Paper Info
Title
RBF Neural Network Backstepping Sliding Mode Adaptive Control for Dynamic Pressure Cylinder Electrohydraulic Servo Pressure System.
Abstract
According to the hydraulic principle diagram of the subgrade test device, the dynamic pressure cylinder electrohydraulic servo pressure system math model and AMESim simulation model are established. The system is divided into two parts of the dynamic pressure cylinder displacement subsystem and the dynamic pressure cylinder output pressure subsystem. On this basis, a RBF neural network backstepping sliding mode adaptive control algorithm is designed: using the double sliding mode structure, the two RBF neural networks are used to approximate the uncertainties in the two subsystems, provide design methods of RBF sliding mode adaptive controller of the dynamic pressure cylinder displacement subsystem and RBF backstepping sliding mode adaptive controller of the dynamic pressure cylinder output pressure subsystem, and give the two RBF neural network weight vector adaptive laws, and the stability of the algorithm is proved. Finally, the algorithm is applied to the dynamic pressure cylinder electrohydraulic servo pressure system AMESim model; simulation results show that this algorithm can not only effectively estimate the system uncertainties, but also achieve accurate tracking of the target variables and have a simpler structure, better control performance, and better robust performance than the backstepping sliding mode adaptive control (BSAC).
Year
DOI
Venue
2018
10.1155/2018/4159639
COMPLEXITY
Field
DocType
Volume
Control theory,Backstepping,Servo,Control theory,Cylinder,Adaptive control,Artificial neural network,Mathematics,Pressure system,Dynamic pressure
Journal
2018
ISSN
Citations 
PageRank 
1076-2787
0
0.34
References 
Authors
1
3
Name
Order
Citations
PageRank
Pan Deng1253.85
Liangcai Zeng200.68
Yang Liu372.72