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Improved coot optimizer algorithm-based MPPT for PV systems under complex partial shading conditions and load variation
•Introduces the use of the innovative Coot Optimization Algorithm (COA) for MPPT in PV systems under complex partial shading conditions.•Addresses the challenge of partial shading, which can result in multiple local maxima in the power-voltage curve of PV systems.•Proposes a novel approach to improv...
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Published in: | Energy conversion and management. X 2024-04, Vol.22, p.100565, Article 100565 |
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Main Authors: | , , , , |
Format: | Article |
Language: | English |
Subjects: | |
Citations: | Items that this one cites Items that cite this one |
Online Access: | Get full text |
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Summary: | •Introduces the use of the innovative Coot Optimization Algorithm (COA) for MPPT in PV systems under complex partial shading conditions.•Addresses the challenge of partial shading, which can result in multiple local maxima in the power-voltage curve of PV systems.•Proposes a novel approach to improve speed response during load variation, providing a solution to the issue of algorithmic differentiation between irradiance change and load variations in PV systems.•Demonstrates the algorithm’s robustness and adaptability to various partial shading scenarios, ensuring consistent and reliable performance.•Provides a comparative analysis with existing MPPT methods, highlighting the superiority of the Coot Optimization Algorithm -based approach in terms of efficiency and convergence speed under complex partial shading conditions.
Solar power is considered one of the most common renewable energy sources. However, the effective harnessing of maximum solar energy in photovoltaic (PV) systems faces a significant challenge due to weather fluctuations. This challenge becomes particularly pronounced for PV systems aiming to achieve optimal power output during Maximum Power Point Tracking (MPPT), especially under partial shading conditions (PSCs). In the P-V curve of PV arrays, the PSCs cause multiple peaks, known as local peaks, and one global peak. The use of sophisticated MPPT optimization algorithms is necessary to identify the global peak, ensuring the highest point of power production and avoiding entrapment in the local peaks. The main drawbacks of these optimization algorithms are their inability to differentiate between the irradiance change and load variations, as well as their high convergence speed. This paper proposes an Improved Coot Optimization Algorithm (ICOA) based on MPPT to alleviate the issue of convergence speed. Furthermore, a novel approach has also been devised to enhance the speed response during load variation, which can be implemented with any DC-DC converter. A novel approach was adopted, with one tuning parameter implemented to simplify the algorithm. A variety of complex PSCs were tested with a SEPIC converter, and the sampling time was adjusted at 0.05 s. Based on the experimental results, the proposed ICOA has achieved the best performance, with an average tracking time of 0.58 s under different weather conditions and an efficiency of 99.94 %. Additionally, an assessment of the proposed technique against existing metaheuristic algorithms i |
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ISSN: | 2590-1745 2590-1745 |
DOI: | 10.1016/j.ecmx.2024.100565 |