DEVELOPMENT OF AN ARCHITECTURAL DESIGN METHOD FOR MOBILE SDN IN ULTRA-DENSE SENSOR NETWORKS

Oleksandr Shefer; Stanislav Myhal

doi:10.26906/SUNZ.2026.2.279

Автор(и)

Oleksandr Shefer
Stanislav Myhal

DOI:

https://doi.org/10.26906/SUNZ.2026.2.279

Ключові слова:

telecommunication network, edge layer, mobile device, controller, ultra-dense sensor network (UDSN), OpenFlow switch, 5G standard, SDN

Анотація

Background. The method of deploying SDN controllers on mobile nodes within ultra-dense networks is a vital component in enhancing the management efficiency of modern telecommunication systems. Given the rapid proliferation of connected devices and escalating traffic volumes, traditional centralized network management approaches often lack the necessary flexibility and scalability. Subject of Research. This study focuses on methods for constructing mobile SDN architectures tailored for ultra-dense sensor networks (UDSNs). Objectives. The aim of this research is to develop a method for designing a software-defined ultra-dense sensor network architecture, where specific SDN controllers are integrated into mobile nodes at the edge layer. Results. The study proposes an MEC (Multi-access Edge Computing) platform architecture specifically designed for deploying SDN controllers on mobile nodes within 5G/6G ultra-dense networks. A three-tier model for a mobile multi-controller SDN in UDSNs has been established. Furthermore, a specialized method for the placement and distribution of SDN controllers on mobile nodes within these ultra-dense environments was developed. Conclusion. Experimental results indicate that the implementation of the proposed method reduces transaction latency by 60% compared to traditional SDN-based edge computing models. Additionally, energy consumption is reduced by up to 30%.

Завантажити

Дані для завантаження поки недоступні.

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