Title :
Modeling for ship roll-added-resistance and its application on fin stabilizer control system
Author :
Zhiquan Liu ; Hongzhang Jin
Author_Institution :
Coll. of Autom., Harbin Eng. Univ., Harbin, China
Abstract :
Large roll motion induced by sea waves can severely affect the ability of surface ships and the ship speed will loss due to added resistance which caused by ship motions, especially in high sea states. In addition, with increasing needs of fuel efficiency and emissions reduction, the effect of added resistance on surface ship performance and control quality must be considered when a ship roll stabilisation control system is designed. An alternative roll added resistance model is introduced based on the near field method and the software ANSYS-AQWA is selected to determine the model parameters. As an application, fin stabilizer system is activated with a neural network proportional-integral-derivative (NN-PID) controller base on genetic algorithm (GA). Two kinds of input reference signals are adopted to investigate the effectiveness of this idea.
Keywords :
control engineering computing; genetic algorithms; marine engineering; motion control; neurocontrollers; ships; stability; three-term control; ANSYS-AQWA software; NN-PID controller; alternative roll added resistance model; emission reduction; fin stabilizer control system; fuel efficiency; genetic algorithm; near field method; neural network proportional-integral-derivative controller; roll motion; ship roll stabilisation control system; ship roll-added-resistance; surface ship control quality; surface ship performance; Control systems; Educational institutions; Immune system; Marine vehicles; Mathematical model; Neural networks; Resistance; NN-PID; added resistance; fin stabilizer; near filed method;
Conference_Titel :
OCEANS - Bergen, 2013 MTS/IEEE
Conference_Location :
Bergen
Print_ISBN :
978-1-4799-0000-8
DOI :
10.1109/OCEANS-Bergen.2013.6607942
