Earth Observation-Driven Digital (Smart) Agriculture: Research Frontiers and Application Cases

doi:10.12133/j.smartag.SA202512027

Smart Agriculture ›› 2026, Vol. 8 ›› Issue (2): 1-17.doi: 10.12133/j.smartag.SA202512027

• Topic--Multi-source Remote Sensing Driven Digital Agriculture Innovation and Practice •

Earth Observation-Driven Digital (Smart) Agriculture: Research Frontiers and Application Cases

WU Bingfang¹(), MA Hui¹^,², ZHANG Miao¹^,², PAN Qingcheng¹^,², ZHANG Xiang³^,⁴, CHEN Shuisen⁵, QIU Bingwen⁶, XU Xingang⁷, LIU Jianhong⁸, FAN Jinlong⁹, HUANG Jianxi¹⁰^,¹¹, JIANG Jiale¹², HE Changchui¹³

^1. State Key Laboratory of Remote Sensing and Digital Earth, Aerospace Information Research Institute, Chinese Academy of Sciences, Beijing 100101, China
^2. College of Resources and Environment, University of Chinese Academy of Sciences, Beijing 101408, China
^3. National Engineering Research Center of Geographic Information System, School of Geography and Information Engineering, China University of Geosciences, Wuhan 430074, China
^4. Hubei Luojia Laboratory, Wuhan 430079, China
^5. GuangDong Engineering Technology Research Center of Remote Sensing Big Data Application, Guangzhou Institute of Geography, Guangdong Academy of Sciences, Guangzhou 510070, China
^6. Key Laboratory of Spatial Data Mining & Information Sharing of Ministry of Education, Academy of Digital China (Fujian), Fuzhou University, Fuzhou 350116, China
^7. Key Laboratory of Quantitative Remote Sensing in Agriculture of Ministry of Agriculture and Rural Affairs, Information Technology Research Center, Beijing Academy of Agriculture and Forestry Sciences, Beijing 100097, China
^8. College of Urban and Environmental Sciences, Northwest University, Xi'an 710127, China
^9. Faculty of Geographical Science, Beijing Normal University, Beijing 100875, China
^10. Faculty of Geosciences and Engineering, Southwest Jiaotong University, Chengdu 611756, China
^11. College of Land Science and Technology, China Agricultural University, Beijing 100083, China
^12. Guangdong Province Data Center of Terrestrial and Marine Ecosystems Carbon Cycle, School of Atmospheric Sciences, Sun Yat-sen University, Zhuhai 519082, China
^13. Former Food and Agriculture Organization of the United Nations (FAO), Rome 00153, Italy

Received:2025-12-29 Online:2026-03-30
Foundation items:National Natural Science Foundation of China(42461144211); Key Project of Guangzhou Science and Technology Plan(2025B03J0067)
corresponding author:
WU Bingfang, E-mail: wubf@aircas.ac.cn

Abstract

Abstract:

[Significance] Digital agriculture is unequivocally the core driving force for modern agricultural transformation, fundamentally aiming to achieve full-process digital mapping and intelligent management of production through the deep integration of advanced information technologies such as the Internet of Things, big data, artificial intelligence (AI), and remote sensing, with earth observation (EO) technology serving as the essential data engine providing indispensable spatial information support for this systemic shift. However, the current landscape of digital agriculture development remains unbalanced, exhibiting a tendency to be "heavy on transactions and light on production", where the core production links suffer from low digitalization penetration rates; furthermore, the profound knowledge embedded within the vast corpus of EO data has yet to be fully extracted and interpreted, leading to a situation where many established algorithms demonstrate insufficient robustness and universality when confronted with the complexity and diversity of global cropping systems, thereby limiting their practical efficacy. Crucially, an over-reliance on technology to optimize production efficiency alone, without ecological guidance, can induce secondary environmental risks, such as exacerbating regional groundwater depletion or contributing to a decline in biodiversity through agricultural landscape simplification, thus necessitating an approach that promotes the deep coupling of EO technology with agronomic principles and local ecological practices to construct a resilient smart agricultural system that achieves a holistic balance between productivity, resource efficiency, and ecological integrity. [Progress] The current research frontiers of EO-driven digital agriculture primarily converge on three critical domains: intelligent crop condition monitoring, digital twin farming systems, and the enhancement of agricultural system resilience. Intelligent monitoring utilizes the fusion of high-resolution remote sensing imagery and machine learning frameworks to enable large-scale, comprehensive crop mapping and the fine-grained identification of crop types at the field scale, with next-generation yield prediction models integrating advanced deep learning techniques to significantly improve accuracy, while remote sensing is also effectively employed for agricultural disaster monitoring. The digital twin farming system represents an advanced stage of precision agriculture, centered on digitally modeling all agricultural production elements to construct a highly consistent virtual replica of the physical environment, operating through a real-time closed-loop mechanism of perception, simulation and analysis, and decision-making support to guide optimal interventions; successful applications include intelligent water resource scheduling in Chinese irrigation districts and the use of AI vision algorithms to manage complex biological processes like crab farming, although the field must overcome the issue of "pseudo-twins" that focuses on mere visualization rather than driving concrete operational decisions. The focus on agricultural system resilience is supported by digital agriculture providing crucial spatial data on global crop yields, cultivated land distribution, and practices like terracing. To illustrate the practical efficacy of these technologies, this paper analyzes two representative application cases. First, the CropWatch system represents a paradigm shift in agricultural monitoring by constructing a "Cloud-Edge" collaborative ecosystem. It integrates machine learning with a "Pre-training, Prompting, and Fine-tuning" large language model (LLM) framework to automate remote sensing-based crop monitoring, report generation and enhance decision-support intelligence. Through open application programming interfaces (APIs) and multi-scale capabilities, CropWatch provides cross-scale information and decision support from macro-level policy support to micro-level farm management, serving as a global public good that bridges the digital divide in developing nations. Second, in the domain of agricultural water management, the ETWatch technical system demonstrates a robust solution for the precise governance of water resources. By achieving high-resolution evapotranspiration (ET) monitoring from basin to field scales, it enables the accurate assessment of water productivity and the optimization of irrigation schedules. Crucially, this technology is successfully embedded into institutional mechanisms, such as water rights allocation and tiered pricing based on actual consumption, thereby realizing a transformation from empirical water use to data-driven, precise regulation. [Conclusions and Prospects] In sum, digital (smart) agriculture is rapidly transcending its role as a mere extension of agricultural informatization to become the "new-quality productivity" driving high-quality agricultural development, achieving this by fundamentally restructuring production factors, enhancing resource efficiency, strengthening risk response capabilities, and promoting value chain upgrading, thereby offering critical momentum for constructing a more efficient, greener, and sustainable modern agricultural system. Given China's pronounced global advantages in the digital economy, information technology, remote sensing, and intelligent equipment, the nation is well-positioned to integrate these strengths to construct comprehensive, full-chain smart agricultural solutions whose mature systemic models and business paradigms can ultimately form a "China Card" in the global agricultural revolution, contributing Chinese wisdom and solutions towards the realization of global food security and the zero-hunger goal.

Key words: digital agriculture, earth observation, digital twin, sustainable development, food security, agricultural resilience

CLC Number:

WU Bingfang, MA Hui, ZHANG Miao, PAN Qingcheng, ZHANG Xiang, CHEN Shuisen, QIU Bingwen, XU Xingang, LIU Jianhong, FAN Jinlong, HUANG Jianxi, JIANG Jiale, HE Changchui. Earth Observation-Driven Digital (Smart) Agriculture: Research Frontiers and Application Cases[J]. Smart Agriculture, 2026, 8(2): 1-17.

Figures/Tables 4

Table 1

Core information on agricultural AI development

国家	核心定位	关键政策/计划	重点应用场景
中国	顶层规划-部委行动-专项落实	《新一代人工智能发展规划》《数字乡村发展战略纲要》《“十四五”全国农业农村信息化发展规划》《“十四五”数字农业建设规划》《全国智慧农业行动计划（2024—2028年）》《关于大力发展智慧农业的指导意见》《关于深入实施“人工智能+”行动的意见》	AI育种、智能农机、农业无人机、农业机器人、农业生产管理、风险防范^［17-19］
美国	政策引导+市场驱动	《美国人工智能倡议》、美国农业部国家食品与农业研究所（National Institute of Food and Agriculture，NIFA）精准农业项目	精准种植、表型组学、智能农机、监测预报^{［20， 21］}
日本	数据基建驱动	国家AI战略、农业数据协作平台（Agricultural Data Collaboration Platform，WAGRI）	定制化AI模型、农场精准管理^［22］
澳大利亚	项目补贴主导	国家AI能力发展计划、气候智慧农业计划	精准施肥、AI 除草机器人、产量预测^［23］
加拿大	联邦-省协同补贴	可持续加拿大农业伙伴关系、British Columbia（BC）省农场技术计划	自动化种植、智能包装存储、畜牧AI^［24］
以色列	研发+出口导向	农业AI国家旗舰计划、国家级AI 计算中心	智能灌溉、航拍AI 分析、昆虫监测^［25］
韩国	系统规划推进	《智能农业培育支持法》、2025—2029五年规划	智能农场、开源AI模型、垂直农业^{［26， 27］}
巴西	战略新兴探索	《巴西人工智能计划》（2025版）	智能农机、农业物联网、墒情监测^［28］
欧盟	绿色+数字双重转型	“数字欧洲”“地平线欧洲”《人工智能法案》	农业机器人、数字孪生、可持续育种^［29］

Table 1

Fig. 1

Fig. 2

Fig. 3

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Earth Observation-Driven Digital (Smart) Agriculture: Research Frontiers and Application Cases

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