Design of a switching control scheme for uncertain objects based on PID-type FNN and LS_SVMs
PID control schemes have been widely used for industrial process systems over the past several decades.Recently,by combining traditional PID method with modem intelligent control scheme,various control design methodologies have been proposed such as fuzzy PID,neural PID and PID self-tuning by pattern recognition.However,the serious problem here is that the controller parameters must be suitably adjusted according to the property of the controlled object,which often changes gradually.Many identification methods are introduced to cope with this problem,among which the neural network identification is widely used.Generally a static network cannot adequately approximate a dynamic system and the training speed of dynamic network is very slow while the convergence cannot be guaranteed.Moreover,if the range of system uncertainty is very wide,the control performance becomes quite conservative.In this paper,a kind of objects with the wide range of uncertainty is considered and a novel control scheme with switching structure is proposed.A PID-type fuzzy neural network(PFNN) is designed as the controller and optimized by offiine quantum-behaved particle swarm optimization(QPSO) with chaos strategy and online error back propagation tuning.The least square support vector machines (LS_SVMs) are introduced to determine the suitable controller parameters by switching and identifying the controlled object.Finally,the simulation results show the feasibility and validity of the proposed method.
uncertain object fuzzy neural network quantum-behaved particle swarm optimization nominal model least square support vector machine
Jun Zhao Gan-ping Li Chao-dan Zheng
Information Engineering School,Nanchang University Nanchang, China
国际会议
西安
英文
550-554
2012-08-24(万方平台首次上网日期,不代表论文的发表时间)