Title :
PD Control of Overhead Crane with Velocity Estimation and Uncertainties Compensation
Author :
Toxqui, R. ; Yu, Wen ; Li, XiaoOu
Author_Institution :
Departamento de Control Automatico, CINVESTAV-IPN, Mexico City
Abstract :
Normal industrial PD control of overhead crane has two drawbacks, it needs joint velocity sensors; it cannot guarantee zero steady state error. In this paper we make two modifications to overcome these problems. High-gain observer is applied to estimate the joint velocities, and a RBF neural network is used to compensate gravity and friction. We give a new proof for high-gain observer, which explains a direct relation between observer gain and observer error. Based on Lyapunov-like analysis, we also prove the stability of the closed-loop system if the weights of RBF neural networks have certain learning rules and the observer is fast enough
Keywords :
Lyapunov methods; PD control; closed loop systems; compensation; control system analysis; cranes; learning (artificial intelligence); neurocontrollers; observers; radial basis function networks; stability; uncertain systems; Lyapunov-like analysis; RBF neural network; closed-loop system; friction; gravity; high-gain observer; industrial PD control; joint velocity sensors; learning rules; overhead crane; stability; uncertainty compensation; velocity estimation; Cranes; Error correction; Friction; Gravity; Industrial control; Neural networks; Observers; PD control; Steady-state; Uncertainty; PD control; RBF neural network; high-gain observer;
Conference_Titel :
Intelligent Control and Automation, 2006. WCICA 2006. The Sixth World Congress on
Conference_Location :
Dalian
Print_ISBN :
1-4244-0332-4
DOI :
10.1109/WCICA.2006.1712378
