Table 2.
Location | Model | Input Parameters | Output Parameter | Data Scale | Statistical Benchmarks | Key Findings | References |
---|---|---|---|---|---|---|---|
Kansas, Denver, and Arizona, United States | ARIMA | Historical solar radiation | Daily average global horizontal solar radiation | January 01, 1987, to December 31, 1990 | MAPE | ARIMA has better results when applied to the time-varying daily solar radiation prediction. | [52] |
Many countries in Europe and Asia | ARIMA | Historical solar radiation | Daily solar radiation | 9436 days from November 16, 1978 | N/A | The time series in different climatic conditions depend on the long-range variability of solar radiation. | [53] |
Jeddah, Saudi Arabia | AR | Historical solar radiation | Diffuse horizontal radiation, hourly global solar radiation, and direct normal radiation | 1998–2002 | RMSE and MBE | The applicable model developed with the entered parameters resulted in an accurate prediction. | [54] |
Miami and Orlando, United States | ARIMA | Historical solar radiation | Hourly global solar radiation | January 1995 to December 2005 | MBE and RMSE | It was observed that cloud cover information gives more accurate results in terms of prediction. | [55] |
Awali, Bahrain | ARIMA | Historical solar radiation | Daily average solar radiation | May 2010 to April 2011 | MAPE | It was observed that the different ARIMA models used effectively predict solar radiation. | [56] |
Five cities in France | ARMA | Meteorological parameters | Hourly global solar radiation | October 2002 to December 2008 | nRMSE | The nRMSE ranges from 18.9 to 21.1% in five different cities. | [57] |
Ajaccio, France | ARMA | Meteorological parameters | Hourly solar radiation | 2007–2008 | nRMSE | ANN has better results than the ARMA model with a decrease of 1.3 points while performing error prediction. | [58] |
Corsica Island, France | AR and ARIMA | Historical global solar radiation | Daily global solar radiation | January 1998 to December 2007 | RMSE, nRMSE, MAE and MBE | An ANN with extrinsic and intrinsic data has better performance in univariate ARMA models. | [59] |
Seoul, South Korea | ARIMA and SARIMA | Historical solar radiation data | Daily and monthly solar radiation | 1981–2017 | R2 and RMSE | While the ARIMA model has good results for daily solar radiation, SARIMA has more accurate results for monthly solar radiation estimation. | [60] |
Oran, Algeria | ARMANAR | Meteorological parameters | Hourly global horizontal solar radiation | 2010–2012 | RMSE and nRMSE | nRMSE is 0.2634 and 0.3241, respectively for NAR and ARMA. | [61] |
Seoul, South Korea | SARIMA NARX | Historical global solar radiation | Global solar radiation | 1981–2015 | RMSE and R2 | R2 and RMSE are 0.95 and 0.23 MJ/m2, respectively for NARX. | [62] |
New Delhi, India | ARIMA | Meteorological parameters | Monthly solar radiation | July 01, 1983, to December 31, 2007 | RMSE, MAPE, MAE, and R2 |
MAPE, R2, RMSE, and MAE results are 6.556, 0.9293, 0.3529, and 0.2659, respectively. | [63] |
Las Vegas, United States | ARMA | Historical solar radiation | Hourly solar radiation | 1995–2004 | MBE and nRMSE | MBE and nRMSE are 0.133% and 11.76%, respectively. | [64] |
Morocco | ARMA and ARIMA | Historical solar radiation | Daily global solar radiation | 2018 (November to December) and 2019 (January to March) | MBE RMSE, and MAPE |
ARIMA has a better performance compared to the ARMA model. | [65] |
Two cities (Algiers and Ghardaia) in Algeria | AR and NAR | Historical solar radiation | Daily global solar radiation | 1 January 2005 to 31 December 2006 | NRMSE, S, R2, RMSE, MAE and MBE | NAR has a better performance compared to the AR model. | [66] |
Ghardaia, Algeria | ARMA, NARX, and AR | Historical solar radiation | Hourly global solar radiation | May 2013 to October 2013 | RMSE, NRMSE, MAPE, NMBE and R | NARX estimated the solar radiation data more accurately than other models. | [67] |