Jinhyeong Ahn scite author profile

Jinhyeong Ahn

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System Identification and Pitch Control of a Planing Hull Ship with a Controllable Stern Intercepter

Choi¹,

Park²,

Kim³

et al. 2018

SNAK

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This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License(http://creativecommons.org/licenses/by-nc/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.Planing hull type ships are often equipped with interceptor or trim tab to improve the excessive trim angle which leads to poor resistance and sea keeping performances. The purpose of this study is to design a controller to control the attitude of the ship by controllable stern interceptor and validate the effectiveness of the attitude control by the towing tank test. Embedded controller, servo motor and controllable stern interceptor system were equipped with planing hull type model ship. Prior to designing the control algorithm, a model test was performed to identify the system dynamic model of the planing hull type ship including the stern interceptor. The matrix components of model were optimized by Genetic Algorithm. Using the identified model, PID controller which is a classical controller and sliding mode controller which is a nonlinear robust controller were designed. Gain tuning of the controllers and running simulation was conducted before the towing tank test. Inserting the designed control algorithm into the embedded controller of the model ship, the effectiveness of the active control of the stern interceptor was validated by towing tank test. In still water test with small disturbance, the sliding mode controller showed better performance of canceling the disturbance and the steady-state control performance than the PID controller. Keywords : High speed planing hull(고속 활주선), Stern interceptor(선미 인터셉터), Ship attitude control(선박 자세 제어), System identification(시스템 식별), Genetic algorithm(유전 알고리즘), Towing tank test(예인수조실험) 1. 서 론 활주선형 선박은 여러 고속선형 중에서도 빠른 편에 속해 임 무수행 능력이 우수하고, 선저형상이 단순하여 설계가 용이하다 는 장점이 있다. 활주선형 선박은 고속으로 항주 시 중량의 상당 부분을 양력으로 지지하게 되며, 이때 선박의 부상량이 급격히 증가하게 되는데 이를 활주상태라고 한다. 활주상태에서는 종종 운항 중 과도한 트림각(trim)을 갖게 된다. 이럴 경우 항해사의 가시영역이 줄어들 뿐만 아니라 해상환경이 나빠질 경우 안 좋은 저항성능 및 내항성능을 보이게 된다. 이러한 문제를 개선하기 위하여 활주선형 선박에 인터셉터, 트림탭, 트린섬 웻지와 같은 부가물을 부착하여 음의 종동요 모멘트를 발생시켜 트림각을 줄

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Simulation-Based Determination of Hydrodynamic Derivatives and 6DOF Motion Analysis for Underwater Vehicle

Go¹,

Ahn²,

Ahn³

2017

J. Ocean Eng. Technol.

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This paper introduces a simulation-based determination method for hydrodynamic derivatives and 6DOF (degrees-offreedom) motion analysis for an underwater vehicle. Hydrodynamic derivatives were derived from second-order modulus expansion and composed of the added mass, and linear and nonlinear damping coefficients. The added mass coefficients were analytically obtained using the potential theory. All of the linear and nonlinear damping coefficients were determined using CFD simulation, which were performed for various cases based on the actual operating condition. Then, the linear and nonlinear damping coefficients were determined by fitting the CFD results, which referred to 6DOF forces and moments acting on an underwater vehicle, with the least square method. To demonstrate the applicability of the current study, 6DOF simulations for three different scenarios (L-, U-, and S-turn) were carried out, and the results were validated on the basis of physical plausibility.

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Development of the SONAR System for an Unmanned Surface Vehicle

Bae¹,

Kim

Kim³

et al. 2015

Journal of the Korea Institute of Military Science and Technolo

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Recently, unmanned systems are largely utilized in various fields due to the persistency and the least operational risk and an unmanned surface vehicle(USV) is the one of the representative application in the naval field. To assign multiple roles to an USV, we developed a sonar system which consists of a forward detecting sonar for the long-range detection, a downward detecting sonar for the small target scan and identification, and a strut type body for mounting sonar systems. In this paper, we described the developed sonar system for USV and the sea test results for verifying system performance. The test results showed that the developed sonar system was able to detect the underwater target about several kilometers away and could recognize a small object at the downside of the sonar system. We expect that the developed sonar system will be easily applied to other unmanned platforms without serious consideration.

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A Study on the Analysis of Underwater Behaviors of Two Bodies Having Different Weight Characteristics

Ahn¹,

Jung²

2012

Journal of the Korea Society for Simulation

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In this study, underwater behaviors of negative buoyant body and positive buoyant body, which are ejected from a platform, are compared through eject test and simulation. CFD(Computational Fluid Dynamics) method is used to calculate the hydrodynamic derivatives of negative buoyant body with varied hull. Hydrodynamic derivatives that cannot be calculated with CFD are used with the same values of base shape. The pitch angles of test data are much bigger than those of simulated data, and the reason is supposed to be the trailing air effect. A more accurate simulation is possible via modified force modeling which reflects this phenomenon. The underwater behaviors of positive buoyant body and negative buoyant body are somewhat different with each other at the same eject condition, but it may not be a problem in the view of operation.

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Study on the Development of the Maneuvering Mathematical Model Considering the Large Angle Motion of Submarine

Choi¹,

Lee²,

Ahn³

2023

J. Ocean Eng. Technol.

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Maneuverability is a crucial factor for the safety and success of submarine missions. This paper introduces a mathematical model that considers the large drift and angle of attack motions of submarines. Various computational fluid dynamics (CFD) simulations were performed to adapt Karasuno's fishery vessel maneuvering mathematical model to submarines. The study also presents the procedure for obtaining the physics-based hydrodynamic coefficients proposed by Karasuno through CFD calculations. Based on these coefficients, the reconstructed forces and moments were compared with those obtained from CFD and to the hydrodynamic derivatives expressed by a Taylor expansion. The study also discusses the mathematical maneuvering model that accounts for the large drift angles and angles of attack of submarines. The comparison results showed that the proposed maneuvering mathematical model based on modified Karasno’s model could cover a large range of motions, including horizontal motion and vertical motions. In particular, the results show that the physics-based mathematical maneuvering model can represent the forces and moments acting on the submarine hull during large drift and angle of attack motions. The proposed mathematical model based on the Karasuno model could obtain more accurate results than the Taylor third-order approximation-based mathematical model in estimating the hydrodynamic forces acting on submarines during large drift and angle of attack motions.

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Jinhyeong Ahn

System Identification and Pitch Control of a Planing Hull Ship with a Controllable Stern Intercepter

Simulation-Based Determination of Hydrodynamic Derivatives and 6DOF Motion Analysis for Underwater Vehicle

Development of the SONAR System for an Unmanned Surface Vehicle

A Study on the Analysis of Underwater Behaviors of Two Bodies Having Different Weight Characteristics

Study on the Development of the Maneuvering Mathematical Model Considering the Large Angle Motion of Submarine

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