|
|
|
|
References
|
|
| |
| 1. |
J. S. Hojnicki, R. D. Green, T. W. Kerslake, D. B. McKissock, J. J. Trudell, “Space Station Freedom electrical performance model”, 28th Intersociety Energy Conversion Engineering Conference (Atlanta, Georgia, 1993) |
| 2. |
M. Kh. Kui, L. V. Markin, “Raschet vzaimnogo zateneniia solnechnykh antenn kosmicheskikh letatelnykh apparatov”, Trudy MAI. Elektronnyi zhurnal, 2017, no. 93 |
| 3. |
T. Li, W. Li, L. Yang, “Development of Spacecraft Solar Array Electrical Performance Simulation System”, 8th IEEE International Conference on Software Engineering and Service Science (ICSESS) (Beijing, 2017), 735–738  |
| 4. |
Open Inventor$^{\text{TM}}$, http://openinventor.com/ |
| 5. |
R. Ramaprabha, B. L. Mathur, “A comprehensive review and analysis of solar photovoltaic array configurations under partial shaded conditions”, International Journal of Photoenergy, 12:6 (2012), 1–16  |
| 6. |
M. R. Akhmedov, “Metodika veroiatnostnogo rascheta moshchnosti solnechnykh batarei kosmicheskogo apparata pri chastichnom osveshchenii”, Izvestiia RAN. Energetika, 2018, no. 5, 109–123 |
| 7. |
Vas. V. Sazonov, “Algoritm opredeleniia osveshchennosti solnechnykh batarei Rossiiskogo segmenta Mezhdunarodnoi kosmicheskoi stantsii”, Izvestiia MGTU «MAMI», 3:2 (20) (2014), 65–70 |
| 8. |
Vas. V. Sazonov, “Postroenie interaktivnoi geometricheskoi modeli vneshnei poverkhnosti kosmicheskogo apparata”, Matematicheskoe modelirovanie, 32:6 (2020), 37–52   |
| 9. |
G. S. Rauschenbach, Solar Cell Array Design Handbook, Springer, Dordrecht, 1980, 501 pp. |
| 10. |
V. A. Letin, “Funktsionirovanie solnechnykh batarei v kosmicheskoi srede”, Model kosmosa, Nauchno-informatsionnoe izdanie v 2 t., v. 2, KDU, M., 2007, 561–594  |
| 11. |
V. N. Gushchin, Osnovy ustroistva kosmicheskikh apparatov, Mashinostroenie, M., 2003, 272 pp. |
| 12. |
V. A. Matvienko, Elektronika, uchebnoe posobie, UMTS UPI, Ekaterinburg, 2012, 127 pp. |
| 13. |
V. I. Gorbulin, N. V. Radionov, D. L. Kargu, P. A. Komarov, N. N. Astakhov, “Opredelenie orientatsii kosmicheskogo apparata po izmereniiam zasvetki testovykh blokov solnechnykh batarei”, Trudy voenno-kosm. akademii im. A.F. Mozhaiskogo, 2015, no. 646, 134–138 |
| 14. |
I. V. Belokonov, A. V. Kramlikh, I. A. Lomaka, P. N. Nikolaev, “Vosstanovlenie uglovogo dvizheniia kosmicheskogo apparata po dannym o tokosieeme s panelei solnechnykh batarei”, Izvestiia RAN. Teoriia i sistemy upravleniia, 2019, no. 2, 133–144 |
| 15. |
V. Ia. Averbukh, D. M. Vainberg, E. A. Leshchinskii, “Razrabotka sistemy orientatsii solnechnykh batarei unifitsirovannoi kosmicheskoi platformy”, Voprosy elektromekhaniki, Trudy VNIIEM, 100, 2001, 97–103 |
| 16. |
A. S. Zernov, V. D. Nikolaev, “Opyt ekspluatatsii solnechnykh batarei sluzhebnogo modulia Mezhdunarodnoi kosmicheskoi stantsii”, Kosmicheskaia tekhnika i tekhnologii, 2016, no. 1 (12), 29–38 |
| 17. |
D. A. Vallado, P. Crawford, “SGP4 Orbit Determination”, AIAA/AAS Astrodynamics Specialist Conference (Honolulu, 2008) |
| 18. |
I. K. Bazhinov, B. N. Petrov, V. D. Iastrebov, Navigatsionnoe obespechenie poleta orbitalnogo kompleksa “Saliut-6”–“Soiuz”–“Progress”, Nauka, M., 1985, 376 pp. |
| 19. |
K. R. Bairamov, V. V. Betanov, G. G. Stupak, Iu. M. Urlichich, Metody, modeli i algoritmy resheniia nekorrektnykh zadach navigatsionno-ballisticheskogo obespecheniia, Radiotekhnika, M., 2012, 357 pp. |
| 20. |
O. Montenbruck, T. Pfleger, Astronomy on the Personal Computer, Springer, Berlin, 1997, 255 pp. |
| 21. |
E. Haines, T. Akenine-Moller, Ray Tracing Gems. High-Quality and Real-Time Rendering, Apress, NY, 2019, 607 pp. |
| 22. |
Iu. S. Elizarov, A. V. Kuznetsov, R. M. Abdulkhalikov, A. G. Bideev, I. I. Khamits, “Energo-balans nauchno-energeticheskogo modulia pri ego avtonomnom polete i integratsii v Rossiiskii segment Mezhdunarodnoi kosmicheskoi stantsii”, Kosmicheskaia tekhnika i tekhnologii, 2019, no. 4 (27), 38–44 |
| 23. |
M. R. Akhmedov, A. G. Bideev, E. Yu. Makarova, V. V. Sazonov, I. I. Khamits, “Sravnitelnyi analiz raschetnoi i eksperimentalnoi proizvoditelnosti solnechnykh batarei orbitalnogo kosmicheskogo apparata na primere sluzhebnogo modulia Rossiiskogo segmenta MKS”, Kosmicheskaia tekhnika i tekhnologii, 2018, no. 3 (22), 69–81 |
| 24. |
F. G. Lemoine, S. C. Kenyon, J. K. Factor, R. G. Trimmer, N. K. Palvis, D. S. Chinn, C. M. Cox, S. M. Klosko, S. B. Luthcke, M. H. Torrence, Y. M. Wang, R. G. Williamson, E. C. Pavlis, R. H. Rapp, T. R. Olson, The Development of the Joint NASA GSFC and the National Imagery and Mapping Agency (NIMA) Geopotential Model EGM96, NASA Goddard Space Flight Center, Greenbelt, Maryland 20771, 1998, 584 pp. |
| 25. |
V. V. Beletskii, A. M. Ianshin, Vliianie aerodinamicheskikh sil na vrashatelnoe dvizhenie iskusstvennykh sputnikov, Naukova dumka, Kiev, 1984, 187 pp. |
| 26. |
GOST R 25645.166-2004. Atmosfera Zemli verkhniaia. Model plotnosti dlia ballisticheskogo obespecheniia poletov iskusstvennykh sputnikov Zemli, IPK Izdatelstvo standartov, M., 2004, 24 pp. |
