V.N. Skosyrev¹, R.O. Stepanov², V.A. Usachev³, V.V. Savchenko4

1–3 Bauman Moscow State Technical University (Moscow, Russia)

 4 JSC Rostec – Project Technologies (Moscow, Russia)

Ensuring transport connectivity of the territories of the Arctic zone is largely provided by means of regional aviation. To ensure flight safety, it is necessary to equip small airfields with radar facilities, while it is not economically effective to use the traditional range of navigation radar facilities for airfields with a low frequency of use. Therefore, it is necessary to search for and justify new scientific and technical solutions to ensure the creation of navigation tools that solve the tasks facing the dispatching services of regional airfields in the Arctic zone.

This article presents an analysis of global trends in the development of air traffic control systems and options for equipping information sensors for dispatching services for airfields in the Arctic zone. The appearance of equipment complexes for information support of regional airports and small aircraft airfields based on a highly informative multifunctional three-coordinate all-round radar is proposed.

The application of the obtained results and the proposed technical solutions and principles for the construction of navigation aids for regional airports and small aircraft airfields will significantly reduce the cost of production and operation of a new generation of modular high-information radars and increase the safety of navigation systems.

Skosyrev V.N., Stepanov R.O., Usachev V.A., Savchenko V.V. The evolutionary path of the organization of the air traffic control system in Arctic. Science Intensive Technologies. 2021. V. 22. № 3. P. 39−50. DOI: 10.18127/j19998465-202103-05 (In Russian)

1. Sozinov P.A. Vklad koncerna PVO «Almaz-Antej» v process modernizacii aeronavigacionnoj sistemy Rossii i grazhdanskoe aviastroenie. Special'nyj vypusk zhurnala «Eksport vooruzhenij», Posvyashchennyj grazhdanskoj aviacii. 2007 [Elektronnyj resurs]. Rezhim dostupa: http://pvo.guns.ru/book/cast/uvd.htm – (Data obrashcheniya 30.10.2020) (In Russian). 
2. Normy godnosti k ekspluatacii v SSSR oborudovaniya grazhdanskih aerodromov i vozdushnyh trass (NGEO-81). M.: Vozdushnyj transport, 1983. 129 s. (In Russian). 
3. Izmeneniya i dopolneniya k normam letnoj godnosti k ekspluatacii v SSSR Oborudovaniya grazhdanskih aerodromov i vozdushnyh trass (NGEO-81) i metodikam ocenki sootvetstviya normam godnosti k ekspluatacii v SSSR oborudovaniya grazhdanskih aerodromov i vozdushnyh trass (MOS NGEO). L. 1991. 79 s. (In Russian). 
4. Sajt kompanii Frequentis AG. Rezhim dostupa: www.frequentis.com (data obrashcheniya 20.09.2020). 
5. Ananenkov A.E., Skosyrev V.N., Konovaltsev A.V., Nuzhdin V.M., Rastorguev V.V. Multi-functional aerodrome controlradar by USPR technology. Proc. of the 29th Congress of the International Council of the Aeronautical Sciences (ICAS 2014) (St.-Petersburg, Russia, 7-12 September 2014). In 6 vols. V. 1. International Council of Aeronautical Sciences- ICAS. 2014. Art. № ICAS2014_0146. P. 3867–3873.
6. Skosyrev V.N., Kochkin V.A., Ananenkov A.E. Puti sozdaniya radioopticheskogo kompleksa kontrolya vozdushnogo i nazemnogo prostranstva v zone aerodroma. Nauka i obrazovanie. MGTU im. N.E. Baumana. Elektron. zhurn. 2015. № 11. S. 301–324. DOI: 10.7463/1115.0825935(In Russian). 
7. Kizilov M.G. Kompleksnoe reshenie zadach nablyudeniya za dvizheniem vozdushnyh sudov, transporta i drugimi ob"ektami na aerodromah GA. Konferenciya NAIS-2015 [Elektronnyj resurs]. Rezhim dostupa: https://docplayer.ru/40046162-Kompleksnoe-resheniezadach-nablyudeniya-za-dvizheniem-vozdushnyh-sudov-transporta-i-drugimi-obektami-na-aerodromah-ga.html (Data obrashcheniya 30.10.2020) (In Russian). 
8. Skosyrev V.N., Nuzhdin V.M., Ananenkov A.E., Konoval'cev A.V. Tekhnologiya sverhkorotkoimpul'snoj radiolokacii – klyuch k povysheniyu informacionnyh vozmozhnostej RLS. I Mezhdunarodnaya konferenciya «Sverhshirokopolosnye signaly i sverhkorotkie impul'sy v radiolokacii, svyazi i akustike». g. Suzdal', 27–29 sentyabrya 2005 g. (In Russian). 
9. Skosyrev V.N., Nuzhdin V.M., Ananenkov A.E., Marin D.V., Sokolov P.V. Puti povysheniya nablyudaemosti malorazmernyh ob"ektov v RLS maloj dal'nosti. H Vserossijskaya nauchno-tekhnicheskaya konferenciya «Radioopticheskie tekhnologii v priborostroenii». 2014 g. M.: MNTORES im. A.S. Popova. S. 306 (In Russian). 
10. Aerodromnyj radiolokacionnyj kompleks «Valdaj» 2015 [Elektronnyj resurs]. Rezhim dostupa: https://innovation.mintrans.ru/postupivshiepredlozheniya/182/ (Data obrashcheniya 30.10.2020) (In Russian). 
11. Patent na izobretenie № 2630686 (RF), MPK G01S 13/42(200601). Sposob izmereniya ugla mesta (vysoty) nizkoletyashchih celej pod malymi uglami mesta v trekhkoordinatnyh radiolokatorah krugovogo obzora pri nalichii meshayushchih otrazhenij ot podstilayushchej poverhnosti. V.N. Skosyrev i dr. 2017 (In Russian). 
12. Bakulev P.A., Stepin V.M. Metody i ustrojstva selekcii dvizhushchihsya celej. M.: Radio i svyaz'. 1986. 288 s. (In Russian). 
13. Loskutov V.Yu., Skosyrev V.N., Rastvorov S.A. Mnogofunkcional'nyj trekhkoordinatnyj radiolokator regional'nyh aerodromov. Radiostroenie. 2018. № 02. S. 1–12 (In Russian).