Control-Oriented Planar Motion Modeling of Unmanned Surface Vehicles

OCEANS 2010 MTS/IEEE SEATTLE Pub Date : 2010-12-10 DOI:10.1109/OCEANS.2010.5664297

C. Sonnenburg, A. S. Gadre, D. Horner, S. Kragelund, A. Marcus, D. Stilwell, C. Woolsey

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引用次数: 30

Abstract

This paper describes a comparison of experimentally identified dynamic models for the planar motion of an unmanned surface vehicle (USV). The objective is to determine a model which is rich enough to enable effective motion planning and control, simple enough to allow straight forward parameter identification, and general enough to describe a variety of hullforms and actuator configurations. Starting from a three degree-of-freedom nonlinear model obtained from physical principles, we consider four simplified variants: (1) a linear model obtained by linearizing about straight, constant-speed motion, (2) a first order steering model (for turn rate) coupled with a first order speed model, (3) a second order steering model (for turn rate and sideslip angle), coupled with a first order speed model, and (4) a nonlinear model for low speed operation. The paper provides analysis of system identification data collected from field trials of three USV platforms in Summer 2010. The platforms represent three distinct control system implementations: a servo-actuated outboard engine, a servo-actuated jet-drive thruster, and differential thrusters.

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面向控制的无人水面车辆平面运动建模

本文对无人水面飞行器平面运动动力学模型进行了比较。目标是确定一个足够丰富的模型，以实现有效的运动规划和控制，足够简单，可以直接进行参数识别，并且足够通用，以描述各种船体形式和执行器配置。从由物理原理得到的三自由度非线性模型出发，我们考虑了四种简化的变量:(1)通过线性化直线、等速运动得到的线性模型，(2)一阶转向模型(关于转弯速率)耦合一阶速度模型，(3)二阶转向模型(关于转弯速率和侧滑角)耦合一阶速度模型，以及(4)低速运行的非线性模型。本文对2010年夏季三个USV平台现场试验收集的系统识别数据进行了分析。这些平台代表了三种不同的控制系统实现:伺服驱动的舷外发动机、伺服驱动的喷气驱动推进器和差动推进器。

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 2010 MTS/IEEE SEATTLE

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