考虑水上物体识别和识别结果的航线生成

IF 2.6 4区工程技术 Q1 Engineering

Journal of Marine Engineering and Technology Pub Date : 2023-09-01 DOI:10.5988/jime.58.629

Yuichiro Dake, Suisei Wada, Tomoya Fukukawa, Satoshi Minamiyama, Naohiro Hara, Hisashi Sugiura

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引用次数: 0

摘要

在近海自动导航中，由于目标区域较宽，导航环境稀疏，障碍物较少，一般不需要高精度的航路跟踪。另一方面，在港口等相对受限的区域进行自动导航时，目标区域环境密集，其他船只、浮标等障碍物较多，需要高度精确的航路跟踪。此外，该系统必须导航路线，能够与障碍物保持适当的距离，以准备应对意想不到的外力，如风。本文提出了一种生成合适航路的方法，以满足两种海图类型的不同需求，即近海自动航行海图，定义为稀疏广域海图，自动靠泊出海海图，定义为密集窄域海图。将该方法应用于实际环境验证其有效性，并利用生成的路径进行自动导航。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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水上での物体認識および認識結果を考慮した航路生成

In the case of automatic navigation in an offshore area, as the target area is wide and the navigation environment is sparse with few obstacles, highly accurate route-tracking is not generally required. On the other hand, when automatic navigation is performed in a relatively restricted area, such as a harbor, the target area has a dense environment with many obstacles such as other vessels and buoys, which requires highly accurate route tracking. In addition, the system must navigate a course that can maintain appropriate distances from obstacles in preparation for unexpected external forces such as wind. In this paper, we propose a method to generate an appropriate navigation route to satisfy different requirements of two chart types, namely charts for automatic navigation in offshore areas that are defined as sparse wide-area maps and those for automatic berthing and unberthing that are defined as dense narrow-area maps. The proposed method was then applied to the actual environment to verify its usefulness, and then automatic navigation was performed using a generated route.

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来源期刊

Journal of Marine Engineering and Technology 工程技术-工程：海洋

CiteScore

5.20

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of Marine Engineering and Technology will publish papers concerned with scientific and theoretical research applied to all aspects of marine engineering and technology in addition to issues associated with the application of technology in the marine environment. The areas of interest will include: • Fuel technology and Combustion • Power and Propulsion Systems • Noise and vibration • Offshore and Underwater Technology • Computing, IT and communication • Pumping and Pipeline Engineering • Safety and Environmental Assessment • Electrical and Electronic Systems and Machines • Vessel Manoeuvring and Stabilisation • Tribology and Power Transmission • Dynamic modelling, System Simulation and Control • Heat Transfer, Energy Conversion and Use • Renewable Energy and Sustainability • Materials and Corrosion • Heat Engine Development • Green Shipping • Hydrography • Subsea Operations • Cargo Handling and Containment • Pollution Reduction • Navigation • Vessel Management • Decommissioning • Salvage Procedures • Legislation • Ship and floating structure design • Robotics Salvage Procedures • Structural Integrity Cargo Handling and Containment • Marine resource and acquisition • Risk Analysis Robotics • Maintenance and Inspection Planning Vessel Management • Marine security • Risk Analysis • Legislation • Underwater Vehicles • Plant and Equipment • Structural Integrity • Installation and Repair • Plant and Equipment • Maintenance and Inspection Planning.