Tau Theory-Based Flare Control in Autonomous Helicopter Autorotation

IF 2.1 3区工程技术 Q2 ENGINEERING, AEROSPACE

Aerospace Pub Date : 2023-12-29 DOI:10.3390/aerospace11010033

Umberto Saetti, Jonathan Rogers, Mushfiqul Alam, Michael Jump

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Abstract

A novel trajectory generation and control architecture for fully autonomous autorotative flare that combines rapid path generation with model-based control is proposed. The trajectory generation component uses optical Tau theory to compute flare trajectories for both longitudinal and vertical speed. These flare trajectories are tracked using a nonlinear dynamic inversion (NDI) control law. One convenient feature of NDI is that it inverts the plant model in its feedback linearization loop, which eliminates the need for gain scheduling. However, the plant model used for feedback linearization still needs to be scheduled with the flight condition. This key aspect is leveraged to derive a control law that is scheduled with linearized models of the rotorcraft flight dynamics obtained in steady-state autorotation, while relying on a single set of gains. Computer simulations are used to demonstrate that the NDI control law is able to successfully execute autorotative flare in the UH-60 aircraft. Autonomous flare trajectories are compared to piloted simulation data to assess similarities and discrepancies between piloted and automatic control approaches. Trade studies examine which combinations of downrange distances and altitudes at flare initiation result in successful autorotative landings.

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基于 Tau 理论的自主直升机自动旋转耀斑控制

本文提出了一种用于全自主自动飞行照明弹的新型轨迹生成和控制架构，该架构将快速轨迹生成与基于模型的控制相结合。轨迹生成组件使用光学 Tau 理论计算纵向和垂直速度的照明弹轨迹。使用非线性动态反演（NDI）控制法则对这些照明弹轨迹进行跟踪。NDI 的一个方便之处在于，它在反馈线性化环路中反转植物模型，从而无需进行增益调度。不过，用于反馈线性化的工厂模型仍需根据飞行条件进行调度。利用这一关键环节推导出了一种控制法则，该法则可根据稳态自动旋转时获得的旋翼机飞行动力学线性化模型进行调度，同时只依赖一组增益。计算机仿真证明，NDI 控制法能够在 UH-60 飞机上成功执行自转耀斑。将自主照明弹轨迹与驾驶模拟数据进行比较，以评估驾驶和自动控制方法之间的相似性和差异。贸易研究检查了在启动照明弹时，哪些下射距离和高度组合会导致成功的自动着陆。

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

Aerospace ENGINEERING, AEROSPACE-

CiteScore

3.40

自引率

23.10%

发文量

661

审稿时长

6 weeks

期刊介绍： Aerospace is a multidisciplinary science inviting submissions on, but not limited to, the following subject areas: aerodynamics computational fluid dynamics fluid-structure interaction flight mechanics plasmas research instrumentation test facilities environment material science structural analysis thermophysics and heat transfer thermal-structure interaction aeroacoustics optics electromagnetism and radar propulsion power generation and conversion fuels and propellants combustion multidisciplinary design optimization software engineering data analysis signal and image processing artificial intelligence aerospace vehicles'' operation, control and maintenance risk and reliability human factors human-automation interaction airline operations and management air traffic management airport design meteorology space exploration multi-physics interaction.