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    Publicações

    Publicações por Tatiana Guedes

    2017

    State feedback control for DC-photovoltaic systems

    Autores
    Fernandes, D; Almeida, R; Guedes, T; Sguarezi Filho, A; Costa, F;

    Publicação
    Electric Power Systems Research

    Abstract

    2019

    A maximum power point tracking for photovoltaic systems based on Monod equation

    Autores
    Camilo, JC; Guedes, T; Fernandes, DA; Melo, J; Costa, F; Sguarezi Filho, AJ;

    Publicação
    Renewable Energy

    Abstract

    2021

    Aggregator units allocation in low voltage distribution networks with penetration of photovoltaic systems

    Autores
    Palate, BO; Guedes, TP; Grilo-Pavani, A; Padilha-Feltrin, A; Melo, JD;

    Publicação
    International Journal of Electrical Power & Energy Systems

    Abstract

    2022

    Two-Stage Stochastic Optimization Model for Multi-Microgrid Planning

    Autores
    Vera, EG; Canizares, CA; Pirnia, M; Guedes, TP; Melo, JD;

    Publicação
    IEEE Transactions on Smart Grid

    Abstract

    2025

    Graph Neural Networks for Fault Location in Large Photovoltaic Power Plants

    Autores
    Klyagina O.; Silva C.G.; Silva A.S.; Guedes T.; Andrade J.R.; Bessa R.J.;

    Publicação
    2025 IEEE Kiel Powertech Powertech 2025

    Abstract
    A fast response to faults in large-scale photovoltaic power plants (PVPPs), which can occur on hundreds of components like photovoltaic panels and inverters, is fundamental for maximizing energy generation and reliable system operation. This work proposes using a Graph Neural Network (GNN) combined with a digital twin for synthetic fault data scenario generation for fault location in PVPPs. It shows that GNN can adapt to system changes without requiring model retraining, thus offering a scalable solution for the real operating PVPPs, where some parts of the system may be disconnected for maintenance. The results for a real PVPP show the GNN outperforms baseline models, especially in larger topologies, achieving up to twice the accuracy in a fault location task. The GNN's adaptability to topology changes was tested on the simulated reconfigured systems. A decrease in performance was observed, and its value depends on the complexity of the original training topology. It can be mitigated by using several system reconfigurations in the training set.

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