An improved 0.8Voc model‐based global maximum power point tracking algorithm for photovoltaic system

In this paper, a low‐cost and high‐speed partial shading condition (PSC) detection scheme and global maximum power point tracking (GMPPT) technique are presented. The proposed technique detects the PSC using a low‐cost voltage sensor without setting any threshold parameter. The proposed GMPPT algori...

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Veröffentlicht in:	International journal of circuit theory and applications 2024-05, Vol.52 (5), p.2170-2190
Hauptverfasser:	Nadeem, Ahsan, Ahmed Sher, Hadeed, Faisal Murtaza, Ali, Ahmed, Nisar
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Sprache:	eng
Schlagworte:	Algorithms Electric potential Irradiance Maximum power tracking Shading Voltage
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container_end_page	2190
container_issue	5
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container_title	International journal of circuit theory and applications
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creator	Nadeem, Ahsan Ahmed Sher, Hadeed Faisal Murtaza, Ali Ahmed, Nisar
description	In this paper, a low‐cost and high‐speed partial shading condition (PSC) detection scheme and global maximum power point tracking (GMPPT) technique are presented. The proposed technique detects the PSC using a low‐cost voltage sensor without setting any threshold parameter. The proposed GMPPT algorithm utilizes the 0.8 model along with the load‐line observation to skip the unwanted interval of – curve. Moreover, in case of dynamic shading, a smart scanning mechanism is used along with the load‐line observation to reduce the voltage iterations which leads to an improvement in tracking speed. The proposed technique is implemented in a Matlab/Simulink environment and compared with the conventional 0.8 method and accurate PSC detection method. The results indicate the following advantages of the proposed algorithm: (1) iteration free and accurate detection of PSC and uniform irradiance condition, (2) enhancement in average tracking time by 67.44% and 69.48%, and (3) improvement in average transient efficiency by 17.36% and 21.25% compared with 0.8 method and accurate PSC detection method. Besides, the experimental results depict that the proposed method enhances the average tracking time by 68.6% and 72.69% and improves the average transient efficiency by 17.62% and 15.06% compared with 0.8 method and accurate PSC detection method, respectively.
doi_str_mv	10.1002/cta.3869
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subjects	Algorithms Electric potential Irradiance Maximum power tracking Shading Voltage
title	An improved 0.8Voc model‐based global maximum power point tracking algorithm for photovoltaic system
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