Abstract
Crop evapotranspiration (ET) is one of the main components in calculating the water balance in agricultural, hydrological, environmental, and climatological studies. Solar radiation (Rs) supplies the available energy for ET, and therefore, precise measurement of Rs is required for accurate ET estimation. However, measured Rs and ET and are not available in many areas and they should be estimated indirectly by the empirical methods. The Angström-Prescott (AP) is the most popular method for estimating Rs in areas where there are no measured data. In addition, the locally calibrated coefficients of AP are not yet available in many locations, and instead, the default coefficients are used. In this study, we investigated different approaches for Rs and ET calculations. The daily measured Rs values in 14 stations across arid and semi-arid areas of Fars province in south of Iran were used for calibrating the coefficients of the AP model. Results revealed that the calibrated AP coefficients were very different and higher than the default values. In addition, the reference ET (ETo) was estimated by the FAO56 Penman–Monteith (FAO56 PM) and FAO24-radiation methods by using the measured Rs and were then compared with the measured pan evaporation as an indication of the potential atmospheric demand. Interestingly and unlike many previous studies, which have suggested the FAO56 PM as the standard method in calculation of ETo, the FAO24-radiation with the measured Rs showed better agreement with the mean pan evaporation. Therefore, the FAO24-radiation with the measured Rs was used as the reference method for the study area, which was also confirmed by the previous studies based on the lysimeter data. Moreover, the accuracy of calibrated Rs in the estimation of ETo by the FAO56 PM and FAO24-radiation was investigated. Results showed that the calibrated Rs improved the accuracy of the estimated ETo by the FAO24-radiation compared with the FAO24-radiation using the measured Rs as the reference method, whereas there was no improvement in the estimation of ETo by the FAO56 PM method compared with the FAO24-radiation using the measured Rs. Moreover, the empirical coefficient (α) of the Priestley and Taylor (PT) ETo estimation method was calibrated against the reference method and results indicated ca. 2 or higher α values than the recommended α = 1.26 in all stations. An empirical equation was suggested based on yearly mean relative humidity for estimation of α in the study area. Overall, this study showed that (1) the FAO24-radiation method with the either measured or calibrated Rs is more accurate than the FAO56 PM, (2) the spatially calibrated AP coefficients are very different from each other over an arid and semi-arid area and are higher than those proposed by the FAO56, (3) the original PT model is not applicable in arid and semi-arid area and substantially underestimates the ETo, and (4) the coefficient of the PT should be locally calibrated for each station over an arid and semi-arid area.
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References
Adamala S, Raghuwanshi N, Mishra A (2015) Generalized quadratic synaptic neural networks for ETo modeling. Environ Process 2:309–329
Ahmadi SH, Fooladmand HR (2008) Spatially distributed monthly reference evapotranspiration derived from the calibration of Thornthwaite equation: a case study, south of Iran. Irrig Sci 26:303–312
Al-Ghobari HM (2000) Estimation of reference evapotranspiration for southern region of Saudi Arabia. Irrig Sci 19:81–86
Allen RG, Pereira LS, Raes D, Smith M (1998) Crop evapotranspiration—guidelines for computing crop water requirements-FAO irrigation and drainage paper 56 FAO. Rome 300:D05109
Allen RG, Clemmens AJ, Burt CM, Solomon K, O’Halloran T (2005) Prediction accuracy for projectwide evapotranspiration using crop coefficients and reference evapotranspiration. J Irrig Drain Eng 131:24––36
Almorox J, Benito M, Hontoria C (2008) Estimation of global solar radiation in Venezuela. Interciencia 33:280–283
Angstrom A (1924) Solar and terrestrial radiation. Report to the international commission for solar research on actinometric investigations of solar and atmospheric radiation. Q J R Meteorol Soc 50:121–126
Badescu V, Gueymard CA, Cheval S, Oprea C, Baciu M, Dumitrescu A, Iacobescu F, Milos I, Rada C (2013) Accuracy analysis for fifty-four clear-sky solar radiation models using routine hourly global irradiance measurements in Romania. Renew Energy 55:85–103
Bakhtiari B, Ghahraman N, Liaghat A, Hoogenboom G (2010) Evaluation of reference evapotranspiration models for a semiarid environment using lysimeter measurements. J Agric Sci Technol 13:223–237
Bidlake WR (2002) Evapotranspiration and canopy resistance at an undeveloped prairie in a humid subtropical climate. J Am Water Resour Assoc 38:197–211
Cai J, Liu Y, Lei T, Pereira LS (2007) Estimating reference evapotranspiration with the FAO Penman–Monteith equation using daily weather forecast messages. Agric For Meteorol 145:22–35
Castellvi F, Stockle C, Perez P, Ibanez M (2001) Comparison of methods for applying the Priestley–Taylor equation at a regional scale. Hydrol Process 15:1609–1620
Chuanyan Z, Zhongren N, Zhaodong F (2004) GIS-assisted spatially distributed modeling of the potential evapotranspiration in semi-arid climate of the Chinese Loess Plateau. J Arid Environ 58:387–403
Cristea NC, Kampf SK, Burges SJ (2012) Revised coefficients for Priestley-Taylor and Makkink-Hansen equations for estimating daily reference evapotranspiration. J Hydrol Eng 18:1289–1300
Dehbozorgi F, Sepaskhah AR (2012) Comparison of artificial neural networks and prediction models for reference evapotranspiration estimation in a semi-arid region. Arch Agron Soil Sci 58:477–497
DehghaniSanij H, Yamamoto T, Rasiah V (2004) Assessment of evapotranspiration estimation models for use in semi-arid environments. Agric Water Manag 64:91–106
Didari S, Zand-Parsa S (2017) Estimation of daily global solar irradiation under different sky conditions in central and southern Iran. Theor Appl Climatol 127:587–596
Didari S, Norouzi H, Zand-Parsa S, Khanbilvardi R (2017) Estimation of daily minimum land surface air temperature using MODIS data in southern Iran. Theor Appl Climatol 130:1149–1161
Dinpashoh Y (2006) Study of reference crop evapotranspiration in I.R. Of Iran. Agric Water Manag 84:123–129
Doorenbos J (1977) Guidelines for predicting crop water requirements. FAO, Rome
Er-Raki S, Chehbouni A, Khabba S, Simonneaux V, Jarlan L, Ouldbba A, Rodriguez JC, Allen R (2010) Assessment of reference evapotranspiration methods in semi-arid regions: can weather forecast data be used as alternate of ground meteorological parameters? J Arid Environ 74:1587–1596
Flint AL, Childs SW (1991) Use of the Priestley-Taylor evaporation equation for soil water limited conditions in a small forest clearcut. Agric For Meteorol 56:247–260
Garcia M, Raes D, Allen R, Herbas C (2004) Dynamics of reference evapotranspiration in the Bolivian highlands (Altiplano). Agric For Meteorol 125:67–82
Gavilan P, Lorite IJ, Tornero S, Berengena J (2006) Reginonal calibration of Hargreaves equation for estimationf reference ET in a semiarid environment. Agric Water Manag 81:257–281
Hargreaves GH, Samani ZA (1985) Reference crop evapotranspiration from temperature. Appl Eng Agric 1:96–99
Hobbins MT, Ramirez JA, Brown TC (2001) The complementary relationship in estimation of regional evapotranspiration: an enhanced advection-aridity model. Water Resour Res 37:1389–1403
Irmak S, Allen RG, Whitty EB (2003) Daily grass and alfalfareference evapotranspiration estimates and alfalfa to grass evapotranspiration ratios in Florida. J Irrig Drain Eng 129:360–370
Jafarpur K, Yaghoubi M (1989) Solar radiation for Shiraz, Iran. Solar Wind Technol 6:177–179
Jensen ME, Burman RD, Allen RG. (1990) Evapotranspiration and irrigation water requirements. ASCE Manuals and Reports on Engineering Practice, No. 70, American Society of Civil Engineers
Kamel M, Shalaby S, Mostafa S (1993) Solar radiation over Egypt: comparison of predicted and measured meteorological data. Sol Energy 50:463–467
Kasten F, Golchert HJ, Stolley M (1983) Parameterization of radiation fluxes as function of solar elevation, cloudiness and turbidity. In: Palz W (ed) Solar Radiation Data. Solar Energy R&D in the European Community Series F, vol 2. Springer, Dordrecht
Katerji N, Rana G (2014) FAO-56 methodology for determining water requirement of irrigated crops: critical examination of the concepts, alternative proposals and validation in Mediterranean region. Theor Appl Climatol 116:515–536
Kisi O, Cengiz TM (2013) Fuzzy genetic approach for estimating reference evapotranspiration of Turkey: Mediterranean region. Water Resour Manag 27:3541–3553
Kloss S, Pushpalatha R, Kamoyo KJ, Schütze N (2012) Evaluation of crop models for simulating and optimizing deficit irrigation systems in arid and semi-arid countries under climate variability. Water Resour Manag 26:997–1014
Liu D, Scott B (2001) Estimation of solar radiation in Australia from rainfall and temperature observations. Agric For Meteorol 106:41–59
Liu X, Mei X, Li Y, Wang Q, Zhang Y, Porter JR (2009) Variation in reference crop evapotranspiration caused by the Ångström–Prescott coefficient: locally calibrated versus the FAO recommended. Agric Water Manag 96:1137–1145
Makkink G (1957) Testing the Penman formula by means of lysimeters. J Inst Water Eng 11:277–288
Malek E (1979) Determination of the constants for the global radiation equation at badjgah, Iran. Agric Meteorol 20:233–235
McAneney K, Itier B (1996) Operational limits to the Priestley-Taylor formula. Irrig Sci 17:37–43
Mehdizadeh S, Saadatnejad Gharahassanlou H, Behmanesh J (2017) Calibration of Hargreaves-Samani and Priestley-Taylor equations in estimating reference evapotranspiration in the northwest of Iran. Arch Agron Soil Sci 63:942–955
Meza F, Varas E (2000) Estimation of mean monthly solar global radiation as a function of temperature. Agric For Meteorol 100:231–241
Moazed H, Ghaemi AA, Rafiee F (2014) Evaluation of several reference evapotranspiration methods: a comparative study of greenhouse and outdoor conditions. Transactions of. Civ Eng 38:421–437
Moradi I (2009) Quality control of global solar radiation using sunshine duration hours. Energy 34:1–6
Mousavi R, Sabziparvar AA, Marofi S, Pak NAE, Heydari M (2015) Calibration of the Angström-Prescott solar radiation model for accurate estimation of reference evapotranspiration in the absence of observed solar radiation. Theor Appl Climatol 119:43–54
Ngongondo C, Xu C-Y, Tallaksen LM, Alemaw B (2013) Evaluation of the FAO Penman–Montheith, Priestley–Taylor and Hargreaves models for estimating reference evapotranspiration in southern Malawi. Hydrol Res 44:706–722
Penman HL (1948) Natural evaporation from open water, bare soil and grass. In: Proceedings of the Royal Society of London a: mathematical, physical and engineering sciences, 1948. Vol 1032. The Royal Society, pp 120–145
Pereira AR, Pruitt WO (2004) Adaptation of the Thornthwaite scheme for estimating daily reference evapotranspiration. Agric Water Manag 66:251–257
Perugu M, Singam AJ, Kamasani CSR (2013) Multiple linear correlation analysis of daily reference evapotranspiration. Water Resour Manag 27:1489–1500
Prescott J (1940) Evaporation from a water surface in relation to solar radiation. Trans R Soc S Aust 64:114–118
Priestley C, Taylor R (1972) On the assessment of surface heat flux and evaporation using large scale parameters. In: Mon. Weather Rev, 1972. Citeseer,
Razzaghi F, Sepaskhah AR (2010) Assessment of nine different equations for ETo estimation using lysimeter data in a semi-arid environment. Arch Agron Soil Sci 56:1–12
Rojas JP, Sheffield RE (2013) Evaluation of daily reference evapotranspiration methods as compared with the ASCE-EWRI Penman-Monteith equation using limited weather data in Northeast Louisiana. J Irrig Drain Eng 139:285–292
Sabziparvar AA, Shetaee H (2007) Estimation of global solar radiation in arid and semi-arid climates of east and west Iran. Energy 32:649–655
Sabziparvar A-A, Tabari H (2010) Regional estimation of reference evapotranspiration in arid and semiarid regions. J Irrig Drain Eng 136:724–731
Sabziparvar AA, Mousavi R, Marofi S, Ebrahimipak NA, Heidari M (2013) An improved estimation of the Angstrom–Prescott radiation coefficients for the FAO56 Penman–Monteith evapotranspiration method. Water Resour Manag 27:2839–2854
Shahrokhnia MH, Sepaskhah AR (2013) Single and dual crop coefficients and crop evapotranspiration for wheat and maize in a semi-arid region. Theor Appl Climatol 114:495–510
Shuttleworth WJ, Wallace JS (2009) Calculating the water requirements of irrigated crops in Australia using the Matt-Shuttleworth approach. Trans ASABE 52:1895–1906
Steduto P et al. (1996) Penman-Monteith reference evapotranspiration estimates in the Mediterranean region. In: Proceedings of the International Conference on Evapotranspiration and Irrigation Scheduling, San Antonio, TX, USA, 1996. pp 3–6
Sumner DM, Jacobs JM (2005) Utility of Penman–Monteith, Priestley–Taylor, reference evapotranspiration, and pan evaporation methods to estimate pasture evapotranspiration. J Hydrol 308:81–104
Tabari H, Talaee PH (2011) Local calibration of the Hargreaves and Priestley-Taylor equations for estimating reference evapotranspiration in arid and cold climates of Iran based on the Penman-Monteith model. J Hydrol Eng 16:837–845
Tabari H, Hosseinzadehtalaei P, Willems P, Martinez C (2016) Validation and calibration of solar radiation equations for estimating daily reference evapotranspiration at cool semi-arid and arid locations. Hydrol Sci J 61:610–619
Temesgen B, Eching S, Davidoff B, Frame K (2005) Comparison of some reference evapotranspiration equations for California. J Irrig Drain Eng 131:73–84
Thornthwaite CW (1948) An approach toward a rational classification of climate. Geogr Rev 38:55–94
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
Tomar AS (2016) Performance of radiation-based reference evapotranspiration equation developed for Indian sub-humid conditions. J Agrometeorol 18:76–82
Traore S, Guven A (2012) Regional-specific numerical models of evapotranspiration using gene-expression programming interface in Sahel. Water Resour Manag 26:4367–4380
Willmott CJ (1982) Some comments on the evaluation of model performance. Bull Am Meteorol Soc 63:1309–1313
Xu CY, Chen D (2005) Comparison of seven models for estimation of evapotranspiration and groundwater recharge using lysimeter measurement data in Germany. Hydrol Process 19:3717–3734
Xu C-Y, Singh V (2005) Evaluation of three complementary relationship evapotranspiration models by water balance approach to estimate actual regional evapotranspiration in different climatic regions. J Hydrol 308:105–121
Yin Y, Wu S, Zheng D, Yang Q (2008) Radiation calibration of FAO56 Penman–Monteith model to estimate reference crop evapotranspiration in China. Agric Water Manag 95:77–84
Yoder R, Odhiambo L, Wright W (2005) Evaluation of methods for estimating daily reference crop evapotranspiration at a site in the humid Southeast United States. Appl Eng Agric 21:197–202
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Didari, S., Ahmadi, S.H. Calibration and evaluation of the FAO56-Penman-Monteith, FAO24-radiation, and Priestly-Taylor reference evapotranspiration models using the spatially measured solar radiation across a large arid and semi-arid area in southern Iran. Theor Appl Climatol 136, 441–455 (2019). https://doi.org/10.1007/s00704-018-2497-2
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DOI: https://doi.org/10.1007/s00704-018-2497-2