Hybrid LSTM–FACTS Control Strategy for Voltage and Frequency Stability in EV-Penetrated Microgrids

Wilian Paul Arévalo Cordero; Félix  Sebastian González Cantos; Andrés Alberto Martínez Curipoma; Diego Enmanuel Zarie Bonilla; Augusto Orlando Rodas Vélez; Danny Vinicio Ochoa Correa; Darío Javier  Benavides Padilla

doi:10.3390/technologies13090402

Hybrid LSTM–FACTS Control Strategy for Voltage and Frequency Stability in EV-Penetrated Microgrids

Wilian Paul Arévalo Cordero (Primer Autor)
, Félix Sebastian González Cantos
, Andrés Alberto Martínez Curipoma
, Diego Enmanuel Zarie Bonilla
, Augusto Orlando Rodas Vélez
, Danny Vinicio Ochoa Correa
, Darío Javier Benavides Padilla (Último Autor)

University of Jaén
Departamento de Ingeniería Eléctrica, Electrónica y Telecomunicaciones, Universidad de Cuenca
Facultad de Ingeniería, Universidad de Cuenca
Universidad Técnica de Ambato

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Resumen

This paper proposes a real-time energy management strategy for low-voltage microgrids that combines short-horizon forecasting with a rule-based supervisory controller to coordinate battery energy storage usage and reactive power support provided by flexible alternating current transmission technologies. The central contribution is the forecast-informed, joint orchestration of active charging and reactive power dispatch to regulate voltage and preserve stability under large photovoltaic variability and uncertain electric vehicle demand. The work also introduces a resilience response index that quantifies performance under external disturbances, forecasting delays, and increasing levels of electric-vehicle integration. Validation is carried out through time-domain numerical simulations in MATLAB/Simulink using realistic solar irradiance and electric vehicle charging profiles. The results show that the coordinated strategy reduces voltage deviation events, maintains stable operation across a wide range of scenarios, and enables electric vehicle charging to be supplied predominantly by renewable generation. Sensitivity analysis further indicates that support from flexible alternating current devices becomes particularly decisive at high charging demand and in the presence of forecasting latency, underscoring the practical value of the proposed approach for distribution-level microgrids.

Idioma original	Inglés
Número de artículo	402
Páginas (desde-hasta)	1-27
Número de páginas	27
Publicación	Technologies
Volumen	13
N.º	9
DOI	https://doi.org/10.3390/technologies13090402
Estado	Publicada - 4 sep. 2025

ODS de las Naciones Unidas

Este resultado contribuye a los siguientes Objetivos de Desarrollo Sostenible

ODS 7: Energía asequible y no contaminante

Palabras clave

FACTS devices
Electric vehicle charging
Microgrid energy management

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10.3390/technologies13090402Licencia: CC BY

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title = "Hybrid LSTM–FACTS Control Strategy for Voltage and Frequency Stability in EV-Penetrated Microgrids",

abstract = "This paper proposes a real-time energy management strategy for low-voltage microgrids that combines short-horizon forecasting with a rule-based supervisory controller to coordinate battery energy storage usage and reactive power support provided by flexible alternating current transmission technologies. The central contribution is the forecast-informed, joint orchestration of active charging and reactive power dispatch to regulate voltage and preserve stability under large photovoltaic variability and uncertain electric vehicle demand. The work also introduces a resilience response index that quantifies performance under external disturbances, forecasting delays, and increasing levels of electric-vehicle integration. Validation is carried out through time-domain numerical simulations in MATLAB/Simulink using realistic solar irradiance and electric vehicle charging profiles. The results show that the coordinated strategy reduces voltage deviation events, maintains stable operation across a wide range of scenarios, and enables electric vehicle charging to be supplied predominantly by renewable generation. Sensitivity analysis further indicates that support from flexible alternating current devices becomes particularly decisive at high charging demand and in the presence of forecasting latency, underscoring the practical value of the proposed approach for distribution-level microgrids. ",

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year = "2025",

month = sep,

day = "4",

doi = "10.3390/technologies13090402",

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Hybrid LSTM–FACTS Control Strategy for Voltage and Frequency Stability in EV-Penetrated Microgrids. / Arévalo Cordero, Wilian Paul (Primer Autor); González Cantos, Félix Sebastian; Martínez Curipoma, Andrés Alberto et al.
En: Technologies, Vol. 13, N.º 9, 402, 04.09.2025, p. 1-27.

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

TY - JOUR

T1 - Hybrid LSTM–FACTS Control Strategy for Voltage and Frequency Stability in EV-Penetrated Microgrids

AU - Arévalo Cordero, Wilian Paul

AU - González Cantos, Félix Sebastian

AU - Martínez Curipoma, Andrés Alberto

AU - Zarie Bonilla, Diego Enmanuel

AU - Rodas Vélez, Augusto Orlando

AU - Ochoa Correa, Danny Vinicio

AU - Benavides Padilla, Darío Javier

PY - 2025/9/4

Y1 - 2025/9/4

N2 - This paper proposes a real-time energy management strategy for low-voltage microgrids that combines short-horizon forecasting with a rule-based supervisory controller to coordinate battery energy storage usage and reactive power support provided by flexible alternating current transmission technologies. The central contribution is the forecast-informed, joint orchestration of active charging and reactive power dispatch to regulate voltage and preserve stability under large photovoltaic variability and uncertain electric vehicle demand. The work also introduces a resilience response index that quantifies performance under external disturbances, forecasting delays, and increasing levels of electric-vehicle integration. Validation is carried out through time-domain numerical simulations in MATLAB/Simulink using realistic solar irradiance and electric vehicle charging profiles. The results show that the coordinated strategy reduces voltage deviation events, maintains stable operation across a wide range of scenarios, and enables electric vehicle charging to be supplied predominantly by renewable generation. Sensitivity analysis further indicates that support from flexible alternating current devices becomes particularly decisive at high charging demand and in the presence of forecasting latency, underscoring the practical value of the proposed approach for distribution-level microgrids.

AB - This paper proposes a real-time energy management strategy for low-voltage microgrids that combines short-horizon forecasting with a rule-based supervisory controller to coordinate battery energy storage usage and reactive power support provided by flexible alternating current transmission technologies. The central contribution is the forecast-informed, joint orchestration of active charging and reactive power dispatch to regulate voltage and preserve stability under large photovoltaic variability and uncertain electric vehicle demand. The work also introduces a resilience response index that quantifies performance under external disturbances, forecasting delays, and increasing levels of electric-vehicle integration. Validation is carried out through time-domain numerical simulations in MATLAB/Simulink using realistic solar irradiance and electric vehicle charging profiles. The results show that the coordinated strategy reduces voltage deviation events, maintains stable operation across a wide range of scenarios, and enables electric vehicle charging to be supplied predominantly by renewable generation. Sensitivity analysis further indicates that support from flexible alternating current devices becomes particularly decisive at high charging demand and in the presence of forecasting latency, underscoring the practical value of the proposed approach for distribution-level microgrids.

KW - electric vehicle charging

KW - FACTS devices

KW - microgrid energy management

KW - FACTS devices

KW - Electric vehicle charging

KW - Microgrid energy management

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DO - 10.3390/technologies13090402

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SN - 2227-7080

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JO - Technologies

JF - Technologies

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ER -

Hybrid LSTM–FACTS Control Strategy for Voltage and Frequency Stability in EV-Penetrated Microgrids

Resumen

ODS de las Naciones Unidas

Palabras clave

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