智慧灌溉大数据管理平台设计与应用
收稿日期: 2023-12-08
录用日期: 2024-01-19
网络出版日期: 2024-04-08
基金资助
中国农业科学院科技创新工程项目(CAAS-ASTIP-2023-AII)
Design and Application of Smart Irrigation Big Data Management Platform
Received date: 2023-12-08
Accepted date: 2024-01-19
Online published: 2024-04-08
以粗放型为主的漫灌方式浪费水资源,探索高效节水农业灌溉意义重大。本研究研制了集数据采集、数据管理、数据可视化、分析决策和远程管理为一体的智慧灌溉大数据管理平台,旨在以数字化管理与智能化控制方式提升水资源利用效率。平台利用嵌入式、物联网、互联网、3S(GIS、GPS、RS)等技术,采取“1+1+N”的设计模式,构建作物需水预报模型与灌溉决策模型,基于B/S构架和Java语言,设计了1个灌溉数据中心、1个灌溉数据管理系统、4个应用系统,打造了智慧灌溉大数据管理平台。平台在河北、河南、山东、江苏等地区设有多个示范基地,汇聚了8个科研小组、24个试验基地的有关多种作物的生长、灌溉、气象、土壤等数据,平均采集数据18829条/天,帮助管理人员摸清家底;集成了多个团队的软件系统和62套物联网设备,及时、定量地呈现了农作物生长状况及环境状态,实现了农作区动态监测,助力生产决策;生成农作物需水预报和灌溉决策方案,完成了远程灌溉目标,并且经过实地试验,验证了自动灌溉的有效性,将灌溉水有效利用系数最高提升了31%以上;形成了大田产业、温室中心、数字科研和区域灌溉等不同专题可视化布局,满足多种农业场景应用需求。为农业生产和跨区域管理提供了便捷工具,为农业灌溉数字化系统搭建和应用提供了参考。
张杰, 黄仲冬, 梁志杰, 李世娟, 刘升平 . 智慧灌溉大数据管理平台设计与应用[J]. 农业大数据学报, 2024 , 6(1) : 82 -93 . DOI: 10.19788/j.issn.2096-6369.000007
Predominantly extensive flood irrigation method leads to wastage of water resources. Therefore, exploring efficient and water-saving agricultural irrigation methods is crucial. This study has developed an intelligent irrigation big data management platform that integrates data collection, management, visualization, analysis, decision-making, and remote management. Its goal is to improve water resource utilization efficiency through digital management and intelligent control. The platform utilizes embedded systems, the Internet of Things(IoT), and Internet technologies, as well as "3S" (GIS, RS, and GPS) technology. It follows the design model of "1+1+N" and includes the construction of a crop water requirement forecasting model, an irrigation decision-making model, an irrigation data center, an irrigation data management system, and four application systems. The entire platform is based on the B/S architecture and programmed using the Java language. The platform has been successfully implemented in several demonstration bases across regions such as Hebei, Henan, Shandong, Jiangsu, etc. It has gathered data on the growth, irrigation, weather, soil, and other aspects of various crops from 8 research teams and 24 experimental bases. On average, it collects 18 829 pieces of data per day, helping management personnel understand the overall situation. It integrates software systems from multiple teams and 62 sets of IoT devices to present the growth and environmental status of crops in a timely and quantitative manner, achieving dynamic monitoring of agricultural areas and assisting production decisions. It has also generated crop water demand forecasts and irrigation decision-making plans, accomplished remote irrigation targets, and through field experiments, validated the effectiveness of automatic irrigation, increasing the irrigation water utilization efficiency by more than 31% at its highest. The platform meets the application needs of different agricultural scenarios through thematic visualizations such as field industry, greenhouse center, digital scientific research, and regional irrigation. The smart irrigation big data management platform serves as a convenient tool for agricultural production and cross-regional management. Its construction and application provide valuable references for the development of digital agricultural irrigation systems.
Key words: smart irrigation; big data; crop water requirement forecasting; platform design; IoT
| [1] | UN WATER. Sustainable Development Goal 6 synthesis report on water and sanitation[M]. New York: The United Nations New York, 2018, 10017. |
| [2] | 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, 2023. |
| [3] | YANG L, HENG T, YANG G, et al. Analysis of factors influencing effective utilization coefficient of irrigation water in the Manas River Basin. Water, 2021, 13(2):189. https://doi.org/10.3390/w13020189. |
| [4] | 张亮, 周薇, 李道西. 农业高效节水灌溉模式选择研究进展[J]. 排灌机械工程学报, 2019, 37(5):447-453. |
| [5] | BWAMBALE E, ABAGALE F K, ANORNU G K. Smart irrigation monitoring and control strategies for improving water use efficiency in precision agriculture: A review[J]. Agricultural Water Management, 2022, 260:107324. https://doi.org/10.1016/j.agwat.2021.107324. |
| [6] | 袁紫晋, 毛克彪, 曹萌萌, 等. 国内外农业大数据发展的现状与存在的问题[J]. 中国农业信息, 2021, 33(3):1-12. |
| [7] | 综述:缺水国家以色列的“指尖”节水农业[EB/OL]. (2022-03-22) [2023-12-17]. http://www.xinhuanet.com/tech/2022-03/22/c_1128492406.htm. |
| [8] | Irrigation & Water Use[EB/OL]. (2023-09-08)[2023-12-17]. https://www.ers.usda.gov/topics/farm-practices-management/irrigation-water-use/. |
| [9] | 康绍忠. 贯彻落实国家节水行动方案推动农业适水发展与绿色高效节水[J]. 中国水利, 2019(13):1-6. |
| [10] | 国家统计局. 第三次全国农业普查主要数据公报(第五号)[EB/OL]. (2017-12-16)[2023-11-08]. http://www.stats.gov.cn/sj/tjgb/nypcgb/qgnypcgb/202302/t20230206_1902105.html. |
| [11] | 中华人民共和国国务院. 国务院关于印发“十四五”数字经济发展规划的通知[EB/OL]. (2022-01-12)[2023-11-08]. https://www.gov.cn/zhengce/zhengceku/2022-01/12/content_5667817.htm. |
| [12] | 陆红飞, 王涛, 乔冬梅, 等. 物联网在农业灌溉中的应用:从灌溉自动化到智慧灌溉[J]. 灌溉排水学报, 2023, 42(1):87-99. |
| [13] | OBAIDEEN K, YOUSEF B A, AlMALLAHI M N, et al. An overview of smart irrigation systems using IoT[J/OL]. Energy Nexus, 2022:100124. https://doi.org/10.1016/j.nexus.2022.100124. |
| [14] | GAMAL Y, SOLTAN A, SAID L A, et al. Smart irrigation systems: Overview[J/OL]. IEEE Access, 2023. https://doi.org/10.1109/ACCESS.2023.3251655. |
| [15] | 沈建炜, 李林, 魏新华. 丘陵地区蓝莓园智能灌溉决策系统设计[J]. 农业机械学报, 2018, 49(S1):379-386. |
| [16] | 付少华, 兰壬庚, 李伟, 等. 智慧农业灌溉系统的设计与实现[J]. 节水灌溉, 2022(2):71-74. |
| [17] | 鲁旭涛, 张丽娜, 刘昊, 等. 智慧农业水田作物网络化精准灌溉系统设计[J]. 农业工程学报, 2021, 37(17):71-81. |
| [18] | WaterBit Uses AT&T Connectivity in Smart Irrigation Solution[EB/OL]. (2018-01-23)[2023-12-17]. https://about.att.com/story/waterbit_attconnectivity.html. |
| [19] | Phytech Plant-Based Irrigation[EB/OL]. (2022-01-31)[2023-12-17]. https://www.aginfo.net/report/52017/Farm-of-the-Future/Phytech-Plant-Based-Irrigation. |
| [20] | ROY S K, MISRA S, RAGHUWANSHI N S. AgriSens: IoT-based dynamic irrigation scheduling system for water management of irrigated crops[J]. IEEE Internet of Things Journal, 2020, 8(6): 5023-5030. https://doi.org/10.1109/JIOT.2020.3036126. |
| [21] | TACE Y, TABAA M, ELFILALI S, et al. Smart irrigation system based on IoT and machine learning[J]. Energy Reports, 2022, 8: 1025-1036. https://doi.org/10.1016/j.egyr.2022.07.088. |
| [22] | 许海婷, 黄娟萍, 朱永华, 等. 淮北平原冬小麦土壤含水率时空特征分析[J]. 灌溉排水学报, 2021, 40(7):1-8. |
| [23] | 张杰, 王川, 董晓霞, 等. 基于裂变模式的农业农村信息快速调查及分析平台开发与应用[J]. 中国农业科学, 2022, 55(21):4158-4174. |
| [24] | 刘钰, 汪林, 倪广恒, 等. 中国主要作物灌溉需水量空间分布特征[J]. 农业工程学报, 2009, 25(12):6-12. |
| [25] | ALLEN R G, PEREIRA L S, RAES D. Crop evapotranspiration- guidelines for computing crop water requirements-FAO Irrigation and drainage paper 56[Z]. 1998: 300, D5109. |
| [26] | 宋妮, 孙景生, 王景雷, 等. 基于Penman修正式和Penman-Monteith公式的作物系数差异分析[J]. 农业工程学报, 2013, 29(19):88-97. |
| [27] | KUMAR R, JAT M K, SHANKAR V. Methods to estimate irrigated reference crop evapotranspiration-a review[J]. Water Science and Technology, 2012, 66(3):525-535. https://doi.org/10.2166/wst.2012.191. |
| [28] | PEREIRA L S, ALLEN R G, SMITH M, et al. Crop evapotranspiration estimation with FAO56: Past and future[J]. Agricultural Water Management, 2015, 147:4-20. https://doi.org/10.1016/j.agwat.2014.07.031. |
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