation systems. The prototype achieves several movements of the fingers of the hand. The design is closely based on the natural human hand to ensure effectiveness and comfort. The exoskeleton is worn as a tight glove, and the joints are flexed by cables and motors. Some preliminary test results are reported.

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