Related papers: Near Real-Time Distributed State Estimation via AI/ML-Empowered 5G Networks

Near Real-Time Distributed State Estimation via AI/ML-Empowered 5G Networks

URL: http://arxiv.org/abs/2207.11117v1
Date: Fri, 22 Jul 2022 14:48:10 GMT
Title: Near Real-Time Distributed State Estimation via AI/ML-Empowered 5G Networks
Authors: Ognjen Kundacina, Miodrag Forcan, Mirsad Cosovic, Darijo Raca, Merim Dzaferagic, Dragisa Miskovic, Mirjana Maksimovic, Dejan Vukobratovic
Abstract summary: We focus on the State Estimation function as a key element of the energy management system. We compare two powerful distributed SE methods based on: i) graphical models and belief propagation, and ii) graph neural networks.
Score: 1.1938918581443054
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Fifth-Generation (5G) networks have a potential to accelerate power system transition to a flexible, softwarized, data-driven, and intelligent grid. With their evolving support for Machine Learning (ML)/Artificial Intelligence (AI) functions, 5G networks are expected to enable novel data-centric Smart Grid (SG) services. In this paper, we explore how data-driven SG services could be integrated with ML/AI-enabled 5G networks in a symbiotic relationship. We focus on the State Estimation (SE) function as a key element of the energy management system and focus on two main questions. Firstly, in a tutorial fashion, we present an overview on how distributed SE can be integrated with the elements of the 5G core network and radio access network architecture. Secondly, we present and compare two powerful distributed SE methods based on: i) graphical models and belief propagation, and ii) graph neural networks. We discuss their performance and capability to support a near real-time distributed SE via 5G network, taking into account communication delays.

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