利用时间控制和不同水平的飞行制导进行飞行模拟

D. De Smedt, T. Putz
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引用次数: 10

摘要

SESAR和NextGen提出了基于4d轨迹的操作,作为未来空中交通管理(ATM)系统改进的基础。机载所需到达时间(RTA)功能被视为一个初始的使能器,可以更好、更准确地规划飞机到达,例如在空域边界或在终端区(TMA)的入口。今天,并不是所有的飞机都配备了RTA。此外,飞机有不同的FMS弹道预测性能,不同级别的飞行制导功能(例如VNAV)和一些飞机没有自动推力。所有这些因素都可能对飞机在限定时间内沿轨迹飞行的能力产生影响。为了评估在现有飞机上实施到达时间控制的可行性,在不进行过多硬件修改的情况下,开发了一个具有RTA功能的试验性FMS,并将其与柏林理工学院科研设施的现有空客A330飞行模拟器相结合。利用RTA函数结合不同的垂直剖面和不同的飞行制导和自动化水平,进行了一系列的飞行仿真。一些飞行使用手动俯仰控制,没有自动推力。几乎所有航班的到达时间误差都在10秒以内。最低飞行制导要求被确定为飞行员主要视场中所需校准空速(CAS)的指示和偏离参考垂直剖面(VDEV)的指示。最后,设计了一种新的RTA算法,以减小速度变化的幅度,并通过快速仿真进行了验证。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Flight simulations using time control with different levels of flight guidance
4D-trajectory-based operations are proposed by SESAR and NextGen as fundamental cornerstones of Air Traffic Management (ATM) system improvements of the future. An airborne Required Time of Arrival (RTA) function is seen as an initial enabler to allow better and more accurate planning of aircraft arriving, for example, at airspace sector boundaries or at the entry of a Terminal Area (TMA). Today, not all aircraft are equipped with RTA. In addition, aircraft have varying FMS trajectory prediction performances, varying levels of flight guidance functions (for example VNAV) and some aircraft do not have auto-thrust. All these factors may have an impact on the ability of an aircraft to fly a trajectory with a time constraint. To assess the feasibility of implementing arrival time control in an existing aircraft without excessive hardware modifications, an experimental FMS with RTA capability was developed and coupled to an existing Airbus A330 flight simulator at the scientific research facility of the Berlin Institute of Technology. A series of flight simulations was performed, using the RTA function in combination with different vertical profiles and different levels of flight guidance and automation. Some flights were flown using manual pitch control and without auto-thrust. Nearly all flights achieved an arrival time error of less than 10 seconds. Minimum flight guidance requirements were identified as an indication of the required calibrated airspeed (CAS) in the primary field of view of the pilot and an indication of the deviation from the reference vertical profile (VDEV). Finally a new RTA algorithm was designed to reduce the magnitude of the speed variations and was tested by means of fast-time simulation.
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