Modelling, design, and control of a robotic running foot for footwear testing with flexible actuator
Footwear effects on the human feet have been widely studied to prevent injuries, improve sports performance, and human health through running exercise. Due to the dynamics of human joints and passive imitative feet, current automatic footwear testing systems reported in the literat...
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| Main Authors: | , , , |
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| Other Authors: | |
| Format: | Conference or Workshop Item |
| Language: | English |
| Published: |
2015
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| Subjects: | |
| Online Access: | https://hdl.handle.net/10356/103777 http://hdl.handle.net/10220/25519 http://www.icsst14.com/ |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Footwear effects on the human feet have been widely studied to prevent injuries, improve
sports performance, and human health through running exercise. Due to the dynamics of
human joints and passive imitative feet, current automatic footwear testing systems reported
in the literature are not very realistic, are limited in the imitation of running gaits, and still use
the passive prosthetic foot. In addition, many studies on humanoid walking robots, orthotic
ankles, and prosthetic foot for amputees only focus on the human ankle joint and walking
gaits. In this project, the design and control of a realistic robotic running foot-leg testing of
shoes are introduced. The designed robotic foot possesses a higher number of degrees of
freedom compared to other robotic systems in the literature and have abilities to mimic
accurately biomechanical patterns of the human foot as well as to replicate the plantar
pressure distribution under the foot sole in running in the sagittal plane. Because of
lightweight, flexibility, and ease of power transmission, the Bowden-cable or the tendon-
sheath mechanism (TSM) is used in this project for the actuation of the robotic joints.
However, nonlinear friction and backlash hysteresis in such mechanisms vary with the
change of cable configuration and they degrade the system performances. In this project,
novel nonlinear and adaptive schemes for controlling the position of the ankle and
metatarsophalangeal joints will also be presented. The control schemes consider the nonlinear
and backlash hysteresis as uncertainties and are able to deal with unexpected disturbances
due to the change of the cable configuration and the unknown environments. In addition, no
knowledge of the model parameters is required. To validate the design systems and control
approaches, simulations are also introduced. There are good agreements between the
proposed approaches and simulation results. |
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