International Journal of Renewable Energy Research-IJRER

Worldwide electricity production has switched from fossil fuel combustion to renewable energy sources and solar power generation has increased significantly in recent years, particularly in the form of photovoltaic (PV) power. Solar radiation is mainly influenced by the process of sunlight interaction with clouds. Being able to quantify the variability of solar irradiance due to clouds is crucial for better integration of the energy generated in the power grid by reducing the uncertainties in solar irradiance forecasts. Our objective is the characterization of a given solar site by quantifying the variability of solar irradiance caused by clouds. To do so, we provide a classification scheme of clouds conditions classes based on the daily clear sky index K_c, and the hourly intraday variability δ(K_c) defined by the standard deviation of the variations of the clear sky index. As a result of irradiance classification, we obtained nine classes identified as the overcast, mixed, and clear sky conditions and subdivided into three categories: low, medium, and high variability. We used the solar irradiance data set measured at the high precision meteorological station installed in Benguerir, Morocco, for the period from 01/01/2018 to 31/12/2018.

Solar irradiance; Clear sky; Variability; Photovoltaic

S. Sobri, S. Koohi-Kamali, and N. A. Rahim, “Solar photovoltaic generation forecasting methods: A review,†Energy Conversion and Management, vol. 156, pp. 459–497, 2018.

E. Taibi et al., “Power system flexibility for the energy transition: Part 1, Overview for policy makers,†2018.

A. M. Ismail, R. Ramirez-Iniguez, M. Asif, A. B. Munir, and F. Muhammad-Sukki, “Progress of solar photovoltaic in ASEAN countries: A review,†Renewable and Sustainable Energy Reviews, vol. 48, pp. 399–412, 2015.

“Market Report Series: Renewables 2017 – Analysis,†IEA. https://www.iea.org/reports/renewables-2017 (accessed Aug. 31, 2020).

M. Lave, M. J. Reno, and R. J. Broderick, “Characterizing local high-frequency solar variability and its impact to distribution studies,†Solar Energy, vol. 118, pp. 327–337, 2015.

M. Schroedter-Homscheidt, M. Kosmale, S. Jung, and J. Kleissl, “Classifying ground-measured 1 minute temporal variability within hourly intervals for direct normal irradiances,†Meteorologische Zeitschrift, vol. 27, no. 2, pp. 161–179, 2018.

R. Blaga, A. Sabadus, N. Stefu, C. Dughir, M. Paulescu, and V. Badescu, “A current perspective on the accuracy of incoming solar energy forecasting,†Progress in Energy and Combustion Science, vol. 70, pp. 119–144, 2019.

V. Badescu and M. Paulescu, “Statistical properties of the sunshine number illustrated with measurements from Timisoara (Romania),†Atmospheric research, vol. 101, no. 1–2, pp. 194–204, 2011.

R. Perez, S. Kivalov, J. Schlemmer, K. Hemker, and T. E. Hoff, “Short-term irradiance variability: Preliminary estimation of station pair correlation as a function of distance,†Solar Energy, vol. 86, no. 8, pp. 2170–2176, Aug. 2012, doi: 10.1016/j.solener.2012.02.027.

J. Stein, C. Hansen, and M. J. Reno, “The variability index: A new and novel metric for quantifying irradiance and PV output variability.,†Sandia National Laboratories, 2012.

B. O. Kang and K.-S. Tam, “A new characterization and classification method for daily sky conditions based on ground-based solar irradiance measurement data,†Solar Energy, vol. 94, pp. 102–118, 2013.

P. Lauret, R. Perez, L. M. Aguiar, E. Tapachès, H. M. Diagne, and M. David, “Characterization of the intraday variability regime of solar irradiation of climatically distinct locations,†Solar Energy, vol. 125, pp. 99–110, 2016.

R. Blaga and M. Paulescu, “Quantifiers for the solar irradiance variability: A new perspective,†Solar Energy, vol. 174, pp. 606–616, 2018.

G. M. Lohmann, “Irradiance variability quantification and small-scale averaging in space and time: A short review,†Atmosphere, vol. 9, no. 7, p. 264, 2018.

X. Sun, J. M. Bright, C. A. Gueymard, B. Acord, P. Wang, and N. A. Engerer, “Worldwide performance assessment of 75 global clear-sky irradiance models using Principal Component Analysis,†Renewable and Sustainable Energy Reviews, vol. 111, pp. 550–570, Sep. 2019, doi: 10.1016/j.rser.2019.04.006.

M. Lefèvre et al., “McClear: a new model estimating downwelling solar radiation at ground level in clear-sky conditions,†Atmospheric Measurement Techniques, vol. 6, pp. 2403–2418, 2013.

M. Schroedter-Homscheidt et al., “The Copernicus atmosphere monitoring service (CAMS) radiation service in a nutshell,†2016.

O. E. Alani, A. Ghennioui, A. A. Merrouni, H. Ghennioui, Y.-M. Saint-Drenan, and P. Blanc, “Validation of surface solar irradiances estimates and forecast under clear-sky conditions from the CAMS McClear model in Benguerir, Morocco,†2019, vol. 2126, no. 1, p. 190005.

C. F. Coimbra, J. Kleissl, and R. Marquez, “Overview of solar-forecasting methods and a metric for accuracy evaluation,†Solar energy forecasting and resource assessment, pp. 171–194, 2013.

“World Meteorological Organization,†World Meteorological Organization. https://public.wmo.int/en (accessed Aug. 31, 2020).

L. M. Aguiar, B. Pereira, M. David, F. Díaz, and P. Lauret, “Use of satellite data to improve solar radiation forecasting with Bayesian Artificial Neural Networks,†Solar Energy, vol. 122, pp. 1309–1324, 2015.

J. Ascencio-Vásquez, K. Brecl, and M. TopiÄ, “Methodology of Köppen-Geiger-Photovoltaic climate classification and implications to worldwide mapping of PV system performance,†Solar Energy, vol. 191, pp. 672–685, 2019.