A. Anderson, Javier G. Martin, N. Bouraqadi, L. Etienne, K. Langueh, L. Rajaoarisoa, G. Lozenguez, L. Fabresse, J. Maestre, E. Duviella
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引用次数: 1
Abstract
: Acquiring vast and reliable data of physicochemical parameters is critical to environment monitoring. In the context of water quality analysis, data collection solutions have to overcome challenges related to the scale of environments to be explored. Sites to monitor can be large or remote. These challenges can be approached by the use of Unmanned Vehicles (UVs). Robots provide both flexibility on intervention plans and technological methods for real-time data acquisition. Being autonomous, UVs can explore areas difficult to access or far from the shore. This paper presents a nonlinear Model Predictive Control (MPC) for UV-based exploration. The strategy aims to improve the data collection of physicochemical parameters with the use of an Unmanned Surface Vehicle (USV) targeting water quality analysis. We have performed simulations based on real field experiments with a SPYBOAT® on the Heron Lake in Villeneuve d’Ascq, France. Numerical results suggest that the proposed strategy outperforms the schedule of mission planning and exploration for large areas.
获取大量可靠的理化参数数据对环境监测至关重要。在水质分析的背景下,数据收集解决方案必须克服与待探索的环境规模相关的挑战。要监视的站点可以是大型的,也可以是远程的。这些挑战可以通过使用无人驾驶车辆(UVs)来解决。机器人提供了干预计划的灵活性和实时数据采集的技术方法。由于是自主的,uv可以探索难以进入或远离海岸的地区。提出了一种基于uv探测的非线性模型预测控制方法。该战略旨在通过使用针对水质分析的无人水面飞行器(USV)改进物理化学参数的数据收集。我们在法国Villeneuve d 'Ascq的Heron湖上进行了基于真实现场实验的SPYBOAT®模拟。数值计算结果表明,该策略在大范围内优于任务规划和勘探进度。
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