Optimal adaptive gain LQR-based energy management strategy for battery–supercapacitor hybrid power system

Seydali Ferahtia; Ali Djeroui; Tedjani Mesbahi; Azeddine Houari; Samir Zeghlache; Hegazy Rezk; Théophile Paul

doi:10.3390/en14061660

Optimal adaptive gain LQR-based energy management strategy for battery–supercapacitor hybrid power system

Seydali Ferahtia
, Ali Djeroui
, Tedjani Mesbahi
, Azeddine Houari
, Samir Zeghlache
, Hegazy Rezk
, Théophile Paul

Electrical Engineering

Research output: Contribution to journal › Article › peer-review

48 Scopus citations

Abstract

This paper aims at presenting an energy management strategy (EMS) based upon optimal control theory for a battery–supercapacitor hybrid power system. The hybrid power system consists of a lithium-ion battery and a supercapacitor with associated bidirectional DC/DC converters. The proposed EMS aims at computing adaptive gains using the salp swarm algorithm and load following control technique to assign the power reference for both the supercapacitor and the battery while achieving optimal performance and stable voltage. The DC/DC converter model is derived utilizing the first-principles method and computes the required gains to achieve the desired power. The fact that the developed algorithm takes disturbances into account increases the power elements’ life expectancies and supplies the power system with the required power.

Original language	English
Article number	1660
Journal	Energies
Volume	14
Issue number	6
DOIs	https://doi.org/10.3390/en14061660
State	Published - 2 Mar 2021

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

Battery
DC/DC converter
Energy management strategy
Hybrid power system
Optimal control
Supercapacitor

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10.3390/en14061660

Cite this

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title = "Optimal adaptive gain LQR-based energy management strategy for battery–supercapacitor hybrid power system",

abstract = "This paper aims at presenting an energy management strategy (EMS) based upon optimal control theory for a battery–supercapacitor hybrid power system. The hybrid power system consists of a lithium-ion battery and a supercapacitor with associated bidirectional DC/DC converters. The proposed EMS aims at computing adaptive gains using the salp swarm algorithm and load following control technique to assign the power reference for both the supercapacitor and the battery while achieving optimal performance and stable voltage. The DC/DC converter model is derived utilizing the first-principles method and computes the required gains to achieve the desired power. The fact that the developed algorithm takes disturbances into account increases the power elements{\textquoteright} life expectancies and supplies the power system with the required power.",

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AU - Ferahtia, Seydali

AU - Djeroui, Ali

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AU - Houari, Azeddine

AU - Zeghlache, Samir

AU - Rezk, Hegazy

AU - Paul, Théophile

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N2 - This paper aims at presenting an energy management strategy (EMS) based upon optimal control theory for a battery–supercapacitor hybrid power system. The hybrid power system consists of a lithium-ion battery and a supercapacitor with associated bidirectional DC/DC converters. The proposed EMS aims at computing adaptive gains using the salp swarm algorithm and load following control technique to assign the power reference for both the supercapacitor and the battery while achieving optimal performance and stable voltage. The DC/DC converter model is derived utilizing the first-principles method and computes the required gains to achieve the desired power. The fact that the developed algorithm takes disturbances into account increases the power elements’ life expectancies and supplies the power system with the required power.

AB - This paper aims at presenting an energy management strategy (EMS) based upon optimal control theory for a battery–supercapacitor hybrid power system. The hybrid power system consists of a lithium-ion battery and a supercapacitor with associated bidirectional DC/DC converters. The proposed EMS aims at computing adaptive gains using the salp swarm algorithm and load following control technique to assign the power reference for both the supercapacitor and the battery while achieving optimal performance and stable voltage. The DC/DC converter model is derived utilizing the first-principles method and computes the required gains to achieve the desired power. The fact that the developed algorithm takes disturbances into account increases the power elements’ life expectancies and supplies the power system with the required power.

KW - Battery

KW - DC/DC converter

KW - Energy management strategy

KW - Hybrid power system

KW - Optimal control

KW - Supercapacitor

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Optimal adaptive gain LQR-based energy management strategy for battery–supercapacitor hybrid power system

Abstract

UN SDGs

Keywords

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