Abstract
Various indicators are used for evaluating the performance of different aspects of an irrigation system, and assessments also differ in terms of the types of performance indicators used. This paper describes a GIS-based assessment system which utilizes a new concept and evaluated the inadequacy of a widely used Relative Water Supply (RWS) concept to characterize the irrigation delivery performance for a rice irrigation system as the season advances. Development of this GIS-based assessment system resulted in the creation of new indicators, viz., the Rice Relative Water Supply (RRWS), Cumulative Rice Relative Water Supply (CRRWS) and Ponding Water Index (PWI). These indicators were determined from field tests and evaluated in a Malaysian Tanjung Karang Rice Irrigation Scheme (TAKRIS). The RWS concept was found to be inaccurate for characterizing the oversupply condition on irrigation deliveries for rice irrigation; and difficult to correctly quantify the oversupply condition for irrigation supplies. Besides, it was found that the RRWS indicator can distinctly characterize the oversupply condition for RRWS > 1.0 and undersupply condition for RRWS < 1.0 on irrigation delivery for any given period. A value of 1.0 for RRWS indicates an irrigation delivery that matches perfectly the actual field water demand. This study presents a cumulative RRWS plot that provides important information on irrigation supplies for any given time interval for management decisions. An increasing slope in the actual CRRWS curve with CRRWS = 1.0, means that irrigation supply can be slightly curtailed in the next period. On the other hand, if the slope is negative, supply has to be increased. If a computed CRRWS line follows the CRRWS = 1.0 line, it means that irrigation deliveries are perfectly matched with the field water demand. A graphical user-interface was developed for structuring the assessment tool within an ArcGIS platform. The system can instantly provide information on the uniformity of water distribution and the shortfall or excess, and provides vital information in terms of decisions that need to be made for the next period. The system helps to maintain continuous updating of input and output databases on real field conditions. Results are displayed on the computer screen together with color-coded maps, graphs and tables in a comprehensible form. The system is likely to be adopted for evaluating various water allocation scenarios and water management options. It can also be used as an analytical and operational tool for irrigation managers.
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References
Abernethy CL, Pearce GR (1987) Research needs in third world irrigation. Hydraulics Research Limited, Wallingford
Amor VMI, Ashim DG, Loof R (2002) Application of GIS and crop growth models in estimating water productivity. J Agric Water Manag 54:205–225
Anbumozhi V, Yamaji T, Tabuchi T (1998) Rice crop growth and yield as influenced by changes in standing water depth, water regime and fertigation level. J Agric Water Manag 37:241–253
Bhuiyan SI, Sattar MA, Khan MAK (1995) Improving water use efficiency in rice irrigation through wet seeding. Irrigat Sci 16:1–8
Bos MG, Murray-Rust DH, Merrey DJ, Johnson HG, Snellen WB (1994) Methodologies for assessing performance of irrigation and drainage management. Irrig Drain Syst 7:231–261
Bos MG, Nugteren J (1982) On irrigation efficiencies, International Institute for Land and Reclamation and Improvement. ILRI Publication No. 19, 3rd Edition, Wageningen, the Netherlands
Chakraborti AK, Rao VV, Shanker M, Suresh BAV (2002) Performance evaluation of an irrigation project using satellite remote sensing GIS and GPS. In: proceeding of the 5th Annual International Conference: Map India 2002, 6–8 February, Taj Palace Hotel, New Delhi, India
Chan CS, Cheong AW (2001) Seasonal water effects on crop evapotranspiration and rice yield. J Trop Agr Food Sci 29:77–92
De Datta SK (1981). Principles and practices of rice production. Los Baños, Philippines: International Rice Research Institute. p 618
De Datta SK, Williams A (1968) Rice cultural practices: Effects of water management practices on the growth characteristics and grain yield of rice. In: Proceedings and papers, fourth seminar on economic and social studies. IRRI, Los Banos, Philipine, pp 78–93
DID & JICA (1998) The study on modernization of irrigation water management system in the granary area of Peninsular Malaysia, Draft Final Report, Volume –II, Annexes, March 1998, Japan International Cooperation Agency
Fortes PS, Platonov AE, Pereira LS (2005) GISAREG—A GIS based irrigation scheduling simulation model to support improved water use. J Agric Water Manag 77:159–179
Francois M, Pongput K (1997) NAGA- A GIS based software for the monitoring and diagnosis of irrigation projects. Special Issue on RS and GIS, Information Techniques for Irrigation Systems (ITIS), International Irrigation management Institute (IIMI), Colombo, Sri Lanka, 4:23–25
George BA, Raghuwanshi NS, Singh R (2004) Development and testing of a GIS integrated irrigation scheduling model. J Agric Water Manag 66:221–237
Hassan SMH (2005) Estimation of Rice Evapotranspiration in Paddy Fields Using Remote Sensing and Field Measurements. PhD Thesis, Faculty of Engineering, Universiti Putra Malaysia
IRRI (1977) Annual Report for 1977. International Rice Research Institute, Los Banos
Knox JW, Weatherhead EK (1999) The application of GIS to irrigation water resources management in England and Wales. Geogr J 165(1):90–98
Levin G (1982) Relative water supply: An explanatory variable for irrigation systems, Technical report no. 6, Cornell University, New York
Molden DJ, Sakthivadivel R, Perry CJ, Fraiture C (1998) Indicators for comparing performance irrigation agricultural system. Research_Report 20. Colombo, Sri Lanka: IWMI
Moya TB, Walter MF (1988) Irrigation system operations intensity and relative water supply: The Asian Case. Water Management Synthesis Report No. 22. Logan, UT: Utah State University
Nihal F (1992) Monitoring irrigation water delivery performance: The concept of Cumulative Relative Water Supply (CRWS). In: Proceedings of an International Conference on Advances in Planning, Design, and Management of Irrigation Systems as related to Sustainable Land Use, Katholic Universiteit Leuven, Belgium, pp 525–534
Oad R, Podmore TH (1988) Irrigation management in rice-based agriculture: concept of relative water supply. ICID Bulletin 38(1):1–12
Pervez MS, Hoque MA (2002) Interactive Information System for Irrigation Management. http://www.codata.org/codata02/. Accessed on 16 January 2010
Plusquellec H, Burt C, Wolter HW (1994) Modern water control in irrigation. World Bank Technical Paper no. 246—irrigation and drainage series, Washington DC
Rao PS (1993) Review of selected literature on indicators of irrigation performance. IIMI Research Paper
Rao NH, Brownee SM, Sarma PBS (2004) GIS-based decision support system for real time water demand estimation in canal irrigation systems. Curr Sci 87:628–636
Renault D, Hemakumra HM (1997) GIS for irrigation systems management: Sri Lanka experience. Special Issue on RS and GIS, Information Techniques for Irrigation Systems (ITIS), International Irrigation management Institute (IIMI), Colombo, Sri Lanka, 4:25–28
Rowshon MK, Kwok CY, Lee TS (2003) GIS-based scheduling and monitoring of irrigation delivery for rice irrigation system-Part II: monitoring. Agric Water Manag 117:117–126
Sakthivadivel R, Thiruvengadachari S, Mutuwatte L (1997) Performance analysis of a wheat-based irrigation system using SRS and GIS techniques: A case study from India. Special Issue on RS and GIS, Information Techniques for Irrigation Systems (ITIS), International Irrigation management Institute (IIMI), Colombo, Sri Lanka, 4:9–11
Sakthivadivel R, Douglas JM, Nihal F (1993) Cumulative relative water supply: a methodology for assessing irrigation system performance. Irrig Drain Syst 7:43–67
Salman A, Chemin Y, Samia A (1997) Using GIS and RS to monitor and evaluate irrigation and drainage projects. Special Issue on RS and GIS, Information Techniques for Irrigation Systems (ITIS), International Irrigation management Institute (IIMI), Colombo, Sri Lanka, 4:19-20
Srinivas D (1995) Satellite remote sensing and GIS application in diagnostic analysis of Bhadara Command Area. Cited from: Satellite remote sensing for assessment of irrigation system performance: A case study of India. Thiruvengadachi, S. and Sakthivadivel, R., IIMI, Sri Lanaka
Tsihrintzis VA, Hamid R, Fuentes HR (1996) Use of geographic information systems (GIS) in water resources: a review. Water Resour Manag 10:251–257
Vidhya R, Karmegam M, Venugopal K (2002) GIS based diagnostic analysis of irrigation system performance assessment of Bhadra command area at disaggregated level. Proceedings of the 5th Annual International Conference, Map India 2002, 6–8 February 2002, Taj Palace Hotel, New Delhi, pp 223–228
Weller JA (1991) An evaluation of the Porac irrigation system. Irrig Drain Syst 5:1–17
Acknowledgements
We gratefully acknowledge the financial support from IRPA (Intensified Research in Priority Areas) grant for Project No. 01-02-04-0070-EA001-54016 under MOSTE (Ministry of Science, Technology and Environment, Malaysia), and technical assistance by staff of the Tanjung Karang Irrigation Scheme and Integrated Agricultural Development Authority (IADA), Tanjung Karang, Selangor, Malaysia.
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Rowshon, M.K., Amin, M.S.M. & Shariff, A.R.M. GIS user-interface based irrigation delivery performance assessment: a case study for Tanjung Karang rice irrigation scheme in Malaysia. Irrig Drainage Syst 25, 97–120 (2011). https://doi.org/10.1007/s10795-011-9115-0
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DOI: https://doi.org/10.1007/s10795-011-9115-0