Design of Fuzzy gain scheduled PI Controller for a nonlinear SISO Process
Journal: GRD Journal for Engineering (Vol.002, No. 1)Publication Date: 2016-12-18
Authors : S.Nagammai; G.Swathi Lakshmi; A.MahaLakshmi;
Page : 470-478
Keywords : Conical Tank Process; GSC; FGS; SISO;
Abstract
The typical nonlinear process such as conical tank and spherical tank process has the difficulty in controller design because of a change in system dynamics and valve nonlinearity. All industrial processes are almost nonlinear with wide operating range; the use of conventional PID controller becomes inefficient. For this reason the controller design for nonlinear system has become a very determinative and significant field of research. In a gain scheduled PI controller the controller gains are allowed to vary within a predetermined range and therefore eliminates the problem faced by the conventional PI controller. Gain Scheduling is the process through which the multiple local linear controllers are combined in order to control the process over the entire operating range. A main problem on the design of gain scheduling controller (GSC) is the design and implementation of the switching logic to have a smooth transition in plant response as the operating point changes. This difficulty is solved with the application of fuzzy logic controller (FLC). Fuzzy gain-scheduled (FGS) PI controller is a nonlinear controller which utilizes fuzzy rules and reasoning for determining the PI controller parameters. In this paper the illustration of FGS-PI controller is proposed to single input single output (SISO) nonlinear system namely conical tank process. The performances of the controllers are compared based on servo tracking using simulation results.
Citation: S.Nagammai, K.L.N. College of Engineering; G.Swathi Lakshmi ,; A.MahaLakshmi ,. "Design of Fuzzy gain scheduled PI Controller for a nonlinear SISO Process." Global Research and Development Journal For Engineering : 470 - 478.
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