不平整地面条件下直升机机器人起落架的建模与控制

2017 Workshop on Research, Education and Development of Unmanned Aerial Systems (RED-UAS) Pub Date : 2017-10-01 DOI:10.1109/RED-UAS.2017.8101644

Daniel Melia Boix, Keng Goh, J. McWhinnie

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引用次数: 14

摘要

提出了一种利用比例铰接式机器人起落架研究直升机在不平坦地形降落问题的方法。研究了适应不平整地面条件的铰接式机器人起落架的数学模型。该模型由一个平面起落架组成，该起落架由两个支腿组成，两端由一个底座和一个滑块连接。每个滑橇有两个自由度与PID联合控制器，以提供稳定的着陆。结合拉格朗日和牛顿-欧拉技术建立了系统动力学模型。这项工作还包括一个地面相互作用的模型，一个推力控制器和一个在着陆时保持稳定的水平控制器。最后给出了实验结果，并与仿真结果进行了比较。

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Modelling and control of helicopter robotic landing gear for uneven ground conditions

This paper proposes a method to investigate into helicopter landing on uneven terrain by means of using a scaled articulated robotic landing gear. A mathematical model of an articulated robotic landing gear that adapts to uneven ground conditions is considered. The model consists of a planar landing gear composed of two legs connected by a base and a skid at each end. Each skid has two degrees of freedom with PID joint controllers to provide stability while landing. A combination of Lagrange and Newton-Euler techniques is used to model the system dynamics. This work also includes a model of the ground interaction, a thrust controller and a level controller to maintain stability while landing. Experimental results with a laboratory-build scaled prototype are included and compared with the simulations.

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来源期刊

2017 Workshop on Research, Education and Development of Unmanned Aerial Systems (RED-UAS)

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