Abstract
A well-calibrated simple and economical viable Ȧngström–Prescott model has long been accepted to be more accurate than other surface meteorological data-based models. The major limitation is that it is site dependent. This study exploited the appropriateness of a more generalized Ȧngström-based broadband hybrid model in the estimation of solar radiation at seven stations in equatorial region of West Africa. This model features parametric equations that explicitly and accurately account for clear-sky damping processes in the atmosphere. It empirically estimates cloudy sky radiation extinctions using relative sunshine duration. A new cloud transmittance calibration curve that followed the cloud cover patterns of the region of study was also tried. The result indicated that the new cloud transmittance could be unique to equatorial region of West Africa. The performance of the hybrid model, after modification using the new cloud transmittance equation, was tested using mean bias error and root mean squared error. The performance was found to be comparable to the site-dependent, locally calibrated, Ȧngström–Prescott model at the calibration stations, and even better at validation stations. The same performance test comparisons with the original version of the hybrid model, and four other site-independent models: globally calibrated, FAO-recommended Ȧngström–Prescott models, Hay and Gopinathan models indicated the modified version of the hybrid model as better
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adaramola MS (2018) Estimating global solar radiation using common meteorological data in Akure, Nigeria. Renew Energy 47:38–44. https://doi.org/10.1016/j.renene.2012.04.005
Adedokun JA (1978) West African precipitation and dominant mechanisms. Arch Meterol Geophys Bioclimatol Ser A 27:289–310
Adejuwon JO, Odekunle TO (2006) Variability and severity of the little dry season in southwestern Nigeria. J Clim 19:1–8
Adeniyi MO (2014) Variability of daily precipitation over Nigeria. Meteorol Atmos Phys 126:161–176. https://doi.org/10.1007/s00703-014-0340-6
Akpabio LE (2019) Modeling global solar radiation for a tropical location: Onne, Nigeria. Turk J Phys 29:63–68
Allen Richard G, Pereira Luis S, Raes Dirk, Smith M (1998) Crop evapotranspiration-guidelines for computing crop water requirement. FAO Irrig Drain Pap 56:281p
Almorox J, Hontoria CBM (2011) Models for obtaining daily global radiation with measured air temperature data in Madrid (Spain). Appl Energy 88:1703–1709
Angstrom A (1924) Solar and terrestrial radiation. Q J R Meteorol Soc 50:121–125
Balogun EE (1991) Convective activity over Nigeria during the monsoon. Proc Int Conf Early Results FGGE Large Scale Asp Monsoon Exp Tallahassee Fla 12:22–27
Bamiro OA (1983) Empirical relations for the determination of solar radiation in ibadan, Nigeria. Sol Energy 31:85–94
Bristow KL, Campbell GS (1984) on the relationship between incoming solar radiation and daily maximum and minimum temperature. Agric For Meteorol 31:159–166
Chen JL, He L, Wen ZF, Lv MQ, Yi XX, Wu SJ (2018) a general empirical model for estimation of solar radiation in Yangtze river basin. Appl Ecol Environ Res 16(2):1471–1482
Ehnberg JSG, Bollen MHJ (2005) Simulation of global solar radiation based on cloud observations. Sol Energy 78:157–162
Falayi EO, Adepitan JO, Rabiu AB (2008) Empirical models for the correlation of global solar radiation with meteorological data for Iseyin, Nigeria. Niger Int J Phys Sci 3:210–216
Gopinathan KK (1988) A general formula for computing the coefficients of the correlation connecting global solar radiation to sunshine duration. Sol Energy 41:499–502
Gueymard C (1993) Analysis of monthly average solar radiation and bright sunshine for different thresholds at Cape Canaveral, Florida. Sol Energy 51:139–145. https://doi.org/10.1016/0038-092X(93)90075-Y
Gueymard CA (2003) Direct solar transmittance and irradiance predictions with broadband models. Part II: validation with high-quality measurements. Sol Energy 74:381–395. https://doi.org/10.1016/S0038-092X(03)00196-8
Gueymard AC (2003) Direct solar transmittance and irradiance with broadband models. Part I: detailed theoretical performance assessment. Sol Energy 74:355–379. https://doi.org/10.1016/j.solener.2003.11.002
Hay JE (1979) Calculation of monthly mean solar radiation for horizontal and inclined surfaces. Sol Energy 23:301–307
Hess M, Koepke P, Schult I (1998) Optical properties of aerosol and clouds: the software package OPAC. Bull Am Meteorol Soc 79:831–844
Hoogenboom G (2000) Contribution of agrometeorology to the simulation of crop production and its applications. Agric For Meteorol 103:137–157
Hunt LA, Kuchar L, Swanton CJ (1998) Estimation of solar radiation for use in crop modeling. Agric For Meteorol 91:293–300
Igbal M (1980) Prediction of hourly diffuse solar radiation from measured hourly global radiation on a horizontal surface. Sol Energy 24:491–503
Iziomon MG, Mayer H (2001) Performance of solar radiation models—a case study. Agric For Meteorol 110:1–11
Kasten F, Young AT (1989) Revised optical air mass tables and approximation formula. Appl Opt 28:4735–4738
Koepke P, Hess M, Schult I, Shettle E (1997) Global aerosol data set. Max-Planck Institut fu¨r Meteorologie. Rep No 243
Liu DL, Scott BJ (2001) Estimation of solar radiation in Australia from rainfall and temperature observation. Agric For Meteorol 106:41–59
Liu XY, Mei XR, Li YZ, Zhang YQ (2009) Calibration of the Angstrom–Prescott coefficients (a, b) under different time scales and their impacts in estimating global solar radiation in the yellow river basin. Agric For Meteorol 149:697–710
Madkour MA, El-Metwally M, Hamed AB (2006) Comparative study on different models for estimation of direct normal irradiance (DNI) over Egypt atmosphere. Renew Energy 31:361–382. https://doi.org/10.1016/j.renene.2005.03.009
Meza F, Varas E (2000) Estimation of mean monthly solar global radiation as a function of temperature. Agric For Meteorol 100:231–241
Miller DG, Rivington M, Matthews KB, Buchan K, Bellocchi G (2008) Testing the spatial applicability of the Johnson–Woodward method for estimating solar radiation from sunshine duration data. Agric For Meteorol 148:466–480
Nielsen L, Berkowicz R, Conradsen K (1981) Net incomng radiation estimated from hourly global radiation and/or cloud observations. J Clim 1:255–272
Odekunle TO (2004) Determination of rainfall onset and retreat dates. J Hum Ecol 16:239–247
Ogolo EO (2010) Evaluating the performance of some predictive models for estimating global solar radiation across the varying climatic conditions in Nigeria. Pac J Sci Technol 11:60–72
Otunla TA (2019) Estimates of clear-sky solar irradiances over Nigeria. Renew Energy 131:778–787
Paulescu M, Schlett Z (2004) Performance assessment of global solar irradiation models under Romanian climate. Renew Energy 29:767–777
Pohlert T (2004) Use of empirical global radiation models for maize growth simulation. Agric For Meteorol 126:47–58
Prescott JA (1940) Evaporation from water surface in relation to solar radiation. Trans R Soc Aust 641:114–125
Suehrcke H, Bowden RS, Hollands KGT (2013) Relationship between sunshine duration and solar radiation. Sol Energy 92:160–171
Supit I, van Kappel RR (1998) A simple method to estimate global radiation. Sol Energy 63:147–160
Tang W, Yang K, He J, Qin J (2010) Quality control and estimation of global solar radiation in China. Sol Energy 84:466–475. https://doi.org/10.1016/j.solener.2010.01.006
Thornton PE, Running SW (1999) An improved algorithm for estimating incident daily solar radiation from measurements of temperature, humidity, and precipitation. Agric For Meteorol 93:211–228
Weiss A, Hays CJ (2004) Simulation of daily solar irradiance. Agric For Meteorol 123:187–199
WMO (2008) Guide to meteorological instruments and methods of observation. Seventh edition, WMO-NO. 8, Geneva
Wong LT, Chow WK (2001) Solar radiation model. Appl Energy 69:191–224. https://doi.org/10.1016/S0306-2619(01)00012-5
Yang K, Koike T (2005) A general model to estimate hourly and daily solar radiation for hydrological studies. Water Resour Res 41:1–13. https://doi.org/10.1029/2005WR003976
Yang K, Huang GW, Tamai N (2001) A hybrid model for estimating global solar radiation. Sol Energy 70:13–22. https://doi.org/10.1016/S0038-092X(00)00121-3
Yang K, Koike T, Stackhouse P et al (2006a) An assessment of satellite surface radiation products for highlands with Tibet instrumental data. Geophys Res Lett 33:3. https://doi.org/10.1029/2006GL027640
Yang K, Koike T, Ye B (2006b) Improving estimation of hourly, daily, and monthly solar radiation by importing global data sets. Agric For Meteorol 137:43–55. https://doi.org/10.1016/j.agrformet.2006.02.001
Acknowledgements
Prof. Kun Yang of Key Laboratory of Tibetan Environment Changes and Land Surface Processes, Institute of Tibetan Plateau Research, Chinese Academy of Sciences, Beijing 100085, China provided the code for hybrid model and the two auxiliary data through personal communications. Centre for Atmospheric Research, National Space Research and Development Agency (CAR-NSRDA) Anyigba, Nigeria provided meteorological data through its TRODAN project.
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible Editor: M. Telisman Prtenjak.
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Otunla, T.A. Estimation of daily solar radiation at equatorial region of West Africa using a more generalized Ȧngström-based broadband hybrid model. Meteorol Atmos Phys 132, 341–351 (2020). https://doi.org/10.1007/s00703-019-00691-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00703-019-00691-8