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Citation |
Onyango SO, Hamam Y, Djouani K, Daachi B. Simulation 2016; 92(4): 337-355. |
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Copyright |
(Copyright © 2016, SAGE Publishing) |
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DOI |
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PMID |
unavailable |
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Abstract |
Wheelchairs are broadly accepted and are widespread because of the assistance they provide to people with limited mobility. The design of a good controller generally involves the formulation of a comprehensive wheelchair model. Most dynamic models in the literature presume non-inclined planer surfaces within-doors, and therefore fail to take the combined effects of both gravitational forces and rolling friction on the usable-traction into consideration. Wheel-slip situations are also commonly neglected. This paper contributes to wheelchair modeling by proposing and formulating a dynamic model that considers the effects of rolling friction and gravitational potential on the wheelchair's road-load force, on both inclined and non-inclined surfaces. The dynamic model is derived through the Euler Lagrange procedure, and wheel slip is determined by an approach that reduces the convectional number of slip-detection encoders. In the closed-loop model, the input-output feedback controller is proposed for tracking the user inputs by torque compensation. The optimality of the resulting minimum-phase closed-loop system is then ensured through the performance index of the non-linear continuous-time generalized predictive control with good simulation results. The Author(s) 2016. Language: en |
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Keywords |
Wheelchairs; Friction; Models; Control engineering; Wheels; Dynamic models; Controllers; Tribology; Closed loop systems; Continuous time systems; Feedback linearization; Gravitation; Predictive control systems |