In recent years, there has been a rapid shift towards a fully digital paradigm in electrical substations. This shift is driven by the need for greater interoperability between different instruments and control actions, which is facilitated by the IEC 61850 series of standards. In this paper, we specifically focus on Phasor Measurement Units (PMUs) and their role in this digital transformation. One of the challenges in adopting high-performance wired communication standards such as Ethernet and TSN is the cost associated with wiring over long distances between substations. To overcome this limitation, we explore the feasibility of utilizing a 5G communication infrastructure to transmit PMU measurements. Our study simulates a real-world distribution network and assesses the worst-case latency between PMUs and Phasor Data Concentrator (PDC) by scaling the number of PMUs considered. With a mean communication latency of 20 ms, the 5G communication infrastructure proves to be a valuable solution, particularly in distribution networks where line lengths are relatively short.
Optimized 5G Communication Infrastructure for PMU-Based Distributed Measurement Systems / Morato, A.; Frigo, G.; Tramarin, F.. - (2023), pp. -06. (Intervento presentato al convegno 13th IEEE International Workshop on Applied Measurements for Power Systems, AMPS 2023 tenutosi a che nel 2023) [10.1109/AMPS59207.2023.10297144].
Optimized 5G Communication Infrastructure for PMU-Based Distributed Measurement Systems
Tramarin F.
2023
Abstract
In recent years, there has been a rapid shift towards a fully digital paradigm in electrical substations. This shift is driven by the need for greater interoperability between different instruments and control actions, which is facilitated by the IEC 61850 series of standards. In this paper, we specifically focus on Phasor Measurement Units (PMUs) and their role in this digital transformation. One of the challenges in adopting high-performance wired communication standards such as Ethernet and TSN is the cost associated with wiring over long distances between substations. To overcome this limitation, we explore the feasibility of utilizing a 5G communication infrastructure to transmit PMU measurements. Our study simulates a real-world distribution network and assesses the worst-case latency between PMUs and Phasor Data Concentrator (PDC) by scaling the number of PMUs considered. With a mean communication latency of 20 ms, the 5G communication infrastructure proves to be a valuable solution, particularly in distribution networks where line lengths are relatively short.
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