A mathematical model of aerodynamic monitoring of radioactive contamination of the territory is described. The regression equation of the model contains the components of the altitude dependence of the dose rate of radioactive contamination of the territory and the level of the cosmic background. The model makes it possible to determine not only the total radiation dose rate at the height of the aircraft, which indirectly depends on the level of radioactive contamination, but to carry out remote measurement of the dose rate directly on the surface of the territory
radioactive contamination of territories, model of radiation aerodynamic control, error in measuring the dose rate of the surface
1. Federal'nyy zakon ot 09.01.1996 No 3-FZ "O radiacionnoy bezopasnosti naseleniya" [Elektronnyy resurs]. Rezhim dostupa: http://www.consultant.ru/document/cons_doc_LAW_8797/.
2. Metodicheskie rekomendacii po likvidacii posledstviy radiacionnyh i himicheskih avariy / V.A. Vladimirov, A.G. Luk'yanchenkov, K.N. Pavlov, V.A. Puchkov, R.F. Sadikov, A.I. Tkachev pod obschey red. doktora tehnicheskih nauk V.A. Vladimirova. - M.: ZAO "Reklamno-izdatel'skaya firma "MTP-INVEST", zakaz No280L, 2005. EDN: https://elibrary.ru/QWLZEB
3. Obschie instrukcii ocenki i reagirovaniya na radiologicheskie avariynye situacii. Mezhdunarodnoe agentstvo po atomnoy energii MAGATE. [Elektronnyy resurs]. Rezhim dostupa: https://www-pub.iaea.org/MTCD/Publications/PDF/te_1162r_web.pdf.
4. Reshenie kollegii MChS Rossii ot 4 dekabrya 2019 g. No 8/II "Ob utverzhdenii aktualizirovannoy redakcii Koncepcii radiacionnoy, himicheskoy i biologicheskoy zaschity naseleniya" [Elektronnyy resurs]. Rezhim dostupa: https://29.mchs.gov.ru/uploads/resource/2020-01-16/25af2d69368086e94629f54b22d54a89.pdf.
5. Koncepciya kompleksnoy sistemy obespecheniya bezopasnosti zhiznedeyatel'nosti naseleniya", utv. MChS Rossii 16.02.2010, MVD Rossii 19.02.2010, FSB Rossii 16.03.2010.
6. Cposob aerodinamicheskogo kontrolya radiacionnoy obstanovki. Sergeev I.Yu., Pashinin V.A., Valuev N.P., Kosyrev P.N. Tehnologii grazhdanskoy bezopasnosti. 2018. T. 15. No 4 (58). S. 84-87. EDN: https://elibrary.ru/YQSGQP DOI: https://doi.org/10.54234/CST.19968493.2018.15.4.58.13.84
7. Evgenov A.A. Neyrosetevoy regulyator sistemy upravleniya kvadrokopterom. // Nauchnoe obozrenie. Tehnicheskie nauki. - 2014. - No 1. - S. 148-149. URL: https://science-engineering.ru/ru/article/view?id=208 (data obrascheniya: 14.06.2022).
8. Savickiy A.V., Pavlovskiy V.E. Model' kvadrokoptera i neyrosetevoy algoritm upravleniya // Preprinty IPM im. M.V.Keldysha. 2017. No 77. 20 s.https://doi.org/10.20948/prepr-2017-77 URL: http://library.keldysh.ru/preprint.asp?id=2017-77(data obrascheniya: 14.06.2022). DOI:https://doi.org/10.20948/prepr-2017-77URL EDN: https://elibrary.ru/ZDGHOJ
9. Yuschenko A.S., Lebedev K.R., Zabihafar S.H. Sistema upravleniya kvadrokopterom na osnove adaptivnoy neyronnoy seti Nauka i Obrazovanie. MGTU im. N.E. Baumana. Elektron. zhurn. 2017. No 07. S. 262-277.https://doi.org/10.7463/0717.0001282 (data obrascheniya: 14.06.2022). DOI:https://doi.org/10.7463/0717.0001282( EDN: https://elibrary.ru/ZTIBPV
