An unconstrained optimization approach to the resolution of the inverse kinematic problem of redundant and nonredundant robot manipulators

Bestaoui, Y., An unconstrained optimization approach to the resolution of the inverse kinematic problem of redundant and nonredundant robot manipulators, Robotics and Autonomous Systems, 7 (1991) 37-45. This paper presents a comparative study of some unconstrained optimization techniques applied to robotic kinematic control. We are concerned not only with the final location of the end-effector but also with the velocity at which the end-effector moves. The position and velocity kinematic problems are related since the Jacobian matrix depends on the values of the joint variables. In order to move the end-effector in a specified direction at a specified speed, it is necessary to solve, at the same time, a set of nonlinear and a set of linear equations. Some well-known optimization techniques (valid for both nonredundant and redundant robots): steepest descent, conjugate gradient and quasi-Newton methods, are applied to solve this inverse kinematic problem. All these techniques are tested on two manipulators (a nonredundant and a redundant one) and compared by means of simulation.