Towards Flight Envelope Protection for the NASA Tiltwing eVTOL Flight Mode Transition Using Hamilton–Jacobi Reachability

IF 1.4 4区工程技术 Q2 ENGINEERING, AEROSPACE

Journal of the American Helicopter Society Pub Date : 2023-01-01 DOI:10.4050/jahs.69.022003

Ting-Wei Hsu, Jason J. Choi, Divyang Amin, Claire Tomlin, Shaun C. McWherter, Michael Piedmonte

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引用次数: 0

Abstract

Innovative electric vertical take-off and landing (eVTOL) aircraft designs and operational concepts, driven by advancements in battery and electric motor technologies, seek to achieve superior safety records with increased system redundancy. Validating safe flight operations within verified flight envelope regions for passenger flights in densely populated urban environments remains a primary challenge. This paper establishes a framework for applying Hamilton–Jacobi reachability analysis to the full six-degree-of-freedom (6-DOF) dynamics of the NASA Tiltwing vehicle, verifying the flight envelope during the flight mode transition between near-hover and cruise flight, which prevents loss of control of the vehicle and ensures recoverability to safe trim conditions. This involves first verifying the nominal flight mode transition path as a series of trim points, defining the safe flight envelope using reachability, and decomposing the system dynamics into longitudinal and lateral subsystems. Our formulation guarantees the computed envelope's robustness against modeling errors and uncertainties, and the usage of state decomposition significantly improves the tractability of the reachability computation. The result is validated through Monte Carlo 6-DOF nonlinear simulation of vehicle dynamics, demonstrating that the vehicle states within the flight envelope can successfully recover to trim states and continue the flight mode transition safely.

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利用Hamilton-Jacobi可达性实现NASA倾翼eVTOL飞行模式转换的飞行包线保护

在电池和电动机技术进步的推动下，创新的电动垂直起降(eVTOL)飞机设计和操作概念寻求通过增加系统冗余来实现卓越的安全记录。在人口稠密的城市环境中，在经过验证的飞行包线区域内验证客运航班的安全飞行操作仍然是一项主要挑战。本文建立了将Hamilton-Jacobi可达性分析应用于NASA倾翼飞行器全六自由度(6-DOF)动力学的框架，验证了在近悬停和巡航飞行模式转换期间的飞行包线，以防止飞行器失去控制并确保可恢复到安全的倾翼状态。这包括首先验证标称飞行模式转换路径作为一系列修剪点，使用可达性定义安全飞行包线，并将系统动力学分解为纵向和横向子系统。我们的公式保证了计算包络对建模误差和不确定性的鲁棒性，并且状态分解的使用显著提高了可达性计算的可追溯性。通过蒙特卡罗六自由度飞行器动力学非线性仿真验证了结果，表明飞行包线内的飞行器状态能够成功恢复到横置状态，并安全进行飞行模式转换。

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

Journal of the American Helicopter Society 工程技术-工程：宇航

CiteScore

4.10

自引率

33.30%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of the American Helicopter Society is a peer-reviewed technical journal published quarterly (January, April, July and October) by AHS — The Vertical Flight Society. It is the world''s only scientific journal dedicated to vertical flight technology and is available in print and online. The Journal publishes original technical papers dealing with theory and practice of vertical flight. The Journal seeks to foster the exchange of significant new ideas and information about helicopters and V/STOL aircraft. The scope of the Journal covers the full range of research, analysis, design, manufacturing, test, operations, and support. A constantly growing list of specialty areas is included within that scope. These range from the classical specialties like aerodynamic, dynamics and structures to more recent priorities such as acoustics, materials and signature reduction and to operational issues such as design criteria, safety and reliability. (Note: semi- and nontechnical articles of more general interest reporting current events or experiences should be sent to the VFS magazine