Abstract
This paper presents the design of an optimized Interval Type 2 Fuzzy Proportional Derivative Controller (IT2F-PDC) in cascade form for Rotary Inverted Pendulum (RIP) system. The parameters of the IT2F-PDC are optimised by using Genetic Algorithm (GA) and Particle Swarm Optimization (PSO). The goal is to balance the pendulum in upright unstable equilibrium position. The IT2F-PDC which is the extended version of conventional type 1 fuzzy logic controller, improves the control strategy by using the advantage of its footprint of uncertainty for the fuzzy membership function. The performance characteristics considered for the controller are steady state error, settling time, rise time, maximum overshoot, and control energy. Experimental and simulation results indicated that the effectiveness and robustness of the proposed GA- and PSO-based controllers on the RIP with respect to load disturbances, parameter variation, and noise effects have been improved over state-of-the-art method. However, the comparative results for simulation and experiment based on cascade IT2F-PDC indicate that GA-based IT2F-PDC has lower steady state error while PSO-based IT2F-PDC has lower overshoot, settling time, and control energy, but both have almost the same rise time. The proposed control strategy can be regarded as a promising strategy for controlling different unstable and nonlinear systems.
Highlights
Most real industrial systems are nonlinear in nature and exhibit some level of uncertainty [1, 2]
This paper presents the design of an optimized Interval Type 2 Fuzzy Proportional Derivative Controller (IT2F-PDC) in cascade form for Rotary Inverted Pendulum (RIP) system
FLC are of two types, namely, type 1 fuzzy logic controller (T1FLC) and type 2 fuzzy logic controller (T2FLC)
Summary
Most real industrial systems are nonlinear in nature and exhibit some level of uncertainty [1, 2]. Optimized cascade type 1 fuzzy logic controller was used in [33] for controls of pendulum angle and arm angles of RIP. The nonlinear equation of RIP can be found in (2) when the length of the pendulum from its centre of mass (lp), equivalent moment of inertia as seen at the load (Jeq), and equivalent viscous damping coefficient as seen at the load (Beq) are considered. The simulation results show that nonlinear 1 and nonlinear 2 are similar and their behaviours are the same for both pendulum angle and arm angle This shows that nonlinear 1 and nonlinear 2 can be considered as nonlinear model of the RIP because nonlinear 1 has already been proved and used in [33]. The response shows that the whole system is nonlinear and unstable
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