农业多机器人全覆盖作业关键技术研究进展与展望

doi:10.12133/j.smartag.SA202507040

Smart Agriculture ›› 2025, Vol. 7 ›› Issue (5): 17-36.doi: 10.12133/j.smartag.SA202507040

• 专刊--光智农业创新技术与应用 • 上一篇下一篇

农业多机器人全覆盖作业关键技术研究进展与展望

陆在旺¹^,², 张玉成¹, 马宜科¹(), 代锋¹, 董杰¹, 王鹏¹, 陆会贤¹, 李同滨¹^,², 赵凯宾¹

^1. 中国科学院计算技术研究所，北京 100190，中国
^2. 中国科学院大学，北京 100190，中国

收稿日期:2025-07-29 出版日期:2025-09-30
基金项目:
中国科学院战略性先导科技专项（A类）(XDA28040000)
作者简介:
陆在旺，博士研究生，研究方向为多机器人调度与规划、具身智能。E-mail：luzaiwang21b@ict.ac.cn
通信作者:
马宜科，博士，高级工程师，研究方向为视频分析与处理、计算机视觉、SoC处理器设计。E-mail：ykma@ict.ac.cn

Progress and Prospects of Research on Key Technologies for Agricultural Multi-Robot Full Coverage Operations

LU Zaiwang¹^,², ZHANG Yucheng¹, MA Yike¹(), DAI Feng¹, DONG Jie¹, WANG Peng¹, LU Huixian¹, LI Tongbin¹^,², ZHAO Kaibin¹

^1. Institute of Computing Technology, Chinese Academy of Sciences, Beijing 100190, China
^2. University of Chinese Academy of Sciences, Beijing 100190, China

Received:2025-07-29 Online:2025-09-30
Foundation items:Strategic Priority Research Program (Class A) of the Chinese Academy of Sciences(XDA28040000)
About author:
LU Zaiwang, E-mail: luzaiwang21b@ict.ac.cn
Corresponding author:
MA Yike, E-mail: ykma@ict.ac.cn

摘要/Abstract

摘要：

［目的/意义］ 随着智慧农业和精准农业的快速发展，多机器人全覆盖作业技术在农业领域得到了广泛关注。该技术在作业效率、覆盖范围、系统鲁棒性与可扩展性等方面展现出显著优势，能够支持机器人集群高效完成播种、收割等大范围覆盖任务，是实现农业生产智能化的关键。 ［进展］ 本文系统梳理了农业多机器人全覆盖作业系统的整体技术框架，构建了 “感知-决策-执行”一体化闭环框架，并深入分析了各模块关键技术的发展与应用现状。在感知识别层面，重点探讨如何融合多源信息与协同感知技术以构建精确的全局环境模型；在决策规划层面，集成任务分配、全局路径规划和局部路径调整等关键环节，优化机器人集群作业任务与路径策略。在控制执行层面，则聚焦于基于模型的轨迹跟踪控制技术，将规划指令精准转化为农机运动。 ［结论/展望］ 总结当前农业复杂场景下的主要挑战，包括任务数量多且需求变动、作业空间大且具有不规则性、动态环境中存在不可预知的障碍物等，并展望未来技术发展方向，为推进农业智能化和现代化提供参考。

关键词: 多机器人, 全覆盖作业, 感知识别, 任务分配, 路径规划, 控制执行

Abstract:

[Significance] With the deepening of intelligent agriculture and precision agriculture, the agricultural production mode is gradually transforming from traditional manual experience based operations to a modern model driven by data, intelligent decision-making, and autonomous execution. In this context, improving agricultural operation efficiency and achieving large-scale continuous and seamless operation coverage have become key requirements for promoting the modernization of agriculture. The multi-robot full coverage operation technology, with its significant advantages in operation efficiency, system robustness, scalability, and resource utilization efficiency, provides practical and feasible intelligent solutions for key links such as sowing, plant protection, and harvesting in large-scale farmland. This technology, through the collaborative work of multi-robot systems, can not only effectively reduce the repetition rate of tasks and avoid omissions, but also achieve efficient and accurate continuous operations in complex and dynamic agricultural environments, greatly improving the automation and intelligence level of agricultural production. [Progress] Starting from the global perspective of systems engineering, an integrated closed-loop technology framework of "perception-decision-execution" is constructed. It systematically sorts out and deeply analyzes the technological development status and research methods of each key link in the full-coverage operations of agricultural multi robot. At the level of perception and recognition, it focus on exploring the application of multi-source information fusion and collaborative perception technology. By integrating multi-source sensor data, multi-level fusion of data level, feature level, and decision level is achieved, and a refined global environment model is constructed to provide accurate crop status, obstacle distribution, and terrain information for the robot system. Especially in the field of multi-robot collaborative perception, research has covered advanced models such as distributed simultaneous localization and mapping (SLAM) and ground to ground collaboration. Through information sharing and complementary perspectives, the system's perception ability and modeling accuracy in wide area, unstructured agricultural environments have been improved. At the decision-making and planning level, three key aspects are analyzed: task allocation, global path planning, and local path adjustment. Task allocation has evolved from traditional deterministic methods to market mechanisms, heuristic algorithms, and intelligent methods that integrate reinforcement learning and graph neural networks to address the challenges of dynamic and complex resource constraints in agricultural scenarios. The global path planning system analyzes the characteristics of geometric decomposition, grid method, global planning, and learning methods in terms of path redundancy, computational efficiency, and terrain adaptability. Local path planning emphasizes the combination of real-time perception in dynamic environments, using methods such as graph search, sampling optimization, model predictive control, and end-to-end reinforcement learning to achieve real-time obstacle avoidance and trajectory smoothing. At the control execution level, the focus is on model-based trajectory tracking and control technology, aiming to accurately convert planned paths into robot motion. Traditional control methods such as PID, LQR, sliding mode control, etc. are continuously optimized to cope with terrain undulations and system disturbances. In recent years, intelligent methods such as fuzzy control, neural network control, reinforcement learning, and multi machine collaborative strategies have been gradually applied, further improving the control accuracy and collaborative operation capability of the system in dynamic environments. [Conclusions and Prospects] The closed-loop technical framework is systematically constructed for agricultural multi-robot full coverage operations, and in-depth analysis of key modules is conducted, providing some understanding and suggestions, and providing theoretical references and technical paths for related research. However, the technology still faces many challenges, including perceptual uncertainty, dynamic changes in tasks, vast and irregular work areas, unpredictable dynamic obstacles, communication and collaboration barriers, and energy endurance issues. In the future, this field will further strengthen the integration with artificial intelligence, the Internet of Things, edge computing and other technologies, focusing on promoting the following directions, including the development of intelligent dynamic task allocation mechanism; optimize global and local path planning algorithms to enhance their efficiency and adaptability in large-scale complex scenarios; enhance the real-time perception and response capability of the system to dynamic environments; promote software hardware collaboration and intelligent system integration to achieve efficient communication and integrated task management; develop high-efficiency power systems and intelligent energy consumption strategies to ensure long-term continuous operation capability. Through these efforts, agricultural multi-robot systems will gradually achieve higher levels of precision, automation, and intelligence, providing key technological support for the transformation of modern agriculture.

Key words: multi-robot, full-coverage operation, perceptual recognition, task allocation, path planning, control execution

中图分类号:

S126
S-1

陆在旺, 张玉成, 马宜科, 代锋, 董杰, 王鹏, 陆会贤, 李同滨, 赵凯宾. 农业多机器人全覆盖作业关键技术研究进展与展望[J]. 智慧农业(中英文), 2025, 7(5): 17-36.

LU Zaiwang, ZHANG Yucheng, MA Yike, DAI Feng, DONG Jie, WANG Peng, LU Huixian, LI Tongbin, ZHAO Kaibin. Progress and Prospects of Research on Key Technologies for Agricultural Multi-Robot Full Coverage Operations[J]. Smart Agriculture, 2025, 7(5): 17-36.

图/表 11

图1

表 1

图2

表 2

图3

表 3

图4

表 4

图5

表 5

表 6

参考文献 107

[1]	赵春江. 智慧农业发展现状及战略目标研究[J]. 智慧农业, 2019, 1(1): 1-7.
	ZHAO C J. State-of-the-art and recommended developmental strategic objectivs of smart agriculture[J]. Smart agriculture, 2019, 1(1): 1-7.
[2]	ARAI T, PAGELLO E, PARKER L E. Guest editorial advances in multirobot systems[J]. IEEE transactions on robotics and automation, 2002, 18(5): 655-661.
[3]	张津国, 蔡建峰, 姜蓉蓉, 等. 果园作业机器人自主导航多任务联合感知方法研究[J]. 智能化农业装备学报(中英文), 2025(2): 35-43.
	ZHANG J G, CAI J F, JIANG R R, et al. Multi-task joint perception framework for autonomous navigation in orchard robotics[J]. Journal of intelligent agricultural mechanization, 2025(2): 35-43.
[4]	钱震杰, 金诚谦, 刘政, 等. 无人农场中的智能控制技术应用现状与趋势[J]. 智能化农业装备学报(中英文), 2023(3): 1-13.
	QIAN Z J, JIN C Q, LIU Z, et al. Application status and trend of intelligent control technology in unmanned farm[J]. Journal of intelligent agricultural mechanization, 2023(3): 1-13.
[5]	XU Y, XUE X Y, SUN Z, et al. Joint path planning and scheduling for vehicle-assisted multiple unmanned aerial systems plant protection operation[J]. Computers and electronics in agriculture, 2022, 200: ID 107221.
[6]	WANG N, LI S D, XIAO J X, et al. A collaborative scheduling and planning method for multiple machines in harvesting and transportation operations-Part Ⅰ: Harvester task allocation and sequence optimization[J]. Computers and electronics in agriculture, 2025, 232: ID 110060.
[7]	AHSAN Z, DANKOWICZ H. Optimal scheduling and sequencing for large-scale seeding operations[J]. Computers and electronics in agriculture, 2019, 163: ID 104728.
[8]	ALMADHOUN R, TAHA T, SENEVIRATNE L, et al. A survey on multi-robot coverage path planning for model reconstruction and mapping[J]. SN applied sciences, 2019, 1(8): ID 847.
[9]	SA I, POPOVIĆ M, KHANNA R, et al. WeedMap: A large-scale semantic weed mapping framework using aerial multispectral imaging and deep neural network for precision farming[J]. Remote sensing, 2018, 10(9): ID 1423.
[10]	BENDER A, WHELAN B, SUKKARIEH S. A high-resolution, multimodal data set for agricultural robotics: A Ladybird's-eye view of Brassica [J]. Journal of field robotics, 2020, 37(1): 73-96.
[11]	SANKEY T T, MCVAY J, SWETNAM T L, et al. UAV hyperspectral and lidar data and their fusion for arid and semi-arid land vegetation monitoring[J]. Remote sensing in ecology and conservation, 2018, 4(1): 20-33.
[12]	SKOCZEŃ M, OCHMAN M, SPYRA K, et al. Obstacle detection system for agricultural mobile robot application using RGB-D cameras[J]. Sensors, 2021, 21(16): ID 5292.
[13]	SHAFI U, MUMTAZ R, IQBAL N, et al. A multi-modal approach for crop health mapping using low altitude remote sensing, Internet of Things (IoT) and machine learning[J]. IEEE access, 2020, 8: 112708-112724.
[14]	CORTINAS E, EMMI L, GONZALEZ-DE-SANTOS P. Crop identification and growth stage determination for autonomous navigation of agricultural robots[J]. Agronomy, 2023, 13(12): ID 2873.
[15]	DENG X W, QI L, LIU Z W, et al. Weed target detection at seedling stage in paddy fields based on YOLOX[J]. PLoS one, 2023, 18(12): ID e0294709.
[16]	TSIAKAS K, PAPADIMITRIOU A, PECHLIVANI E M, et al. An autonomous navigation framework for holonomic mobile robots in confined agricultural environments[J]. Robotics, 2023, 12(6): ID 146.
[17]	CALTAGIRONE L, BELLONE M, SVENSSON L, et al. LiDAR-camera fusion for road detection using fully convolutional neural networks[J]. Robotics and autonomous systems, 2019, 111: 125-131.
[18]	LÜ P F, WANG B Q, CHENG F, et al. Multi-objective association detection of farmland obstacles based on information fusion of millimeter wave radar and camera[J]. Sensors, 2023, 23(1): ID 230.
[19]	SAMAL K, KUMAWAT H, SAHA P, et al. Task-driven RGB-lidar fusion for object tracking in resource-efficient autonomous system[J]. IEEE transactions on intelligent vehicles, 2022, 7(1): 102-112.
[20]	GUAN L M, CHEN Y, WANG G P, et al. Real-time vehicle detection framework based on the fusion of LiDAR and camera[J]. Electronics, 2020, 9(3): ID 451.
[21]	马楠, 曹姗姗, 白涛, 等. 农业复杂场景下多机器人协同SLAM研究进展与展望[J]. 智慧农业(中英文), 2024, 6(6): 23-43.
	MA N, CAO S S, BAI T, et al. Research progress and prospect of multi-robot collaborative SLAM in complex agricultural scenarios[J]. Smart agriculture, 2024, 6(6): 23-43.
[22]	TIAN Y L, CHANG Y, HERRERA ARIAS F, et al. Kimera-multi: Robust, distributed, dense metric-semantic SLAM for multi-robot systems[J]. IEEE transactions on robotics, 2022, 38(4): 2022-2038.
[23]	LAJOIE P Y, BELTRAME G. Swarm-SLAM: Sparse decentralized collaborative simultaneous localization and mapping framework for multi-robot systems[J]. IEEE robotics and automation letters, 2024, 9(1): 475-482.
[24]	HUANG Y W, SHAN T X, CHEN F F, et al. DiSCo-SLAM: Distributed scan context-enabled multi-robot LiDAR SLAM with two-stage global-local graph optimization[J]. IEEE robotics and automation letters, 2022, 7(2): 1150-1157.
[25]	郝肇铁, 郭斌, 赵凯星, 等. 从规则驱动到群智涌现: 多机器人空地协同研究综述[J]. 自动化学报, 2024, 50(10): 1877-1905.
	HAO Z T, GUO B, ZHAO K X, et al. From rule-driven to collective intelligence emergence: A review of research on multi-robot air-ground collaboration[J]. Acta automatica sinica, 2024, 50(10): 1877-1905.
[26]	DAI B, HE Y Q, GU F, et al. A vision-based autonomous aerial spray system for precision agriculture[C]// 2017 IEEE International Conference on Robotics and Biomimetics (ROBIO). Piscataway, New Jersey, USA: IEEE, 2018: 507-513.
[27]	POTENA C, KHANNA R, NIETO J, et al. AgriColMap: Aerial-ground collaborative 3D mapping for precision farming[J]. IEEE robotics and automation letters, 2019, 4(2): 1085-1092.
[28]	AGUIAR A S, DOS SANTOS F N, CUNHA J B, et al. Localization and mapping for robots in agriculture and forestry: A survey[J]. Robotics, 2020, 9(4): 97.
[29]	ROVIRA-MÁS F, ZHANG Q, REID J F. Stereo vision three-dimensional terrain maps for precision agriculture[J]. Computers and electronics in agriculture, 2008, 60(2): 133-143.
[30]	ZHOU H X, WANG J T, CHEN Y Q, et al. Neural network-based SLAM/GNSS fusion localization algorithm for agricultural robots in orchard GNSS-degraded or denied environments[J]. Agriculture, 2025, 15(15): 1612.
[31]	PIERZCHAŁA M, GIGUÈRE P, ASTRUP R. Mapping forests using an unmanned ground vehicle with 3D LiDAR and graph-SLAM[J]. Computers and electronics in agriculture, 2018, 145: 217-225.
[32]	SANTOS L C, AGUIAR A S, SANTOS F N, et al. Navigation stack for robots working in steep slope vineyard[C]// Intelligent Systems and Applications. Cham, Germany: Springer, 2021: 264-285.
[33]	赵欣, 王万里, 董靓, 等. 面向无人驾驶农机的高精度农田地图构建[J]. 农业工程学报, 2022, 38(S1): 1-7.
	ZHAO X, WANG W L, DONG J, et al. High precision farmland map construction for unmanned agricultural machinery[J]. Transactions of the Chinese society of agricultural engineering, 2022, 38(S1): 1-7.
[34]	FANG H, CHEN H, JIANG H, et al. Research on method of farmland obstacle boundary extraction in UAV remote sensing images[J]. Sensors, 2019, 19(20): ID 4431.
[35]	ZHANG M, LI L, WANG A C, et al. A novel farmland boundaries extraction and obstacle detection method based on unmanned aerial vehicle[C]// 2019 ASABE Annual International Meeting. St. Joseph, Michigan: American Society of Agricultural and Biological Engineers, 2019: ID 1900369.
[36]	杜蒙蒙, 刘颖超, 姬江涛, 等. 基于无人机与激光测距技术的农田地形测绘[J]. 农业工程学报, 2020, 36(22): 60-67.
	DU M M, LIU Y C, JI J T, et al. Farmland topographic mapping based on UAV and LiDAR technology[J]. Transactions of the Chinese society of agricultural engineering, 2020, 36(22): 60-67.
[37]	DI TOMMASO S, WANG S, STREY R, et al. Mapping sugarcane globally at 10 m resolution using Global Ecosystem Dynamics Investigation (GEDI) and Sentinel-2[J]. Earth system science data, 2024, 16(10): 4931-4947.
[38]	WALDNER F, DIAKOGIANNIS F I, BATCHELOR K, et al. Detect, consolidate, delineate: Scalable mapping of field boundaries using satellite images[J]. Remote sensing, 2021, 13(11): ID 2197.
[39]	CAI Z W, HU Q, ZHANG X Y, et al. Improving agricultural field parcel delineation with a dual branch spatiotemporal fusion network by integrating multimodal satellite data[J]. ISPRS journal of photogrammetry and remote sensing, 2023, 205: 34-49.
[40]	ZHAO H, WU B F, ZHANG M, et al. A large-scale VHR parcel dataset and a novel hierarchical semantic boundary-guided network for agricultural parcel delineation[J]. ISPRS journal of photogrammetry and remote sensing, 2025, 221: 1-19.
[41]	GUO H W, MIAO Z H, JI J, et al. An effective collaboration evolutionary algorithm for multi-robot task allocation and scheduling in a smart farm[J]. Knowledge-based systems, 2024, 289: ID 111474.
[42]	王宁, 韩雨晓, 王雅萱, 等. 农业机器人全覆盖作业规划研究进展[J]. 农业机械学报, 2022, 53(S1): 1-19.
	WANG N, HAN Y X, WANG Y X, et al. Research progress on full-coverage operation planning of agricultural robots[J]. Transactions of the Chinese society for agricultural machinery, 2022, 53(S1): 1-19.
[43]	KORSAH G A, STENTZ A, DIAS M B. A comprehensive taxonomy for multi-robot task allocation[J]. The international journal of robotics research, 2013, 32(12): 1495-1512.
[44]	D'URSO G, SMITH S L, METTU R, et al. Multi-vehicle refill scheduling with queueing[J]. Computers and electronics in agriculture, 2018, 144: 44-57.
[45]	胡志文. 绿色收割农机调度模型[J]. 上海农业学报, 2014, 30(6): 133-135.
	HU Z W. A green reaping farm machine scheduling model[J]. Acta agriculturae Shanghai, 2014, 30(6): 133-135.
[46]	FERRER J C, CAWLEY AMAC, MATURANA S, et al. An optimization approach for scheduling wine grape harvest operations[J]. International journal of production economics, 2008, 112(2): 985-999.
[47]	王猛, 赵博, 刘阳春, 等. 同种农机机群动态作业任务分配方法[J]. 农业工程学报, 2021, 37(9): 199-210.
	WANG M, ZHAO B, LIU Y C, et al. Dynamic task allocation method for the same type agricultural machinery group[J]. Transactions of the Chinese society of agricultural engineering, 2021, 37(9): 199-210.
[48]	宫金良, 王伟, 张彦斐, 等. 基于动态刺激响应模型的异质农业Agent群任务分配策略[J]. 农业机械学报, 2021, 52(5): 142-150.
	GONG J L, WANG W, ZHANG Y F, et al. Task allocation strategy for heterogeneous agricultural agent groups based on dynamic stimulus-response models [J]. Transactions of the Chinese society for agricultural machinery, 2021, 52(5): 142-150.
[49]	LIANG Y J, ZHOU K, WU C C. Dynamic task allocation method for heterogenous multiagent system in uncertain scenarios of agricultural field operation[J]. Journal of physics: Conference series, 2022, 2356(1): ID 012049.
[50]	LU Z W, ZHAO Z X, LONG L, et al. Multi-robot task allocation in agriculture scenarios based on the improved NSGA-II algorithm[C]// 2023 IEEE 98th Vehicular Technology Conference (VTC2023-Fall). Piscataway, New Jersey, USA: IEEE, 2023: 1-6.
[51]	CAO R Y, LI S C, JI Y H, et al. Task assignment of multiple agricultural machinery cooperation based on improved ant colony algorithm[J]. Computers and electronics in agriculture, 2021, 182: ID 105993.
[52]	周龙港, 刘婷, 卢劲竹. 基于Floyd和改进遗传算法的丘陵地区农田遍历路径规划[J]. 智慧农业(中英文), 2023, 5(4): 45-57.
	ZHOU L G, LIU T, LU J Z. Traversal path planning for farmland in hilly areas based on floyd and improved genetic algorithm[J]. Smart agriculture, 2023, 5(4): 45-57.
[53]	LU Z W, WANG Y C, DAI F, et al. A reinforcement learning-based optimization method for task allocation of agricultural multi-robots clusters[J]. Computers and electrical engineering, 2024, 120: ID 109752.
[54]	DIN A, ISMAIL M Y, SHAH B, et al. A deep reinforcement learning-based multi-agent area coverage control for smart agriculture[J]. Computers and electrical engineering, 2022, 101: ID 108089.
[55]	JIANG Y M, HAO K R, CAI X, et al. An improved reinforcement-immune algorithm for agricultural resource allocation optimization[J]. Journal of computational science, 2018, 27: 320-328.
[56]	EDWARDS G, SØRENSEN C G, BOCHTIS D D, et al. Optimised schedules for sequential agricultural operations using a Tabu Search method[J]. Computers and electronics in agriculture, 2015, 117: 102-113.
[57]	LIANG H B, MA Y, CAO Z L, et al. SplitNet: A reinforcement learning based sequence splitting method for the MinMax multiple travelling salesman problem[J]. Proceedings of the AAAI conference on artificial intelligence, 2023, 37(7): 8720-8727.
[58]	CHOSET H, PIGNON P. Coverage path planning: The boustrophedon cellular decomposition[M]// Field and Service Robotics. London: Springer London, 1998: 203-209.
[59]	ACAR E U, CHOSET H, RIZZI A A, et al. Morse decompositions for coverage tasks[J]. The international journal of robotics research, 2002, 21(4): 331-344.
[60]	GUASTELLA D C, CANTELLI L, GIAMMELLO G, et al. Complete coverage path planning for aerial vehicle flocks deployed in outdoor environments[J]. Computers & electrical engineering, 2019, 75: 189-201.
[61]	GABRIELY Y, RIMON E. Spiral-STC: An on-line coverage algorithm of grid environments by a mobile robot[C]// Proceedings 2002 IEEE International Conference on Robotics and Automation. Piscataway, New Jersey, USA: IEEE, 2002: 954-960.
[62]	TANG J T, MA H. Mixed integer programming for time-optimal multi-robot coverage path planning with efficient heuristics[J]. IEEE robotics and automation letters, 2023, 8(10): 6491-6498.
[63]	KUSNUR T, LIKHACHEV M. Complete, decomposition-free coverage path planning[C]// 2022 IEEE 18th International Conference on Automation Science and Engineering (CASE). Piscataway, New Jersey, USA: IEEE, 2022: 1431-1437.
[64]	MIER G, VALENTE J, DE BRUIN S. Fields2Cover: An open-source coverage path planning library for unmanned agricultural vehicles[J]. IEEE robotics and automation letters, 2023, 8(4): 2166-2172.
[65]	TANG J T, MA H. Multi-robot connected Fermat spiral coverage[J]. Proceedings of the international conference on automated planning and scheduling, 2024, 34: 579-587.
[66]	WU C M, DAI C K, GONG X X, et al. Energy-efficient coverage path planning for general terrain surfaces[J]. IEEE robotics and automation letters, 2019, 4(3): 2584-2591.
[67]	IANENKO A, ARTAMONOV A, SARAPULOV G, et al. Coverage path planning with proximal policy optimization in a grid-based environment[C]// 2020 59th IEEE Conference on Decision and Control (CDC). Piscataway, New Jersey, USA: IEEE, 2021: 4099-4104.
[68]	LEI T J, LUO C M, JAN G E, et al. Deep learning-based complete coverage path planning with re-joint and obstacle fusion paradigm[J]. Frontiers in robotics and AI, 2022, 9: ID 843816.
[69]	KRISHNA LAKSHMANAN A, ELARA MOHAN R, RAMALINGAM B, et al. Complete coverage path planning using reinforcement learning for Tetromino based cleaning and maintenance robot[J]. Automation in construction, 2020, 112: ID 103078.
[70]	HÖFFMANN M, PATEL S, BÜSKENS C. Optimal coverage path planning for agricultural vehicles with curvature constraints[J]. Agriculture, 2023, 13(11): ID 2112.
[71]	KYAW P T, PAING A, THU T T, et al. Coverage path planning for decomposition reconfigurable grid-maps using deep reinforcement learning based travelling salesman problem[J]. IEEE access, 2020, 8: 225945-225956.
[72]	WANG Z K, ZHAO X Q, ZHANG J K, et al. APF-CPP: An artificial potential field based multi-robot online coverage path planning approach[J]. IEEE robotics and automation letters, 2024, 9(11): 9199-9206.
[73]	TANG J T, MA H. Large-scale multi-robot coverage path planning via local search[J]. Proceedings of the AAAI conference on artificial intelligence, 2024, 38(16): 17567-17574.
[74]	CARVALHO J P, AGUIAR A P. Deep reinforcement learning for zero-shot coverage path planning with mobile robots[J]. IEEE/CAA journal of automatica sinica, 2025, 12(8): 1594-1609.
[75]	MONTEMERLO M, BECKER J, BHAT S, et al. Junior: The stanford entry in the urban challenge[J]. Journal of field robotics, 2008, 25(9): 569-597.
[76]	STENTZ A. Optimal and efficient path planning for partially-known environments[C]// Proceedings of the 1994 IEEE International Conference on Robotics and Automation. Piscataway, New Jersey, USA: IEEE, 2002: 3310-3317.
[77]	BHATTACHARYA P, GAVRILOVA M L. Voronoi diagram in optimal path planning[C]// 4th International Symposium on Voronoi Diagrams in Science and Engineering (ISVD 2007). Piscataway, New Jersey, USA: IEEE, 2007: 38-47.
[78]	SALZMAN O, HALPERIN D. Asymptotically near-optimal RRT for fast, high-quality motion planning[J]. IEEE transactions on robotics, 2016, 32(3): 473-483.
[79]	GONG X, GAO Y F, WANG F B, et al. A local path planning algorithm for robots based on improved DWA[J]. Electronics, 2024, 13(15): ID 2965.
[80]	陈若彤, 刘继芳, 张志勇, 等. 规模化牛场智能巡检路径规划算法[J/OL]. 智慧农业(中英文), 2025: 1-14. (2025-06-13)[2025-07-02].
	CHEN R T, LIU J F, ZHANG Z Y, et al. Intelligent inspection path planning algorithm for large-scale cattle farms[J/OL]. Smart agriculture, 2025: 1-14. (2025-06-13)[2025-07-02].
[81]	AFRAM A, JANABI-SHARIFI F. Theory and applications of HVAC control systems: A review of model predictive control (MPC)[J]. Building and environment, 2014, 72: 343-355.
[82]	WU J F, MA X H, PENG T R, et al. An improved timed elastic band (TEB) algorithm of autonomous ground vehicle (AGV) in complex environment[J]. Sensors, 2021, 21(24): ID 8312.
[83]	CHEN Y F, LIU M, EVERETT M, et al. Decentralized non-communicating multiagent collision avoidance with deep reinforcement learning[C]// 2017 IEEE International Conference on Robotics and Automation (ICRA). Piscataway, New Jersey, USA: IEEE, 2017: 285-292.
[84]	EVERETT M, CHEN Y F, HOW J P. Motion planning among dynamic, decision-making agents with deep reinforcement learning[C]// 2018 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). Piscataway, New Jersey, USA: IEEE, 2019: 3052-3059.
[85]	CHEN C G, LIU Y J, KREISS S, et al. Crowd-robot interaction: Crowd-aware robot navigation with attention-based deep reinforcement learning[C]// 2019 International Conference on Robotics and Automation (ICRA). Piscataway, New Jersey, USA: IEEE, 2019: 6015-6022.
[86]	SALZMANN T, KAUFMANN E, ARRIZABALAGA J, et al. Real-time neural MPC: Deep learning model predictive control for quadrotors and agile robotic platforms[J]. IEEE robotics and automation letters, 2023, 8(4): 2397-2404.
[87]	WANG S Q, HU Y Y, LIU Z N, et al. Research on adaptive obstacle avoidance algorithm of robot based on DDPG-DWA[J]. Computers and electrical engineering, 2023, 109: ID 108753.
[88]	HAN R H, WANG S, WANG S J, et al. NeuPAN: Direct point robot navigation with end-to-end model-based learning[J]. IEEE transactions on robotics, 2025, 41: 2804-2824.
[89]	WANG H W, LOU S J, JING J, et al. The EBS-A* algorithm: An improved A* algorithm for path planning[J]. PLoS one, 2022, 17(2): ID e0263841.
[90]	WANG S J, GAO R, HAN R H, et al. Adaptive environment modeling based reinforcement learning for collision avoidance in complex scenes[C]// 2022 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS). Piscataway, New Jersey, USA: IEEE, 2022: 9011-9018.
[91]	HUANG R H, ZHU S T, DU Y L, et al. MoE-loco: Mixture of experts for multitask locomotion[EB/OL]. arXiv: 2503.08564, 2025.
[92]	LI L, LI J, ZHANG S Y. Review article: State-of-the-art trajectory tracking of autonomous vehicles[J]. Mechanical sciences, 2021, 12(1): 419-432.
[93]	FARAG W. Complex trajectory tracking using PID control for autonomous driving[J]. International journal of intelligent transportation systems research, 2020, 18(2): 356-366.
[94]	刘文龙, 王晨旭, 徐伟东, 等. 基于预瞄模型的农机路径跟踪模糊PID控制方法[J]. 农业工程, 2024, 14(7): 31-36.
	LIU W L, WANG C X, XU W D, et al. Fuzzy PID control method of agricultural machinery path tracking based on preview model[J]. Agricultural engineering, 2024, 14(7): 31-36.
[95]	AMERTET S, GEBRESENBET G, ALWAN H M. Optimizing the performance of a wheeled mobile robots for use in agriculture using a linear-quadratic regulator[J]. Robotics and autonomous systems, 2024, 174: ID 104642.
[96]	马悦琦, 迟瑞娟, 赵彦涛, 等. 基于模糊控制的插秧机LQR曲线路径跟踪控制器优化方法[J]. 农业机械学报, 2023, 54(S1): 1-8, 102.
	MA Y Q, CHI R J, ZHAO Y T, et al. Optimization method of LQR curve path tracking controller for rice transplanter based on fuzzy control[J]. Transactions of the Chinese society for agricultural machinery, 2023, 54(S1): 1-8, 102.
[97]	SHIRZADEH M, SHOJAEEFARD M H, AMIRKHANI A, et al. Adaptive fuzzy nonlinear sliding-mode controller for a car-like robot[C]// 2019 5th Conference on Knowledge Based Engineering and Innovation (KBEI). Piscataway, New Jersey, USA: IEEE, 2019: 686-691.
[98]	葛志康, 白晓平, 王卓, 等. 基于动力学建模的农机路径跟踪鲁棒滑模控制算法研究[J]. 农机化研究, 2025, 47(8): 1-9.
	GE Z K, BAI X P, WANG Z, et al. Robust sliding mode control method for path tracking of unmanned agricultural vehicles based on dynamic modeling[J]. Journal of agricultural mechanization research, 2025, 47(8): 1-9.
[99]	SUN C Y, ZHANG X, ZHOU Q, et al. A model predictive controller with switched tracking error for autonomous vehicle path tracking[J]. IEEE access, 2019, 7: 53103-53114.
[100]	HE J, HU L, WANG P, et al. Path tracking control method and performance test based on agricultural machinery pose correction[J]. Computers and electronics in agriculture, 2022, 200: ID 107185.
[101]	王子杰, 刘国海, 张多, 等. 高地隙四轮独立驱动喷雾机路径跟踪模型预测控制[J]. 智慧农业(中英文), 2021, 3(3): 82-93.
	WANG Z J, LIU G H, ZHANG D, et al. Path following model predictive control of four wheel independent drive high ground clearance sprayer[J]. Smart agriculture, 2021, 3(3): 82-93.
[102]	严国军, 贲能军, 杨彦, 等. 基于自适应模糊PID控制的农用作业机械轨迹跟踪系统研究[J]. 重庆理工大学学报(自然科学), 2019, 33(4): 83-87, 115.
	YAN G J, BEN N J, YANG Y, et al. A novel adaptive fuzzy PID controller for trajectory tracking system of agricultural machinery[J]. Journal of Chongqing university of technology (natural science), 2019, 33(4): 83-87, 115.
[103]	王茂励, 段杰, 唐勇伟, 等. 基于模糊PID算法的农机自动转向系统研究[J]. 农机化研究, 2018, 40(11): 241-245.
	WANG M L, DUAN J, TANG Y W, et al. Research on agricultural machinery automatic steering system based on fuzzy PID algorithm[J]. Journal of agricultural mechanization research, 2018, 40(11): 241-245.
[104]	CARLUCHO I, DE PAULA M, ACOSTA G G. An adaptive deep reinforcement learning approach for MIMO PID control of mobile robots[J]. ISA transactions, 2020, 102: 280-294.
[105]	OBRADOVIĆ J, KRIŽMANČIĆ M, BOGDAN S. Decentralized multi-robot formation control using reinforcement learning[C]// 2023 XXIX International Conference on Information, Communication and Automation Technologies (ICAT). Piscataway, New Jersey, USA: IEEE, 2023: 1-7.
[106]	栾世杰, 孙叶丰, 贡亮, 等. 基于MPC延时补偿器的农机多机器人编队行驶轨迹跟踪方法[J]. 智慧农业(中英文), 2024, 6(3): 69-81.
	LUAN S J, SUN Y F, GONG L, et al. Trajectory tracking method of agricultural machinery multirobot formation operation based on MPC delay compensator[J]. Smart agriculture, 2024, 6(3): 69-81.
[107]	杨琰, 张瑞瑞, 张林焕, 等. 基于DQN的智能农机路径跟踪控制研究[J]. 农机化研究, 2025, 47(3): 28-34.
	YANG Y, ZHANG R R, ZHANG L H, et al. DQN-based path tracking control for intelligent agricultural machinery[J]. Journal of agricultural mechanization research, 2025, 47(3): 28-34.

传感器类型	优点	缺点	感知距离/m	典型农业场景
RGB-D相机	提供彩色纹理图像、深度信息，适合目标识别；低成本易部署	强光/暗光下失效；雨雾穿透力差；计算复杂度高	0.1~5.0	果实采摘姿态引导、作物株高监测、育苗盘分拣
多光谱相机	能够识别作物生理状态；非接触式诊断	依赖光照条件；数据处理复杂；价格昂贵	>0.5	病虫害早期预警、施肥差异图生成、产量预测
LiDAR	毫米级测距精度；强抗光照干扰；可进行三维点云重建	雨雪天气、高反射表面检测性能会下降；成本高	0.2~200.0	果园三维建图、地形坡度分析、避障识别
超声波雷达	成本低；抗粉尘/雾气干扰；简单易集成	易受温度影响；角度分辨率低；仅近距有效	0.02~5.00	农机底盘防撞、自主割草机边缘检测、料斗液位监测
Radar	全天气工作（雨/雾/尘）；运动目标追踪能力	分辨率低（厘米级）；金属干扰敏感	1~300	大型农机夜间导航、牲畜行为监控、土壤墒情估测
IMU	高响应频率（>100 Hz）；不受外部环境干扰；短时精确定位	累积误差显著，需配合其他传感器	—	农机姿态防倾翻、崎岖地形运动补偿、播种机振动监测
GNSS	全局绝对定位；覆盖范围广	信号遮挡易失效，普通模块精度低（米级）	全球覆盖	无人拖拉机路径跟踪、农田边界测绘、精准播种地理标定

分类	分辨率大小/m	特点	示例卫星	适用场景
低分辨率	＞20	覆盖范围广，但细节有限	Landsat系列	气象观测、大范围环境监测
中分辨率	＞5，≤20	平衡覆盖范围与细节，适合区域级分析	Sentinel-2	农业监测、土地利用分类、灾害评估
高分辨率	＞1，≤5	能识别较大的人造地物和自然特征	高分一号	城市规划、基础设施管理、精细化农业
超高分辨率	≤1	可清晰识别小型物体，适合最大细节的场合	高分二号，吉林一号，WorldView系列，GeoEye	精准测绘、国防安全、军事侦察、高精度资源调查

分类	优化机制	典型方法	优势	局限性	计算复杂度	适用场景	相关文献
确定性方法	数学规划	动态规划， B&B，MILP	保证解的最优性	计算复杂度高，难以扩展	高	小规模静态场景	［44-46］
基于市场的方法	分布式竞价	CNP， HBCA	动态响应快，分布式执行	通信开销大，可能局部最优	中等	中等规模动态场景	［47-49］
启发式方法	规则驱动	GA， ACO， TS	多目标优化，易于实现	解质量波动，参数敏感	中到高	中等规模动态场景	［50-52］
基于学习的方法	数据驱动	DDQN， GNN，	适应高维状态，自主学习	需大量训练数据，泛化性待验证	训练高，推理低	复杂不确定场景	［53-55］

分类	优化机制	典型方法	优势	局限性	计算复杂度	适用场景	相关文献
几何分解方法	几何分割	BD、MD、几何分解	适用于结构化环境	非凸环境下易过度分解	中等	结构化农田、简单障碍物场景	［58-60］
基于网格的方法	离散空间遍历	STC、APF-CPP	简化问题求解、工业级应用成熟	大尺度区域计算复杂度指数增长	随尺度指数增长	中等规模复杂地形	［61-63］
全局规划方法	连续路径生成	Fields2Cover、MCFS、EE-CPP	规划效率高、适合大规模场景	路径冗余	低	平方公里级农田、无密集障碍物区域	［64-66］
基于学习的方法	数据驱动策略	DRL+TSP、RL-CPP	适应动态环境、支持可变网格地图、处理非结构化场景	依赖网络模型的构建	训练高，推理低	非结构化场景、自主探索场景	［67-69］

分类	优化机制	典型方法	优势	局限性	适用场景	参考文献
基于模型的学习方法	综合以上两者的特点，保持可解释性和自适应性	NN-MPC、 NEUPAN	平衡模型精度与计算效率、减少对数据的依赖	需模型先验知识、训练复杂度较高	需实时控制的复杂系统	［86-88］
基于模型的方法	利用数学或统计公式表示物理、先验知识，实现路径规划	图搜索基础：A、D、EBS-A*	全局最优路径	计算复杂度高	结构化环境	［75-77］
		采样基础：RRT/RRT*、DWA	高维空间适用	路径可能不光滑	高维空间	［78-80］
		优化基础： MPC、TEB	动态优化能力强	计算成本高	动态控制	［81， 82］
基于学习的方法	通过数据驱动学习策略，无需显式建模	CADRL、LSTM-RL、SCRL、AMCARL	适应动态环境、支持复杂决策	依赖训练数据分布、奖励函数设计困难、真实场景泛化性弱	动态密集场景、多机器人协作	［83-85］

农业多机器人全覆盖作业关键技术研究进展与展望

Progress and Prospects of Research on Key Technologies for Agricultural Multi-Robot Full Coverage Operations

在线阅读

知网下载

本地下载

可视化

摘要/Abstract

引用本文

使用本文

图/表 11

参考文献 107

相关文章 6

编辑推荐

Metrics

本文评价

分类	优势	局限性	适用场景	参考文献
PID	结构简单，易于实现	复杂环境适应性差	平坦农田直线作业	［93， 94］
LQR	能耗优化，稳定性强	依赖精确模型，抗干扰弱	线性化路径跟踪	［95， 96］
SMC	强鲁棒性，抗参数扰动	存在抖振现象	复杂路面作业	［97， 98］
MPC	显式处理约束，优化性能	计算负担重	高速稳定作业	［99-101］
智能控制	无模型自适应，环境适应性强	规则设计依赖经验，需大量训练数据	复杂非结构化农田	［102-104］
协同控制	抗通信延迟，多机同步，自主保持队形	系统复杂度高，限于小型机器人集群	大规模多机编队，农机集群作业	［105，106］

[1]	马楠, 曹姗姗, 白涛, 孔繁涛, 孙伟. 农业复杂场景下多机器人协同SLAM研究进展与展望[J]. 智慧农业(中英文), 2024, 6(6): 23-43.
[2]	何勇, 黄震宇, 杨宁远, 李禧尧, 王玉伟, 冯旭萍. 设施农业机器人导航关键技术研究进展与展望[J]. 智慧农业(中英文), 2024, 6(5): 1-19.
[3]	徐济双, 焦俊, 李淼, 李华龙, 杨选将, 刘先旺, 郭盼盼, 麻之润. 融合改进A*算法与模糊PID的病死畜禽运输机器人路径规划与运动控制方法[J]. 智慧农业(中英文), 2023, 5(4): 127-136.
[4]	周龙港, 刘婷, 卢劲竹. 基于Floyd和改进遗传算法的丘陵地区农田遍历路径规划[J]. 智慧农业(中英文), 2023, 5(4): 45-57.
[5]	毛文菊, 刘恒, 王东飞, 杨福增, 刘志杰. 面向果园多机器人通信的AODV路由协议改进设计与测试[J]. 智慧农业(中英文), 2021, 3(1): 96-108.
[6]	朱姜蓬, 岑海燕, 何立文, 何勇. 农情监测多旋翼无人机系统开发及性能评估[J]. 智慧农业(中英文), 2019, 1(1): 43-52.