Developing the sensor system for lower limb rehabilitation robot : for shifting of body-weight via insole flexi-force sensing

This report reflects the methods for device-assisted body-weight shifting (BWS) during walking rehabilitation. The relevance of this report to device-assisted BWS is that it presents the specific kinematics of pelvis during walking, and suggests a way in which modification of the current robotic reh...

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Main Author: Low, Mui Yen.
Other Authors: Low Kin Huat
Format: Final Year Project
Language:English
Published: 2009
Subjects:
Online Access:http://hdl.handle.net/10356/17544
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-175442023-03-04T19:16:10Z Developing the sensor system for lower limb rehabilitation robot : for shifting of body-weight via insole flexi-force sensing Low, Mui Yen. Low Kin Huat School of Mechanical and Aerospace Engineering Robotics Research Centre DRNTU::Engineering::Mechanical engineering::Assistive technology This report reflects the methods for device-assisted body-weight shifting (BWS) during walking rehabilitation. The relevance of this report to device-assisted BWS is that it presents the specific kinematics of pelvis during walking, and suggests a way in which modification of the current robotic rehabilitation robot to assist patient with body-weight shifting can be implemented. The value of this report in relation to the study of lower-limb rehabilitation is the intensive literature study and the record of relevant experiments that involve some of the clinical rehabilitation equipment, in particular the electromyography system and the piezoelectric sensors. This report includes, firstly, the design of a robotic mechanism for lateral pelvic control which is one of the key body-weight shifting during the stance phase of the walking gait cycle. In designing the robotic mechanism, intensive effort is made to simplify the pelvic movements and possible robotic assistance, thereby a detailed robotic mechanism for compensating one of the movements is designed. Secondly, it consists of the investigation of sensory information from the feet through thin-foil peizo-resistive sensor, known as the Flexi-force sensor, which is intended to provide sensor feedback to the mechanism. This Flexi-force sensor is one of most cost-effective clinical equipment to acquire temporal information of the walking gait. Lastly, the research is substantiated with the study of electromyography (EMG) pattern of lower-limb muscles during walking to understand the human biomechanics involved in normal unassisted walking and device-assisted walking. Bachelor of Engineering 2009-06-09T06:25:24Z 2009-06-09T06:25:24Z 2009 2009 Final Year Project (FYP) http://hdl.handle.net/10356/17544 en Nanyang Technological University 133 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Engineering::Mechanical engineering::Assistive technology
spellingShingle DRNTU::Engineering::Mechanical engineering::Assistive technology
Low, Mui Yen.
Developing the sensor system for lower limb rehabilitation robot : for shifting of body-weight via insole flexi-force sensing
description This report reflects the methods for device-assisted body-weight shifting (BWS) during walking rehabilitation. The relevance of this report to device-assisted BWS is that it presents the specific kinematics of pelvis during walking, and suggests a way in which modification of the current robotic rehabilitation robot to assist patient with body-weight shifting can be implemented. The value of this report in relation to the study of lower-limb rehabilitation is the intensive literature study and the record of relevant experiments that involve some of the clinical rehabilitation equipment, in particular the electromyography system and the piezoelectric sensors. This report includes, firstly, the design of a robotic mechanism for lateral pelvic control which is one of the key body-weight shifting during the stance phase of the walking gait cycle. In designing the robotic mechanism, intensive effort is made to simplify the pelvic movements and possible robotic assistance, thereby a detailed robotic mechanism for compensating one of the movements is designed. Secondly, it consists of the investigation of sensory information from the feet through thin-foil peizo-resistive sensor, known as the Flexi-force sensor, which is intended to provide sensor feedback to the mechanism. This Flexi-force sensor is one of most cost-effective clinical equipment to acquire temporal information of the walking gait. Lastly, the research is substantiated with the study of electromyography (EMG) pattern of lower-limb muscles during walking to understand the human biomechanics involved in normal unassisted walking and device-assisted walking.
author2 Low Kin Huat
author_facet Low Kin Huat
Low, Mui Yen.
format Final Year Project
author Low, Mui Yen.
author_sort Low, Mui Yen.
title Developing the sensor system for lower limb rehabilitation robot : for shifting of body-weight via insole flexi-force sensing
title_short Developing the sensor system for lower limb rehabilitation robot : for shifting of body-weight via insole flexi-force sensing
title_full Developing the sensor system for lower limb rehabilitation robot : for shifting of body-weight via insole flexi-force sensing
title_fullStr Developing the sensor system for lower limb rehabilitation robot : for shifting of body-weight via insole flexi-force sensing
title_full_unstemmed Developing the sensor system for lower limb rehabilitation robot : for shifting of body-weight via insole flexi-force sensing
title_sort developing the sensor system for lower limb rehabilitation robot : for shifting of body-weight via insole flexi-force sensing
publishDate 2009
url http://hdl.handle.net/10356/17544
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