Abstract
SUMMARYA computationally fast inverse kinematic scheme is derived which solves robot's end-effector (EE) trajectories in terms of joint trajectories. The inverse kinematic problem (IKP) is cast as a control problem for a simple dynamic system. The resulting closed-loop algorithms are shown to guarantee satisfactory tracking performance. Differently from previous first-order schemes which only solve for joint positions and velocities, we propose here new second order tracking schemes which allow the on-line generation of joint position + velocity + acceleration (PVA) reference trajectories for any computed torque-like controller in sensor-based robot applications. The algorithms do explicitly solve the IKP for both EE position and orientation. Simulation results for a six-degree-of-freedom PUMA-like geometry demonstrate the effectiveness of the scheme, even near singularities.
Publisher
Cambridge University Press (CUP)
Subject
Computer Science Applications,General Mathematics,Software,Control and Systems Engineering
Reference39 articles.
1. Task-Priority Based Redundancy Control of Robot Manipulators
2. Resolved-acceleration control of mechanical manipulators
3. A rule-based inverse kinematics algorithm for redundant manipulators;Slotine;Intern. J. Robotics and Automation,1987
4. A solution algorithm to the inverse kinematic problem for redundant manipulators;Sciavicco;IEEE J. Robotics and Automation,1988
5. Wrist-Partitioned, Inverse Kinematic Accelerations and Manipulator Dynamics
Cited by
125 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献