Vol. 35, issue 12, article # 13

Znamenskii I. V., Tikhomirov A. A. Outer space surveillance system for monitoring technogenic objects. // Optika Atmosfery i Okeana. 2022. V. 35. No. 12. P. 1051–1057. DOI: 10.15372/AOO20221213 [in Russian].
Copy the reference to clipboard
Abstract:

A technique has been developed and a calculation has been made of the irradiance of the entrance pupil of a ground-based optoelectronic system (OES) from a cylindrical space object illuminated by the Sun at night. The results of calculating the minimum irradiance and corresponding stellar magnitude at the input pupil of the OES are presented with a signal-to-noise ratio at the output of the photodetector matrix with a current equal to 7 in the wavelength range of 0.45 ¸ 0.85 mm. The dependence of the signal-to-noise ratio on the distance to the space object for its three different sizes is constructed. The program ROSN-1 was developed and its control panel was presented for calculating the characteristics of the OES at night in the range of 0.45 ¸ 0.85 mm was presented, and the possibilities of this program were explained.

Keywords:

monitoring, space debris, ground-based optoelectronic system, irradiance, brilliance

References:

  1. Shustov B.M. O fundamental'nyh issledovaniyah po probleme kosmicheskogo musora // Sb. tr. Vseros. konf. «Kosmicheskij musor: fundamental'nye i prakticheskie aspekty ugrozy», 17–19 april 2019 year M.: IKI RAN, 2019. 236 p. P. 7–14. DOI: 10.21046/spacedebris 2019-7-14.
  2. Ogolev A.V., Morozov S.V. Analiz zasorennosti okolozemnogo kosmicheskogo prostranstva ob"ektami tekhnogennogo proiskhozhdeniya i ih vliyanie na funktsionirovanie kosmicheskih apparatov // Sb. tr. Vseros. konf. «Kosmicheskij musor: fundamental'nye i prakticheskie aspekty ugrozy», 17–19 april 2019 year. M.: IKI RAN, 2019. 236 p. P. 15–19. DOI: 10.21046/spacedebris 2019-15-19.
  3. Korobtsev I.V., Mishina M.N. Opticheskie nablyudeniya malyh kosmicheskih apparatov i kosmicheskogo musora v Sayanskoj observatorii ISZF SO RAN // Solnechno-zemnaya fizika. 2019. V. 5, N 4. P. 117–121. DOI: 10.12737/szf-54201913.
  4. Korobtsev I.V., Tsukker T.G., Mishina M.N., Goryashin V.E., Eselevich M.V. Nablyudeniya kosmicheskogo musora v oblasti orbit global'nyh navigatsionnyh sputnikovyh sistem // Solnechno-zemnaya fizik. 2020. V. 6, N 3. P. 115–123. DOI: 10.12737/szf-63202014.
  5. Afanas'eva I.V., Murzin V.A., Ardilanov V.I., Ivashchenko N.G., Prityrchenko M.A., Borisenko A.N. Vysokoskorostnoe maloshumyashchee fotopriemnoe ustrojstvo dlya nazemnyh nablyudenij ob"ektov kosmicheskogo musora // Sb. tr. Vseros. konf. «Kosmicheskij musor: fundamental'nye i prakticheskie aspekty ugrozy», 17–19 april 2019 year. M.: IKI RAN, 2019. 236 p. P. 52–57. DOI: 10.21046/spacedebris2019-52-57.
  6. Matyuhin V.V., Parinov D.G., Tatarinova E.A. Model' shuma fotochuvstvitel'noj matritsy DalsaCM42M // Prikl. fiz. 2017. N 6. P. 60–67.
  7. Shiang-Yu Wang, Hung-Hsu Ling, Bo-Jhou Wang, Geary J.C., Shu-Fu Hsu, Pratlong J., Lehner M., Jorden P. The characteristic of Teledyne e2v CIS 113 CMOS sensors // Proc. SPIE. 2020. V. 11454. DOI: 10.1117/12.2561204.
  8. Image sensor Gpixel GSense4040(BSI). URL: https:// www.gpixel.com/products/area-scan-en/gsense/gsense4040bsi/ (last access: 20.05.2022).
  9. Image sensor Gpixel GSense6060(BSI). URL: https:// www.gpixel.com/products/area-scan-en/gsense/gsense6060bsi/ (last access: 20.05.2022).
  10. Crumey A. Human contrast threshold and astronomical visibility // Mon. Not. R. Astron. Soc. 2014. V. 442, N 3. P. 2600–2619. DOI: 10.1093/mnras/stu992.
  11. Znamenskij I.V., Zot'ev E.O., Yudin S.Yu. Sravnitel'nyj analiz porogovoj chuvstvitel'nosti IK-sistem v razlichnyh spektral'nyh diapazonah // Fotonika. 2021. V. 15, N 6. P. 484–500. DOI: 10.22184/1993-7296.FRos.2021.15.6.484.500.
  12. Tarasov V.V., Torshina I.P., Yakushenkov Yu.G. Sovremennye problemy optotekhniki: ucheb. posobie. M.: MIIGAiK, 2014. 82 p.
  13. Litvinovich G.S., Bruchkovskij I.I. Algoritm predvaritel'noj obrabotki dannyh linejki priborov s zaryadovoj svyaz'yu na osnove adaptivnogo fil'tra Vinera // Informatika. 2021. V. 18, N 1. P. 72–83. DOI: 10.37661/1816-0301-2021-18-1-72-83.
  14. Tymkul V.M., Tymkul L.V., Kudryashov K.V. Otrazhenie opticheskogo izlucheniya poverhnost'yu ob"emnyh tel s napravlenno-rasseivayushchim pokrytiem // Izv. vuzov. Priborostroenie. 2007. V. 50, N 10. P. 58–63.
  15. Miroshnikov M.M. Teoreticheskie osnovy optiko-elektronnyh priborov: ucheb. posobie. SPb.: Lan', 2010. 704 p.