作物生长模型（CropGrow）研究进展

doi:10.3864/j.issn.0578-1752.2020.16.004

中国农业科学 ›› 2020, Vol. 53 ›› Issue (16): 3235-3256.doi: 10.3864/j.issn.0578-1752.2020.16.004

• 耕作栽培·生理生化·农业信息技术 • 上一篇下一篇

作物生长模型（CropGrow）研究进展

朱艳(),汤亮,刘蕾蕾,刘兵,张小虎,邱小雷,田永超,曹卫星()

南京农业大学/国家信息农业工程技术中心/智慧农业教育部工程研究中心/农业农村部农作物系统分析与决策重点实验室/江苏省信息农业重点实验室/江苏现代作物生产协同创新中心,南京 210095

收稿日期:2020-02-29 接受日期:2020-06-10 出版日期:2020-08-16 发布日期:2020-08-27
通讯作者: 曹卫星
作者简介:朱艳,E-mail：yanzhu@njau.edu.cn
基金资助:
国家杰出青年科学基金(31725020);国家自然科学基金(41961124008);国家自然科学基金(51711520319);国家自然科学基金(31872848);国家自然科学基金(31801260);国家自然科学基金(31571566);国家重点研发计划(2019YFA0607404)

Research Progress on the Crop Growth Model CropGrow

ZHU Yan(),TANG Liang,LIU LeiLei,LIU Bing,ZHANG XiaoHu,QIU XiaoLei,TIAN YongChao,CAO WeiXing()

Nanjing Agricultural University/National Engineering and Technology Center for Information Agriculture/Engineering Research Center of Smart Agriculture, Ministry of Education/Key Laboratory of Crop System Analysis and Decision Making, Ministry of Agriculture and Rural Affairs/Jiangsu Key Laboratory for Information Agriculture/Jiangsu Collaborative Innovation Center for Modern Crop Production, Nanjing 210095

Received:2020-02-29 Accepted:2020-06-10 Online:2020-08-16 Published:2020-08-27
Contact: WeiXing CAO

摘要/Abstract

摘要：

农业信息技术是基于信息技术与农业科学的交叉融合而形成的新兴技术,催生了数字农业和智慧农业的快速发展。作物生长模型作为其核心内容之一,可以动态模拟作物生长发育过程及其与气候因子、土壤特性和管理技术之间的关系,从而有效克服传统农业生产管理研究中较强的时空局限性,为不同条件下的作物生产力预测预警与效应评估等提供量化工具。本文重点介绍笔者团队在作物生长模型的构建与应用方面形成的总体技术方法、最新研究进展及未来发展思考。通过20多年系统深入的探索和实践,本团队以小麦、水稻等作物为主要对象,以“生理机制解析-模型算法构建-生产力动态预测-效应定量评估-模拟平台研发”为主线,综合运用系统分析、动态建模、虚拟现实、情景模拟及决策支持等方法,开展了作物生长模型CropGrow的构建与应用研究。首先,利用系统分析方法与动态建模技术,构建了机理性与预测性兼备的综合性作物生长模型（CropGrow）,包括阶段发育与物候期、器官发生与建成、光合生产与物质积累、同化物分配与产量品质形成、养分动态、水分平衡以及作物三维形态建成与虚拟显示等子模型,可数字化、可视化表征不同条件下作物生长发育与生产力形成过程;然后,结合地理信息系统（GIS）和遥感（RS）技术,构建了基于模型、GIS和RS有效耦合的区域作物生产力预测技术;进一步量化了气候变化、品种更新、土壤改良、措施优化对区域作物生产力形成的影响,拓展了适宜方案生成、理想品种设计、气候效应评估、耕地利用评价以及农业政策制定等应用技术;最后,运用构件化程序设计思想,基于作物生产数据库、作物模型构件库等,集成开发了基于模型的数字化、可视化作物生长模拟系统与决策支持平台,实现了数据管理、参数优化、生长模拟、遥感耦合、区域预测、方案设计、效应评估、安全预警、产品发布等综合功能。未来作物模拟研究将在完善基础数据库的基础上,进一步提升预测能力、量化基因效应、拓展智能决策、耦合多功能模型等,为粮食生产的预测预警、情景效应的量化评估、生产管理的智能决策、作物品种的优化设计等提供数字化支撑,对于保障国家粮食安全和推进数字农业发展具有重要意义。

关键词: 作物生长模型, 算法构建, 生产力预测, 效应评估, 决策支持, 系统平台, 数字农作

Abstract:

Agricultural information technology is formed as the result of integrating information technology and agricultural science, and has further facilitated the rapid development of digital agriculture (DA) and smart agriculture (SA). As one of the core technologies of DA and SA, crop growth model can dynamically simulate crop growth and development processes and their relationships with climate condition, soil characteristics and management strategy, so as to overcome the limitation of the spatial-temporal characteristics of traditional research on agricultural production management. It can provide powerful quantitative tools for crop productivity prediction and early warning and impact evaluation under different conditions. Through over 20-years systematic and profound exploration and practicing in wheat and rice crops, and based on the workflow of “physiological mechanism analysis-model algorithm development-dynamic productivity prediction-quantitative effect assessment-simulation platform development”, our research team has been devoted to the development and application of crop simulation model CropGrow, by integrating the technologies of system analysis, dynamic modeling, virtual reality, scenario simulation, and decision support. Firstly, based on the system analysis method and dynamic modeling technology, the comprehensive and mechanistic crop growth model CropGrow has been developed, including the submodels of phasic development and phenology, organ development and population establishment, photosynthetic production and biomass accumulation, assimilate partitioning and yield/quality formation, nutrient dynamics, and water balance, along with three-dimensional morphological and visual submodels, which could digitalize and visualize the processes of crop growth and productivity formation under different conditions. Further, by coupling geographic information system (GIS) and remote sensing (RS), the model-based regional crop productivity prediction technology has been established. Then, based on the scenario analysis, the contributions of climate change, soil improvement, variety updating, and strategy optimization to regional crop production have been quantified, and applications extended to generation of suitable management plan, design of ideal cultivar, assessment of climate impact, evaluation of land use and decision-making of agricultural policy. Finally, based on the component-based programming technology, a model-based digital and visual crop growth simulation system and decision support platform has been developed by integrating the crop production database and crop model components, further realizing the comprehensive functions of data management, parameter optimization, growth simulation, remote sensing coupling, regional prediction, management strategy design, effect evaluation, safety early warning and product release. In the future, based on the improvement of agro-information database, additional efforts in crop modeling will be made toward enhancing prediction ability, quantifying gene effects, developing intelligent decision-making, and coupling multiple models, which will provide digital support for the prediction and early warning of food production, quantitative evaluation of scenario effects, decision-making on management strategy, and optimal design of new crop cultivars, thus facilitating the security of national food and development of digital agriculture.

Key words: crop growth model, algorithm development, productivity prediction, impact assessment, decision support, system platform, digital farming

朱艳,汤亮,刘蕾蕾,刘兵,张小虎,邱小雷,田永超,曹卫星. 作物生长模型（CropGrow）研究进展[J]. 中国农业科学, 2020, 53(16): 3235-3256.

ZHU Yan,TANG Liang,LIU LeiLei,LIU Bing,ZHANG XiaoHu,QIU XiaoLei,TIAN YongChao,CAO WeiXing. Research Progress on the Crop Growth Model CropGrow[J]. Scientia Agricultura Sinica, 2020, 53(16): 3235-3256.

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作物生长模型（CropGrow）研究进展

Research Progress on the Crop Growth Model CropGrow

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