1. INTRODUCTION

IN the recent decade, increasing attention has been given to the tracking control of robot manipulators. Tracking control is needed to make each joint track a desired trajectory. A lot of research has dealt with the tracking control problem: [1]–[4] were based on VSS (variable structure system) theory, [5]–[10] on adaptive theory, and [11]–[12] on Fuzzy logic. Robots have to face many uncertainties in their dynamics, in particular structured uncertainty, such as payload parameter, and unstructured one, such as friction and disturbance. It is difficult to obtain the desired control performance when the control algorithm is only based on the robot dynamic model. To overcome these difficulties, in this paper we propose the adaptive control schemes which utilize a neural network as a compensator for any uncertainty. To reduce the error between the real uncertainty function and the compensator, we design simple and robust adaptive laws based on Lyapunov stability theory. In the proposed control schemes, the NN compensator has to see many neural because uncertainties depend on all state variables. To overcome this problem, therefore, we introduce the control schemes in which the number of neural of the NN compensator can be reduced by using the properties of robot dynamics and uncertainties. By computer simulations, it is verified that the NN is capable to compensate the uncertainties of robot manipulator. This paper is organized as follows. Section 2 presents NN System. In Section 3, several properties of robot dynamics are introduced. In Section4, the adaptive control scheme is proposed, where the NN is utilized to compensate the uncertainties of the robot manipulator. The robust adaptive law is also designed. The algorithms that reduce the number of neural are proposed based on the properties of robot dynamics and uncertainties in Section 5. The decomposition algorithm of uncertainty function and results of computer simulations for the control scheme and experiment on dual-arm robot are also drawn in Section 6. In Section 7, we obtain the conclusions and discussion.