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Active and Reactive Power Control for Wind Turbines Based DFIG Using LQR Controller with Optimal Gain-Scheduling

Ashraf Radaideh, Mu’men Bodoor, Ayman Al‐Quraan

2021Journal of Electrical and Computer Engineering36 citationsDOIOpen Access PDF

Abstract

This paper proposes an optimal gain-scheduling for linear quadratic regulator (LQR) control framework to improve the performance of wind turbines based Doubly Fed Induction Generator (DFIG). Active and reactive power decoupling is performed using the field-oriented vector control which is used to simplify DFIG’s nonlinearity and derive a compact linearized state-space model. The performance of the optimal controller represented by a linear quadratic regulator is further enhanced using the whale optimization algorithm in a multiobjective optimization environment. Adaptiveness against wind speed variation is achieved in an offline training process at a discretized wind speed domain. Lookup tables are used to store the optimal controller parameter and called upon during the online implementation. The control framework further integrates the effects of pitch angle control mechanism for active power ancillary services and possible improvements on reactive power support. The results of the proposed control framework improve the overall performance of the system compared to the conventional PI controller. Comparison is performed using the MATLAB Simulink platform.

Topics & Concepts

Control theory (sociology)Linear-quadratic regulatorWind powerEngineeringAC powerPitch controlGain schedulingVector controlControl engineeringOptimal controlComputer scienceControl systemVoltageControl (management)Mathematical optimizationMathematicsInduction motorArtificial intelligenceElectrical engineeringWind Turbine Control SystemsMicrogrid Control and OptimizationFrequency Control in Power Systems