CDA with RTA in a mixed environment

M. Jackson
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引用次数: 14

Abstract

Procedures for Continuous Descent Approach (CDA) and Optimized Profile Descents (OPD) are being fielded to allow aircraft to approach moderately dense terminal areas while flying efficient, near-idle descent trajectories that save fuel, and reduce emissions and noise. However, CDA operations can have a negative impact on the airspace throughput and controller workload. Air Traffic Management automation systems are being developed and fielded to assist controllers in handling more aircraft and larger airspace per controller. Many of these systems are time-based and built to predict the aircraft trajectories as accurately as possible. Three technologies that can assist ATM automation systems in enabling CDA operations in dense terminal areas while maintaining or increasing airspace throughput and safety: Controller Pilot Data-Link Communications (CPDLC), Automatic Dependent Surveillance Contract, Extended Projected Profile (ADS-C EPP), Required Time-of-Arrival control (RTA). Initial trials using RTA capability have shown some challenges in integrating RTA and non-RTA aircraft due to the structural shape of the speed profile strategy (how the speeds are chosen in different flight segments), and the automatic speed adjustments made by the RTA algorithm in response to observed trajectory error. Both of these issues can reduce the relative spacing between aircraft in trail. This paper presents an operational concept for how the RTA capability can enable the use of CDA procedures in high density traffic in a mixed equipage environment, either with or without the use of digital data link.
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混合环境中的CDA和RTA
持续下降进近(CDA)和优化剖面下降(OPD)程序正在部署,允许飞机在飞行效率高、接近怠速下降轨迹的情况下接近中等密度的终点区,从而节省燃料,减少排放和噪音。然而,CDA操作可能会对空域吞吐量和管制员工作量产生负面影响。空中交通管理自动化系统正在开发和部署,以帮助管制员处理更多的飞机和更大的空域。其中许多系统都是基于时间的,旨在尽可能准确地预测飞机轨迹。三种技术可以帮助ATM自动化系统在密集的终端区域实现CDA操作,同时保持或提高空域吞吐量和安全性:控制器导频数据链通信(CPDLC)、自动相关监视合同、扩展投影剖面(ADS-C EPP)、要求到达时间控制(RTA)。使用RTA能力的初始试验表明,由于速度轮廓策略的结构形状(如何在不同的飞行段中选择速度)以及RTA算法根据观察到的轨迹误差进行的自动速度调整,在整合RTA和非RTA飞机方面存在一些挑战。这两个问题都可以减少飞机之间的相对间距。本文提出了一个操作概念,说明RTA能力如何能够在混合设备环境中的高密度流量中使用CDA程序,无论是否使用数字数据链路。
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