Boosted backtracking search optimization with information exchange for photovoltaic system evaluation

The determination of photovoltaic (PV) parameters is of great importance for the reliability of solar system operation, continuity of the load power consumption, and control management of the energy source. Therefore, this study proposes an advanced backtracking search optimization algorithm (BSA) e...

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Bibliographic Details
Published in:Energy science & engineering 2023-01, Vol.11 (1), p.267-298
Main Authors: Weng, Xuemeng, Liu, Yun, Heidari, Ali Asghar, Cai, Zhennao, Lin, Haiping, Chen, Huiling, Liang, Guoxi, Alsufyani, Abdulmajeed, Bourouis, Sami
Format: Article
Language:English
Subjects:
Algorithms
Design
Diodes
Efficiency
Electrical measurement
Energy sources
Environment models
Environmental conditions
Evaluation
Feature selection
Genetic algorithms
Machine learning
metaheuristics
Neural networks
Optimization
Optimization algorithms
Parameter estimation
parameter extraction
Parameter identification
Parameters
Photovoltaic cells
photovoltaic models
Photovoltaics
Power consumption
R&D
Research & development
Simulation
solar cell
Solar energy
swarm intelligence
Traveling salesman problem
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Summary:The determination of photovoltaic (PV) parameters is of great importance for the reliability of solar system operation, continuity of the load power consumption, and control management of the energy source. Therefore, this study proposes an advanced backtracking search optimization algorithm (BSA) equipped with teaching and learning‐based optimization (TLBO), named TLBOBSA, to accurately simulate the PV model. During the evaluation of the proposed algorithm, the concept of teaching from TLBO is introduced into the BSA to guide optimal individuals, thus improving the convergence rate of the algorithm. The learning behavior among individuals in the student phase of TLBO facilitates interindividual learning and provides beneficial information for its evolution, which is introduced into the BSA to ensure the diversity of the population. The comprehensive test results of different PV module models in different environmental conditions show that the proposed algorithm is more advantageous for parameter extraction than other existing algorithms. This can be seen in the simulation experiments of two commercial PV models, where the simulated current is consistent with the measured current at each measured voltage. This demonstrates that the proposed TLBOBSA is an accurate and reliable tool for evaluating unknown parameters of PV models. (1) An improved backtracking search algorithm with teaching and learning‐based optimization (TLBOBSA) is proposed to extract parameters of the photovoltaic system. (2) The performance of TLBOBSA is compared with some well‐known competitive algorithms. (3) TLBOBSA was evaluated under different irradiance levels and temperature levels. (4) TLBOBSA has improved the convergence speed and obtained optimal accuracy among all competitive algorithms.
ISSN:2050-0505
2050-0505
DOI:10.1002/ese3.1329