Affiliations: Department of Mechanical and Aerospace Engineering, Carleton University, Ottawa, ON, Canada | Department of Automatic Control and Systems Engineering, University of Sheffield, Sheffield, UK
Note: [] Corresponding author: M. Saiful Huq, Department of Mechanical and Aerospace Engineering, Carleton University, Ottawa, ON, Canada. Email: mshuq@connect.carleton.ca
Abstract: A simulation based study of a completely new form of body-weight supported treadmill training (BWSTT) technique which is fully passive in nature is presented in this paper. The approach does not require any powered means at the lower limbs and is implemented using a combination of coordinated joint locking/unlocking and flexible torque transfer mechanisms. The hip extension pertaining to the stance phase of the gait cycle is achieved through the stance foot being literally dragged by the treadmill belt while the required manoeuvring of the trunk is expected to be accomplished by the voluntary arm-support from the subject. The swing phase, on the other hand, is initiated through appropriately coupling the swing knee with the contralateral extending hip and eventually achieve full knee extension through switching the treadmill speed to a lower value. Considering adequate support from the able arms, the process effectively turns the frictional force at the foot-treadmill belt interface into an agent causing the required whole body mechanical energy fluctuation during the gait cycle. The simulation platform consists of a dynamic planer (sagittal) full body humanoid model along with the treadmill model developed within a CAD based software environment interfaced with passive viscoelastic joint properties implemented in Simulink. The voluntary upper body effort as well as control of the gait cycle are also developed within MATLAB/Simulink environment. The gait cycle generated using the new concept is thoroughly investigated through this simulation study.
Keywords: Rehabilitation robotics, body-weight supported treadmill training (BWSTT), spinal cord injury (SCI), gait-cycle, control