Design and Development of an Innovative Exoskeleton Arm
By: Manoj
.
Contributor(s): Sharma, Rohit.
Publisher: New Delhi Journals Pub 2019Edition: Vol.5(1), Jan-Jun.Description: 22-36p.Subject(s): Electrical EngineeringOnline resources: Click here
In:
International journal of electrical machines & drivesSummary: This project depicts a mechanical framework to bolster furthest point restoration in people who maintain neurological debilitations, for example, cervical level spinal rope wounds (SCI), procured mind wounds (ABIs) or stroke. This mechanical assistive restoration gadget would be utilized to give rehashed engine hone with an end goal to advance neurological recuperation and enhance useful utilization of the furthest point. The technical goal is development of a computer-controlled, interactive powered orthosis capable of training upper extremity movements in rehabilitation patients. The second goal is to develop training programs optimized to produce representative movement patterns involved in activities of daily living (ADLs). Control options will include multiple training protocols such as active, active-assistive and resistive modes. Late innovative advances have empowered the improvement of doable exoskeleton robots. Displaying programming has permitted exoskeletons to be tried in simulations before they are created, permitting quick model advancement.
| Item type | Current location | Call number | Status | Date due | Barcode | Item holds |
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Articles Abstract Database
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School of Engineering & Technology Archieval Section | Not for loan | 2020100 |
This project depicts a mechanical framework to bolster furthest point restoration in people who maintain neurological debilitations, for example, cervical level spinal rope wounds (SCI), procured mind wounds (ABIs) or stroke. This mechanical assistive restoration gadget would be utilized to give rehashed engine hone with an end goal to advance neurological recuperation and enhance useful utilization of the furthest point. The technical goal is development of a computer-controlled, interactive powered orthosis capable of training upper extremity movements in rehabilitation patients. The second goal is to develop training programs optimized to produce representative movement patterns involved in activities of daily living (ADLs). Control options will include multiple training protocols such as active, active-assistive and resistive modes. Late innovative advances have empowered the improvement of doable exoskeleton robots. Displaying programming has permitted exoskeletons to be tried in simulations before they are created, permitting quick model advancement.
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