Robust Hybrid Motion Force Control Algorithm for Robot Manipulators
Authors
Abstract:
In this paper we present a robust hybrid motion/force controller for rigid robot manipulators. The main contribution of this paper is that the proposed hybrid control system is able to accomplish motion objectives in free directions and force objectives in constrained directions under parametric uncertainty both in robot dynamics and stiffness constraint constant. Also, the given scheme is proved globally stable in the sense that the control objectives are achieved asymptotically, when a signum function is used in the control law, though giving rise to chattering effects. To avoid this problem a saturation function is used. In this case the motion and force errors are proved to be bounded functions. Using the proposed control structure there is no need to measure the derivative of the interaction forces. Some simulation results are given to illustrate the control system performance.
similar resources
Robust Hybridmotion-force Control Algorithmfor Robot Manipulators
In this paper we present a robust hybrid motion/force controller for rigid robot Abstract manipulators. The main contribution of this paper is that the proposed hybrid control system is able to accomplish motion object ives in free direct ions and force object ives in constrained directions under parametric uncertainty both in robot dynamics and stiffness constraint constant. Also, the given sc...
full textNeural Network Techniques for Robust Force Control of Robot Manipulators
In this paper a neural network force/position control scheme is proposed to compensate uncertainties in both robot dynamics and unknown environment. The proposed impedance control allows us to regulate force directly by specifying a desired force. Training signals are proposed for a feed forward neural network controller. The robustness analysis of the uncertainties in environment position is p...
full textOn Robust Hybrid Force/Motion Control Strategies Based on Actuator Dynamics for Nonholonomic Mobile Manipulators
Robust force/motion control strategies are presented for mobile manipulators under both holonomic and nonholonomic constraints in the presence of uncertainties and disturbances. The controls are based on structural knowledge of the dynamics of the robot, and the actuator dynamics is also taken into account. The proposed control is robust not only to structured uncertainty such as mass variation...
full textAdaptive RBF network control for robot manipulators
TThe uncertainty estimation and compensation are challenging problems for the robust control of robot manipulators which are complex systems. This paper presents a novel decentralized model-free robust controller for electrically driven robot manipulators. As a novelty, the proposed controller employs a simple Gaussian Radial-Basis-Function Network as an uncertainty estimator. The proposed netw...
full textOn robust impedance force control of robot manipulators
In this paper, a new impedance function is proposed to achieve accurate force tracking under the presence of uncertainties in robot dynamics and environment models. The new impedance function is formulated on the basis of PID control of the force tracking error which compensates for the unknown environment stiiness and position. The robot dynamics uncertainties are compensated by a simple time-...
full textAdaptive Robust Motion and Force Tracking Control of Robot Manipulators in Contact with Stiff Surfaces
High performance robust motion and force tracking control of robot manipulators in contact with sti surfaces is considered in this paper. The robot parameters and the sti ness of the contact surface may not be known. The system may also be subjected to uncertain nonlinearities coming from the joint friction of the robot, external disturbances, the contact surface friction model, and the unknown...
full textMy Resources
Journal title
volume 13 issue 4
pages 55- 64
publication date 2000-11-01
By following a journal you will be notified via email when a new issue of this journal is published.
Hosted on Doprax cloud platform doprax.com
copyright © 2015-2023