Notice of Violation of IEEE Publication Principles: Photovoltaic (PV) parameter estimation of a multicrystalline panel using developed iterative and non-iterative methods

Abstract

Notice of Violation of IEEE Publication Principles<br><br>"Photovoltaic (PV) Parameter Estimation of a Multicrystalline Panel Using Developed Iterative and Noniterative Methods,"<br> by A. Obbadi, Y. Errami, A. Elfajri, M Agunaou, M Benhmida and S. Sahnoun,<br> in the Proceedings of the 2015 3rd International Renewable and Sustainable Energy Conference (IRSEC), December 2015<br><br> After careful and considered review of the content and authorship of this paper by a duly constituted expert committee, this paper has been found to be in violation of IEEE's Publication Principles.<br><br> This paper contains portions of text from the paper(s) cited below. A credit notice is used, but due to the absence of quotation marks or offset text, copied material is not clearly referenced or specifically identified.<br><br> "Generalized Classification of PV Modules by Simplified Single-diode Models,"<br> by S. Cannizzaro, M C. Di Piazza, M Luna and G. Vitale,<br> in the Proceedings of the IEEE 23rd International Symposium on Industrial Electronics (ISlE), June 2014, pp. 2266-2273<br><br> and<br><br> "PVID: An Interactive Matlab Application for Parameter Identification of Complete and Simplified Single-diode PV Models,"<br> by S. Cannizzaro, M C. Di Piazza, M Luna and G. Vitale,<br> in the Proceedings of the IEEE 15th Workshop on Control and Modeling for Power Electronics (COMPEL), June 2014<br><br> <br/> Mathematical modeling of photovoltaic (PV) modules is essential for any performance optimization operation or diagnostic of the photovoltaic generator under changing environmental conditions. The limited data available are provided by commercial manufacturing datasheets. The accurately estimating of these parameters remains a challenge for researchers. There is great diversity in the models and the estimation methods i.e., iterative and non-iterative methods. In this paper we are interested in estimating the parameters of both complete (5-parameter) and simplified (4-parameter) single-diode PV models by non-iterative and iterative methods i.e., the Newton-Raphson and Halley's method. The aim is to predict the behavior of a multicrystalline Kyocera KC200GT module under real environmental conditions. A new parameter Series/Parallel Ratio (SPR) ranking photovoltaic modules is defined. Depending on the value SPR, we can neglect the series or shunt resistance of single-diode model without compromising accuracy. The proposed approach is a quick and non-iterative method that allows the estimation of PV parameters. It can be used in tracking applications of Maximum Power Point Tracking (MPPT) for on-line. The results obtained with non-iterative and iterative methods are compared with experimental data. The results are discussed in terms of precision and order statistical errors. They show the limits of the use of these approaches and their relevance. The method is verified by the simulation using MATLAB/Simulink environment.