Title :
Bipedal modeling and decoupled optimal control design of biomechanical sit-to-stand transfer
Author :
Mughal, Asif M. ; Iqbal, Kamran
Author_Institution :
Dept. of Appl. Sci., Univ. of Arkansas at Little Rock, Little Rock, AR
Abstract :
We present the development of a 3D bipedal robotic model with thirteen generalized coordinates, and decoupled optimal controller design for the control of biomechanical sit-to-stand (STS) transfer. The non-linear model developed in Maple DynaFlexPro environment has three frontal and seven sagittal degrees of freedom (DOF). Three holonomic constraints ensure stationary foot placement during performance of the STS task. The controller design proceeds by decoupling the constrained and unconstrained DOF. We propose H2 and Hinfin optimal control designs for feedback control of joint torques in the constrained and unconstrained planes, respectively. We provide analytical and computer simulation results to show the applicability and performance of the decoupling controller for the control of STS task.
Keywords :
Hinfin control; biocontrol; biomechanics; feedback; legged locomotion; nonlinear control systems; torque control; H2 control; Hinfin control; Maple DynaFlexPro environment; biomechanical sit-to-stand transfer; bipedal modeling; bipedal robotic model; decoupled optimal control; feedback control; holonomic constraints; joint torque; nonlinear model; Analytical models; Computational modeling; Control systems; Design optimization; Foot; Humans; Hydrogen; Optimal control; Robot kinematics; Sociotechnical systems; 3D model; biomechanics; decoupled optimal control; sit-to-stand movement;
Conference_Titel :
Robotic and Sensors Environments, 2008. ROSE 2008. International Workshop on
Conference_Location :
Ottawa, ON
Print_ISBN :
978-1-4244-2594-5
Electronic_ISBN :
978-1-4244-2595-2
DOI :
10.1109/ROSE.2008.4669179
