Decision Support System for Surface Irrigation Design
Publication: Journal of Irrigation and Drainage Engineering
Volume 135, Issue 3
Abstract
The SADREG decision support system was developed to help decision makers in the process of design and selection of farm surface irrigation systems to respond to requirements of modernization of surface irrigation—furrow, basin, and border irrigation. It includes a database, simulation models, user-friendly interfaces, and multicriteria analysis models. SADREG is comprised of two components: design and selection. The first component applies database information, and through several simulation and computational tools, produces a set of design alternatives in agreement with the user options. These alternatives are characterized by several hydraulic, economic, and environmental indicators that allow appropriate selection and ranking. The selection component bases upon multicriteria analysis using composite programming and ELECTRE II ranking models, which support the decision maker to select the best alternative. The decision maker participates in all decision processes through a user-friendly interface that allows expressing design options and priorities. SADREG was tested with data collected from field experiments. In addition to describing the modeling approach, an application to a sector of the Lower Mondego Irrigation Project, Portugal, is presented.
Get full access to this article
View all available purchase options and get full access to this article.
Acknowledgments
The support granted by the Agricultural Engineering Research Centre, Lisbon, is acknowledged.
References
Bazzani, G. M. (2005). “An integrated decision support system for irrigation and water policy design: DSIRR.” Environ. Modell. Software, 20(2), 153–163.
Bogardi, I., and Bardossy, A. (1983). “Application of MCDM to geological exploration.” Essays and surveys on multiple criteria decision making, P. Hansen, ed., Springer Verlag, New York.
Boonstra, J., and Jurriens, M. (1978). “BASCAD—A mathematical model for level basin irrigation.” ILRI Publication No. 43, Wageningen.
Burt, C. M., et al. (1997). “Irrigation performance measures: Efficiency and uniformity.” J. Irrig. Drain. Eng., 123, 423–442.
Camacho, E., Pérez, C., Roldán, J., and Alcalde, M. (1997). “IPE: Model for management and control of furrow irrigation in real time.” J. Irrig. Drain. Eng., 123(4), 264–269.
Clemmens, A. J. (1979). “Verification of the zero-inertia model for border-irrigation advance.” J. Irrig. and Drain. Div., 104(3), 339–341.
Clemmens, A. J. (2007). “Simple approach to surface irrigation design: Theory.” e-Journal of Land and Water, 1, 1–19, ⟨http://www.sakia.org/ejlw⟩.
Clemmens, A. J., Dedrick, A. R., and Strand, R., and (1993). “BASIN 2.0 for the design of level-basin systems.” Management of irrigation and drainage systems, R. G. Allen, ed., ASCE, New York, 875–882.
Criddle, W. D., Davis, S., Pair, C., and Shockley, D. (1956). Methods for evaluating irrigation systems, USDA SCS Agricultural Handbook No. 82.
Dedrick, A. R., Gaddis, R. J., Clark, A. W., and Moore, A. W., and (2007). “Land forming for irrigation.” Design and operation of farm irrigation systems, 2nd Ed., G. J. Hoffman, R. G. Evans, M. E. Jensen, D. L. Martin, and R. L. Elliot, eds., ASABE, St. Joseph, Mich., 320–346.
Elliott, R. L., Walker, W. R., and Skogerboe, G. V. (1982). “Zero inertia modeling of furrow irrigation advance.” J. Irrig. and Drain. Div., 108(3), 179–195.
Fangemeier, D. D., and Strelkoff, T. (1978). “Mathematical models and border irrigation design.” Trans. ASAE, 22(1), 93–99.
Gonçalves, J. M., and Pereira, L. S. (1999). “Design of sustainable on-farm surface irrigation systems with a decision support system.” Emerging technologies for sustainable land use and water management (CD-ROM), A. Musy, L. S. Pereira, and M. Fritsch, eds., Presses Polytechniques et Universitaires Romandes, Lausanne, Switzerland, Paper 8.10.
Gonçalves, J. M., Pereira, L. S., Fang, S. X., and Dong, B. (2007). “Modelling and multicriteria analysis of water saving scenarios for an irrigation district in the Upper Yellow River Basin.” Agric. Water Manage., 94(1–3), 93–108.
Hart, W. E., Collins, H. G., Woodward, G., and Humpherys, A. S. (1980). “Design and operation of gravity or surface systems.” Design and operation of farm irrigation systems, M. E. Jensen, ed., ASAE Monograph No. 3, St. Joseph, Mich., 501–580.
Hornbuckle, J. W., Christen, E. W., and Faulkner, R. D. (2005). “Use of SIRMOD as a quasi-real time surface irrigation decision support system.” A. Zerger, and R. M. Argent, eds., Proc., MODSIM 2005 Int. Congress on Modelling and Simulation, by Modeling and Simulation Society of Australia and New Zealand, December 2005, 217–223, ⟨http://www.mssanz.org.au/modsim05/papers/hornbuckle_1.pdf⟩,
Horst, M. G., Shamutalov, S. S., Gonçalves, J. M., and Pereira, L. S. (2007). “Assessing impacts of surge-flow irrigation on water saving and productivity of cotton.” Agric. Water Manage., 87, 115–127.
Janssen, R. (1992). Multiobjective decision support for environmental management, Kluwer, Dordrecht, The Netherlands.
Latimer, E. A., and Reddel, D. L. (1990). “A volume balance model for real time automated furrow irrigation system.” Visions of the future—Technology to enrich our environment, ASAE, St. Joseph, Mich., 13–20.
Mailhol, J. C., Ruelle, P., and Popova, Z. (2005). “Simulation of furrow irrigation practices (SOFIP): A field-scale modelling of water management and crop yield for furrow irrigation.” Interfaces, 24(1), 37–48.
McClymont, D. (1999). “FIDO v2: Furrow irrigation design optimiser.” Proc., Multiple Objective Decision Support Systems Conf., ⟨http://www.ncea.org.au/www/Irrigation/FIDO/Project_FIDO.htm⟩.
Mjeld, J. W., Lacewell, R. D., Talpaz, H., and Taylor, C. R. (1990). “Economics of irrigation systems.” Management of farm irrigation systems, G. F. Hoffman, T. A. Howell, and K. H. Solomon, eds., ASAE, St. Joseph, Mich., 461–493.
Oad, R., Garcia, L., Kinzli, K. D., and Patterson, D. (2006). “Decision support systems for efficient irrigated agriculture.” WIT transactions on ecology and the environment, Vol. 96, G. Lorenzini, and C. A. Brebbia, eds., WIT Press, Wessex, U.K., 247–256.
Oweis, T. Y., and Walker, W. R. (1990). “Zero-inertia model for surge flow furrow irrigation.” Irrig. Sci., 11(3), 131–136.
Pereira, L. S. (1999). “Higher performances through combined improvements in irrigation methods and scheduling: A discussion.” Agric. Water Manage., 40(2–3), 153–169.
Pereira, L. S., Oweis, T., and Zairi, A. (2002). “Irrigation management under water scarcity.” Agric. Water Manage., 57, 175–206.
Pereira, L. S., Teodoro, P. R., Rodrigues, P. N., and Teixeira, J. L. (2003). “Irrigation scheduling simulation: The model ISAREG.” Tools for drought mitigation in mediterranean regions. G. Rossi, A. Cancelliere, L. S. Pereira, T. Oweis, M. Shatanawi, and A. Zairi, eds., Kluwer, Dordrecht, The Netherlands, 161–180.
Pereira, L. S., and Trout, T. J. (1999). “Irrigation methods.” CIGR handbook of agricultural engineering, land and water engineering, Vol. I. H. N. van Lier, L. S. Pereira, and F. R. Steiner, eds., ASAE, St. Joseph, Mich., 297–379.
Pereira, L. S., Zairi, A., and Mailhol, J. C. (2006). “Irrigation de surface.” Traité d’irrigation, 2nd Ed., J. R. Tiercelin and A. Vidal, eds., Lavoisier, Paris, 513–549.
Pomerol, J. C., and Romero, S. B. (2000). Multicriterion decision in management: Principles and practice, Kluwer Dordrecht, The Netherlands.
Raju, K. S., and Duckstein, L. (2002). “Multicriterion analysis for ranking an irrigation system: An Indian case study.” J. Decision Systems, 11, 499–511.
Raju, K. S., Kumar, D. N., and Duckstein, L. (2006). “Artificial neural networks and multicriterion analysis for sustainable irrigation planning.” Comput. Oper. Res., 33(4), 1138–1153.
Rao, N. H., Brownee, S. M., and Sarma, P. B. (2004). “GIS-based decision support system for real time water demand estimation in canal irrigation systems.” Curr. Sci. India, 87, 5–10.
Reddy, J. M., and Clyma, W. (1981a). “Optimal design of border irrigation system.” J. Irrig. and Drain. Div., 17(3), 289–306.
Reddy, J. M., and Clyma, W. (1981b). “Optimal design of furrow irrigation systems.” Trans. ASAE, 24(3), 617–623.
Riesgo, L., and Gómez-Limón, J. A. (2006). “Multi-criteria policy scenario analysis for public regulation of irrigated agriculture.” Agric. Systems, 91, 1–28.
Roy, B. (1996). Multicriteria methodology for decision aiding, Kluwer, Dordrecht, The Netherlands.
Roy, B., and Bouyssou, D. (1993). Aide multicritère: Méthodes et cas, Economica, Paris.
Saaty, T. L. (1990). “How to make a decision: the AHP.” Eur. J. Oper. Res., 48(1), 9–26.
Soil Conservation Service (SCS). (1974). “Chapt. 4, Border Irrigation.” Soil conservation service national engineering handbook. Sect. 15, Irrigation, USDA Soil Conservation Service, Washington, D.C.
Soil Conservation Service (SCS). (1979). “Chap.5, Furrow Irrigation.” Soil conservation service national engineering handbook, Sect. 15, Irrigation, USDA Soil Conservation Service, Washington, D.C.
Solomon, K. H. (1984). “Yield related interpretations of irrigation uniformity and efficiency measures.” Irrig. Sci., 5(3), 161–172.
Solomon, K. H., El-Gindy, A. M., and Ibatullin, S. R. (2007). “Planning and system selection.” Design and operation of farm irrigation systems, 2nd Ed., G. J. Hoffman, R. G. Evans, M. E. Jensen, D. L. Martin, and R. L. Elliot, eds., ASABE, St. Joseph, Mich., 57–75.
Strelkoff, T. (1990). “SRFR. A computer program for simulating flow in surface irrigation furrows-basins-borders.” WC: Rep. 17, U.S. Water Conservation Laboratory, USDA/ARS, Phoenix.
Strelkoff, T., and Clemmens, A. J. (2007). “Hydraulics of surface systems.” Design and operation of farm irrigation systems, 2nd Ed., G. J. Hoffman, R. G. Evans, M. E. Jensen, D. L. Martin, and R. L. Elliot, eds., ASABE, St. Joseph, Mich., 436–498.
Strelkoff, T., Clemmens, A. J., Schmidt, B. V., and Slosky, E. J. (1996). “BORDER—A design and management aid for sloping border irrigation systems. Version 1.0.” WCL Rep. No. 21. USDA, ARS, USWCL, Phoenix, Ariz.
Strelkoff, T., and Katopodes, N. D. (1977). “Border irrigation with zero inertia.” J. Irrig. and Drain. Div., 103(3), 325–342.
Strelkoff, T., and Souza, F. (1984). “Modelling the effect of depth on furrow infiltration.” J. Irrig. Drain. Eng., 110(4), 375–387.
Walker, W. R. (1989). “Guidelines for designing and evaluating surface irrigation systems.” Irrigation and Drainage Paper No. 45, FAO, Rome, Italy.
Walker, W. R. (1998). “SIRMOD–Surface irrigation modeling software.” Utah State Univ., Logan, Utah.
Walker, W. R., and Humpherys, A. S. (1983). “Kinematic-wave furrow irrigation model.” J. Irrig. Drain. Eng., 109(4), 377–392.
Walker, W. R., and Skogerboe, G. V. (1987). Surface irrigation: Theory and practice, Prentice-Hall, Englewood Cliffs, N.J.
Wilke, O., and Smerdon, E. T. (1965). “A solution of the irrigation advance problem.” J. Irrig. and Drain. Div., 91(3), 23–24.
Yu, F. X., and Singh, V. P. (1989). “Analytical model for border irrigation.” J. Irrig. Drain. Eng., 115(6), 982–999.
Yu, F. X., and Singh, V. P. (1990). “Analytical model for furrow irrigation.” J. Irrig. Drain. Eng., 116(2), 154–171.
Information & Authors
Information
Published In
Copyright
© 2009 ASCE.
History
Received: Feb 27, 2008
Accepted: Oct 1, 2008
Published online: Jan 22, 2009
Published in print: Jun 2009
Authors
Metrics & Citations
Metrics
Citations
Download citation
If you have the appropriate software installed, you can download article citation data to the citation manager of your choice. Simply select your manager software from the list below and click Download.