Simulation and flight experiments of a quadrotor tail-sitter vertical take-off and landing unmanned aerial vehicle with wide flight envelope

IF 1.5 4区 工程技术 Q2 ENGINEERING, AEROSPACE International Journal of Micro Air Vehicles Pub Date : 2018-12-01 DOI:10.1177/1756829318813633
X. Lyu, Haowei Gu, Jinni Zhou, Zexiang Li, S. Shen, Fu Zhang
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引用次数: 16

Abstract

This paper presents the modeling, simulation, and control of a small-scale electric powered quadrotor tail-sitter vertical take-off and landing unmanned aerial vehicle. In the modeling part, a full attitude wind tunnel test is performed on the full-scale unmanned aerial vehicle to capture its aerodynamics over the flight envelope. To accurately capture the degradation of motor thrust and torque at the presence of the forward speed, a wind tunnel test on the motor and propeller is also carried out. The extensive wind tunnel tests, when combined with the unmanned aerial vehicle kinematics model, dynamics model and other practical constraints such as motor saturation and delay, lead to a complete flight simulator that can accurately reveal the actual aircraft dynamics as verified by actual flight experiments. Based on the developed model, a unified attitude controller and a stable transition controller are designed and verified. Both simulation and experiments show that the developed attitude controller can stabilize the unmanned aerial vehicle attitude over the entire flight envelope and the transition controller can successfully transit the unmanned aerial vehicle from vertical flight to level flight with negligible altitude dropping, a common and fundamental challenge for tail-sitter vertical take-off and landing aircrafts. Finally, when supplied with the designed controller, the tail-sitter unmanned aerial vehicle can achieve a wide flight speed envelope ranging from stationary hovering to fast level flight. This feature dramatically distinguishes our aircraft from conventional fixed-wing airplanes.
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宽飞行包线四旋翼尾座垂直起降无人机仿真与飞行实验
本文介绍了一种小型电动四旋翼尾座垂直起降无人机的建模、仿真和控制。在建模部分,对全尺寸无人机进行了全姿态风洞试验,以捕捉其在飞行包线上的空气动力学特性。为了准确捕捉在前进速度存在的情况下电机推力和扭矩的退化,还对电机和螺旋桨进行了风洞试验。广泛的风洞试验,结合无人机运动学模型、动力学模型和其他实际约束条件,如电机饱和和延迟,形成了一个完整的飞行模拟器,可以准确地揭示实际飞行实验验证的实际飞机动力学。基于所建立的模型,设计并验证了统一姿态控制器和稳定过渡控制器。仿真和实验都表明,所开发的姿态控制器可以在整个飞行包线上稳定无人机姿态,并且过渡控制器可以成功地将无人机从垂直飞行过渡到水平飞行,这是尾座垂直起降飞机面临的一个常见而根本的挑战。最后,当配备所设计的控制器时,尾座无人机可以实现从静止悬停到快速水平飞行的宽飞行速度包络。这一特点使我们的飞机有别于传统的固定翼飞机。
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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来源期刊
CiteScore
3.00
自引率
7.10%
发文量
13
审稿时长
>12 weeks
期刊介绍: The role of the International Journal of Micro Air Vehicles is to provide the scientific and engineering community with a peer-reviewed open access journal dedicated to publishing high-quality technical articles summarizing both fundamental and applied research in the area of micro air vehicles.
期刊最新文献
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