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Year 2021, Volume: 22 Issue: 2, 199 - 208, 29.06.2021
https://doi.org/10.18038/estubtda.901800

Abstract

References

  • [1] Fares MA, Atik L, Bachir G, Aillerie M. Photovoltaic panels characterization and experimental testing. Energy Procedia 2017;119:945–52.
  • [2] Schill C, Brachmann S, Koehl M. Impact of soiling on IV-curves and efficiency of PV-modules. Sol Energy 2015;112:259–62.
  • [3] Velilla E, Restrepo S, Jaramillo F. Cluster analysis of commercial photovoltaic modules based on the electrical performance at standard test conditions. Sol Energy 2017;144:335–41.
  • [4] Ko SW, Ju YC, Hwang HM, So JH, Jung Y-S, Song H-J, et al. Electric and thermal characteristics of photovoltaic modules under partial shading and with a damaged by-pass diode. Energy 2017;128:232–43.
  • [5] Chen Z, Wu L, Cheng S, Lin P, Wu Y, Lin W. Intelligent fault diagnosis of photovoltaic arrays based on optimized kernel extreme learning machine and I-V characteristics. Appl Energy 2017;204:912–31.
  • [6] Dash PK, Gupta NC, Rawat R, Pant PC. A novel climate classification criterion based on the performance of solar photovoltaic technologies. Sol Energy 2017;144:392–8.
  • [7] Dhimish M, Holmes V, Mehrdadi B, Dales M, Chong B, Zhang L. Seven indicators variations for multiple PV array configurations under partial shading and faulty PV conditions. Renew Energy 2017;113:438–60.
  • [8] Wu Y, Chen Z, Wu L, Lin P, Cheng S, Lu P. An Intelligent Fault Diagnosis Approach for PV Array Based on SA-RBF Kernel Extreme Learning Machine. Energy Procedia 2017;105:1070–6.
  • [9] Dhimish M, Holmes V, Mehrdadi B, Dales M, Mather P. Photovoltaic fault detection algorithm based on theoretical curves modelling and fuzzy classification system. Energy 2017;140:276–90.
  • [10] Rus-Casas C, Aguilar JD, Rodrigo P, Almonacid F, Pérez-Higueras PJ. Classification of methods for annual energy harvesting calculations of photovoltaic generators. Energy Convers Manag 2014;78:527–36.
  • [11] Rodrigo P, Fernández EF, Almonacid F, Pérez-Higueras PJ. Review of methods for the calculation of cell temperature in high concentration photovoltaic modules for electrical characterization. Renew Sustain Energy Rev 2014;38:478–88. doi:10.1016/j.rser.2014.06.008.
  • [12] Fouad MM, Shihata LA, Morgan EI. An integrated review of factors influencing the performance of photovoltaic panels. Renew Sustain Energy Rev 2017;80:1499–511.
  • [13] Catelani M, Ciani L, Cristaldi L, Faifer M, Lazzaroni M. Electrical performances optimization of Photovoltaic Modules with FMECA approach. Meas J Int Meas Confed 2013;46:3898–909.
  • [14] Stanford University. Multi-class SVMs. Cambridge Univ Press 2009. https://nlp.stanford.edu/IR-book/html/htmledition/multiclass-svms-1.html.
  • [15] Gasparin FP, Bühler AJ, Rampinelli GA, Krenzinger A. Statistical analysis of I–V curve parameters from photovoltaic modules. Sol Energy 2016;131:30–8.

ELECTRICAL CHARACTERISTIC CLASSIFICATION OF THE PV’S USING SUPPORT VECTOR MACHINES

Year 2021, Volume: 22 Issue: 2, 199 - 208, 29.06.2021
https://doi.org/10.18038/estubtda.901800

Abstract

Photovoltaics have more attraction day by day due to increasing technologies and decreasing prices. However, in practice, the applicants encounter fundamental problems such as shadow effects and degradation. Due to these problems, the amount of produced annual electricity decreases considerably. Moreover, it is not easy to understand if the company's PV satisfies the requirements or is appropriate for the application. In order to solve such problems, it is instructed to examine the electrical characteristics of the modules. An initial task should be the classification of PV modules according to performance results. Here in this study, it is aimed to classify different PV modules, including different output characteristics. It is aimed to show whether it is possible to classify different PV modules including the same output power or not? To find the answer to this question, a test platform is built. 4 different panels are tested on the platform. While the test, the panels produced by different companies split into two groups, each has the same output power. Under a different insulation condition, the test is performed, and the cells' current-voltage curves are constructed. Different statistics are extracted by using this information. Different variations of these statistics are presented to multi-SVM. Finally, accurate classification results are obtained.

References

  • [1] Fares MA, Atik L, Bachir G, Aillerie M. Photovoltaic panels characterization and experimental testing. Energy Procedia 2017;119:945–52.
  • [2] Schill C, Brachmann S, Koehl M. Impact of soiling on IV-curves and efficiency of PV-modules. Sol Energy 2015;112:259–62.
  • [3] Velilla E, Restrepo S, Jaramillo F. Cluster analysis of commercial photovoltaic modules based on the electrical performance at standard test conditions. Sol Energy 2017;144:335–41.
  • [4] Ko SW, Ju YC, Hwang HM, So JH, Jung Y-S, Song H-J, et al. Electric and thermal characteristics of photovoltaic modules under partial shading and with a damaged by-pass diode. Energy 2017;128:232–43.
  • [5] Chen Z, Wu L, Cheng S, Lin P, Wu Y, Lin W. Intelligent fault diagnosis of photovoltaic arrays based on optimized kernel extreme learning machine and I-V characteristics. Appl Energy 2017;204:912–31.
  • [6] Dash PK, Gupta NC, Rawat R, Pant PC. A novel climate classification criterion based on the performance of solar photovoltaic technologies. Sol Energy 2017;144:392–8.
  • [7] Dhimish M, Holmes V, Mehrdadi B, Dales M, Chong B, Zhang L. Seven indicators variations for multiple PV array configurations under partial shading and faulty PV conditions. Renew Energy 2017;113:438–60.
  • [8] Wu Y, Chen Z, Wu L, Lin P, Cheng S, Lu P. An Intelligent Fault Diagnosis Approach for PV Array Based on SA-RBF Kernel Extreme Learning Machine. Energy Procedia 2017;105:1070–6.
  • [9] Dhimish M, Holmes V, Mehrdadi B, Dales M, Mather P. Photovoltaic fault detection algorithm based on theoretical curves modelling and fuzzy classification system. Energy 2017;140:276–90.
  • [10] Rus-Casas C, Aguilar JD, Rodrigo P, Almonacid F, Pérez-Higueras PJ. Classification of methods for annual energy harvesting calculations of photovoltaic generators. Energy Convers Manag 2014;78:527–36.
  • [11] Rodrigo P, Fernández EF, Almonacid F, Pérez-Higueras PJ. Review of methods for the calculation of cell temperature in high concentration photovoltaic modules for electrical characterization. Renew Sustain Energy Rev 2014;38:478–88. doi:10.1016/j.rser.2014.06.008.
  • [12] Fouad MM, Shihata LA, Morgan EI. An integrated review of factors influencing the performance of photovoltaic panels. Renew Sustain Energy Rev 2017;80:1499–511.
  • [13] Catelani M, Ciani L, Cristaldi L, Faifer M, Lazzaroni M. Electrical performances optimization of Photovoltaic Modules with FMECA approach. Meas J Int Meas Confed 2013;46:3898–909.
  • [14] Stanford University. Multi-class SVMs. Cambridge Univ Press 2009. https://nlp.stanford.edu/IR-book/html/htmledition/multiclass-svms-1.html.
  • [15] Gasparin FP, Bühler AJ, Rampinelli GA, Krenzinger A. Statistical analysis of I–V curve parameters from photovoltaic modules. Sol Energy 2016;131:30–8.
There are 15 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Fatih Serttaş 0000-0003-3109-716X

Fatih Onur Hocaoğlu 0000-0002-3640-7676

Publication Date June 29, 2021
Published in Issue Year 2021 Volume: 22 Issue: 2

Cite

AMA Serttaş F, Hocaoğlu FO. ELECTRICAL CHARACTERISTIC CLASSIFICATION OF THE PV’S USING SUPPORT VECTOR MACHINES. Eskişehir Technical University Journal of Science and Technology A - Applied Sciences and Engineering. June 2021;22(2):199-208. doi:10.18038/estubtda.901800