Stochastic MPC-Based Reconfiguration Approaches for Microgrids

This article focuses on the improvement of the real-time operation of the microgrid based on model predictive control (MPC), taking into account the stochastic nature of renewable resources and demand, as well as fault-tolerant mechanisms. Thus, a fault-tolerant strategy (FTS) module is inserted int...

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Veröffentlicht in:	IEEE transactions on control systems technology 2024-05, Vol.32 (3), p.891-904
Hauptverfasser:	Velarde, Pablo, Zafra-Cabeza, Ascension, Marquez, Juan Jose, Maestre, Jose Maria, Bordons, Carlos
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Constraints Control systems Distributed generation Fault detection Fault diagnosis fault mitigation Fault tolerance Fault tolerant systems fault-tolerant control Microgrids model predictive control (MPC) Parameter modification Predictive control Real time operation Reconfiguration Renewable resources stochastic approach Stochastic processes Uncertainty
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creator	Velarde, Pablo Zafra-Cabeza, Ascension Marquez, Juan Jose Maestre, Jose Maria Bordons, Carlos
description	This article focuses on the improvement of the real-time operation of the microgrid based on model predictive control (MPC), taking into account the stochastic nature of renewable resources and demand, as well as fault-tolerant mechanisms. Thus, a fault-tolerant strategy (FTS) module is inserted into the control loop, which is devoted to fault diagnosis and isolation, as well as setting reconfiguration actions that may involve modifications through the model parameters, the objective function, and the constraints used in the optimization problem solved by the MPC. Meanwhile, the MPC controller is responsible for managing the power of the microgrid, where two stochastic approaches are compared: tree-based MPC (TB-MPC) and chance-constrained MPC (CC-MPC). Experiments carried out in a simulated full-scale laboratory microgrid under various conditions demonstrate the effectiveness of the proposed algorithms in dealing with power equipment faults.
doi_str_mv	10.1109/TCST.2023.3342135
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subjects	Algorithms Constraints Control systems Distributed generation Fault detection Fault diagnosis fault mitigation Fault tolerance Fault tolerant systems fault-tolerant control Microgrids model predictive control (MPC) Parameter modification Predictive control Real time operation Reconfiguration Renewable resources stochastic approach Stochastic processes Uncertainty
title	Stochastic MPC-Based Reconfiguration Approaches for Microgrids
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