Дата поступления: 
01.02.2019
Год: 
2019
Номер журнала (Том): 
УДК: 
621.396.96
Файл статьи: 
Страницы: 
46
61
Аннотация: 

Process of the organization and the operational management of air traffic (ATМ) at the service of air traffic (ATЫ) is possible on the basis of obtaining necessary information by decomposition of the general process of measurement observation. One of the perspective directions of improvement of observation is development and deployment of multiposition system of observation (MLAT – Multilateration), allowing to define location of the aircrafts, transferring at the same time the minimum volume of information. For data exchange in the system of the ATM it is offered to use automatic dependent surveillance broadcast (ADS-B), it will be carried out in the automatic mode throughout all flight of aircraft. Process of positioning of aircraft is based on time difference of arrival of the signal radiated by an object and decoded at reception stations. For definition of the moment of receipt of a signal on the accepting stations, the system needs uniform basic time therefore hours on all receivers it is offered on the GNSS (Global Navigation Satellite Systems).

It is executed imitating modeling of the MLAT system, characteristics of system with placement option for the purpose of overlapping of a zone of airspace of the Irkutsk Regional center and satisfying to factors on realization of the MLAT system are provided. It is shown that use of multiposition system of observation on the basis of multilateratsionny technology allows to increase the accuracy of positioning of the aircraft thanks to the high-precision pseudo-ranging measurements caused by high quality of synchronization of places of acceptance of system on signals of the navigation GNSS satellites and structure of a signal of ADS-B. the expediency of use of the MLAT system as the watch facility for the solution of problems of high-precision positioning of aircraft is confirmed.

The direction of structural synthesis of a complex information-control system MLAT, based on the principle of hierarchical associative-network information processing, is proposed. The methodology for calculating MLAT efficiency is considered.

Список цитируемой литературы: 

1. Global'nyy aeronavigatsionnyy plan na 2013-2028 gg. Mezhdunarodnaya organizatsiya grazhdanskoy aviatsii. [The Global Air Navigation Plan for 2013-2028. International Civil Aviation Organization]. Doc 9750-AN / 963. 4 th ed., - 2013. - 147 pp. (in Russian).

2. Kryzhanovskiy G.A. Kontseptsiya i sistemy CNS/ATM v grazhdanskoy aviatsii [The concept and systems of CNS / ATM in civil aviation]. - Moscow: Akademkniga, 2003. - 415 p. (in Russian).

3. Anodina T.G., Kuznetsov A.A., Markovich Ye.D. Avtomatizatsiya upravleniya vozdushnym dvizheniyem [Automation of air traffic control] / Ed. A.A. Kuznetsov. - Moscow: Transport, 1992. - 280 p. (in Russian).

4. Akhmedov R.M., Bibutov A.A., Vasil'yev A.V. Avtomatizirovannyye sistemy upravleniya vozdushnym dvizheniyem: novyye informatsionnyye tekhnologii v aviatsii [Automated air traffic control systems: new information technologies in aviation] / Ed. S.G. Pyatko and A.I. Krasova. - St. Petersburg: Politechnica, 2004. - 446 p. (in Russian).

5. Strohmeier M., Lenders V., Martinovic I. On the Security of the Automatic Dependent Surveillance-Broadcast Protocol. IEEE Communications Surveys & Tutorials 17 (2): 04-2014. – P. 1066-1087.

6. Chen Y-H, Lo S, Akos DM, Wong G, Enge PA Testbed for Studying Automatic Dependent Surveillance Broadcast (ADS-B) Based Range and Positioning Performance to Support Alternative Position Navigation and Timing (APNT). Proceedings of the 26th International Technical Meeting of The Satellite Division of the Institute of Navigation (ION GNSS+ 2013), Nashville, TN: 09-2013, pp. 263-273

7. Cho T, Lee C, Choi S Multi-Sensor Fusion with Interacting Multiple Model Filter for Improved Aircraft Position Accuracy. Sensors 2013, 13, 4122-4137; doi:10.3390/s130404122.

8. Doukas D., Berends J., Rees M., Kerkhofs G.  CNS/ATM Ground Station and Service Status Reports; SUR.ET1.ST05.2000-STD-16-01; European Air Traffic Management: Brussels, Belgium.

9. Mezhetov M.A., Turintsev S.V. Vydeleniye signalov taktovoy sinkhronizatsii v sistemakh peredachi informatsii rezhima VDL-2 [Isolation of clock synchronization signals in VDL-2 mode information transfer systems] Crede Experto: transport, society, education, language. 2017. № 2. P. 191-200. (in Russian).

10. Mezhetov M.A., Turintsev S.V., Serebrennikov Ye.A., Nikitich P.T. Increase of efficiency of airdrome traffic control on the base of receiving the differential corrections by mobile airdrome vehicles. Crede Experto: transport, society, education, language. 2017. № 2. P. 288-298.

11. Mantilla-Gaviria I. A., Leonardi M., Galati G., Balbastre-Tejedor J. V. Localization algorithms for multilateration (MLAT) systems in airport surface surveillance. Signal, Image and Video Processing. 2015, Volume 9, Issue 7, pp. 1549-1558.

12. Shestakov I.N., Kryzhanovskiy G.A. Rasshireniye polya SRNS s pomoshch'yu nazemnykh stantsiy AZN-V [Expansion of the SRNS field by means of ground stations ADS-B]. Scientific Bulletin of MGTU GA No. 210, Moscow, 2014 - p. 114-117. (in Russian).

13. Yarlykov, M. S. Statistichtskaya teoriya radionavigatsii / M. S. Yarlykov. – M.: Radio i sviaz, 1985. – 344 p.

14. Kharlamov А.A. Neyrosetevaya tekhnologiya  predstavleniya obrabotki informatsii (estestvennoe  predstavleniye znanij). Kn. 19. Monografiya / Pod.red. Galushkina. – M .: Radiotekhnika, 2006. – 88 p.

15. Mariukhnenko, V. S., Erokhin V.V. Sintez assotsiativno-setevoy struktury kompleksnoy navigatsionnoy sistemy s optimal'noy obrabotkoy informatsii / Uspekhi sovremennoy radioelektroniki. 2017, №4. – P.18–29

16. Setevyye sputnikovyye radionavigatsionnyye sistemy / Dmitriyev [i dr.]; pod red. V. S. She-bshayevich. – 2-ye izd., pererab. i dop. – M.: Radio i svyaz', 1993. – 408 p.