Adaptive neural network control for a Robotic Manipulator with unknown deadzone

Author

Shuzhi Sam Ge ; Wei He ; Shengtao Xiao

Author_Institution

Robot. Inst. & Sch. of Comput. Sci. & Eng., Univ. of Electron. Sci. & Technol. of China, Chengdu, China

fYear

2013

Firstpage

2997

Lastpage

3002

Abstract

In this paper, adaptive neural network control is designed for a robotic manipulator with unknown dynamics. Neural networks are used to compensate for the unknown deadzone effect faced by the manipulator´s actuator. State-feedback control is proposed first and high-gain observer is then designed to make the proposed control scheme more practical. The deadzone effect is approximated by a Radial Basis Function Neural Network (RBFNN) and the tracking error for the deadzone effect is bounded and converging. The unknown dynamics of the robotic manipulator is estimated with another RBFNN. Compensating for the estimated deadzone effect in the control law then leads to our proposed control. The proposed control is then verified on a two-joint rigid manipulator via numerical simulations.

Keywords

actuators; adaptive control; compensation; control system synthesis; manipulator dynamics; neurocontrollers; observers; radial basis function networks; state feedback; RBFNN; adaptive neural network control; control law; high-gain observer; manipulator actuator; numerical simulations; radial basis function neural network; robotic manipulator; state-feedback control; tracking error; two-joint rigid manipulator; unknown deadzone effect; unknown dynamics; Manipulator dynamics; Neural networks; Output feedback; State feedback; Vectors; Neural network control; Radial basis function neural network (RBFNN); Robotic manipulator; Unknown deadzone;

fLanguage

English

Publisher

ieee

Conference_Titel

Control Conference (CCC), 2013 32nd Chinese

Conference_Location

Xi´an

Type

conf

Filename

6639934