Abstract
Vast growing global concern of solar energy in last few years has bought to focus the maximum power point tracking and module mismatch losses. Photovoltaic energy is the exhaustible, clean, and pollution-free energy. Mainly, the losses are occurred by different types of solar modules. These losses can be reduced by different parameter analyses. This paper represents the novel method to forecast existing PV array for all. The efficiency of solar module is influenced by different shading configurations. There are various interconnected plans, which depict reasonably reliable power production prognosticate under normal operating condition. PV is the method of generating electric power converting, i.e., solar radiation into electrical power using semiconductor devices, which exhibits the photovoltaic effects. The analysis of current over voltage and power over voltage curves at changing solar irradiation levels and temperatures have been obtained. In this study, a new theoretical model, offering a good compromise between simplicity and accuracy, was developed in Matlab to determine the parametric study of different types of solar module to demonstrate a feasibility and reliability of the simulation model.
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Das, G., De, M., Mandal, K.K. (2019). PV Array’s Resistance and Temperature Sensitivity Analysis with Shading Effects. In: Nath, V., Mandal, J. (eds) Proceeding of the Second International Conference on Microelectronics, Computing & Communication Systems (MCCS 2017). Lecture Notes in Electrical Engineering, vol 476. Springer, Singapore. https://doi.org/10.1007/978-981-10-8234-4_41
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DOI: https://doi.org/10.1007/978-981-10-8234-4_41
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