Air Traffic Control software implemented in RADAR

Q2 Engineering

INCAS Bulletin Pub Date : 2023-06-09 DOI:10.13111/2066-8201.2023.15.2.6

Andrei Neamtu, Anton Balaban, S. Berbente, G. Stroe, Emil Costea, I. Stefanescu, I. Andrei, Ionel Popescu

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引用次数: 1

Abstract

This study presents the flight plan data related to aircraft performance and is tested against the aircraft performance database. The Significant Meteorological Information Reports - SIGMET will be generated by the system according to the selected turbulence areas by attaching different AIS data to an exercise that can change the simulation objectives. The exercise must be assigned to one or more courses to be able to attach meteorological data when viewing a data recording; changes can be made to the aircraft as in a normal exercise run, while the other instructions will be loaded from the recorded data file. A data recording is airspace dependent, changing the airspace can make the data recording fail during playback. Video Recording is only available for the RADAR Simulator. A video recording can be made at any time during a simulation session; a data recording can be selected only at the beginning of the simulation session and cannot be started during the simulation session; if the simulator is integrated with the Voice Communication System and the audio channels, then a sound recording window will automatically pop-up. For this study, an ideal case, for the configuration presentation we will assume that the 3D Tower Simulator is composed of 4 LCD/Projectors to create the out-of-the- window view, 180 degrees, 2 Pseudo-Pilots, and 1 Supervisor/FEEDER Position. The 4 image generators will be provided by SIM01, SIM02, SIM03, and SIM04. The Pseudo-Pilots positions will be provided by SIM05 and SIM06. The Supervisor/Feeder Position will be provided by SIM07. For the Tower Controller Working Positions, we will provide the following information displays: DE – Flight Data Equipment/Clearance Delivery, MET – Meteorological Information, LCP –Lights Control Panel, and a RADAR Image. Station SIM08 will be used. Stations SIM01, SIM02, SIM03, and SIM04 are equipped with one large LCD Display or a Projector; Stations SIM05 and SIM07 are equipped with 2 monitors, one for the RADAR Image and the other one for the bird-eye view over the airport; Station SIM06 is equipped with one monitor for the bird-eye view over the airport; Station SIM08 is equipped with 4 monitors providing all necessary information for the Tower Controller Working Positions. SIM07, as presented above, is the FEEDER/SUPERVISOR for the RADAR Simulator, the approach sector is “TMA” and the application will be started on the second monitor, the first monitor is used for the 3D Tower Simulator. SIM07 is also FEEDER/SUPERVIZOR for the 3D Tower Simulator, the station function will be “3DTWR” and the sector will be the previously created 3D Tower configuration, “TOWER”. On SIM08 will add a RADAR Image for the Tower Controller Working Positions, sector is “TMA”, the application will be started on monitor 4, and the station function is “TWR”. Usually, for an aircraft departing from an airport inside an approach sector, the first owner will be the tower until passing the maximum flight level/ altitude for the tower, the second owner will be the approach sector and the third owner will be the en-route sector. In this case, the tower sector has power over the approach sector, and the en-route sector, the approach sector has power over the en-route sector. The outside FIR sectors will be used in the determination of the next en-route sector, for coordination purposes. If the VFR points do not appear on the RADAR Map after the “DRAW” button has been pushed, use the “MAP MENU” – “VFR” button. The aircraft performance database is not airspace structure dependent. When a new airspace structure is created the aircraft performance database will remain unchanged.

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RADAR中实现的空中交通管制软件

本研究提供了与飞机性能相关的飞行计划数据，并根据飞机性能数据库进行了测试。重要气象信息报告-SIGMET将由系统根据选定的湍流区域生成，方法是将不同的AIS数据附加到可以改变模拟目标的演习中。练习必须分配给一个或多个课程，以便在查看数据记录时能够附加气象数据；可以像在正常的演习中一样对飞机进行更改，而其他指令将从记录的数据文件中加载。数据记录依赖于空域，更改空域可能会使数据记录在回放过程中失败。视频录制仅适用于雷达模拟器。可以在模拟会话期间的任何时间进行视频记录；数据记录只能在模拟会话开始时选择，并且不能在模拟会话期间启动；如果模拟器与语音通信系统和音频通道集成，则会自动弹出录音窗口。在本研究中，理想的情况是，在配置演示中，我们假设3D塔台模拟器由4个LCD/投影仪组成，用于创建180度的窗外视图、2个伪飞行员和1个主管/FEEDER位置。4个图像生成器将由SIM01、SIM02、SIM03和SIM04提供。伪导频位置将由SIM05和SIM06提供。SIM07将提供监督员/给料机位置。对于塔台管制员工作位置，我们将提供以下信息显示：DE–飞行数据设备/净空交付、MET–气象信息、LCP–灯光控制面板和雷达图像。将使用SIM08工作站。SIM01、SIM02、SIM03和SIM04工作站配有一个大型液晶显示器或投影仪；SIM05和SIM07站配备了2台监视器，一台用于雷达图像，另一台用于机场鸟瞰图；SIM06站配备了一台监视器，用于鸟瞰机场；SIM08站配备了4个监视器，为塔台管制员工作位置提供所有必要信息。如上所述，SIM07是雷达模拟器的馈线/监督员，进近扇区为“TMA”，应用程序将在第二个监视器上启动，第一个监视器用于3D塔台模拟器。SIM07也是3D Tower Simulator的FEEDER/SUPERVIZOR，车站功能将为“3DTWR”，扇区将为之前创建的3D Tower配置“Tower”。SIM08将为塔台控制器工作位置添加雷达图像，扇区为“TMA”，应用程序将在监视器4上启动，工作站功能为“TWR”。通常，对于在进近扇区内从机场起飞的飞机，第一个所有人将是塔台，直到通过塔台的最大飞行高度/高度，第二个所有人是进近扇区，第三个所有人为途中扇区。在这种情况下，塔台扇区对进场扇区具有权力，而在途中扇区，进场扇区对在途中扇区具有权力。外部FIR扇区将用于确定下一个途中扇区，以进行协调。如果按下“绘图”按钮后，VFR点没有出现在雷达地图上，请使用“地图菜单”-“VFR”按钮。飞机性能数据库与空域结构无关。当创建新的空域结构时，飞机性能数据库将保持不变。

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

INCAS Bulletin Engineering-Aerospace Engineering

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： INCAS BULLETIN is a scientific quartely journal published by INCAS – National Institute for Aerospace Research “Elie Carafoli” (under the aegis of The Romanian Academy) Its current focus is the aerospace field, covering fluid mechanics, aerodynamics, flight theory, aeroelasticity, structures, applied control, mechatronics, experimental aerodynamics, computational methods. All submitted papers are peer-reviewed. The journal will publish reports and short research original papers of substance. Unique features distinguishing this journal: R & D reports in aerospace sciences in Romania The INCAS BULLETIN of the National Institute for Aerospace Research "Elie Carafoli" includes the following sections: 1) FULL PAPERS. -Strength of materials, elasticity, plasticity, aeroelasticity, static and dynamic analysis of structures, vibrations and impact. -Systems, mechatronics and control in aerospace. -Materials and tribology. -Kinematics and dynamics of mechanisms, friction, lubrication. -Measurement technique. -Aeroacoustics, ventilation, wind motors. -Management in Aerospace Activities. 2) TECHNICAL-SCIENTIFIC NOTES and REPORTS. Includes: case studies, technical-scientific notes and reports on published areas. 3) INCAS NEWS. Promote and emphasise INCAS technical base and achievements. 4) BOOK REVIEWS.