Optimization Techniques for Wind Turbine Power Recovery Using Average Models and Genetic Algorithms

Saber Hadj Abdallah; Fatma Ben Salem; Jaouhar Mouine; Souhir Tounsi

doi:10.3390/electronics14234630

Optimization Techniques for Wind Turbine Power Recovery Using Average Models and Genetic Algorithms

Saber Hadj Abdallah
, Fatma Ben Salem
, Jaouhar Mouine
, Souhir Tounsi

Electrical Engineering

University of Sfax

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

Abstract

This paper presents a systemic design methodology for wind energy power systems. The foundation of this research is the creation of two average models of wind energy power systems, which are based on average value theory for power converters like rectifiers and analytical techniques for permanent magnet generator design. The power component library, which is integrated into the Matlab–Simulink R2022b simulation environment, is used to validate these models against custom models as well as with each other. A permanent magnet generator design model was created by combining the analytical model with the average rectifier model. The power chain average models are coupled to a Genetic Algorithm tool for turbine recovered power optimization.

Original language	English
Article number	4630
Journal	Electronics (Switzerland)
Volume	14
Issue number	23
DOIs	https://doi.org/10.3390/electronics14234630
State	Published - Dec 2025

Keywords

analytic
average models
optimization
permanent magnet generator
systemic design
wind energy systems

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10.3390/electronics14234630

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title = "Optimization Techniques for Wind Turbine Power Recovery Using Average Models and Genetic Algorithms",

abstract = "This paper presents a systemic design methodology for wind energy power systems. The foundation of this research is the creation of two average models of wind energy power systems, which are based on average value theory for power converters like rectifiers and analytical techniques for permanent magnet generator design. The power component library, which is integrated into the Matlab–Simulink R2022b simulation environment, is used to validate these models against custom models as well as with each other. A permanent magnet generator design model was created by combining the analytical model with the average rectifier model. The power chain average models are coupled to a Genetic Algorithm tool for turbine recovered power optimization.",

keywords = "analytic, average models, optimization, permanent magnet generator, systemic design, wind energy systems",

author = "\{Hadj Abdallah\}, Saber and \{Ben Salem\}, Fatma and Jaouhar Mouine and Souhir Tounsi",

note = "Publisher Copyright: {\textcopyright} 2025 by the authors.",

year = "2025",

month = dec,

doi = "10.3390/electronics14234630",

language = "English",

volume = "14",

journal = "Electronics (Switzerland)",

issn = "2079-9292",

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T1 - Optimization Techniques for Wind Turbine Power Recovery Using Average Models and Genetic Algorithms

AU - Hadj Abdallah, Saber

AU - Ben Salem, Fatma

AU - Mouine, Jaouhar

AU - Tounsi, Souhir

PY - 2025/12

Y1 - 2025/12

N2 - This paper presents a systemic design methodology for wind energy power systems. The foundation of this research is the creation of two average models of wind energy power systems, which are based on average value theory for power converters like rectifiers and analytical techniques for permanent magnet generator design. The power component library, which is integrated into the Matlab–Simulink R2022b simulation environment, is used to validate these models against custom models as well as with each other. A permanent magnet generator design model was created by combining the analytical model with the average rectifier model. The power chain average models are coupled to a Genetic Algorithm tool for turbine recovered power optimization.

AB - This paper presents a systemic design methodology for wind energy power systems. The foundation of this research is the creation of two average models of wind energy power systems, which are based on average value theory for power converters like rectifiers and analytical techniques for permanent magnet generator design. The power component library, which is integrated into the Matlab–Simulink R2022b simulation environment, is used to validate these models against custom models as well as with each other. A permanent magnet generator design model was created by combining the analytical model with the average rectifier model. The power chain average models are coupled to a Genetic Algorithm tool for turbine recovered power optimization.

KW - analytic

KW - average models

KW - optimization

KW - permanent magnet generator

KW - systemic design

KW - wind energy systems

UR - https://www.scopus.com/pages/publications/105024541701

U2 - 10.3390/electronics14234630

DO - 10.3390/electronics14234630

M3 - Article

AN - SCOPUS:105024541701

SN - 2079-9292

VL - 14

JO - Electronics (Switzerland)

JF - Electronics (Switzerland)

IS - 23

M1 - 4630

ER -

Optimization Techniques for Wind Turbine Power Recovery Using Average Models and Genetic Algorithms

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Keywords

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