Modelling Irrigation Water Requirements at Physiological Growth Stages of Okra Life Cycle Using CROPWAT Model for Derived Savannah and Humid Forest Zones of Nigeria

Abdelhadi A.W., Hata T., Tanakumaru H., Tada A., Tariq M.A. (2000): Estimation of crop water requirements in arid region using Penman-Monteith equation with derived crop coefficients: a case study on Acala cotton in Sudan Gezira irrigated scheme. Agricultural Water Management 45(3): 203-214.10.1016/S0378-3774(99)00077-3Search in Google Scholar

Abu Zeid K., Abdel Megeed A. (2004): Status of Integrated water resources management planning in Arab Mediterranean Countries. IWRM, International Water Demand Management Conference, Dead Sea, Jordan. June 2004.Search in Google Scholar

Aiyelaagbe I.O.O., Ogbonnaya F.C. (1996): Growth, fruit production and seed yield of okra (Abelmoschus esculentus L) in response to irrigation and mulching. Research Bulletin No. 18. National Horticultural Research Institute, Ibadan, 13 p.Search in Google Scholar

Ali M.H., Hoque M.R., Hassan A.A., Khair A. (2007): Effects of deficit irrigation on yield, water productivity, and economic returns of wheat. Agricultural Water Management 92: 151-161.10.1016/j.agwat.2007.05.010Search in Google Scholar

Aliku O. (2013): Determination of crop water requirement for two okra varieties under three rates of potential evapotranspiration. Ph.D Thesis, the Department of Agronomy, University of Ibadan, Nigeria.Search in Google Scholar

Allen R.G., Pereira L.S., Raes D., Smith M. (1998): Crop evapotranspiration guidelines for computing crop water requirements. FAO Irrigation and Drainage Paper No. 56, United Nations - Food and Agricultural Organization, Rome, Italy, 300 p.Search in Google Scholar

Anaç M.S., Ali U.M., Tuzal I.H., Anac D., Okur B., Hakerlerler H. (1999): Optimum irrigation schedules for cotton under deficit irrigation conditions. In: C. Kirda, P. Moutonnet, C. Hera, D.R Nielsen, eds. Crop Yield Response to Deficit Irrigation. p. 196-212. Dordrecht, Netherlands, Kluwer Academic Publishers.10.1007/978-94-011-4752-1_15Search in Google Scholar

Anadranistakis M., Liakatas A., Kerkides P., Rizos S. (2000): Crop water requirements model tested for crop grown in Greece. Agricultural Water Management 45 (3), 297-316.10.1016/S0378-3774(99)00106-7Search in Google Scholar

Dastane N.G. (1978): Effective rainfall. Irrigation and drainage paper 25, FAO, Rome, Italy.Search in Google Scholar

El-Quasy D. (2009): Impact of climate change: vulnerability and adaptation on fresh water. In: (Ed.) Tolba MK, and Saab NW, Impact of climate change on Arab countries. Arab Forum for Environment and Development pp .75-86.Search in Google Scholar

FAO (1977): Guidelines for profile description. Second Edition, FAO, Rome.Search in Google Scholar

FAO (1979): Soil survey investigations for irrigation. Soil Bulletin No. 42. FAO, Rome.Search in Google Scholar

FAO (1998): Crop Evapotranspiration, Guidelines for Computing Crop Water Requirements - FAO Irrigation and Drainage Paper No. 56. FAO Rome.Search in Google Scholar

FAO (1996): Irrigation scheduling: From theory to practice -Proceedings. Food and Agriculture Organization of United Nations. ICID-CIID. Water Reports 8. Rome. ISBN 92-5-103968-2. [Online]. Available from: http://www.fao.org/docrep/W4367E/W4367E00.htm#Contents. [Accessed 23 November, 2015].Search in Google Scholar

FAO-Aquastat (2009): Water Reports, 34. In: (Ed.) Karen Frenken., Irrigation in the Middle East region in figures AQUASTAT Survey - 2008. Land and Water Division, FAO Rome. ftp://ftp.fao.org/agl/aglw/docs/wr34_eng.pdf.Search in Google Scholar

Farmwest (2013): Effective precipitation: http://www.farmwest.com/node/934 [Accessed 23 November, 2015].Search in Google Scholar

George B., Shende S., Raghuwanshi N., (2000): Development and testing of an irrigation scheduling model. Agricultural Water Management 46 (2), 121-136.10.1016/S0378-3774(00)00083-4Search in Google Scholar

Hashim M.A.A., Siam N., Al-Dosari A., Asl-Gaadi K.A., Patil V.C. (2012): Determination of Water Requirement and Crop Water Productivity of Crops Grown in the Makkah Region of Saudi Arabia. Australian Journal of Basic and Applied Sciences 6(9): 196-206.Search in Google Scholar

Hillel D. (2003): Environmental soil physics. Academic Press, New York. 484 p.Search in Google Scholar

Home P.G., Kar S., Panda R.K. (2000): Effect of irrigation scheduling on water and nitrogen balances in the crop root zone. Zeitschrift fuer Bewasserungswirtschaft 35(2), 223-235. http://www.fao.org/docrep/X5560E/X5560E00.htm [Accessed 23 November, 2015].Search in Google Scholar

Hunsaker D.J., Pinter P.J. Jr., Cai H. (2002): Alfalfa basal crop coefficients for FAO-56 procedures in the desert regions of the Southwestern U.S., Transactions of the ASAE 45(6): 1799-1815.10.13031/2013.11431Search in Google Scholar

Kamel N., Mohamed M.M., Mechliaba N.B. (2012): Impacts of irrigation regimes with saline water on carrot productivity and soil salinity. Journal of the Saudi Society of Agricultural Sciences 11(1): 19-27.Search in Google Scholar

Kang S., Payne W.A., Evett S.R., Stewart B.A., Robinson C.A. (2009): Simulation of winter wheat evapotranspiration in Texas and Henan using three models of differing complexity. Agricultural Water Management 96, 167-178.10.1016/j.agwat.2008.07.006Search in Google Scholar

Manjunath B.L., Mishra P.K., Rao J.V., Reddy G.S. (1994): Water requirement of vegetables in a dry-land watershed. Indian Journal of Agricultural Sciences 64 (12), 845-846.Search in Google Scholar

Marica A. (2013): Short description of the CROPWAT model. http://agrometcost.bo.ibimet.cnr.it/fileadmin/cost718/repository/cropwat.pdf) (Accessed 24 April, 2014)Search in Google Scholar

Mhashu S.V. (2007): Yield response to water function and simulation of deficit irrigation scheduling of sugarcane at estate in Zimbabwe using CROPWAT 8.0 and CLIMWAT 2.0, Master thesis, Università degli Studi di Firenze Facoltá di Agraria (University of Florence, Faculty of Agriculture).Search in Google Scholar

Mimi Z.A., Jamous S.A. (2010): Climate change and agricultural water demand: impacts and adaptations. African Journal of Environmental Science and Technology 4 (4), 183-191.Search in Google Scholar

Narasimhan B., Srinivasan R. (2005): Development and evaluation of Soil Moisture Deficit Index (SMDI) and Evapotranspiration Deficit Index (ETDI) for agricultural drought monitoring. Agricultural and Forest Meteorology, 133: 69-88.10.1016/j.agrformet.2005.07.012Search in Google Scholar

Nazeer M. (2009): Simulation of maize crop under irrigated and rainfed conditions with CROPWAT model. ARPN Journal of Agricultural and Biological Sciences 4 (2), 68-73.Search in Google Scholar

Odofin A.J., Oladiran J.A., Oladipo J.A., Wuya E.P. (2011): Determination of evapotranspiration and crop coefficients for bush okra (Corchorus olitorius) in a subhumid area of Nigeria. African Journal of Agricultural Research 6(17) :3949 - 3953.Search in Google Scholar

Ojanuga A.G. (1979): Evaluation of existing soil surveys of Northern Nigeria for irrigation development. 6th National Irrigation Seminar Proceeding, A.B.U., Zaria, pp. 124 - 137.Search in Google Scholar

Oshunsanya S.O., Aiyelari E.A., Aliku O., Odekanyin R.A. (2016): Comparative Performance of Okra (Abelmoschus Esculentus) Under Subsistence Farming Using Drip and Watering Can Methods of Irrigation. Irrigation and Drainage System Engineerging 5: 159. doi:10.4172/2168-9768.1000159.Search in Google Scholar

Ouda S., Khalil F., Gamal A., Sayed A.H. (2011): Prediction of total water requirements for agriculture in the Arab world under climate change. Fifteenth International Water Technology Conference, IWTC-15 2011, Alexandria, Egypt.Search in Google Scholar

Phene C.J., Reginato R.J., Itier B., Tanner B.R. (1990): Sensing irrigation needs. pp. 207-261. In: G.J. Hoffman, T.A. Howell, and K.H. Solomon (eds.) Management of Farm Irrigation Systems, Am. Soc. Agric. Engr., St. Joseph, MI. USA Saif-ud-din, Al-Rumikhani Y.A., Mohammad S.L. (2004): Use of remote sensing and agrometerology for irrigation management in arid lands: A case study from Northwestern Saudi Arabia. Journal of Environmental Hydrology 2 (9): 10-17.Search in Google Scholar

Sheng-Feng K., Shin-Shen H., Chen-Wuing L. (2006): Estimation irrigation water requirements with derived crop coefficients for upland and paddy crops in Chia Nan Irrigation Association, Taiwan. Agricultural Water Management 82 (6), 433-451.Search in Google Scholar

Singh B.P. (1987): Effect of irrigation on the growth and yield of okra. Horticulture Science, 22, 879-880.10.21273/HORTSCI.22.5.879Search in Google Scholar

Smith K.A., Mullins C.E. (1991): Soil Analysis: Physical Methods. Marcel Dekker, New York, 620 p.Search in Google Scholar

Smith M. (1991): CROPWAT Manual and Guidelines. FAO of UN, Rome.Search in Google Scholar

Snyder R.L., Bali K.M. (2012): Irrigation scheduling of alfalfa using evapotranspiration. In: Proceedings, 2008 California Alfalfa and Forage Symposium and Western Seed Conference, San Diego, CA, 2-4 December, 2008.Search in Google Scholar

Stancalie G., Marica A., Toulios L. (2010): Using earth observation data and CROPWAT model to estimate the actual crop evapotranspiration. Physics and Chemistry of the Earth 35, 25-30.10.1016/j.pce.2010.03.013Search in Google Scholar

Sys C. (1985): Land evaluation. State University of Ghent, International Training Centre for Postgraduate Soil Scientists, Parts 1, 11, and 111, Ghent.Search in Google Scholar

Van Genuchten M.Th., Leij F.J. (1992): On estimating the hydraulic properties of unsaturated soils. pp. 1-14. In: M.Th. Van Genuchten et al. (ed.) indirect methods for estimating the hydraulic properties of unsaturated soils. University of California, Riverside, CA.Search in Google Scholar