Comparative analysis of 31 reference evapotranspiration methods under humid conditions

Albrecht F (1950) DieMethoden zur Bestimmung Verdunstung der natürlichen Erdoberfläche. Arch Meteor Geoph Biokl Ser B2:1–38

Alexandris S, Kerkides P, Liakatas A (2006) Daily reference evapotranspiration estimates by the ‘‘Copais’’ approach. Agric Water Manage 82:371–386

Ali MH, Shui LT (2009) Potential evapotranspiration model for Muda irrigation project, Malaysia. Water Resour Manage 23:57–69

Alkaeed O, Flores C, Jinno K, Tsutsumi A (2006) Comparison of several reference evapotranspiration methods for Itoshima Peninsula Area, Fukuoka, Japan, vol 66, no. 1. Memoirs of the Faculty of Engineering, Kyushu University

Allen RG, Pruitt WO (1991) FAO-24 reference evapotranspiration factors. J Irrig Drain Eng ASCE 117(5):758–773

Allen RG, Pereira LS, Raes D, Smith M (1998) Crop evapotranspiration. Guidelines for computing crop water requirements. FAO Irrigation and Drainage. Paper no. 56. FAO, Rome

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 ASCE 131(1):24–36

Allen RG, Pruitt WO, Wright JL, Howell TA, Ventura F, Snyder R, Itenfisu D, Steduto P, Berengena J, Beselga J, Smith M, Pereira LS, Raes D, Perrier A, Alves I, Walter I, Elliott R (2006) A recommendation on standardized surface resistance for hourly calculation of reference ETo by the FAO56 Penman–Monteith method. Agric Water Manage 81:1–22

Blaney HF, Criddle WD (1950) Determining water requirements in irrigated areas from climatological and irrigation data. Soil conservation service technical paper 96, Soil conservation service. US Department of Agriculture, Washington

Brockamp B, Wenner H (1963) Verdunstungsmessungen auf den Steiner See bei Münster. Dt Gewässerkundl Mitt 7:149–154

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

Chen D, Gao G, Xu C-Y, Guo J, Ren G (2005) Comparison of the Thornthwaite method and pan data with the standard Penman–Monteith estimates of reference evapotranspiration in China. Clim Res 28:123–132

Cuenca RH (1989) Irrigation system design: an engineering approach. Prentice-Hall, Englewood Cliffs, NJ, p 133

Dalton J (1802) Experimental essays on the constitution of mixed gases; on the force of steam of vapour from waters and other liquids in different temperatures, both in a torricellian vacuum and in air on evaporation and on the expansion of gases by heat. Mem Manch Lit Philos Soc 5:535–602

DehghaniSanij H, Yamamoto T, Rasiah V (2004) Assessment of evapotranspiration estimation models for use in semi-arid environments. Agric Water Manage 64:91–106

Doorenbos J, Pruitt WO (1977) Crop water requirements. FAO irrigation and drainage. Paper no. 24 (rev.). FAO, Rome

Droogers P, Allen RG (2002) Estimating reference evapotranspiration under inaccurate data conditions. Irrig Drain Syst 16:33–45

Gocic M, Trajkovic S (2010) Software for estimating reference evapotranspiration using limited weather data. Comput Electron Agric 71:158–162

Grismer ME, Orang M, Snyder R, Matyac R (2002) Pan evaporation to reference evapotranspiration conversion methods. J Irrig Drain Eng ASCE 128(3):180–184

Hargreaves GL, Samani ZA (1985) Reference crop evapotranspiration from temperature. Appl Eng Agric 1(2):96–99

IRIMO (2007) Islamic Republic of Iran Meteorological Office. Data Center, Tehran, Iran

Irmak S, Haman DZ, Jones JW (2002) Evaluation of Class A pan coefficients for estimating reference evapotranspiration in humid location. J Irrig Drain Eng ASCE 128(3):153–159

Irmak S, Irmak A, Jones JW, Howell TA, Jacobs JM, Allen RG, Hoogenboom G (2003a) Predicting daily net radiation using minimum climatological data. J Irrig Drain Eng ASCE 129(4):256–269

Irmak S, Irmak A, Allen RG, Jones JW (2003b) Solar and net radiation-based equations to estimate reference evapotranspiration in humid climates. J Irrig Drain Eng ASCE 129(5):336–347

Jensen ME, Haise HR (1963) Estimation of evapotranspiration from solar radiation. J Irrig Drain Div 89:15–41

Jensen ME, Burman RD, Allen RG (1990) Evapotranspiration and irrigation water requirements. ASCE manual and reports on engineering practice no. 70. ASCE, New York, NY

Jensen DT, Hargreaves GH, Temesgen B, Allen RG (1997) Computation of ETo under non ideal conditions. J Irrig Drain Eng ASCE 123:394–400

Jones JW, Ritchie JT (1990) Crop growth models. Management of farm irrigation systems. In: Hoffman GJ, Howel TA, Solomon KH (eds), ASAE Monograph No. 9, ASAE, St. Joseph, Mich. pp. 63–89

Kashyap PS, Panda RK (2001) Evaluation of evapotranspiration estimation methods and development of crop-coefficients for potato crop in sub-humid region. Agric Water Manage 50:9–25

Landeras G, Ortiz-Barredo A, Lopez JJ (2008) Comparison of artificial neural network models and empirical and semi-empirical equations for daily reference evapotranspiration estimation in the Basque Country (Northern Spain). Agric Water Manage 95:553–565

Lopez-Urrea R, Martin de Santa Olalla F, Fabeiro C, Moratalla A (2006) Testing evapotranspiration equations using lysimeter observations in a semiarid climate. Agric Water Manage 85:15–26

Mahringer W (1970) Verdunstungsstudien am Neusiedler See. Arch Met Geoph Biokl Ser B 18:1–20

Makkink GF (1957) Testing the Penman formula by means of lysimeters. J Inst Water Eng 11:277–288

McGuinness JL, Bordne EF (1972) A comparison of lysimeter-derived potential evapotranspiration with computed values. Technical Bulletin 1452, Agricultural Research Service, US Department of Agriculture, Washington, DC

Meyer A (1926) Über einige Zusammenhänge zwischen Klima und Boden in Europa. Chemie der Erde 2:209–347

Orang M (1998) Potential accuracy of the popular non-linear regression equations for estimating pan coefficient values in the original and FAO-24 Table, Unpublished Rep., Calif. Department of Water Resources, Sacramento

Penman HC (1948) Natural evaporation from open water, bare soil and grass. Proc R Soc Lond Ser A 193:120–145

Pereira AR, Villanova N, Pereira AS, Baebieri VA (1995) A model for the class-A pan coefficient. Agric Water Manage 76:75–82

Priestley CHB, Taylor RJ (1972) On the assessment of surface heat flux and evapotranspiration using large scale parameters. Mon Weather Rev 100:81–92

Ritchie JT (1972) Model for predicting evaporation from a row crop with incomplete cover. Water Resour Res 8:1204–1213

Rohwer C (1931) Evaporation from free water surface. USDA Tech Null 217:1–96

Romanenko VA (1961) Computation of the autumn soil moisture using a universal relationship for a large area. In: Proceedings, Ukrainian Hydrometeorological Research Institute, no. 3. Kiev

Sabziparvar AA, Tabari H (2010) Regional estimation of reference evapotranspiration in arid and semi-arid regions. J Irrig Drain Eng ASCE 136(10):724–731

Sabziparvar AA, Tabari H, Aeini A, Ghafouri M (2010) Evaluation of class A pan coefficient models for estimation of reference crop evapotranspiration in cold-semi arid and warm arid climates. Water Resour Manage 24:909–920

Schendel U (1967) Vegetationswasserverbrauch und -wasserbedarf. Habilitation, Kiel, p 137

Sentelhas PC, Gillespie TJ, Santos EA (2010) Evaluation of FAO Penman–Monteith and alternative methods for estimating reference evapotranspiration with missing data in Southern Ontario, Canada. Agric Water Manage 97:635–644

Singh VP (1989) Hydrologic systems, vol 2. Prentice-Hall, Englewood Cliffs, NJ

Singh VP, Xu C-Y (1997) Evaluation and generalization of 13 mass-transfer equations for determining free water evaporation. Hydrol Process 11:311–323

Snyder RL (1992) Equation for evaporation pan to evapotranspiration conversions. J Irrig Drain Eng ASCE 118(6):977–980

Stanhill G (2002) Is the Class A evaporation pan still the most practical and accurate meteorological method for determining irrigation water requirements? Agric For Meteorol 112(3–4):233–236

Tabari H (2010) Evaluation of reference crop evapotranspiration equations in various climates. Water Resour Manage 24:2311–2337

Tabari H, Hosseinzadeh Talaee P (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 ASCE. doi: 10.1061/(ASCE)HE.1943-5584.0000366

Temesgen B, Eching S, Davidoff B, Frame K (2005) Comparison of some reference evapotranspiration equations for California. J Irrig Drain Eng ASCE 131:73–84

Thornthwaite CW (1948) An approach toward a rational classification of climate. Geogr Rev 38:55–94

Trabert W (1896) Neue Beobachtungen über Verdampfungsgeschwindigkeiten. Meteorol Z 13:261–263

Trajkovic S (2007) Hargreaves versus Penman–Monteith under Humid Condition. J Irrig Drain Eng ASCE 133:38–42

Trajkovic S, Kolakovic S (2009) Evaluation of reference evapotranspiration equations under humid conditions. Water Resour Manage 23:3057–3067

Turc L (1961) Evaluation des besoins en eau irrigation, l’evapotranspiration potentielle. Ann Agron 12:13–49

WMO (1966) Measurement and estimation of evaporation and evapotranspiration. Tech. Pap. (CIMO-Rep) 83. Genf

Xing Z, Chow L, Meng F, Rees HW, Monteith J, Lionel S (2008) Testing reference evapotranspiration estimation methods using evaporation pan and modeling in Maritime region of Canada. J Irrig Drain Eng ASCE 134(4):417–424

Xu C-Y, Singh VP (2000) Evaluation and generalization of radiation-based methods for calculating evaporation. Hydrol Process 14:339–349

Xu C-Y, Singh VP (2002) Cross comparison of empirical equations for calculating potential evapotranspiration with data from Switzerland. Water Resour Manage 16:197–219

Yoder RE, Odhiambo LO, Wright WC (2004) Evaluation of methods for estimating daily reference crop evapotranspiration at a site in the humid southeast United States. Appl Eng Agric 21(2):197–202