An interval multiobjective approach considering irrigation canal system conditions for managing irrigation water

In order to consider irrigation canal system conditions in irrigation-water management, this study developed an interval multiobjective approach for helping irrigation-water managers solve the multiobjective problem under interval uncertainty in the process of allocating limited irrigation water. Ir...

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Published in:	Journal of cleaner production Vol. 211; pp. 293 - 302
Main Authors:	Zhang, Fan, Guo, Shanshan, Zhang, Chenglong, Guo, Ping
Format:	Journal Article
Language:	English
Published:	Elsevier Ltd 20.02.2019
Subjects:	Interval multiobjective programming Irrigation canal system conditions irrigation canals irrigation management irrigation water Irrigation water allocation regression analysis seepage topology Uncertainty watersheds Uncertainty Interval multiobjective programming Irrigation canal system conditions Irrigation water allocation
ISSN:	0959-6526, 1879-1786
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Abstract	In order to consider irrigation canal system conditions in irrigation-water management, this study developed an interval multiobjective approach for helping irrigation-water managers solve the multiobjective problem under interval uncertainty in the process of allocating limited irrigation water. Irrigation canal system conditions in this study mainly refer to canals distribution reflected by topological relations between canals and irrigation districts, and canals seepage estimated by multiple linear regression model. The proposed approach could address the conflicting objectives under interval uncertainty and help irrigation-water managers obtain more practical allocation schemes. This approach was applied to the middle reaches of Heihe River basin for allocating limited irrigation water among multiple irrigation districts (IDs) to demonstrate its applicability and practicality. Through the proposed approach, three different objectives were coordinated. These obtained results can not only display the amount of water allocated to each ID and canal but also show the amount of seepage from canals and field. From the optimized results, local water managers could obtain both better irrigation-water allocation scheme and find out the limited points of canals for IDs’ future development. Additionally, two comparisons illustrated that the results obtained by proposed approach are more practical than single objective with the same constraints and the interval multiobjective programming (IMP) model without considering canal system conditions in allocating irrigation water among IDs. This approach is valuable for improving the feasibility of optimal results in irrigation-water management, and it provides a possible way to take these important factors into account for related researches. •An interval multiobjective approach is developed considering irrigation canal system conditions.•The proposed approach can improve the practicality of the optimized schemes in practice.•This approach is applied to a case study for planning limited irrigation water.•The results offer operable allocation schemes for local irrigation-water managers to improve agricultural production ability.
AbstractList	In order to consider irrigation canal system conditions in irrigation-water management, this study developed an interval multiobjective approach for helping irrigation-water managers solve the multiobjective problem under interval uncertainty in the process of allocating limited irrigation water. Irrigation canal system conditions in this study mainly refer to canals distribution reflected by topological relations between canals and irrigation districts, and canals seepage estimated by multiple linear regression model. The proposed approach could address the conflicting objectives under interval uncertainty and help irrigation-water managers obtain more practical allocation schemes. This approach was applied to the middle reaches of Heihe River basin for allocating limited irrigation water among multiple irrigation districts (IDs) to demonstrate its applicability and practicality. Through the proposed approach, three different objectives were coordinated. These obtained results can not only display the amount of water allocated to each ID and canal but also show the amount of seepage from canals and field. From the optimized results, local water managers could obtain both better irrigation-water allocation scheme and find out the limited points of canals for IDs’ future development. Additionally, two comparisons illustrated that the results obtained by proposed approach are more practical than single objective with the same constraints and the interval multiobjective programming (IMP) model without considering canal system conditions in allocating irrigation water among IDs. This approach is valuable for improving the feasibility of optimal results in irrigation-water management, and it provides a possible way to take these important factors into account for related researches. •An interval multiobjective approach is developed considering irrigation canal system conditions.•The proposed approach can improve the practicality of the optimized schemes in practice.•This approach is applied to a case study for planning limited irrigation water.•The results offer operable allocation schemes for local irrigation-water managers to improve agricultural production ability. In order to consider irrigation canal system conditions in irrigation-water management, this study developed an interval multiobjective approach for helping irrigation-water managers solve the multiobjective problem under interval uncertainty in the process of allocating limited irrigation water. Irrigation canal system conditions in this study mainly refer to canals distribution reflected by topological relations between canals and irrigation districts, and canals seepage estimated by multiple linear regression model. The proposed approach could address the conflicting objectives under interval uncertainty and help irrigation-water managers obtain more practical allocation schemes. This approach was applied to the middle reaches of Heihe River basin for allocating limited irrigation water among multiple irrigation districts (IDs) to demonstrate its applicability and practicality. Through the proposed approach, three different objectives were coordinated. These obtained results can not only display the amount of water allocated to each ID and canal but also show the amount of seepage from canals and field. From the optimized results, local water managers could obtain both better irrigation-water allocation scheme and find out the limited points of canals for IDs’ future development. Additionally, two comparisons illustrated that the results obtained by proposed approach are more practical than single objective with the same constraints and the interval multiobjective programming (IMP) model without considering canal system conditions in allocating irrigation water among IDs. This approach is valuable for improving the feasibility of optimal results in irrigation-water management, and it provides a possible way to take these important factors into account for related researches.
Author	Guo, Shanshan Guo, Ping Zhang, Chenglong Zhang, Fan
Author_xml	– sequence: 1 givenname: Fan surname: Zhang fullname: Zhang, Fan – sequence: 2 givenname: Shanshan surname: Guo fullname: Guo, Shanshan – sequence: 3 givenname: Chenglong surname: Zhang fullname: Zhang, Chenglong – sequence: 4 givenname: Ping surname: Guo fullname: Guo, Ping email: guop@cau.edu.cn
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References_xml	– reference: Jamshid Mousavi S, Anzab NR, Asl-Rousta B, Kim JH. (2017). Multi-objective optimization-simulation for reliability-based inter-basin water allocation. Water Resour. Manag., 31(11), 3445-3464. DOI: – reference: Zhuang XW, Li YP, Nie S, Fan YR, Huang GH. (2018). Analyzing climate change impacts on water resources under uncertainty using an integrated simulation-optimization approach. J. Hydrol., 556, 523-538. DOI: – reference: Mao XM, Yao LQ, Feng SY, Wang YY. (2011). Numerical simulation on canal seepage and soil water distribution for concrete lining canal with layered soil structure. J. Hydraul. Eng., 42(8), 949-955. (in Chinese) – reference: Gui Z, Li M, Guo P. (2016). Simulation-based inexact fuzzy semi-infinite programming method for agricultural cultivated area planning in the shiyang river basin. J. Irrigat. Drain. Eng... 143(2). DOI: – reference: Li M, Guo P, Singh VP, Zhao J. (2016). Irrigation water allocation using an inexact two-stage quadratic programming with fuzzy input under climate change. J. Am. Water Resour. Assoc., 52(3), 667-684. DOI: – reference: Ministry of Water Resources, P.R.O.C. 2016. China Water Resources Bulletin. Beijing: China Water & Power Press. (in Chinese) – reference: Zimmermann HJ. (1978). Fuzzy programming and linear programming with several objective functions Fuzzy Set Syst., 1(1), 45-55. DOI: – year: 2013 ident: bib1 article-title: Bi-level multi-objective programming problem with fuzzy demands: a fuzzy goal programming algorithm publication-title: Opsearch – year: 2017 ident: bib22 article-title: Stochastic optimization model for water allocation on a watershed scale considering wetland's ecological water requirement publication-title: Ecol. Indic. – reference: Li M, Fu Q, Singh VP, Liu D. (2018). An interval multi-objective programming model for irrigation water allocation under uncertainty. Agr. Water Manage., 196, 24-36. 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Manag., 143(040170207). DOI: – reference: Tabari MMR, Mari MM. (2016). The integrated approach of simulation and optimization in determining the optimum dimensions of canal for seepage control. Water Resour. Manag., 30(3), 1271-1292. DOI: – reference: Zhang F, Li M, Guo S, Zhang C, Guo P. (2018b). Integrated uncertain models for runoff forecasting and crop planting structure optimization of the Shiyang River Basin, north-west China. Front. Agricul. Sci. Eng., 5(2). DOI: – reference: Hota PK, Chakrabarti R, Chattopadhyay PK. (2000). Economic emission load dispatch through an interactive fuzzy satisfying method. Electr. Pow. Syst. Res., 54(3), 151-157. DOI: – reference: Engelbert PJ, Hotchkiss RH, Kelly WE. (1997). Integrated remote sensing and geophysical techniques for locating canal seepage in Nebraska. J. Appl. Geophys., 38(2), 143-154. DOI: – reference: Chen S, Shao D, Tan X, Gu W, Lei C. (2017b). An interval multistage classified model for regional inter- and intra-seasonal water management under uncertain and nonstationary condition. Agr. Water Manage., 191, 98-112. DOI: – reference: Tan Q, Huang GH, Cai YP. (2013). Multi-source multi-sector sustainable water supply under multiple uncertainties: an inexact fuzzy-stochastic quadratic programming approach. Water Resour. Manag., 27(2), 451-473. DOI: – reference: Zhang C, Li M, Guo P. (2017). An interval multistage joint-probabilistic chance-constrained programming model with left-hand-side randomness for crop area planning under uncertainty. J. Clean. Prod., 167(20), 1276-1289. DOI: – reference: Tan Q, Zhang S, Li R. (2017). Optimal use of agricultural water and land resources through reconfiguring crop planting structure under socioeconomic and ecological objectives. Water-Sui, 9(7), 488. DOI: – reference: Chen S, Shao D, Gu W, Xu B, Li H, Fang L. (2017a). An interval multistage water allocation model for crop different growth stages under inputs uncertainty. Agr. Water Manage., 186, 86-97. DOI: – reference: Kinzli K, Martinez M, Oad R, Prior A, Gensler D. (2010). Using an ADCP to determine canal seepage loss in an irrigation district. Agr. Water Manage., 97(6), 801-810. DOI: – reference: Cui L, Li Y, Huang G. (2015). Planning an agricultural water resources management system: a two-stage stochastic fractional programming model. Sustain.-Basel, 7(8), 9846-9863. DOI: – reference: Zhang F, Zhang C, Yan Z, Guo S, Wang Y, Guo P. (2018c). An interval nonlinear multiobjective programming model with fuzzy-interval credibility constraint for crop monthly water allocation. Agr. Water Manage., 209(2018),123-133. 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Snippet	In order to consider irrigation canal system conditions in irrigation-water management, this study developed an interval multiobjective approach for helping...
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SubjectTerms	Interval multiobjective programming Irrigation canal system conditions irrigation canals irrigation management irrigation water Irrigation water allocation regression analysis seepage topology Uncertainty watersheds
Title	An interval multiobjective approach considering irrigation canal system conditions for managing irrigation water
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