Physics of Wave Processes and Radio SystemsPhysics of Wave Processes and Radio Systems1810-31892782-294XPovolzhskiy State University of Telecommunications and Informatics935610.18469/1810-3189.2021.24.2.49-54Research ArticleCalculated estimation of electromagnetic compatibility of radio-electronic means of space systems and complexesKrivobokovYevgeny E.<p>Lead Engineer of Khrunichev State Research and Production Space Center</p>krv-evgeny@yandex.ruKhrunichev State Research and Production Space Center06092021242495406092021Copyright © 2021, Krivobokov Y.2021<p>This article presents the methods of complex computational and analytical assessment of ensuring electromagnetic compatibility of technical means (electrical, electronic and radio-electronic means of launch vehicles and spacecraft). These methods allow us to conduct a comprehensive computational and analytical assessment of the electromagnetic compatibility of the technical means of rocket and space technology, which in its essence allows us to assess the mutual influence of the technical means of rocket and space technology already at the design stage of rocket and space technology objects. The analysis of the results of the assessment of the electromagnetic compatibility of the technical means of rocket and space technology allows us to develop organizational and technical measures aimed at ensuring the electromagnetic compatibility of the technical means of rocket and space technology at all stages of the life cycle of objects of rocket and space technology. To assess the electromagnetic compatibility of the technical means of rocket and space technology, an integrated approach was chosen due to the large dimension of the initial data and the variety of possible variants of interference penetration.</p>electromagnetic compatibilityantenna deviceconducted interferenceradio electronic meanslaunch vehiclespacecraftrocket and space technologyэлектромагнитная совместимостьантенное устройствокондуктивная помехарадиоэлектронное средстворакета-носителькосмический аппаратракетно-космическая техника[Uill’jams T. EMC for Product Developers. Moscow: Izdatel’skij Dom «Tehnologii», 2003, 540 p. (In Russ.)][Uajt D.R.Zh. Electromagnetic Compatibility of Radio Electronic Equipment and Unintentional Interference. Moscow: Sovetskoe radio, 1977, 347 p. (In Russ.)][Dementyev A.N. et al. Interference immunity of satellite communication systems with multi-beam active phased antenna arrays. Voprosy radioelektroniki, 2016, no. 11 (7), pp. 6–12. URL: https://vre.instel.ru/jour/article/view/565 (In Russ.)][Dementyev A.N. et al. Approximation, linearization and modeling of nonlinear transmission channels of satellite communication systems. Voprosy radioelektroniki, 2016, no. 11 (7), pp. 18–21. URL: https://vre.instel.ru/jour/article/view/567 (In Russ.)][Dementyev A.N. et al. Physical model of a strip loop antenna located on a dielectric cylinder. Kosmonavtika i raketostroenie, 2016, no. 4 (89), pp. 137–142. (In Russ.)][Dementyev A.N. Development of methods for noise immunity of radio engineering systems by implementing the technology of individual selection and qualification of a radiation-resistant electronic component base at the stage of its production. Physics of Wave Processes and Radio Systems, 2018, vol. 21, no. 3, pp. 129–137. URL: https://journals.ssau.ru/pwp/article/view/7027 (In Russ.)][Dementyev A.N., Kljuev D.S., Sokolova Yu.V. Calculation of the input impedance of a strip vibrator conformally located on a dielectric cylinder. Radiotehnika i elektronika, 2017, vol. 62, no. 11, pp. 1061–1066. (In Russ.)][Dementyev A.N., Kljuev D.S., Sokolova Yu.V. Input impedance of a strip loop antenna conformally located on a dielectric cylinder. Fizika i tehnicheskie prilozhenija volnovyh protsessov: mat. XIII Mezhd. nauch.-tehn. konf., Kazan, 2015, pp. 90–92. (In Russ.)][Dementyev A.N. Mathematical modeling of the electromagnetic environment on board the spacecraft. Physics of Wave Processes and Radio Systems, 2018, vol. 21, no. 4, pp. 26–36. URL: https://journals.ssau.ru/pwp/article/view/6946 (In Russ.)][Dementyev A.N., Aralkin M.V., Osipov O.V. Investigation of the electromagnetic characteristics of planar chiral metastructures based on composite helical components taking into account the heterogeneous Bruggemann model. Physics of Wave Processes and Radio Systems, 2020, vol. 23, no. 3, pp. 44–55. DOI: https://doi.org/10.18469/1810-3189.2020.23.3.44-55 (In Russ.)][Dementyev A.N., Aralkin M.V., Osipov O.V. Reflection of a plane electromagnetic wave from a planar layer of a metamaterial based on N-orthogonal microspirals. Sb. mat. XXVII Rossijskoj nauchnoj konf. prof.-prep. sostava, nauchnyh sotrudnikov i aspirantov PGUTI s priglasheniem veduschih uchenyh rodstvennyh vuzov i organizatsij, Samara, PGUTI, 2020, pp. 110–111. (In Russ.)][Dementyev A.N. et al. Microwave and Optical Devices. Samara: PGUTI, 2018, 220 p. (In Russ.)][Dementyev A.N. Development of methods for noise immunity of radio engineering systems by implementing the technology of individual selection and qualification of a radiation-resistant electronic component base at the stage of its production. Physics of Wave Processes and Radio Systems, 2018, vol. 21, no. 3, pp. 129–137. URL: https://journals.ssau.ru/pwp/article/view/7027 (In Russ.)][Dementyev A.N., Aralkin M.V., Osipov O.V. Reflection of a plane electromagnetic wave from a planar layer of a metamaterial based on N-entry gammadions. Sb. mat. XXVII Rossijskoj nauchnoj konf. prof.-prep. sostava, nauchnyh sotrudnikov i aspirantov PGUTI s priglasheniem veduschih uchenyh rodstvennyh vuzov i organizatsij, Samara, PGUTI, 2020, pp. 109–110. (In Russ.)][Dementyev A.N., Aralkin M.V., Osipov O.V. Mathematical model of a metamaterial taking into account heterogeneity, chirality and dispersion. Sb. trud. IV nauchnogo foruma telekommunikatsii: teorija i tehnologii TTT-2020. Fizika i tehnicheskie prilozhenija volnovyh protsessov: materialy XVIII Mezhdunarodnoj nauchno-tehnicheskoj konferentsii, Samara, 2020, pp. 216–217. (In Russ.)][Dementyev A.N., Nefedov V.I., Filatov A.A. Electromagnetic compatibility and noise immunity of satellite communication systems with orbital and intrasystem sources of radio interference. Sb. trud. OAO «Kontsern radiostroenija “Vega”», 2016, no. 4, pp. 45–49. (In Russ.)][Dementyev A.N. et al. Analysis of methods for assessing the electromagnetic compatibility of radio electronic equipment of a heavy-class launch vehicle of the «Angara-A5» type. Kosmonavtika i raketostroenie, 2016, no. 3 (88), pp. 21–27. (In Russ.)]