INTEGRATION OF INTELLIGENT TECHNOLOGIES IN COMPUTER NETWORKS
DOI:
https://doi.org/10.28925/2663-4023.2026.32.1024Keywords:
computer networks, advanced technologies, аrtificial intelligence, AIOps, 5G, 6G, post-quantum cryptography, CSIDH, Edwards curve, isogeny, IIoT, Edge/Fog computing, integration of technologies, quantum and optical networksAbstract
The increased need for transmitted information, the emergence of new types of devices and services, as well as the increased security and reliability of computer networks mean the need to develop new technologies and new technical features and solutions. The statistics examines current trends and promising developments of computer networks, including the integration of artificial intelligence (AI), autonomous systems (AIOps) and others technologies (SDN, NFV) in management of networks. It is important to use advanced self-innovation technology to increase the reliability of the measurement process. The transition to the fifth and sixth generations (5G/6G) and their power, as well as the development of post-quantum cryptography to ensure cybersecurity in the minds of quantum computing, is examined. The CSIDH cryptosystem on the isogenies of Edwards elliptic curves with additional modernization is being introduced for the upcoming development. With the recent modernization of the speed code, the increasingly comprehensive cryptosystem is growing by three orders of magnitude. Particular attention is paid to industrial process control measures (IIoT) and the role of cloud and peripheral calculations in the increased efficiency, reliability and scalability of process solutions. A significant perspective is the sensory networks from different channels and interfaces. The prospects for the creation of quantum and optical channels are examined. It is believed that the advent of smart algorithms, secure cryptographic protocols and partitioned architectures creates the basis for a new generation of digital economy.
Downloads
References
Cabinet of Ministers of Ukraine. (2023). On approval of the strategy for the development of electronic communications until 2030. https://zakon.rada.gov.ua
Cisco Systems. (2024). Global networking trends report 2025. Cisco Press.
Stetsenko, V. P., & Titova, I. (2022). Modern network technologies. Uman State Pedagogical University named after Pavlo Tychyna.
Zhurakovskyi, B. Yu., & Zeniv, I. O. (2020). Computer networks. Igor Sikorsky Kyiv Polytechnic Institute.
Roslyakov, A. (n.d.). Network 2030: ITU-T vision for the future of fixed communication networks. https://www.lastmile.su/files/article_pdf/8/article_8861_92.pdf
International Telecommunication Union. (2022). Recommendation ITU-T Y.3100: Framework of the IMT-2020 network.
6G Flagship. (2023). Key drivers and research challenges for 6G ubiquitous wireless intelligence. University of Oulu.
Orlov, R. (n.d.). Introduction to IPv6 compared to IPv4. https://4te.me/post/vvedenie-v-ipv6-na-praktike
Sukhorukova, H. (n.d.). Drivers of fiber-optic internet development: What to expect from the technology. https://hub.kyivstar.ua/author/ganna-suhorukova
Nielsen, M. A., & Chuang, I. L. (2010). Quantum computation and quantum information (10th anniversary ed.). Cambridge University Press.
Shalahinov, A. (2025). Migration from 4G to 5G using network function virtualization (NFV). https://shalaginov.com/2023/03/13/4g-to-5g-nfv-migration
European Telecommunications Standards Institute. (2023). Network function virtualisation (NFV): Management and orchestration (ETSI GR NFV-EVE 012).
Stallings, W. (2022). Foundations of modern networking: SDN, NFV, QoE, IoT, and cloud. Pearson Education.
Jooby. (n.d.). How LPWAN networks work and why LoRaWAN stands out. https://jooby.eu/ru/blog/kak-rabotayut-lpwan-seti-i-pochemu-lorawan-vydelyaetsya-na-ih-fone/
Shalahinov, A. (2023). Edge cloud. https://shalaginov.com/2023/09/20/edge-cloud
TTT. (n.d.). The future of virtual reality: Where the industry is heading. https://www.ttt.ua/ua/articles-reviews/budushchee-virtualnoi-realnosti-kuda-dvizhetsia-industriia
Rolik, A. I., Telenyk, S. F., & Yasochka, M. V. (2018). Management of corporate IT infrastructure. Naukova Dumka.
Cisco Systems. (2025). Intent-based networking (IBN). https://www.cisco.com/site/us/en/solutions/intent-based-networking/index.html
Microsoft. (2025). Azure IoT Hub documentation. https://learn.microsoft.com/azure/iot-hub
Khazyka, S. (2025). Artificial intelligence for IT operations (AIOps). https://www.unite.ai/ru/what-is-aiops
Tang, F., Kawamoto, Y., & Kato, N. (2024). Future intelligent and autonomous 6G networks: AI-based self-optimization. IEEE Network, 38(2), 12–21.
Sibanda, I. (2025, February 7). Self-healing networks: The next evolution in network management. ComputerWeekly.com.
Cobourne, S. (2025). Quantum key distribution: Protocols and applications. Royal Holloway, University of London.
Mattsson, J. P., et al. (2021). Quantum-resistant cryptography. arXiv. https://arxiv.org/abs/2112.00399
ML-KEM Network Crystal Legacy. (n.d.). Events, news and roadmap. https://coindar.org/en/coin/ML-KEM-network
National Institute of Standards and Technology. (2024). Post-quantum cryptography standardization: Finalists and round 4 candidates.
Jao, D., & De Feo, L. (2023). Towards quantum-resistant cryptosystems from supersingular elliptic curve isogenies (CSIDH). In Post-Quantum Cryptography Conference Proceedings.
Castryck, W., Lange, T., Martindale, C., Panny, L., & Renes, J. (2018). CSIDH: An efficient post-quantum commutative group action. In T. Peyrin & S. Galbraith (Eds.), Advances in cryptology – ASIACRYPT 2018 (pp. 395–427). Springer.
Bessalov, A., Sokolov, V., & Abramov, S. (2024). Efficient switching algorithms for PQC on Edwards curve isogenies. Cryptography, 8, 38.
Bessalov, A. V., & Abramov, S. V. (2023). PQC CSIKE algorithm on non-cyclic Edwards curves. Cybernetics and Systems Analysis, 59, 3–18.
Published
How to Cite
Issue
Section
License
Copyright (c) 2026 Вадим Абрамов, Оксана Глушак , Сергій Абрамов
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
