Model Predictive Control of Irrigation Decisions Considering Moisture Sensitivity

doi:10.11924/j.issn.1000-6850.casb2024-0541

Abstract

Abstract:

In order to make full use of irrigation water resources and improve irrigation water production efficiency, this paper proposed a model predictive control irrigation decision-making method considering water sensitivity. This method first used the water sensitivity index of crops in each period and the Jensen model, and used the nonlinear programming method to determine the daily irrigation upper limit of each growth stage of crops. Then the irrigation upper limit was incorporated into the model predictive control (MPC) framework as a limiting condition to construct a MPC irrigation decision-making model considering water sensitivity. Summer corn simulation irrigation experiments were conducted in Yuanyang County, Henan Province by using three methods: conventional MPC decision-making, MPC decision-making in this article, and decision-making based on the Jensen model. The simulation experiment results showed that compared with the conventional MPC irrigation decision-making, although the yield of the MPC irrigation decision-making in this paper was somewhat reduced, it saved more irrigation water and improved irrigation water productivity. Compared with the decision-making based on the Jensen model, the MPC irrigation decision-making in this paper not only saved irrigation water, but also increased yield and significantly improved irrigation water production efficiency. The method in this article can further save water resources, enhance irrigation water production efficiency, and effectively serve smart irrigation of agricultural water.

Key words: Yuanyang County of Henan Province, irrigation decision, model predictive control, Jensen model, irrigation water production efficiency, water sensitivity

LIU Pai, ZHAO Dongbao, WEI Yichang, XIAO Lian. Model Predictive Control of Irrigation Decisions Considering Moisture Sensitivity[J]. Chinese Agricultural Science Bulletin, 2025, 41(7): 128-137.

Figures/Tables 7

References 20

[1]	时荣超, 郭文忠. 农业灌溉水资源优化配置研究进展[J]. 农业工程学报, 2024, 40(4):1-13.
[2]	GU Z, QI Z, BURGHATE R, et al. Irrigation scheduling approaches and applications: A review[J]. Journal of irrigation and drainage engineering, 2020(6):04020007.
[3]	MALVE S H, RAO P, DHAKE A. Evaluation of water production function and optimization of water for winter wheat (Triticum aestivum L.) under drip irrigation[J]. Ecology, environment and conservation, 2017, 23(1):416-424.
[4]	李中恺, 刘鹄, 赵文智. 作物水分生产函数研究进展[J]. 中国生态农业学报, 2018, 26(12):1781-1794.
[5]	STEWART J I, HAGAN R M, PRUITT W O, et al. Optimizing crop production through control of water and salinity levels in the soil[J]. Research centers,1977:67.
[6]	JENSEN M E. Water consumption by agricultural plants (Chapter 1). In: Water deficits and plants growth[M]. New York: Academic press, 1968.
[7]	STEDUTO P, HSIAO T C, RAES D, et al. AquaCrop-The FAO crop model to simulate yield response to water: I. Concepts and underlying principles[J]. Agronomy journal, 2009, 101(3):426-437.
[8]	王国重, 李中原, 张继宇, 等. 豫西黄土区夏玉米非充分灌溉制度研究[J]. 中国农学通报, 2022, 38(18):8-11. doi: 10.11924/j.issn.1000-6850.casb2021-0689
[9]	周梦林, 陈士彪, 赵学银, 等. 云南省洱海灌区水稻智能灌溉决策模型研究[J]. 节水灌溉, 2024(5):52-58. doi: 10.12396/jsgg.2023354
[10]	EMMANUEL A A, ZAINAL S M A, AZIMI S M M, et al. Model based predictive control strategy for water saving drip irrigation[J]. Smart agricultural technology, 2023,4
[11]	GABRIELA C, PABLO M, MARIO P, et al. Smart farm irrigation: model predictive control for economic optimal irrigation in agriculture[J]. Agronomy, 2021, 11(9):1810.
[12]	DELGODA D, MALANO H, SALEEM K S, et al. Irrigation control based on model predictive control (MPC): Formulation of theory and validation using weather forecast data and AQUACROP model[J]. Environmental modelling and software, 2016,78:40-53.
[13]	CHAO S, HAN W C, DUNCAN A S, et al. Robust model predictive control of irrigation systems with active uncertainty learning and data analytics[J]. IEEE transactions on control systems technology, 2019, 28(4):1-12.
[14]	MAO Y, LIU S, NAHAR J, et al. Soil moisture regulation of agro-hydrological systems using zone model predictive control[J]. Computers and electronics in agriculture, 2018,154:239-247.
[15]	ZHANG R, LIU A D, YU L, et al. Distributed model predictive control based on nash optimality for large scale irrigation systems[J]. IFAC PapersOnLine, 2015, 48(8):551-555.
[16]	ABIODUN E A, ZAINAL S M A, NAVEED M A, et al. A model predictive controller for precision irrigation using discrete lagurre networks[J]. Computers and electronics in agriculture, 2021,181.
[17]	刘傲, 赵东保, 魏义长, 等. 顾及时空特征的参考作物蒸散量集成学习估算[J]. 排灌机械工程学报, 2024, 42(2):179-186.
[18]	王延珺, 姬辰, 张海涛, 等. 成都平原主要作物有效降雨量不同时间尺度的计算分析[J]. 水电能源科学, 2022, 40(3):13-16.
[19]	范秀娟, 马东春. 北京市农业灌溉水分生产效率测算及分析(2013—2017年)[A].北京水问题研究与实践(2018年)[C].北京市水科学技术研究院, 2019:10.
[20]	刘丽, 张玉翠, 张小帅, 等. 北方缺水地区农业智慧灌溉应用与发展[J]. 农业工程, 2023, 13(10):78-83.

生育阶段	苗期	拔节期	抽雄期	灌浆期
作物敏感指数	0.025	0.129	0.173	0.082
作物系数/%	0.85	1.32	1.79	1.26

生育阶段	苗期	拔节期	抽雄期	灌浆期
作物敏感指数	0.025	0.129	0.173	0.082
作物系数/%	0.85	1.32	1.79	1.26

总供水量/mm	3种决策方法的灌溉总量/mm			3种决策方法的产量比(Y_a/Y_m)
总供水量/mm	Jensen模型决策	本研究的MPC决策	MPC决策	Jensen模型决策	本研究的MPC决策	MPC决策
318	318	253.3	318	0.973	0.984	0.997
260	260	214.5		0.952	0.966
200	200	184.5		0.920	0.948

总供水量/mm	3种决策方法的灌溉总量/mm			3种决策方法的产量比(Y_a/Y_m)
总供水量/mm	Jensen模型决策	本研究的MPC决策	MPC决策	Jensen模型决策	本研究的MPC决策	MPC决策
318	318	253.3	318	0.973	0.984	0.997
260	260	214.5		0.952	0.966
200	200	184.5		0.920	0.948

总供水量	本研究MPC决策	基于Jensen模型决策	常规MPC决策
318 mm	3.88	3.14	3.06
260 mm	4.51	3.66
200 mm	5.14	4.60