农业机器人技术进展、挑战与趋势

doi:10.12133/j.smartag.SA202312030

摘要/Abstract

摘要：

［目的/意义］农业机器人是全球农业装备的战略制高点和竞争焦点，也是加快推动中国农业强国建设的重点方向之一。世界农业强国与中国均围绕本国农业发展特点，正在加强农业机器人政策与规划布局，带动农业机器人产业进入稳定增长期。［进展］本文阐述了农业机器人概念及特征，全球农业机器人发展政策与战略规划布局，以及产业发展状况。针对农田作业机器人、果园采摘机器人和设施蔬菜生产机器人等3类典型农业机器人的产业背景、前沿进展、发展面临的挑战和关键技术卡点开展了深入分析。［结论/展望］展望了在全球农业劳动力的日益短缺的大背景下，农业机器人产业快速发展面临的机遇，提出了未来农业机器人技术在自主导航、自主学习、实时监控、作业管控等方面的发展趋势。

关键词: 农业机器人, 智能农机, 精准作业, 无人农场, 自主导航

Abstract:

[Significance] Autonomous and intelligent agricultural machinery, characterized by green intelligence, energy efficiency, and reduced emissions, as well as high intelligence and man-machine collaboration, will serve as the driving force behind global agricultural technology advancements and the transformation of production methods in the context of smart agriculture development. Agricultural robots, which utilize intelligent control and information technology, have the unique advantage of replacing manual labor. They occupy the strategic commanding heights and competitive focus of global agricultural equipment and are also one of the key development directions for accelerating the construction of China's agricultural power. World agricultural powers and China have incorporated the research, development, manufacturing, and promotion of agricultural robots into their national strategies, respectively strengthening the agricultural robot policy and planning layout based on their own agricultural development characteristics, thus driving the agricultural robot industry into a stable growth period. [Progress] This paper firstly delves into the concept and defining features of agricultural robots, alongside an exploration of the global agricultural robot development policy and strategic planning blueprint. Furthermore, sheds light on the growth and development of the global agricultural robotics industry; Then proceeds to analyze the industrial backdrop, cutting-edge advancements, developmental challenges, and crucial technology aspects of three representative agricultural robots, including farmland robots, orchard picking robots, and indoor vegetable production robots. Finally, summarizes the disparity between Chinese agricultural robots and their foreign counterparts in terms of advanced technologies. (1) An agricultural robot is a multi-degree-of-freedom autonomous operating equipment that possesses accurate perception, autonomous decision-making, intelligent control, and automatic execution capabilities specifically designed for agricultural environments. When combined with artificial intelligence, big data, cloud computing, and the Internet of Things, agricultural robots form an agricultural robot application system. This system has relatively mature applications in key processes such as field planting, fertilization, pest control, yield estimation, inspection, harvesting, grafting, pruning, inspection, harvesting, transportation, and livestock and poultry breeding feeding, inspection, disinfection, and milking. Globally, agricultural robots, represented by plant protection robots, have entered the industrial application phase and are gradually realizing commercialization with vast market potential. (2) Compared to traditional agricultural machinery and equipment, agricultural robots possess advantages in performing hazardous tasks, executing batch repetitive work, managing complex field operations, and livestock breeding. In contrast to industrial robots, agricultural robots face technical challenges in three aspects. Firstly, the complexity and unstructured nature of the operating environment. Secondly, the flexibility, mobility, and commoditization of the operation object. Thirdly, the high level of technology and investment required. (3) Given the increasing demand for unmanned and less manned operations in farmland production, China's agricultural robot research, development, and application have started late and progressed slowly. The existing agricultural operation equipment still has a significant gap from achieving precision operation, digital perception, intelligent management, and intelligent decision-making. The comprehensive performance of domestic products lags behind foreign advanced counterparts, indicating that there is still a long way to go for industrial development and application. Firstly, the current agricultural robots predominantly utilize single actuators and operate as single machines, with the development of multi-arm cooperative robots just emerging. Most of these robots primarily engage in rigid operations, exhibiting limited flexibility, adaptability, and functionality. Secondly, the perception of multi-source environments in agricultural settings, as well as the autonomous operation of agricultural robot equipment, relies heavily on human input. Thirdly, the progress of new teaching methods and technologies for human-computer natural interaction is rather slow. Lastly, the development of operational infrastructure is insufficient, resulting in a relatively low degree of "mechanization". [Conclusions and Prospects] The paper anticipates the opportunities that arise from the rapid growth of the agricultural robotics industry in response to the escalating global shortage of agricultural labor. It outlines the emerging trends in agricultural robot technology, including autonomous navigation, self-learning, real-time monitoring, and operation control. In the future, the path planning and navigation information perception of agricultural robot autonomy are expected to become more refined. Furthermore, improvements in autonomous learning and cross-scenario operation performance will be achieved. The development of real-time operation monitoring of agricultural robots through digital twinning will also progress. Additionally, cloud-based management and control of agricultural robots for comprehensive operations will experience significant growth. Steady advancements will be made in the innovation and integration of agricultural machinery and techniques.

Key words: agricultural robot, intelligent agricultural machinery, precise operation, unmanned farms, autonomous navigation

赵春江, 范贝贝, 李瑾, 冯青春. 农业机器人技术进展、挑战与趋势[J]. 智慧农业(中英文), 2023, 5(4): 1-15.

ZHAO Chunjiang, FAN Beibei, LI Jin, FENG Qingchun. Agricultural Robots: Technology Progress, Challenges and Trends[J]. Smart Agriculture, 2023, 5(4): 1-15.

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国家	企业	成立年份	主营机器人产品
美国	Deere & Company	1837	智能拖拉机
美国	Trimble Inc.	1978	播种、喷药、整地
英国	CNH Industrial NV	2013	播种、收获
荷兰	Lely	1948	饲喂、挤奶
日本	YANMAR Co.	1912	移栽、插秧、收获
以色列	FFRobotics	2018	果园采摘
德国	Deepfield Robotics	2008	物理对靶除草

公司名称	机器人产品方向	融资时间	轮次
极飞科技	农业无人机	2021.03	C++轮
中科原动力	农业无人驾驶	2021.06	A轮
丰疆智能	农业机器人自动化技术套件	2021.11	B轮
麦麦趣耕科技	农业智慧平台	2022.05	天使轮
岚江科技	果园多功能机器人	2022.07	天使轮
极目机器人	农业无人机	2023.02	C轮

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