Nonlinear robust‐optimal control of boost converter in photovoltaic applications

The negative aspects of overusing fossil fuels for producing electricity attract the attention of engineers society to use renewable energies. Power electronic converters play an important role in the transmission and usage of renewable energy in the industry. Boost converters are a major part of de...

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Veröffentlicht in:	Advanced control for applications 2020-12, Vol.2 (4), p.n/a
Hauptverfasser:	Amirparast, Ali, Gholizade‐Narm, Hossein
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Sprache:	eng
Schlagworte:	Active damping boost converter Control methods Control systems design Control theory Converters Electric potential Feedback control Fossil fuels Linear quadratic regulator Nested loops Nonlinear control Optimal control optimal control theory Parameter uncertainty parametric uncertainty Proportional integral derivative Quantitative feedback theory Robust control robust control theory State feedback Voltage
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creator	Amirparast, Ali Gholizade‐Narm, Hossein
description	The negative aspects of overusing fossil fuels for producing electricity attract the attention of engineers society to use renewable energies. Power electronic converters play an important role in the transmission and usage of renewable energy in the industry. Boost converters are a major part of devices in which convert renewable energies into usable energy for various industries or appliances. In this article, to control a boost converter with parametric uncertainty, a new robust‐optimal controller is designed. The proposed control method is designed based on merging two conventional control theory: the robust control theory and linear quadratic regulator technique. This method consists of two nested loops. The inner loop composed of a state feedback controller which works as active damping to improve the transient state. The outer loop consists of a PI controller to track the desired voltage and reject disturbance. The coefficients of both controllers are computed by a robust‐optimal control technique. To evaluate the proposed control method, a well‐tuned single‐loop PI controller and a quantitative feedback theory based PID controller are compared with the proposed method. As shown by simulations, the proposed method has a more reliable performance in dealing with parameters uncertainties such as load changes and input voltage drops. The proposed control method is designed based on merging two conventional control theory: the robust control theory and linear quadratic regulator technique. This method consists of two nested loops. The inner loop composed of a state feedback controller which works as active damping to improve the transient state. The outer loop consists of a PI controller to track the desired voltage and reject disturbance. The coefficients of both controllers are computed by a robust‐optimal control technique.
doi_str_mv	10.1002/adc2.53
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To evaluate the proposed control method, a well‐tuned single‐loop PI controller and a quantitative feedback theory based PID controller are compared with the proposed method. As shown by simulations, the proposed method has a more reliable performance in dealing with parameters uncertainties such as load changes and input voltage drops. The proposed control method is designed based on merging two conventional control theory: the robust control theory and linear quadratic regulator technique. This method consists of two nested loops. The inner loop composed of a state feedback controller which works as active damping to improve the transient state. The outer loop consists of a PI controller to track the desired voltage and reject disturbance. 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Power electronic converters play an important role in the transmission and usage of renewable energy in the industry. Boost converters are a major part of devices in which convert renewable energies into usable energy for various industries or appliances. In this article, to control a boost converter with parametric uncertainty, a new robust‐optimal controller is designed. The proposed control method is designed based on merging two conventional control theory: the robust control theory and linear quadratic regulator technique. This method consists of two nested loops. The inner loop composed of a state feedback controller which works as active damping to improve the transient state. The outer loop consists of a PI controller to track the desired voltage and reject disturbance. The coefficients of both controllers are computed by a robust‐optimal control technique. 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source	Wiley Online Library Journals Frontfile Complete
subjects	Active damping boost converter Control methods Control systems design Control theory Converters Electric potential Feedback control Fossil fuels Linear quadratic regulator Nested loops Nonlinear control Optimal control optimal control theory Parameter uncertainty parametric uncertainty Proportional integral derivative Quantitative feedback theory Robust control robust control theory State feedback Voltage
title	Nonlinear robust‐optimal control of boost converter in photovoltaic applications
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