29.08.2025; Чернівці, Україна: V Міжнародна наукова конференція «Інтелектуальний ресурс сьогодення: наукові задачі, розвиток та запитання»
Роботи, що індексуються в Google Scholar

ENSURING CYBERSECURITY IN MILITARY COMMUNICATIONS THROUGH THREAT ANALYSIS AND DEFENSE MEASURES

  • Fagan Amanullazade
DOI: https://doi.org/10.62731/mcnd-29.08.2025.010
PDF

Опубліковано 29.08.2025

Як цитувати

Amanullazade, F. (2025). ENSURING CYBERSECURITY IN MILITARY COMMUNICATIONS THROUGH THREAT ANALYSIS AND DEFENSE MEASURES. Матеріали конференцій МЦНД, (29.08.2025; Чернівці, Україна), 229–238. https://doi.org/10.62731/mcnd-29.08.2025.010

Завантаження

Дані завантаження ще не доступні.

Авторське право (c) 2025 Fagan Amanullazade

Creative Commons License

Ця робота ліцензується відповідно до Creative Commons Attribution-ShareAlike 4.0 International License.

Google Scholar

Анотація

This article explores the growing challenges of cybersecurity in military communication systems, focusing on both tactical and strategic operational environments. The study analyzes common cyber threats, including jamming, spoofing, data breaches, malware, and phishing, with attention to their frequency and potential operational impact. By reviewing recent incidents and current defense protocols, the article evaluates the effectiveness of protective measures used in different branches of the armed forces. The findings reveal that while some units employ advanced cryptography and intrusion detection, many communication networks are still vulnerable due to outdated infrastructure and inconsistent security standards. The paper discusses emerging solutions such as artificial intelligence, quantum encryption, and blockchain, emphasizing both opportunities and practical limitations. The conclusion calls for unified multi-level cybersecurity frameworks, continuous investment in advanced technologies, and greater international collaboration to strengthen the resilience of military communication systems against evolving cyber threats.

PDF

Посилання

  1. 1. Agayev, S.O., et al. (2016). Modern pedagogical technologies in military education. Textbook. Part I. Baku: Military Publishing House.
  2. 2. Akhundov, R. (2017). Radiation-thermal activation of coal for water purification. In Ecological and environmental chemistry (pp. 141-141).
  3. 3. Akhundov, R. (2024). Environmental Warfare–Modern Global Challenge. In Modeling, Control and Information Technologies: Proceedings of International scientific and practical conference (No. 7, pp. 332-335).
  4. 4. Akhundov, R. (2024). The Environmental Consequences of Military Activity. In 20 години България в НАТО и НАТО в България (pp. 410-422).
  5. 5. Akhundov, R. (2024). The environmental impact of military activities. ResearchGet.
  6. 6. Akhundov, R. (2024, April 25–26). Basics of Special Forces Operations Planning. In Current Directions of Development of Information and Communication Technologies and Control Tools: Abstracts of the Fourteenth International Scientific and Technical Conference (Vol. 1, pp. 12–13). Kharkiv, Ukraine.
  7. 7. Akhundov, R. (2025). Establishing a global system for radiation and chemical security monitoring: importance and opportunities for international cooperation. Collection of scientific papers «ΛΌГOΣ», (July 4, 2025; Zurich, Switzerland), 121-127.
  8. 8. Akhundov, R. G., & Mustafayev, I. I. (2020). Radiation-initiated processes of activation of charcoal. Journal of Radiation Researches, 7(1), 27-34.
  9. 9. Akhundov, R., & Hashimov, E. (2025). Military activity and the environment: The need for a systemic approach to radiological and chemical safety. Матеріали конференцій МЦНД, (16.05. 2025; Миколаїв, Україна), 187-197.
  10. 10. Akhundov, R., & Hashimov, E. (2025). Radiation and chemical protection as a strategic priority of environmental security in the military sphere. Матеріали конференцій МЦНД, (16.05. 2025; Миколаїв, Україна), 202-211.
  11. 11. Akhundov, R., & Islamov, I. (2025). Innovative technologies for radiation and chemical protection in the armed forces. Collection of scientific papers «ΛΌГOΣ», (June 6, 2025; Bologna, Italy), 247-255.
  12. 12. Akhundov, R., & Nabizadə, Z. (2017, December). Production of high-efficiency carbon adsorbents for gas masks by radiation-chemical method. In Natural disasters and human life safety” International scientific-technical Conference. Baku, Azerbaijan (pp. 113-114).
  13. 13. Akhundov, R., & Sh, D. (2019, November). The use of modified activated coal in sorption of carbon-monoxide. In Materials of the international scientific-practical conference “Radiation and chemical safety problems”, –Baku (pp. 161-162).
  14. 14. Axundov, R. Q. (2017). Karbon adsorbentlərinin xüsusiyyətlərinin tədqiqi. Milli təhlükəsizlik və hərbi elmlər, 1(3), 129-135.
  15. 15. Axundov, R. Q. (2023). Azərbaycan Ordusunda radiasiya, kimyəvə bioloji mühafizənin inkişaf problemləri və onlarin həlli yollari. Hərb sənətinin aktual problemləri” beynəlxalq elmi-praktik konfransın materialları,–Bakı: MMU, 137-138.
  16. 16. Axundov, R. Q. (2023). Dərinin fərdi qoruyucu vasitələrinin tətbiqi və inkişaf perspektivləri. Bakı: Milli təhlükəsizlik və hərbi elmlər, (4), 9.
  17. 17. Axundov, R. Q. (2023). Pilotsuz uçuş aparatlarinin radiasiya və kimyəvi kəşfiyyatda tətbiqi. Bakı: Hərbi bilik,(2), 23-31.
  18. 18. Axundov, R. Q. (2024). Xüsusi təyinatlı bölmələrin icra etdiyi əməliyyatlar və onların tətbiqinin prinsip və xüsusiyətləri. Müasir radiotexniki silahlar” respublika elmi-praktik konfransın materialları–Bakı: MMU HETİ, 39-42.
  19. 19. Babanlı, A. M., & Ibragimov, B. G. (2017). Specific heat in diluted magnetic semiconductor quantum ring. Superlattices and Microstructures, 111, 574-578.
  20. 20. Babayev, S. M. et al. The impact of new technologies on the progress of military art. In Proceedings of International Scientific and Practical Conference (Vol. 6, pp. 54-56).
  21. 21. Bayramov, A. (2016). Seismic location station for detection of unobserved moving military machineries. Journal of Management and Inform. Science, 4(2), 61-66.
  22. 22. Bayramov, A. A. et al. (2018). SMART control system of systems for dynamic objects group. Bulgarska Voenna Misal.–2018.
  23. 23. Bayramov, A.A. (2019). Development of UAV SoS flight combat reconnaissance mission program. Advanced Information Systems, 3(1), 152-156.
  24. 24. Bayramov, A.A., et al. (2018, April). The supervisory control systems deployment in mountainous terrain. In VIII Int. Conf.“Modern development trends of ICT and control methods (pp. 3-4).
  25. 25. Hasanov, A. H. et al. (2024). Scientific and technological progress or environmental safety.
  26. 26. Hasanov, A.H. et al. (2023). Comparative analysis of the efficiency of various energy storages. Advanced Information Systems, 7(3), 74-80.
  27. 27. Hasanov, M. H., Ibrahimov, B. G., & Mardanov, N. T. (2019, June). Research and analysis performance indicators NGN/IMS networks in the transmission multimedia traffic. In 2019 Wave Electronics and its Application in Information and Telecommunication Systems (WECONF) (pp. 1-4). IEEE.
  28. 28. Hasanov, M. H., Ibrahimov, B. G., & Qodjaeva, S. F. (2018). Research efficiency optical transport networks with use transferring and reception optoelectronics module. International Journal of Research-Granthaalayah, 6(2), 324-330.
  29. 29. Hashimov, E. et al. (2016, May). Terrain orthophotomap making and combat control. In Proceeding of Internatonal Conf.“Modern Call of Security and Defence”. I-st (Vol. 19, pp. 68-71).
  30. 30. Hashimov, E. G. (2013). About one method of navigation task solution. AHMC after H. Aliyev. Scientific Review, 1(20), 45-49.
  31. 31. Hashimov, E. G. et al. (2017, May). Determination of the bearing angle of unobserved ground targets by use of seismic location cells. In 2017 International Conference on Military Technologies (ICMT) (pp. 185-188).
  32. 32. Hashimov, E. G., & Maharramov, R. R. Methods of effective detection of unmanned aerial vehicles. Проблеми інформатизації. Тези доповiдей, 9, 18-19.
  33. 33. Hashimov, E., et al. (2017). GIS technology and terrain orthophotomap making for military application. Journal of Defense Resources Management, 8(2), 81-90.
  34. 34. Hashimov, E.G. et al. (2017). Development of the multirotor unmanned aerial vehicle. National security and military sciences, 3(4), 21-31.
  35. 35. Hashimov, E.G. et al. (2023) About some aspects of using a flock of UAVS. İn Сучасні напрями розвитку інформаційно-комунікаційних технологій та засобів управління. Том 1: - pp.4-5.
  36. 36. Hashimov, E.G., & Bayramov, A.A. (2016). The flight dynamics of drones. National security and military sciences, 2(3), 11-16.
  37. 37. Hashimov, E.G., et al. (2015). Operative detection of ground enemy objects. Herbi Bilik, (1), 33-47.
  38. 38. Hashimov, E.G., et al. (2023). Mathematical aspects of determining the motion parameters of a target by UAV. Advanced Information Systems, 7(1), 18-22.
  39. 39. Huseynov, B.S. (2023). Characteristics of UAVs application during the second Karabakh war. İn Problems of informatization. Vol. 3. -p.10-11.
  40. 40. Ibrahimov, B. (2023). Investigation of noise immunity telecommunication systems according to the criterion energy efficiency. Transport and Telecommunication, 24(4), 375-384.
  41. 41. Ibrahimov, B. G. (2010). Research and estimation characteristics of terminal equipment a part of multiservice communication networks. Automatic Control and Computer Sciences, 48(6), 54-59.
  42. 42. Ibrahimov, B. G., & Hasanov, A. H. (2020). The investigation and evaluation multiservice network NGN/IMS for multimedia traffic. Synchroinfo journal, 6(3), 10-13.
  43. 43. Ibrahimov, B. G., & Talibov, A. M. (2019). Researches efficiency functioning systems processings information flows automobile services. T-Comm-Телекоммуникации и Транспорт, 13(5), 56-60.
  44. 44. Ibrahimov, B., Hasanov, A., & Hashimov, E. (2024). Research and analysis of efficiency indicators of critical infrastructures in the communication system. Advanced Information Systems, 8(2), 58-64.
  45. 45. Ibrahimov, B.G., et al. (2024). Research and analysis mathematical model of the demodulator for assessing the indicators noise immunity telecommunication systems. Advanced Information Systems, 8(4), 20-25.
  46. 46. Ibrahimov, B.G., et al. (2024). Research and analysis of efficiency indicators of critical infrastructures in the communication system. Advanced Information Systems, 8(2), 58-64.
  47. 47. Ibrаhimov B. G. (2023) Research quality of functioning of the efficiency optical telecommunication systems using spectral technologies// İn Проблеми інформатизації, Т.1. p.29-30.
  48. 48. Ibrаhimov B.G. et al. (2020) Research throughput multiservice telecommunication networks. İn “Сучасні напрями розвитку інформаційно-комунікаційних технологій та засобів управліньння”. Том 1: сек.1.-p.30.
  49. 49. Ibrаhimov, B. G., & Hashimov, E. G. (2023). Research quality of functioning of the efficiency optical telecommunication systems using spectral technologies.
  50. 50. Khudeynatov, E.K. (2023, November). V-model for Air Defense Systems. In Modeling, Control and Information Technologie (No. 6, pp. 46-49).
  51. 51. Mustafayev, I. I., & Akhundov, R. G. (2019). The formation of carbon adsorbent at the influence of radiation to the carboneus substances. Warsaw, Poland: East European Scientific Journal, (12), 52.
  52. 52. Piriyev, H.K., et al. (2014). Some issues of pedagogical staff training for special-purpose higher education institutions. Military knowledge, (4), 3-9.
  53. 53. Piriyev, H.K., et al. (2016). Provide interactive training methods. Methodological materials. Baku: Military publishing house.
  54. 54. Piriyev, H.K., Hashimov, E.G. (2023) The Second Karabakh War: military-political and military-technical aspects. Scientific Proceedings. 1(21), 7-16.
  55. 55. Talibov, A. M. et al. (2024). Environmental safety of nanomaterials application. In Problems of Informatization: Proceedings of the 12th International Scientific and Technical Conference (Vol. 3, pp. 55–56).
  56. 56. Ахундов, Р. Г. (2019). Модифицирование радиационо-термическим методом углеродных сорбентов и их применение в гемосорбции. Москва: Евразийский союз ученых, (11), 68.
  57. 57. Ахундов, Р. Г. (2019). Получение углеродных адсорбентов для противогазов радиационо-химическим методом. Кемерово: Точная наука, (64), 14-18.
  58. 58. Ахундов, Р. Г. О. (2019). Cорбционные и структурные характеристики углеродных адсорбентов. Вестник науки и образования, (22-1 (76)), 22-27.
  59. 59. Ахундов, Р. Г. О. (2019). Построение экспериментальных изотерм адсорбции образцами угленаполненного химзащитного субстрата. Наука, техника и образование, (10 (63)), 16-20.
  60. 60. Ахундов, Р. Г., Ахмедова, А. Г., Даньялов, Ш. Д., & Мустафаев, И. И. (2020). Радиационно-стимулированные процессы получения активного угля. Санкт-Петербург, 25(1), 47.
  61. 61. Ибрагимов, Б. Г. О., Гасанов, А. Г. О., Алиева, А. А. К., & Исаев, А. М. О. (2019). Исследование показателей качества функционирования мультисервисных телекоммуникационных сетей на базе архитектурной концепции будущих сетей. Надежность и качество сложных систем, (1 (25)), 88-95.
  62. 62. Мустафаев, И. И., & Ахундов, Р. Г. (2019). Коксование углеродистых материалов под воздействием ионизирующего излучения. Вестник Международной академии наук экологии и безопасности жизнедеятельности, 24(4), 37-44.