Abstract

The rolling and heeling experienced by a ship during turning will be more severe under the interference of winds and waves, which will seriously affect the navigation safety of the ship. The fin stabilizer is currently the best active anti-rolling device, which is usually used to reduce the roll of the ship during straight-line sailing. The purpose of this work is to study the use of fin stabilizers to reduce the rolling and heeling during ship turning, considering the non-linearity and uncertainty during the rotation. The 4 degrees of freedom (4-DOF) nonlinear motion model of a multi-purpose naval vessel is established. The forces and moments produced by fin stabilizers, rudders, propellers, and waves are also considered. The nonlinear control model of rotation and roll is derived and established. Given the non-linearity and uncertainty in the ship turning process, an L2-gain based robust adaptive control is proposed to control the fin stabilizers to reduce the turning heel and roll motion. The proof of the stability and the detailed design process of the controller are also given. Simulations are carried out to verify the effectiveness of the proposed control strategy. For comparison purposes, the simulation results under a well-tuned PID controller are also given. The simulation results show that the developed control strategy can effectively reduce the heel and roll during ship turns, and it has good robustness against uncertainty and internal and external interference.

Highlights

  • When a ship is sailing at sea, it will experience movement in six degrees of freedom under the influence of winds, waves, and currents [1]

  • Since this paper mainly studies the use of fin stabilizer to reduce the heeling and rolling motion caused by ship turning and environmental disturbance, the pitch and heave attitudes, and their influence on the other four degrees of freedom can be neglected [30]

  • The 4 degrees of freedom (4-DOF) nonlinear mathematical model of a multipurpose naval vessel with forces and moments caused by hydrodynamics, waves, fin stabilizers, rudders and propellers is established

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Summary

Introduction

When a ship is sailing at sea, it will experience movement in six degrees of freedom under the influence of winds, waves, and currents [1]. The roll motion, mainly caused by waves, has the largest impact on ship navigation safety [2]. The fin stabilizer is currently the most effective active roll reduction device in the world [11]. The design and optimization of fin stabilizers are all aimed at minimizing the rolling motion of the ship caused by disturbances, such as sea waves during regular straight-line navigation, to ensure that the ship can sail smoothly and safely [6,12]

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