A Robotic Model of Transfemoral Amputee Locomotion for Design Optimization of Knee Controllers
[摘要] A two-dimensional, seven link, nine degrees of freedom biped model was developed to investigate the dynamic characteristics of normal and transfemoral amputee locomotion during the entire gait cycle. The equations of motion were derived using the Lagrange method and the stance foot-ground contact was simulated using a five-point penetration model. The joint driving torques were obtained using forward dynamic optimization of the normal human gait and applied to the intact joints of the amputee. Three types of motion controllers; frictional, elastic and hydraulic were considered for the prosthetic joints of the amputee and their design parameters were optimized to achieve the closest kinematics to that of the normal gait. It was found that, if optimally designed, all three passive controllers could reasonably reproduce a normal kinematical pattern in the swing phase. However, the stance phase kinematics could only be replicated by the hydraulic and elastic controllers; the performance of the latter was high...
[发布日期] [发布机构]
[效力级别] [学科分类] 自动化工程
[关键词] Human Gait;Above-Knee Prosthesis;Robotic Modelling;Passive Controller;Forward Optimization [时效性]