Research status and development trends of water and fertilizer integration technology

doi:10.13733/j.jcam.issn.2095-5553.2025.03.042

Abstract

Abstract:

Water and fertilizer integration technology can effectively improve the utilization rate of agricultural resources and reduce surface pollution, which is one of the important ways to realize green agriculture. To promote the research innovation, popularization and application of water and fertilizer integration technology, and solve the actual problems. This paper describes the development history of water-fertilizer integration technology at home and abroad. It also describes the functions and characteristics of the system's water source engineering, control head, fertilizer applicators, field pipeline network. Compare the working principle and advantages and disadvantages of different fertilizer applicators. And analyzes the current research status and development dynamics of the current water-fertilizer integration equipment in terms of pipeline design, fertilizer applicator structure optimization, intelligent control algorithm improvement, enhancement of the level of intelligence, and improvement of the irrigation and fertilization system. It is found that the current supporting facilities for water-fertilizer integration technology, irrigation and fertilization system are not perfect, the model construction is difficult and cannot be used for actual production, and the performance of the fertilizer applicator still needs to be optimized. It also proposes to optimize the structure of the fertilizer applicator, strengthen the research on the water-fertilizer mixing law, and improve the performance of fertilizer application. Establish the irrigation and fertilization system and application guidance model according to the actual situation. Enhance the comprehensive performance of agricultural special sensors, apply new technologies, improve the intelligence level of waterfertilizer integration equipment, and realize the efficient use of water and fertilizer.

Key words: water and fertilizer integration technology, fertilizer applicator, development trends, structure optimization, control algorithm, fertilization and irrigation system

摘要：

水肥一体化技术可以有效提高农业资源利用率、减少面源污染，是实现绿色农业的重要途径之一。为剖析水肥一体化技术在种植中面临的实际问题，促进水肥一体化技术的研究创新与推广应用，通过阐述国内外水肥一体化技术的发展历程，系统介绍水肥一体化系统中水源工程、首部枢纽、施肥装置、田间管网及灌水器的功能及特点，对比不同施肥器的工作原理及优缺点，着重分析当前水肥一体化技术在优化装置结构、改进控制算法、建立指导模型、提升装备智能水平等方面的研究现状与发展动态。在此基础上，总结当前水肥一体化技术存在的配套设施、灌溉施肥制度不完善，模型构建困难且难以应用于实际生产，施肥器性能还有待优化等问题。提出后续应加强水肥混合规律研究，通过优化施肥器结构以提高施肥性能，结合地域特点完善灌溉施肥制度与指导模型，提升农业专用传感器的综合性能，加强新技术的融合与应用，促进水肥一体化装备的智能化升级，实现水肥的高效利用。

关键词: 水肥一体化技术, 施肥器, 发展动态, 结构优化, 控制算法, 施肥灌溉制度

CLC Number:

S275

Xia Wenhao, Jiang Yuan, Wang Xufeng, Zheng Xuan, Hu Can, Xing Jianfei. Research status and development trends of water and fertilizer integration technology[J]. Journal of Chinese Agricultural Mechanization, 2025, 46(3): 295-304.

夏文豪, 蒋媛, 王旭峰, 郑炫, 胡灿, 邢剑飞. 水肥一体化技术研究现状与发展动态[J]. 中国农机化学报, 2025, 46(3): 295-304.

References

［1］　国家统计局. 中国统计年鉴2024［M］. 北京: 中国统计出版社, 2024.
［2］　李华, 李秀英, 王磊, 等. “双碳”目标下肥料行业发展对策——基于2011—2020年碳减排与存在问题的分析［J］. 中国生态农业学报（中英文）, 2023, 31（2）: 206-213.
Li Hua, Li Xiuying, Wang Lei, et al. Development measures of the fertilizer industry under the carbon peaking and carbon neutrality goals: Analysis of carbon emission reduction and existing problems from 2011 to 2020 ［J］. Chinese Journal of EcoAgriculture, 2023, 31（2）: 206-213.
［3］　祝海燕, 李婷婷. 过量施肥对设施番茄影响的调查分析［J］. 中国瓜菜, 2020, 33（1）: 55-58.Zhu Haiyan, Li Tingting. Effect of excessive fertilization on facilities tomato ［J］. China Cucurbits and Vegetables, 2020, 33（1）: 55-58.
［4］　Zhang Y, Ye C, Su Y, et al. Soil acidification caused by excessive application of nitrogen fertilizer aggravates soilborne diseases: Evidence from literature review and field trials ［J］. Agriculture, Ecosystems and Environment, 2022, 340.
［5］　纪梦梦, 吴晓刚, 吴欣欣, 等. 过量施肥对设施菜田土壤菌群结构及N2O产生的影响［J］. 微生物学通报, 2018, 45（6）: 1323-1332.
Ji Mengmeng, Wu Xiaogang, Wu Xinxin, et al. Effect of overuse nitrogen fertilizer on bacterial community and N2O emission from greenhouse soil ［J］. Microbiology China, 2018, 45（6）: 1323-1332.
［6］　Albornoz F. Crop responses to nitrogen over fertilization: A review ［J］. Scientia Horticulturae, 2016, 205: 79-83.
［7］　Tei F, Neve D S, Haan D J, et al. Nitrogen management of vegetable crops ［J］. Agricultural Water Management, 2020, 240（1）: 106316.
［8］　张吉辉, 李健, 唐燕. 中国水资源与经济发展要素的时空匹配分析［J］. 资源科学, 2012, 34（8）: 1546-1555.
Zhang Jihui, Li Jian, Tang Yan. Analysis of the spatiotemporal matching of water resource and economic development factors in China ［J］. Resources Science, 2012, 34（8）: 1546-1555.
［9］　中华人民共和国水利部. 中国水资源公报2022［M］. 北京: 中国水利水电出版社, 2022.
［10］　中华人民共和国农业农村部. 农业部办公厅关于印发《推进水肥一体化实施方案（2016—2020年）》的通知［EB/OL］.http://wwwzzysmoagovcn/tzgg/201604/t20160422_6310
634htm, 2016-04-22.
［11］　中华人民共和国农业农村部. 农业农村部关于印发《到2025年化肥减量化行动方案》和《到2025年化学农药减量化行动方案》的通知［EB/OL］. http: //wwwmoagov
cn/govpublic/ZZYGLS/202212/t20221201_6416398htm,
2022-11-18.
［12］　中共中央国务院关于做好二二三年全面推进乡村振兴重点工作的意见［N］. 人民日报, 2023-02-14（1）.
［13］　Tal A. Rethinking the sustainability of Israels irrigation practices in the drylands ［J］. Water Research, 2016, 90（MAR1）: 387-394.
［14］　Postel S, Polak P, Gonzales F,et al. Drip irrigation for small farmers ［J］. Water International, 2001, 26（1）: 3-13.
［15］　潘文维. 温室生菜滴灌施肥技术研究［D］. 重庆: 西南农业大学, 2002.Pan Wenwei. Study on the fertilization of greenhouse lactuca sativa by drip irrigation ［D］. Chongqing: Southwest University, 2002.
［16］　高祥照, 杜森, 钟永红, 等. 水肥一体化发展现状与展望［J］. 中国农业信息, 2015（4）: 14-19, 63.
［17］　隋方功, 王运华, 长友诚, 等. 滴灌施肥技术对大棚甜椒产量与土壤硝酸盐的影响［J］. 华中农业大学学报, 2001（4）: 358-362.
［18］　冯先明, 王保明, 彭全, 等. 我国水溶肥的发展概况与建议［J］. 现代化工, 2018, 38（1）: 6-11.Feng Xianming, Wang Baoming, Peng Quan, et al. Development situation and suggestions on Chinas water soluble fertilizer ［J］. Modern Chemical Industry, 2018, 38（1）: 6-11.
［19］　尹飞虎. 中国北方旱区主要粮食作物滴灌水肥一体化技术［M］. 北京: 科学出版社, 2017.
［20］　徐卫红. 水肥一体化实用新技术［M］. 北京: 化学工业出版社, 2015.
［21］　刘思汝, 石伟琦, 马海洋, 等. 果树水肥一体化高效利用技术研究进展［J］. 果树学报, 2019, 36（3）: 366-384.
Liu Siru, Shi Weiqi, Ma Haiyang, et al. Advances in research on efficient utilization of fertigation in fruit trees ［J］. Journal of Fruit Science, 2019, 36（3）: 366-384.
［22］　魏正英, 葛令行, 赵万华, 等. 灌溉施肥自动控制系统的研究与开发［J］. 西安交通大学学报, 2008（3）: 347-349, 363.Wei Zhengying, Ge Lingxing, Zhao Wanhua, et al. Development of automatic control system of fertigation technique ［J］. Journal of Xian Jiaotong University, 2008（3）: 347-349, 363.
［23］　王永涛, 刘坚, 李家春, 等. 并联四文丘里管施肥器“旁路吸肥”模式性能分析［J］. 排灌机械工程学报, 2021, 39（9）: 959-965.
Wang Yongtao, Liu Jian, Li Jiachun, et al. Performance analysis of “bypass suction fertilizer” mode of parallel fourVenturi tube fertilizer applicator ［J］. Journal of Drainage and Irrigation Machinery Engineering, 2021, 39（9）: 959-965.
［24］　李坚, 刘云骥, 王丹丹, 等. 日光温室小型水肥一体灌溉机设计及其控制模型的建立［J］. 节水灌溉, 2017（4）: 87-91.
Li Jian, Liu Yunji, Wang Dandan, et al. Design of a small integrated water and fertilizer irrigation machine for solar greenhouse and its control model establishment ［J］. Water Saving Irrigation, 2017（4）: 87-91.
［25］　王海涛, 王建东, 杨彬, 等. 施肥机管路布置对文丘里施肥器吸肥性能的影响［J］. 排灌机械工程学报, 2019, 37（6）: 534-539.
Wang Haitao, Wang Jiandong, Yang Bin, et al, Effect of pipeline layout of fertilizer applicator on performance of Venturi injector ［J］. Journal of Drainage and Irrigation Machinery Engineering, 2019, 37（6）: 534-539.
［26］　张志洋, 李红, 陈超, 等. 溶解混施水肥一体化装置施肥性能试验研究［J］. 排灌机械工程学报, 2018, 36（11）: 1115-1119.
Zhang Zhiyang, Li Hong, Chen Chao, et al. Experiment on fertilization performance of dissolved and mixed waterfertilizer integrated device ［J］. Journal of Drainage and Irrigation Machinery Engineering, 2018, 36（11）: 1115-1119.
［27］　范兴科, 孔令阳. 文丘里施肥器能量转化关系［J］. 排灌机械工程学报, 2013, 31（6）: 528-533.
Fan Xingke, Kong Lingyang. Relationship of energy conversion for Venturi injector ［J］. Journal of Drainage and Irrigation Machinery Engineering, 2013, 31（6）: 528-533.
［28］　韩启彪, 黄兴法, 刘洪禄, 等. 6种文丘里施肥器吸肥性能比较分析［J］. 农业机械学报, 2013, 44（4）: 113-117, 136.
Han Qibiao, Huang Xingfa, Liu Honglu, et al. Comparative analysis on fertilization performance of six Venturi injectors ［J］.Transactions of the Chinese Society for Agricultural Machinery, 2013, 44（4）: 113-117, 136.
［29］　严海军, 初晓一, 王敏, 等. 微灌系统文丘里施肥器吸肥性能试验［J］. 排灌机械工程学报, 2010, 28（3）: 251-255, 264.
Yan Haijun, Chu Xiaoyi, Wang Min, et al. Injectjon performance of Venturi injector in microirrigation system ［J］. Journal of Drainage and Irrigation Machinery Engineering, 2010, 28（3）: 251-255, 264.
［30］　严海军, 初晓一. 喉管直径对文丘里施肥器性能影响的数值模拟［J］. 排灌机械工程学报, 2011, 29（4）: 359-363.
Yan Haijun, Chu Xiaoyi. Numerical simulation for influence of throat diameter on Venturi injector performance ［J］. Journal of Drainage and Irrigation Machinery Engineering, 2011, 29（4）: 359-363.
［31］　严海军, 陈燕, 初晓一, 等. 文丘里施肥器结构参数优化对吸肥性能的影响［J］. 排灌机械工程学报, 2013, 31（2）: 162-166, 179.
Yan Haijun, Chen Yan, Chu Xiaoyi, et al. Influence of optimization of structural parameters on injection performance of Venturi injector ［J］. Journal of Drainage and Irrigation Machinery Engineering, 2013, 31（2）: 162-166, 179.
［32］　刘永华, 沈明霞, 蒋小平, 等. 水肥一体化灌溉施肥机吸肥器结构优化与性能试验［J］. 农业机械学报, 2015, 46（11）: 76-81, 48.
Liu Yonghua, Shen Mingxia, Jiang Xiaoping, et al. Structure optimization of suction device and performance test of integrated water and fertilizer fertigation machine ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2015, 46（11）: 76-81, 48.
［33］　穆永航, 李莉, 孟繁佳, 等. 复合式吸肥装置结构设计与性能试验［J］. 农业机械学报, 2016, 47（S1）: 280-284.
Mu Yonghang, Li Li, Meng Fanjia, et al. Structure design and performance test of combined fertilizer absorption device ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2016, 47（S1）: 280-284.
［34］　杨大森, 李红, 骆志文. 活塞式比例施肥器性能对比试验［J］. 节水灌溉, 2015（11）: 47-50.
Yang Dasen, Li Hong, Luo Zhiwen. Working principle and performance test of the piston proportion fertilizer applicator ［J］. Water Saving Irrigation, 2015（11）: 47-50.
［35］　刘俊萍, 李吉鹏, 史永杰, 等. 水肥一体化灌溉装置蠕动泵结构优化［J］. 节水灌溉, 2021（2）: 70-74.
Liu Junping, Li Jipeng, Shi Yongjie, et al. Structure optimization of peristaltic pump in water fertilizer integrated irrigation device ［J］. Water Saving Irrigation, 2021（2）: 70-74.
［36］　Ma X, Zhang L, Wang W, et al. The shell shape optimization and fluidstructure interaction simulation of hose pump in waterfertilizer integrated fertilizer application ［J］. Scientific Reports, 2022, 12（1）:1-16.
［37］　周倩, 宁利中, 张淑芸, 等. 混合流体对流中扰动的成长［J］. 电网与清洁能源, 2011, 27（2）: 82-85.
Zhou Qian, Ning Lizhong, Zhang Shuyun, et al. Growth of perturbation in convection for binary fluid mixture ［J］. Power System and Clean Energy, 2011, 27（2）: 82-85.
［38］　李文宇, 王延军, 高飞, 等. 滞后系统的一种改进PID控制方法［J］. 自动化与仪器仪表, 2017（1）: 19-21.
［39］　王丽娟, 吕途, 马刚, 等. 基于模糊控制的水肥一体化控制策略［J］. 江苏农业科学, 2018, 46（23）: 238-241.
［40］　秦丽, 李兵. 一种基于云模型的不确定性数据的建模与分类方法［J］. 计算机科学, 2014, 41（8）: 233-240.
Qin Li, Li Bing. Novel method of uncertain data modeling and classification based on cloud model ［J］. Computer Science, 2014, 41（8）: 233-240.
［41］　李洪兴. 变论域自适应模糊控制器［J］. 中国科学E辑:技术科学, 1999（1）: 32-42.
［42］　孙文峰, 刘海洋, 王润涛, 等. 基于神经网络整定的PID控制变量施药系统设计与试验［J］. 农业机械学报, 2020, 51（12）: 55-64, 94.
Sun Wenfeng, Liu Haiyang, Wang Runtao, et al. Design and experiment of PID control variable application system based on neural network tuning ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2020, 51（12）: 55-64, 94.
［43］　屈毅, 宁铎, 赖展翅, 等. 温室温度控制系统的神经网络PID控制［J］. 农业工程学报, 2011, 27（2）: 307-311.
Qu Yi, Ning Duo, Lai Zhanchi, et al. Neural networks based on PID control for greenhouse temperature ［J］. Transactions of the Chinese Society of Agricultural Engineering, 2011, 27（2）: 307-311.
［44］　杨剑锋, 乔佩蕊, 李永梅, 等.机器学习分类问题及算法研究综述［J］. 统计与决策, 2019, 35（6）: 36-40.Yang Jianfeng, Qiao Perui, Li Yongmei, et al. A review of machinelearning classification and algorithms ［J］. Statistics & Decision, 2019, 35（6）: 36-40.
［45］　张磊, 魏正英, 张育斌, 等. 水肥混合液浓度检测交叉敏感抑制的研究［J］. 节水灌溉, 2017（9）: 85-87, 93.
Zhang Lei, Wei Zhengying, Zhang Yubin, et al. Study on crosssensitive inhibition of concentration detection in waterfertilizer mixtures ［J］. Water Saving Irrigation, 2017（9）: 85-87, 93.
［46］　皇甫立群. 基于改进B样条神经网络—PID控制器的温室温度控制技术［J］. 中国农机化学报, 2020, 41（7）: 68-74.
Huangfu Liqun. Temperature control technology of greenhouse based on improved B spline neural network—PID ［J］. Journal of Chinese Agricultural Mechanization, 2020, 41（7）: 68-74.
［47］　李颀, 马琳, 王康. 水肥一体化施肥机EC和pH改进自抗扰解耦控制［J］. 中国农机化学报, 2020, 41（2）: 161-170.
Li Qi, Ma Lin, Wang Kang.Improved autodisturbancerejection decoupling control for EC and pH of water and fertilizer integrated fertilizer applicator ［J］. Journal of Chinese Agricultural Mechanization, 2020, 41（2）: 161-170.
［48］　张育斌, 魏正英, 马胜利, 等. 灰色预测模糊PID灌溉控制技术开发［J］. 中国农村水利水电, 2016（2）: 5-8.Zhang Yubin, Wei Zhengying, Ma Shengli, et al. Grey prediction fuzzy PID control technology for irrigation ［J］. China Rural Water and Hydropower, 2016（2）: 5-8.
［49］　张育斌, 魏正英, 朱新国, 等. 精量水肥灌溉系统控制策略及验证［J］. 排灌机械工程学报, 2017, 35（12）: 1088-1095.
Zhang Yubin, Wei Zhengying, Zhu Xinguo, et al. Control strategy for precision waterfertilizer irrigation system and its verification ［J］. Journal of Drainage and Irrigation Machinery Engineering, 2017, 35（12）: 1088-1095.
［50］　李帅帅, 李莉, 穆永航, 等. 基于FuzzySmith控制器的营养液pH值调控系统研究［J］. 农业机械学报, 2017, 48（S1）: 347-352, 393.
Li Shuaishuai, Li Li, Mu Yonghang, et al. pH value control system of nutrient solution based on FuzzySmith controller ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2017, 48（S1）: 347-352, 393.
［51］　袁洪波, 李莉, 王俊衡, 等. 温室水肥一体化营养液调控装备设计与试验［J］. 农业工程学报, 2016, 32（8）: 27-32.
Yuan Hongbo, Li Li, Wang Junheng, et al. Design and test of regulation and control equipment for nutrient solution of water and fertilizer integration in greenhouse ［J］. Transactions of the Chinese Society of Agricultural Engineering, 2016, 32（8）: 27-32.
［52］　李天星. 陕西苹果补灌效应及灌溉需水量空间分布规律研究［D］. 杨凌: 西北农林科技大学, 2016.
Li Tianxing. Study on supplementary irrigation effects on, and spatial variations of irrigation requirements for apple in Shaanxi Province ［D］. Yangling: Northwest A & F University, 2016.
［53］　王淑君, 夏桂敏, 李永发, 等. 生物炭基肥和水分胁迫对花生产量、耗水和养分吸收的影响［J］. 水土保持学报, 2017, 31（6）: 285-290, 301.
Wang Shujun, Xia Guimin, Li Yongfa, et al. Water stress on peanut yield, water consumption and nutrition absorption ［J］. Journal of Soil and Water Conservation, 2017, 31（6）: 285-290, 301.
［54］　鲁剑巍, 邹娟, 周世利, 等. 施磷对越冬期高羊茅生长、养分吸收及抗寒性的影响［J］. 草地学报, 2008（5）: 436-441.
Lu Jianwei, Zou Juan, Zhou Shili, et al. Effect of phosphorus application amount on the growth, nutrient absorption, and coldresistance of tall fescue （festuca arundinacea schreb.） in winter ［J］. Acta Agrestia Sinica, 2008, 16（5）: 436-441.
［55］　邓庆玲, 崔宁博, 陈飞, 等. 滴灌脐橙产量和品质的水肥生产函数研究［J］. 干旱地区农业研究, 2023（5）: 80-88.
Deng Qingling, Cui Ningbo,Chen Fei, et al. Study on water and fertilizer production function for yield and quality of navel orange under drip irrigation ［J］. Agricultural Research in the Arid Areas, 2023（5）: 80-88.
［56］　马霄. 棉花膜下滴灌施肥水肥脉动性及施肥装置优化研究［D］. 石河子: 石河子大学, 2023.
Ma Xiao. Study on fertigation pulsatility and optimization of fertilization device for cotton undermembrane drip fertigation application ［D］. Shihezi: Shihezi University, 2023.
［57］　张海秀. 基于模型库的水肥决策支持系统的设计与实现［D］. 合肥: 安徽农业大学, 2020.
Zhang Haixiu. Design and implementation of water and fertilizer decision support system based on model base ［D］. Hefei: Anhui Agricultural University, 2020.
［58］　陈绍民. 水肥一体化水氮用量对苹果园氮素利用的影响及其供应决策［D］. 杨凌: 西北农林科技大学, 2022.
Chen Shaomin. Effects of water and nitrogen application amountunder fertigation on Nitrogen utilization and its supply decision in apple orchard ［D］. Yangling: Northwest A & F University, 2022.
［59］　孙一鑫, 马乐乐, 苗丽丽, 等. 基于光辐射时滞效应的温室番茄蒸腾量模型的构建［J］. 西北农林科技大学学报（自然科学版）, 2023, 51 （2）: 83-92.
Sun Yixin,Ma Lele, Miao Lili, et al. Construction of greenhouse tomato transpiration model based on light radiation timelag effect ［J］. Journal of Northwest A & F University（Natural Science Edition）, 2023, 51 （2）: 83-92.
［60］　沈忠健. 水肥一体化机分层灌溉装置及系统研发［D］. 广州：广州大学, 2023.
Shen Zhongjian. Research and development of layered irrigation device and system for water and fertilizer integration machine ［D］. Guangzhou: Guangzhou University, 2023.
［61］　卢超, 潘宏利, 卢进军, 等. 分布式无线自动浇灌系统的设计［J］. 中国农机化学报, 2019, 40（7）: 133-140.
Lu Chao, Pan Hongli, Lu Jinjun, et al. Design of distributed wireless automatic irrigation system ［J］. Journal of Chinese Agricultural Mechanization, 2019, 40（7）: 133-140.
［62］　赵燕东, 李宁, 皮婷婷. 土壤多参数复合测试系统研究［J］. 农业机械学报, 2015, 46（8）: 289-298.
Zhao Yandong, Li Ning, Pi Tingting. Multiparameter compounded testing system for soil ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2015, 46（8）: 289-298.
［63］　Chen Y, Tang Z, Zhu Y, et al. Miniature multilon sensor integrated with artificial neural network ［J］. IEEE Sensors Journal, 2021, 21（22）: 25606-25615.
［64］　熊钦, 肖丽萍, 蔡金平. 基于物联网的果园药水肥一体化控制系统设计与实现［J］. 中国农机化学报, 2023, 44（3）: 73-81.
Xiong Qin, Xiao Liping, Cai Jinping, et al. Design and implementation of integration of medicine, water and fertilizer control system based on internet of things in orchard ［J］. Journal of Chinese Agricultural Mechanization, 2023, 44（3）: 73-81.
［65］　石莹. 基于物联网技术的水肥一体化服务云平台［D］. 石家庄: 河北科技大学, 2019.
Shi Ying. Water and fertilizer integrated service cloud plat form based on internet of things technology ［D］. Shijiazhuang: Hebei University of Science & Technology, 2019.
［66］　张宝峰, 陈枭, 朱均超, 等. 基于物联网的水肥一体化系统设计与试验［J］. 中国农机化学报, 2021, 42（3）: 98-104.
Zhang Baofeng, Chen Xiao, Zhu Junchao, et al. Design and experiment of integrated water and fertilizer system based on Internet of Things ［J］. Journal of Chinese Agricultural Mechanization, 2021, 42（3）: 98-104.
［67］　江新兰, 杨邦杰, 高万林, 等. 基于两线解码技术的水肥一体化云灌溉系统研究［J］. 农业机械学报, 2016, 47（S1）: 267-272.
Jiang Xinlan, Yang Bangjie, Gao Wanlin, et al. Cloud computing irrigation system of water and fertilizer based on dualline decoding technology ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2016, 47（S1）: 267-272.
［68］　许澍. 基于GIS的水肥一体化智慧灌溉系统开发及应用研究［D］. 郑州: 华北水利水电大学, 2022.
Xu Shu. Development and application of intelligent irrigation system for fertigation based on GIS［D］. Zhengzhou: North China University of Water Resources and Electric Power, 2022.
［69］　Ha W, Gowda P H, Howell T A.A review of downscaling methods for remote sensingbased irrigation management: Part I ［J］.Irrigation Science, 2013, 31（4）:831-850.
［70］　Perea G R, Moreno M,Ortega J, et al. Dynamic simulation tool of fertigation in drip irrigation subunits ［J］. Computers and Electronics in Agriculture,2020,173（C）:105434.

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