• 한국항해학회지
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• 제10권1호
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• pp.11-17
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• 1986

• International Journal of Naval Architecture and Ocean Engineering
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• 제8권1호
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• pp.102-109
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• 2016

The hydrodynamic interaction between two large vessels can't be neglected when two large vessels are closed to each other in restricted waterways such as in a harbor or narrow channel. This paper is mainly concerned with the ship maneuvering motion based on the hydrodynamic interaction effects between two large vessels moving each other in curved narrow channel. In this research, the characteristic features of the hydrodynamic interaction forces between two large vessels are described and illustrated, and the effects of velocity ratio and the spacing between two vessels are summarized and discussed. Also, the Inchon outer harbor area through the PALMI island channel in Korea was selected, and the ship maneuvering simulation was carried out to propose an appropriate safe speed and distance between two ships, which is required to avoid sea accident in confined waters. From the inspection of this investigation, it indicates the following result. Under the condition of $SP_{12}{\leq}0:5L$, it may encounter a dangerous tendency of grounding or collision due to the combined effect of the interaction between ships and external forces. Also considering the interaction and wind effect as a parameter, an overtaken and overtaking vessel in narrow channel can navigate while keeping its own original course under the following conditions; the lateral separation between two ships is about kept at 0.6 times of ship length and 15 degrees of range in maximum rudder angle. On the other hand, two ships while overtaking in curved narrow channel such as Inchon outer harbor in Korea should be navigated under the following conditions; $SP_{12}$ is about kept at 1.0 times of ship length and the wind velocity should not be stronger than 10 m/s.

• 한국항해항만학회지
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• 제27권6호
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• pp.611-618
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• 2003

It can be said that the relationship between the maneuvering ability of operators and the navigational environment affects the safe degree of navigation in the collision avoidance situation. In order to reduce the occurrence probability of accident and to maintain the safety, it is necessary to clarify the relationship between human behavior and navigational environment. In this study, therefore, we analyzed and discussed the relationship between the maneuvering characteristics and the safety focused on human behavior as a fundamental factor of marine accidents using ship handling simulator and questionnaire. As a result, we concluded that navigational environment changes variously and the maneuvering ability of operators also varies with the navigational environment, and the ship handling characteristics strongly affect the occurrence probability of accident.

• 한국항해학회지
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• 제16권3호
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• pp.33-41
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• 1992

Handling performance of a vessel is greatly related with her steering characteristics which consist of two kinds of motion characteristics ; namely course stability and turning ability. The correct prediction of the qualities, especially the steering characteristics is as much important in ship handling as in ship design. It is the purpose of this paper to provide ships handlers better understanding of steering characteristics and then to help them in safe controlling and maneuvering of vessels presenting distinct inherent steering characteristic difference that lies between a fine-form vessel and full-form vessel. The authors calculated dynamic course stabilities of two kinds of ideal models, one of which represents a fine-form ship and the other a full-form ship, based on hydrodynamic data of forces and moments obtained by model tests in maneuvering tanks. The result of calculations indicated that a ship of full-form configuration has inhernet course instability. Though significant nonlinearties affect ship montions in maneuvers, application of linear theory is sufficient for prediction of the maneuvering characteristics of vessels on calm waters for handling reference.

• 한국항해항만학회지
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• 제34권5호
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• pp.343-348
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• 2010

해상 교통량이 증가함에 따라 높아지는 선박 사고위험을 줄이기 위해 안전 운항을 위한 시스템은 필수적이다. 국제해사기구의 SOLAS에서는 선박에 AIS(Automatic Identification System)의 탑재를 의무화 하였다. AIS는 육상과 타 선박에 신원, 종류, 위치, 항해 상태를 포함한 각종 항해정보와 선박상태를 자동으로 알리는 시스템이다. 안전운항을 위한 응용서비스 개발의 대부분의 경우에 AIS는 활용될 수 있으므로, 체계적인 정보의 관리가 필요하다. 본 논문에서는 수신된 메시지 정보를 관리하기 위해 데이터베이스를 도입하였다. AIS메시지를 정적정보와 동적정보로 나누어 저장하고, 전자해도 기반 AIS 정보를 디스플레이하는 시스템 구현을 통해 설계의 결과를 확인했다.

• International Journal of Naval Architecture and Ocean Engineering
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• 제10권5호
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• pp.529-544
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• 2018

Ship owners now demand a new design approach for the rudder that considers detailed design information such as maneuverability and environmental loads etc. on a quantified basis. In this paper, we developed the concept of a safe operation capability chart for the design of a rudder area. The chart can be used as the basis of design considering the maneuverability and environmental loads. To confirm the applicability of the safe operation capability chart for use as the basis of design, four different rudders are assumed in this work. First, it is determined whether or not it is appropriate to design a rudder by applying a conventional design approach based on IMO maneuvering tests. The proposed concept is reviewed for use as the basis of the design by investigating the effect of rudder area on capability charts that are plotted according to the rudder under various environmental conditions.

• 해양환경안전학회:학술대회논문집
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• 해양환경안전학회 2006년도 추계학술발표회
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• pp.143-149
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• 2006

This paper is primarily focused on the safe navigation between overtaking and overtaken vesselsin restricted waterways under the external forces, such as wind and current. The maneuvering simulation between two ships was conducted to find an appropriate safe speed and distance, which is required to avoid collision. From the viewpoint of marine safety, a greater transversedistance between two ships is more needed for the smaller vessel. Regardless of external forces, the smaller vessel will get a greater effect of hydrodynamic forces than the higher one. In the case of close navigation between ships under the forces of wind and current, the vessel moving at a lower speed is potentially hazardous because the rudder force of the lower speed vessel is not sufficient for steady-state course-keeping, compared to that of the higher speed vessel.

• Journal of Mechanical Science and Technology
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• 제20권11호
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• pp.2002-2009
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• 2006

This paper is primarily focused on the safe navigation between overtaking and overtaken vessels in restricted waterways under the external forces, such as wind and current. The maneuvering simulation between two ships was conducted to find an appropriate safe speed and distance, which is required to avoid collision. From the viewpoint of marine safety, a greater transverse distance between two ships is more needed for the smaller vessel. Regardless of external forces, the smaller vessel will get a greater effect of hydrodynamic forces than the bigger one. In the case of close navigation between ships under the forces of wind and current, the vessel moving at a lower speed is potentially hazardous because the rudder force of the lower speed vessel is not sufficient for steady-state course-keeping, compared to that of the higher speed vessel.

• 한국항해항만학회:학술대회논문집
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• 한국항해항만학회 2006년도 International Symposium on GPS/GNSS Vol.1
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• pp.89-93
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• 2006

This paper is primarily focused on the safe navigation between overtaking and overtaken vessels in restricted waterways under the external forces, such as wind and current. The maneuvering simulation between two ships was conducted to find an appropriate safe speed and distance, which is required to avoid collision. From the viewpoint of marine safety, a greater transverse distance between two ships is more needed for the smaller vessel. Regardless of external forces, the smaller vessel will get a greater effect of hydrodynamic forces than the bigger one. In the case of close navigation between ships under the forces of wind and current, the vessel moving at a lower speed is potentially hazardous because the rudder force of the lower speed vessel is not sufficient for steady-state course-keeping, compared to that of the higher speed vessel.

• 한국ITS학회 논문지
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• 제16권4호
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• pp.153-163
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• 2017

본 연구에서는 운전자 별로 생활 중에 이동하는 주행 도로의 특징 및 교통상황이 서로 다르며 운전습관이 상이함을 고려하여, 운전자 혹은 운전자 그룹별 기계학습모형을 구성하고, 학습된 모델을 분석하여 운전자의 주행모드 별 특징을 탐색하여 자율 주행 자동차를 시뮬레이션 하였다. 운전지식을 활용하여 주행조작 전후 센서의 동작 상황에 따라 8종류의 종방향 모드와 4종류 회전모드로 구분하고, 종방향 모드와 회전모드를 결합한 21개의 결합형 주행모드로 세분화 하였다. 주행모드가 레이블 된 시계열 데이터에 대해 딥러닝 지도학습 모델인 RNN (Recurrent Neural Network), LSTM (Long Short-Term Memory), Bi-LSTM 모델을 활용하여서 운전자 별 혹은 운전자 그룹별 주행데이터를 학습하고, 학습된 모델을 테스트 데이터 셋에서 주행 모드인식률을 검증하였다. 실험 데이터는 미국 VTTI 기관에서 수집된 22명의 운전자의 1,500개의 실생활 주행 데이터가 사용되었다. 주행 모드 인식에 있어, 데이터 셋에 대해 Bi-LSTM 모델이 RNN, LSTM 모델에 비해 향상된 성능을 보였으며, 최대 93.41%의 주행모드 인식률을 확인하였다.