Title :
Nonlinear rudder roll stabilization using Fuzzy Gain Scheduling - PID controller for naval vessel
Author :
Santoso, Mochamad Yusuf ; Shun-Feng Su ; Aisjah, Aulia Siti
Author_Institution :
Dept. of Electr. Eng., Nat. Taiwan Univ. of Sci. & Technol., Taipei, Taiwan
Abstract :
Rudder roll stabilization (RRS) for ship steering is to only use the rudder as the actuator for maintaining the autopilot heading and reducing the roll angle. In this study, a nonlinear control scheme for RRS was proposed based on Fuzzy Gain Scheduling (FGS)-PID. The proposed method was applied to a nonlinear multirole naval vessel model. The proposed method is compared with traditional PID and LQR. FGS-PID has more robust performance than the counterparts in yaw motion. For roll motion, the proposed control method has bigger roll reduction than Ziegler-Nichols PID. Based on the tracking control simulation result, FGS-PID can follow the desired heading changing very well, as well as in maintaining the roll angle below the limit.
Keywords :
fuzzy control; linear quadratic control; naval engineering; nonlinear control systems; ships; stability; three-term control; FGS-PID; LQR; PID controller; RRS; autopilot heading; fuzzy gain scheduling; nonlinear control scheme; nonlinear multirole naval vessel model; nonlinear rudder roll stabilization; roll reduction; ship steering; Actuators; Computational modeling; Damping; Educational institutions; Marine vehicles; Mathematical model; Simulation; PID controller; fuzzy gain scheduling; naval vessel; rudder roll stabilization;
Conference_Titel :
Fuzzy Theory and Its Applications (iFUZZY), 2013 International Conference on
Conference_Location :
Taipei
DOI :
10.1109/iFuzzy.2013.6825416
