A review of flight trajectory optimisations

IF 1.9 4区工程技术 Q2 ENGINEERING, MARINE

Journal of Navigation Pub Date : 2022-05-01 DOI:10.1017/S0373463322000248

O. Pleter, C. Constantinescu

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引用次数: 0

Abstract

Abstract The paper reviews the optimisation methods of the flight trajectory for airliners. In contrast to maritime navigation, where the shortest route (the orthodrome) is preferred, in air navigation, the brachistochrone is the optimal flight trajectory on the sphere or on the ellipsoid, considering the wind vector field (maximising the tail wind and minimising the head wind over the duration of the flight). The major impact of the wind on the flight trajectory results from the possible significant velocity at the normal cruise flight levels, which could reach 200 kts, or 40% of the aircraft true airspeed (TAS). Brachistochrone is independent of the flight performance optimisation (range versus speed), as computed by the flight management system. Whichever cost index (CI) is selected (and consequently, the cruise Mach number), the brachistochrone is the minimum time of flight trajectory at that target Mach number. In cruise flight, the minimum time of flight is also equivalent to the minimum fuel consumption. It concerns just the wind velocity field. All these qualify the brachistochrone as the greenest trajectory, the most fuel and emissions efficient solution relative to the atmosphere. The paper classifies the brachistochrone problems (2D, 3D and 4D brachistochrones, with or without flexible time of departure). Some numerical examples are provided. The overall optimal 4D trajectory considers many aspects, including safety, by minimisation of total costs and risks of the 4D trajectory.

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飞行轨迹优化的回顾

摘要本文综述了客机飞行轨迹的优化方法。与海上导航不同的是，在空中导航中，最短路线（正射场）是优选的，考虑到风矢量场（在飞行过程中最大化尾风并最小化逆风），腕式时间是球体或椭球体上的最佳飞行轨迹。风对飞行轨迹的主要影响源于正常巡航飞行水平下可能的显著速度，该速度可能达到200 kts，即飞机真实空速（TAS）的40%。根据飞行管理系统的计算，短时程与飞行性能优化（航程与速度）无关。无论选择哪一个成本指数（CI）（以及巡航马赫数），腕式时间是该目标马赫数下飞行轨迹的最小时间。在巡航飞行中，飞行的最短时间也相当于最低油耗。它只涉及风速场。所有这些都使腕式时序成为最环保的轨迹，是相对于大气而言最具燃料和排放效率的解决方案。本文对腕表时间问题（2D、3D和4D腕表时间，有或没有弹性出发时间）进行了分类。给出了一些数值例子。总体最优4D轨迹考虑了许多方面，包括安全性，通过最小化4D轨迹的总成本和风险。

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 Navigation 工程技术-工程：海洋

CiteScore

6.10

自引率

4.20%

发文量

审稿时长

4.6 months

期刊介绍： The Journal of Navigation contains original papers on the science of navigation by man and animals over land and sea and through air and space, including a selection of papers presented at meetings of the Institute and other organisations associated with navigation. Papers cover every aspect of navigation, from the highly technical to the descriptive and historical. Subjects include electronics, astronomy, mathematics, cartography, command and control, psychology and zoology, operational research, risk analysis, theoretical physics, operation in hostile environments, instrumentation, ergonomics, financial planning and law. The journal also publishes selected papers and reports from the Institute’s special interest groups. Contributions come from all parts of the world.