DocumentCode :
2248172
Title :
An Alternative CMAC Trained with Genetic Algorithms to Solve an Instable Control Process
Author :
Chung, Yun-Kung ; Hu, Shing-Chung
Author_Institution :
Dept. of Ind. Eng., Yuan-Ze Univ., Chung-Li
fYear :
2004
fDate :
22-26 Aug. 2004
Firstpage :
950
Lastpage :
954
Abstract :
Since CMAC (cerebellar model articulation controller), which mimics the recognition process of human cerebellum, is an artificial neural network (ANN) characterized by the fast learning or high convergence, it is easy to be programmed for online learning and real-time control. Diversified applications have exhibited the learning and solution abilities of CMAC; nevertheless, CMAC has an unstable learning performance in certain experimental cases presented by Chen and Chang (1996, 1995 and 1994). To overcome the above CMAC learning instability, a GA (genetic algorithm) is used as an alternative approach to train CMAC in this paper. GA is an optimization technique that mimics genetic changes in the life evolutionary process. It takes advantage of the multiple starting points for searching an optimal solution within a relatively short computational time. By comparing the standard CMAC and the GA-based CMAC (GACMAC), the usefulness of the GACMAC for overcoming the CMAC learning instability was verified by experimenting the Chan and Chang´s time series control problem. More general cases are needed to study for the confirmation of the alternative CMAC training performance in the near future
Keywords :
cerebellar model arithmetic computers; genetic algorithms; learning (artificial intelligence); time series; artificial neural network; cerebellar model articulation controller; dynamic control; genetic algorithm; human cerebellum; learning instability; life evolutionary process; online learning; real-time control; recognition process; time series control; Artificial neural networks; Brain modeling; Character recognition; Control systems; Genetic algorithms; Humans; Industrial engineering; Orbital robotics; Process control; Real time systems; CMAC; dynamic control; genetic algorithm; neural network; optimization;
fLanguage :
English
Publisher :
ieee
Conference_Titel :
Robotics and Biomimetics, 2004. ROBIO 2004. IEEE International Conference on
Conference_Location :
Shenyang
Print_ISBN :
0-7803-8614-8
Type :
conf
DOI :
10.1109/ROBIO.2004.1521913
Filename :
1521913
Link To Document :
بازگشت