Email this article PREDICTION OF ELECTRON FLUXES IN A CIRCULAR POLAR ORBIT: SELECTION OF PREDICTORS
- Authors: Belova A.O.1, Myagkova I.N.2
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Affiliations:
- Lomonosov Moscow State University
- D.V. Skobeltsyn Scientific Research Institute of Nuclear Physics
- Issue: Vol 11, No 3 (2025)
- Pages: 77-87
- Section: 20th Annual Conference “Plasma Physics in the Solar System” February 10–14, 2025, Space Research Institute RAS
- URL: https://bakhtiniada.ru/2712-9640/article/view/362427
- DOI: https://doi.org/10.12737/szf-113202509
- ID: 362427
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Abstract
We have investigated the relationship of variations in >0.7 and >2 MeV electron fluxes of Earth's outer radiation belt in a circular polar orbit with solar wind and interplanetary magnetic field parameters, as well as with geomagnetic indices and the logarithmic electron flux in the geostationary orbit in order to explore the possibility of predicting them. We have selected the optimal input features for predicting electron fluxes in low polar orbits, which is important for ensuring the radiation safety of future space missions.
We have examined integral and maximum electron fluxes of these energies over the span of a day. We have obtained forecasts with a horizon of 1 and 2 days for an interval of 2 months in 2020 for daily maximum and integral fluxes based on linear regression.
We have examined integral and maximum electron fluxes of these energies over the span of a day. We have obtained forecasts with a horizon of 1 and 2 days for an interval of 2 months in 2020 for daily maximum and integral fluxes based on linear regression.
About the authors
Anastasiya Olegovna Belova
Lomonosov Moscow State University
Email: belova.ao20@physics.msu.ru
Department of Space Physics
Irina Nikolaevna Myagkova
D.V. Skobeltsyn Scientific Research Institute of Nuclear PhysicsLaboratory of Space Physics Research, Senior Researcher, candidate of physical and mathematical sciences
References
Белов А.В., Виллорези Дж., Дорман Л.И. и др. Влияние космической среды на функционирование искусственных спутников Земли. Геомагнетизм и аэрономия. 2004, т. 44, № 4, с. 502–510. Вернов С.Н., Григоров Н.Л., Логачев Ю.И., Чудаков А.Е. Измерения космического излучения на искусственном спутнике Земли. Доклады Академии наук. 1958, т. 120, № 6, с. 1231–1233. Демиденко Е.З. Линейная и нелинейная регрессия. М.: Финансы и статистика. 1981, 302 с. Кузнецов С.Н., Мягкова И.Н., Юшков Б.Ю. и др. Динамика радиационных поясов Земли во время сильных магнитных бурь по данным ИСЗ «КОРОНАС-Ф». Астрономический вестник. Исследования солнечной системы. 2007, т. 41, № 4, с. 369–378. Мягкова И.Н., Широкий В.Р., Шугай Ю.С. и др. Краткосрочное и среднесрочное прогнозирование потоков релятивистских электронов внешнего радиационного пояса Земли методами машинного обучения. Метеорология и гидрология. 2021, № 3, с. 47–57. doi: 10.52002/0130-2906-2021-3-47-57. Новиков Л.С., Воронина Е.Н. Взаимодействие космических аппаратов с окружающей средой. М.: КДУ. 2021, 560 с. Оседло В.И., Калегаев В.В., Рубинштейн И.А. и др. Мониторинг радиационного состояния околоземного пространства на спутнике «Арктика-М» № 1. Космические исследования. 2022, т. 60, № 6, с. 439–453. doi: 10.31857/S0023420622060085. Романова Н.В., Пилипенко В.А., Ягова Н.В., Белов А.В. Статистическая связь частоты сбоев на геостационарных спутниках с потоками энергичных электронов и протонов. Космические исследования. 2005, т. 43, № 3, с. 186–193. Alwosheel A., van Cranenburgh S., Chorus C.G. Is your dataset big enough? Sample size requirements when using artificial neural networks for discrete choice analysis. J. Choice Modelling. 2018, vol. 28, pp. 167–182. doi: 10.1016/j.jocm.2018.07.002. Baker D.N., McPherron R.L., Cayton T.E., Klebesadel R.W. Linear prediction filter analysis of relativistic electron properties at 6.6 RE. J. Geophys. Res. 1990, vol. 95, iss. A9, pp. 15133–15140. doi: 10.1029/JA095iA09p15133. Balikhin M.A., Boynton R.J., Walker S.N., et al. Using the NARMAX approach to model the evolution of energetic electrons fluxes at geostationary orbit. Geophys. Res. Lett. 2011, vol. 38, iss. 18. doi: 10.1029/2011GL048980. Botek E., Pierrard V., Winant A. Prediction of radiation belts electron fluxes at a Low Earth Orbit using neural networks with PROBA-V/EPT data. Space Weather. 2023, vol. 21, iss. 7, e2023SW003466. doi: 10.1029/2023SW003466. Cole D.G. Space weather: Its effects and predictability. Space Sci. Rev. 2003, vol. 107, pp. 295–302. doi: 10.1023/A:1025500513499. Denton M.H., Henderson M.G., Jordanova V.K., et al. An improved empirical model of electron and ion fluxes at geosynchronous orbit based on upstream solar wind conditions. Space Weather. 2016, vol. 14, iss. 7, pp. 511–523. doi: 10.1002/2016SW001409. Glauert S.A., Horne R.B., Meredith N.P. Three-dimensional electron radiation belt simulations using the BAS Radiation Belt Model with new diffusion models for chorus, plasma-spheric hiss, and lightning-generated whistlers. J. Geophys. Res.: Space Phys. 2014, vol. 119, iss. 1, pp. 268–289. doi: 10.1002/2013JA019281. Iucci N., Levitin A., Belov E., et al. Space weather conditions and spacecraft anomalies in different orbits. Space Weather. 2005, vol. 3, iss. 1. doi: 10.1029/2003SW000056. Kalegaev V., Panasyuk M., Myagkova I., et al. Monitoring, analysis and post-casting of the Earth’s particle radiation environment during February 14 – March 5, 2014. Space Weather Space Climate. 2019, vol. 9, iss. A29. doi: 10.1051/swsc/2019029. Kalegaev V., Kaportseva K., Myagkova I., et al. Medium-term prediction of the fluence of relativistic electrons in geostationary orbit using solar wind streams forecast based on solar observations. Adv. Space Res. 2023, vol. 72, iss. 12, pp. 5376–5390. doi: 10.1016/j.asr.2022.08.033. Kataoka R., Miyoshi Y. Average profiles of the solar wind and outer radiation belt during the extreme flux enhancement of relativistic electrons at geosynchronous orbit. Ann. Geophys. 2008, vol. 26, iss. 6, pp. 1335‒1339. doi: 10.5194/angeo-26-1335-2008. Koons H.C., Gorney D.J. A neural network model of the relativistic electron flux at geosynchronous orbit. J. Geophys. Res. 1991, vol. 96, iss. A4, pp. 5549–5556. doi: 10.1029/90JA02380. Kudela K. Space weather near Earth and energetic particles: Selected results. J. Physics Conference Ser. 2013, vol. 409, iss. 1. doi: 10.1088/1742-6596/409/1/012017. Landis D.A., Saikin A.A., Zhelavskaya I., et al. NARX neural network derivations of the outer boundary radiation belt electron flux. Space Weather. 2022, vol. 20, iss. 5, e2021SW002774. doi: 10.1029/2021SW002774. Li W., Hudson M.K. Earth’s Van Allen radiation belts: From discovery to the Van Allen Probes era. J. Geophys. Res.: Space Phys. 2019, vol. 124, iss. 11, pp. 8319–8351. doi: 10.1029/2018JA025940. Li X., Baker D.N., Kanekal S.G., et al. Long term measurements of radiation belts by SAMPEX and their variations. Geophys. Res. Lett. 2001, vol. 28, iss. 20, pp. 3827–3830. doi: 10.1029/2001gl013586. Ling A.G., Ginet G.P., Hilmer R.V., Perry K.L. A neural network-based geosynchronous relativistic electron flux forecasting model. Space Weather. 2010, vol. 8, iss. 9. doi: 10.1029/2010SW000576. Lyatsky W., Khazanov G.V. A predictive model for relativistic electrons at geostationary orbit. Geophys. Res. Lett. 2008, vol. 35, iss. 15, L15108. doi: 10.1029/2008GL034688. Myagkova I., Efitorov A., Shiroky V., Dolenko S.A. Quality of prediction of daily relativistic electrons flux at geostationary orbit by machine learning methods. Artificial Neural Networks and Machine Learning – ICANN 2019: Text and Time Series. 2019, pp. 556–565. doi: 10.1007/978-3-030-30490-4_45. Pilipenko V., Yagova N., Romanova N., Allen J. Statistical relationships between the satellite anomalies at geostationary orbits and high-energy particles. Adv. Space Res. 2006, vol. 37, iss. 6, pp. 1192–1205. doi: 10.1016/j.asr.2005.03.152. Potapov A., Ryzhakova L., Tsegmed B. A new approach to predict and estimate enhancements of “killer” electron flux at geosynchronous orbit. Acta Astronaut. 2016, vol. 126, pp. 47–51. doi: 10.1016/j.actaastro.2016.04.017. Son J., Moon Y.-J., Shin S. 72-hour time series forecasting of hourly relativistic electron fluxes at geostationary orbit by deep learning. Space Weather. 2022, vol. 20, iss. 10, e2022SW003153. doi: 10.1029/2022sw003153. Stepanova M., Pinto V., Antonova E. Regarding the relativistic electron dynamics in the outer radiation belt: a historical view. Rev. Modern Plasma Physics. 2024, vol. 8, iss. 25. doi: 10.1007/s41614-024-00165-4. Sun X., Lin R., Liu S., et al. Modeling the relationship of ≥2 MeV electron fluxes at different longitudes in geostationary orbit by the machine learning method. Remote Sensing. 2021, vol. 13, iss. 17, p. 3347. doi: 10.3390/rs13173347. Wei L., Zhong Q., Lin R., et al. Quantitative prediction of high-energy electron integral flux at geostationary orbit based on deep learning. Space Weather. 2018, vol. 16, iss. 7, pp. 903–916. doi: 10.1029/2018SW001829. Williams D.J., Arens J.F., Lanzerotti L.J. Observations of trapped electrons at low and high altitudes. J. Geophys. Res. 1968, vol. 73, iss. 17, pp. 5673–5696. doi: 10.1029/ja073i017p05673. URL: https://swx.sinp.msu.ru/ (дата обращения 10 сентября 2024 г.). URL: http://www.swpc.noaa.gov/ (дата обращения 10 сентября 2024 г.). URL: https://rscf.ru/project/22-62-00048/ (дата обращения 10 сентября 2024 г.).
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