Title :
Flexible link control using multiple forward paths, multiple RBF neural networks in a direct control application
Author :
Wedding, Daniel K. ; Eltimsahy, Adel
Author_Institution :
Owens Coll., Toledo, OH, USA
Abstract :
The article presents a control scheme that uses multiple radial basis function neural networks (RBFNNs) as a direct controller for a flexible link robot. Each RBFNN is trained to specialize in one type of movement and a logical switch determines which neural network (NN) will be active for each update time. Unlike most NN controllers, this controller will be trained offline and inserted after the output error drops to an acceptable level. By training the NNs offline, the update speed of the controller is increased. The goal of this design is to produce a highly accurate controller that can be easily and inexpensively implemented in industry. Simulation results are presented when the controller is tested with an aluminum alloy link driven by a dc motor
Keywords :
flexible manipulators; intelligent control; neurocontrollers; radial basis function networks; NN controllers; RBFNNs; accurate controller; aluminum alloy link; control scheme; dc motor; direct control application; direct controller; flexible link control; flexible link robot; logical switch; multiple RBF neural networks; multiple forward paths; multiple radial basis function neural networks; offline training; output error; update time; Aluminum alloys; DC motors; Error correction; Industrial control; Industrial training; Neural networks; Radial basis function networks; Robots; Switches; Testing;
Conference_Titel :
Systems, Man, and Cybernetics, 2000 IEEE International Conference on
Conference_Location :
Nashville, TN
Print_ISBN :
0-7803-6583-6
DOI :
10.1109/ICSMC.2000.884389
