Design of the сommunication network operational support system based on microservice architecture

Relevance. The development of information technology has led to a significant increase in the volume of transmitted data, which in turn creates serious challenges for telecommunications networks. Goal. Designing the architecture of the communication network operational support system, as well as selecting appropriate and relevant technologies for further system development. Materials and methods. Apache Zookeeper distributed service, Apache Kafka distributed streaming platform, PostgreSQL open object-relational database, Java programming language, Spring framework, Hilla web application framework, GeoJSON open format for storing and transmitting geographical data, D3 data visualization library.js, the React JavaScript library. Results. The built system, based on a client-server architecture and micro-service interaction, allows efficient management of network resources, minimizes delays and adapts to dynamic changes in the network. Conlusion. The use of modern technologies on both the client and server sides ensures high performance and scalability of the solution, which makes it promising for further development in the face of rapidly growing information infrastructure requirements.

1. Sorokin G.O., Sinitsyn A.V. Routing algorithm to ensure fault tolerance of the communication network. Information and innovations. 2024;19(2):84-95. https://doi.org/10.31432/1994-2443-2024-19-2-84-95

2. Letov N.K. A method for reducing competition in parallel access to data in a database based on message distribution in Apache Kafka. Bulletin of Science. 2024;4(12): 1598-1603. https://doi.org/10.24412/2712-8849-2024-1281-1598-1603

3. Platonova A.I. Performance Comparison of PostgreSQL and its TimescaleDB extension. Modern innovations, systems and technologies. 2024;4(3):0121-0133. https://doi.org/10.47813/2782-2818-2024-4-3-0121-0133

4. Panasenko N.D., Dyachenko N.V. Traffic routing algorithm. Young researcher of the Don. 2021; No 4(31):12-13. EDN SGWKQU.

5. Boldyrevsky P.B., Zyuzin V.D. Formalization of calculation of route options in peer-to-peer networks for information security tasks. Economics and quality of communication systems. 2025; No.35:66-76.

6. Dilmurodov Z.D. Routing protocols and their application in computer networks. Economics and Society. 2025; No.1-2(128):1018-1022. EDN: UJUKYR.

7. Novikov A.S., Pestin M.S. Distributed traffic routing in wireless decentralized self-organizing communication networks. News of TulSU. Technical sciences. 2021; No. 5: 149-154. https://doi.org/10.24412/2071-6168-2021-5-149-154

8. Chertkov A.A., Kask Ya.N., Ochina L.B. Streaming network routing based on Bellman-Ford algorithm modification. Vestnik Gosudarstvennogo universiteta morskogo i rechnogo flota imeni admirala S.O. Makarova. 2022;14(4):615-627. https://doi.org/10.21821/2309-5180-2022-14-4-615-627

9. Listopad N.I., Lavshuk O.A. QoS routing in telecommunications networks. Reports of BSUIR. 2022;20(3):45-53. (In Russ.) https://doi.org/10.35596/1729-7648-2022-20-3-45-53

10. Chiganov D.R. Spring: a powerful framework for developing Java applications. Bulletin of Science. 2023;4(7):273-275. EDN: KOINJB.

11. Lyashov E.I. Designing highly loaded reactive systems using Java and Spring Webflux: advantages over the traditional stack. International Journal of Humanities and Natural Sciences. 2025; No.1-3(100):180-185. https://doi.org/10.24412/2500-1000-2025-1-3-180-185

12. Kravtsov E.P. Development of high-performance React applications: optimization methods and practices. European science. 2024; No.1(69):53-58.

13. Volkov A.N. The routing problem in a dynamic fog computing network. Proceedings of educational institutions of communication. 2024;10(4):27-37. (In Russ.). https://doi.org/10.31854/1813-324X-2024-10-4-27-37

14. Utepbergenov A.O. Big data in human resource management. Economics and Society. 2022; No.4-3(95):513-519. EDN: VGFUNU.