DocumentCode
1965790
Title
Inverse Neural MIMO NARX Model Identification of Nonlinear System Optimized with PSO
Author
Anh, Ho Pham Huy ; Phuc, Nguyen Huu
Author_Institution
Electr. & Electron. Eng. Dept., Ho Chi Minh City Univ. of Technol., Ho Chi Minh City, Vietnam
fYear
2010
fDate
13-15 Jan. 2010
Firstpage
144
Lastpage
149
Abstract
In this paper, a neural Inverse Dynamic MIMO NARX (Neural IDMN) model is applied for modelling and identifying simultaneously both of joints of the prototype 2- axes PAM robot arm. The contact force variations and highly nonlinear coupling features of both links of the 2-axes PAM system are modelled thoroughly through an Inverse Neural MIMO NARX Model-based identification process using experiment input-output training data. For the first time, the parameters of dynamic Inverse neural MIMO NARX Model of the 2-axes PAM robot arm has been identified and optimized with Particle Swarm optimisation (PSO) algorithm. The results show that the neural IDMN Model trained by PSO algorithm yields outstanding performance and perfect accuracy.
Keywords
MIMO systems; manipulator dynamics; neurocontrollers; nonlinear control systems; particle swarm optimisation; 2-axes PAM robot arm; experiment input-output training data; inverse dynamic neural MIMO NARX model; nonlinear system identification; particle swarm optimization; pneumatic artificial muscle; Design engineering; Force control; Friction; Intelligent robots; MIMO; Manipulators; Nonlinear systems; Particle swarm optimization; Rehabilitation robotics; Robust control; 2-axes PAM robot arm; Keywords-pneumatic artificial muscle (PAM); Particle Swarm optimisation (PSO) algorithm; modelling and identification; neural Inverse Dynamic MIMO NARX (Neural IDMN) model;
fLanguage
English
Publisher
ieee
Conference_Titel
Electronic Design, Test and Application, 2010. DELTA '10. Fifth IEEE International Symposium on
Conference_Location
Ho Chi Minh City
Print_ISBN
978-0-7695-3978-2
Electronic_ISBN
978-1-4244-6026-7
Type
conf
DOI
10.1109/DELTA.2010.61
Filename
5438697
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