Title :
Adaptive non-linear least squares for inverse kinematics
Author :
Deo, A.S. ; Walker, I.D.
Author_Institution :
Dept. of Electr. Eng., Rice Univ., Houston, TX, USA
Abstract :
The use of an adaptive non-linear least squares algorithm to solve the inverse kinematic problem for robotic manipulators is proposed. The algorithm uses the Gauss-Newton model of the direct kinematic function with the Levenberg-Marquardt iteration. This first-order approximation is supplemented with a quadratic model in certain situations. If required the algorithm can converge to singular configurations, and hence is especially useful when the desired end-effector position is outside the reachable workspace of the manipulator. The authors prove that the task space error function has no local minimizers
Keywords :
inverse problems; kinematics; least squares approximations; manipulators; Gauss-Newton model; Levenberg-Marquardt iteration; adaptive nonlinear least squares algorithm; convergence; direct kinematic function; end-effector position; first-order approximation; inverse kinematics; quadratic model; robotic manipulators; singular configurations; task space error function; Acceleration; Convergence; Jacobian matrices; Kinematics; Least squares approximation; Least squares methods; Legged locomotion; Manipulators; Newton method; Recursive estimation;
Conference_Titel :
Robotics and Automation, 1993. Proceedings., 1993 IEEE International Conference on
Conference_Location :
Atlanta, GA
Print_ISBN :
0-8186-3450-2
DOI :
10.1109/ROBOT.1993.291981
