天空地数字农业管理系统框架设计与构建建议

doi:10.12133/j.smartag.2019.1.2.201812-SA021

摘要/Abstract

摘要：

数据正在成为基础性战略资源。构建以天空地大数据为关键要素的数字农业管理系统,对于建设数字中国、推进农业高质量发展、抢占全球农业制高点具有重要意义。本研究围绕农业农村部提出的天空地数字农业管理系统建设任务,从农业信息技术学科出发,首先给出了天空地数字农业的科学内涵,阐述了其与传统数字农业的异同点,理清了天空地数字农业管理系统在资源调查、生产调度、灾害监测、市场预警、决策服务的五大核心功能;其次,重点阐述了天空地数字农业管理系统的关键任务,即一个观测体系（天空地一体化的数字农业观测体系）、四个数字化（农业资源权属、生产过程、灾害监测和市场预警）、一个管理平台（农业生产、加工、经营、管理、服务等全产业链的天空地数字农业管理平台）;然后,明确提出了天空地数字农业管理系统在标准规范研制、关键技术与装备研发、系统集成与平台开发三方面的科技创新重点任务;最后,针对天空地数字农业管理系统建设的复杂性和系统性,从规划设计、科技创新、资源共享、多方参与、应用领域拓展等方面提出了发展建议。

关键词: 天空地一体化, 数字农业, 管理系统, 监测, 预警, 决策

Abstract:

The human society is entering the era of big data and data is becoming one of the key production elements. It is thus critical to develop the China's data-driving digital agriculture system, which would greatly promote the construction of digital China, stimulate the agriculture high-quality development and improve the agricultural competitiveness at the global market. To achieve this goal, strong integration of information is needed from multi-sources, multi-sensors, and multi-scales. This research, from the perspective of agricultural information science, describes the new framework of satellite, aerial, and ground integrated (SAGI) digital agriculture system for comprehensive agricultural monitoring, modeling, and management. The SAGI system differs from traditional digital agriculture systems and includes 5 important functionalities which are resource survey, production controlling, disaster monitoring, market early-warning and decision supporting. To make the system running in operation, it is necessary to first build an observation system, which integrates the satellite, aerial, and ground in-situ observation systems to capture more sophisticated, accurate and reliable data at different scales. The system is extremely needed for China, a large country with a great geographic difference, diverse agricultural cultivation and multiple agricultural traditions. This observing system helps to form the agricultural big data for subsequent data analysis and data mining. Secondly, using the big data collected, 4 key digitalization and monitoring tasks targeting at resource property right, production process, natural disaster and market status should be implemented so as to transform the data to knowledge. In this process, some diagnosis algorithms and models are developed to understand the growth and health of crops and animals, as well as their interaction with the agro-environment. With the above support, a management system covering the full range of agricultural production, processing, selling, management and services should be established to provide the rapid and reliable information support to decision-making as well to the local farming management, thereby guaranteeing agricultural sustainability and national food security. Thirdly, some key fields for future science and technology innovation to support the applications of the SAGI system should to be enhanced such as the standardization designing, innovation in technologies and instruments, system integration and platform development. Finally, considering the complicated and integrative characteristics of this SAG system, this research also proposed some recommendations such as holistic planning, science-technology innovation, resource sharing, multi-stakeholders participation, and expansion of application fields, so as to drive this idea to the reality.

Key words: aerial and ground integrated (SAGI), digital agriculture, management system, monitoring, early-warning, decision

中图分类号:

S126

吴文斌, 史云, 周清波, 杨鹏, 刘海启, 王飞, 刘佳, 王利民, 张保辉. 天空地数字农业管理系统框架设计与构建建议[J]. 智慧农业, 2019, 1(2): 64-72.

Wu Wenbin, Shi Yun, Zhou Qingbo, Yang Peng, Liu Haiqi, Wang Fei, Liu Jia, Wang Limin, Zhang Baohui. Framework and recommendation for constructing the SAGI digital agriculture system[J]. Smart Agriculture, 2019, 1(2): 64-72.

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