Optimizing autonomous underwater vehicle routes with the aid of high resolution ocean models

OCEANS 2019 MTS/IEEE SEATTLE Pub Date : 2019-10-01 DOI:10.23919/OCEANS40490.2019.8962569

Miguel Aguiar, J. D. de Sousa, J. Dias, J.E. da Silva, R. Mendes, A. Ribeiro

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引用次数: 4

Abstract

In underwater vehicle operations in areas such as estuaries, vehicles may face currents with magnitudes equal to or exceeding the vehicle's maximum forward speed. We propose a method which generates vehicle routes taking into account ocean current forecasts from high resolution ocean models, in order to both take advantage of the ocean current velocity and avoid its negative effects. We formulate the problem in an optimal control setting and derive the associated Hamilton-Jacobi-Bellman partial differential equation (PDE). We solve this PDE using a parallelized C++ implementation of a numerical method which allows us to obtain the solution in a few minutes on a mainstream computer. After obtaining the solution of the PDE, optimal trajectories with any initial condition can be computed efficiently. The method is illustrated using data from high-resolution ocean models of the Sado river estuary in Portugal. Two mission scenarios are analyzed, which highlight the influence of ocean currents on optimal trajectories and the benefits of considering ocean current forecasts in mission planning.

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基于高分辨率海洋模型的自主水下航行器路线优化

在河口等区域的水下航行器作业中，航行器可能会面临等于或超过航行器最大前进速度的水流。本文提出了一种考虑高分辨率海洋模型海流预报的车辆路线生成方法，既利用了海流速度的优势，又避免了其负面影响。在最优控制条件下，推导出相关的Hamilton-Jacobi-Bellman偏微分方程(PDE)。我们使用并行化c++实现的数值方法来求解这个PDE，这使我们能够在主流计算机上几分钟内得到解。在得到PDE的解后，可以有效地计算任意初始条件下的最优轨迹。该方法用葡萄牙萨多河河口的高分辨率海洋模型数据进行了说明。分析了两种任务情景，强调了洋流对最优轨迹的影响，以及在任务规划中考虑洋流预报的好处。

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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OCEANS 2019 MTS/IEEE SEATTLE

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