农业轮式机器人三维环境感知技术研究进展

doi:10.12133/j.smartag.SA202308006

摘要/Abstract

摘要：

［目的/意义］作为未来农机装备的研究重点，农业轮式机器人正向着智能化与多功能化的方向发展。三维环境感知技术因其获取的信息量丰富、复杂环境下的鲁棒性和适应性好，成为了农业轮式机器人智能化无人作业的基础与关键，其发展水平直接影响到包括农业轮式机器人在内的无人农机的作业质量与效率。［进展］本文首先总结了农业轮式机器人和农业环境感知技术的发展现状，分析了不同类型农业轮式机器人的使用特点和应用现状。其次分析了在农业轮式机器人上实现三维环境感知所主要使用的感知设备及其对应的关键技术，重点阐述了基于激光雷达、视觉传感器和多传感器融合的农业轮式机器人三维环境感知技术的研究进展。［结论/展望］结合农业作业特点与实际需求，指出了农业轮式机器人三维环境感知技术在适用性、环境信息处理和感知效果等方面存在的一些问题，并提出了提升传感器的农业适用性、发展基于深度学习的农业环境感知技术、发展智能化的高速在线多传感器信息融合技术三个方面的建议，以期为农业轮式机器人三维环境感知技术发展提供参考与借鉴。

关键词: 轮式机器人, 三维环境感知, 激光雷达, 视觉传感器, 多传感器融合, 自主导航

Abstract:

[Significance] As the research focus of future agricultural machinery, agricultural wheeled robots are developing in the direction of intelligence and multi-functionality. Advanced environmental perception technologies serve as a crucial foundation and key components to promote intelligent operations of agricultural wheeled robots. However, considering the non-structured and complex environments in agricultural on-field operational processes, the environmental information obtained through conventional 2D perception technologies is limited. Therefore, 3D environmental perception technologies are highlighted as they can provide more dimensional information such as depth, among others, thereby directly enhancing the precision and efficiency of unmanned agricultural machinery operation. This paper aims to provide a detailed analysis and summary of 3D environmental perception technologies, investigate the issues in the development of agricultural environmental perception technologies, and clarify the future key development directions of 3D environmental perception technologies regarding agricultural machinery, especially the agricultural wheeled robot. [Progress] Firstly, an overview of the general status of wheeled robots was introduced, considering their dominant influence in environmental perception technologies. It was concluded that multi-wheel robots, especially four-wheel robots, were more suitable for the agricultural environment due to their favorable adaptability and robustness in various agricultural scenarios. In recent years, multi-wheel agricultural robots have gained widespread adoption and application globally. The further improvement of the universality, operation efficiency, and intelligence of agricultural wheeled robots is determined by the employed perception systems and control systems. Therefore, agricultural wheeled robots equipped with novel 3D environmental perception technologies can obtain high-dimensional environmental information, which is significant for improving the accuracy of decision-making and control. Moreover, it enables them to explore effective ways to address the challenges in intelligent environmental perception technology. Secondly, the recent development status of 3D environmental perception technologies in the agriculture field was briefly reviewed. Meanwhile, sensing equipment and the corresponding key technologies were also introduced. For the wheeled robots reported in the agriculture area, it was noted that the applied technologies of environmental perception, in terms of the primary employed sensor solutions, were divided into three categories: LiDAR, vision sensors, and multi-sensor fusion-based solutions. Multi-line LiDAR had better performance on many tasks when employing point cloud processing algorithms. Compared with LiDAR, depth cameras such as binocular cameras, TOF cameras, and structured light cameras have been comprehensively investigated for their application in agricultural robots. Depth camera-based perception systems have shown superiority in cost and providing abundant point cloud information. This study has investigated and summarized the latest research on 3D environmental perception technologies employed by wheeled robots in agricultural machinery. In the reported application scenarios of agricultural environmental perception, the state-of-the-art 3D environmental perception approaches have mainly focused on obstacle recognition, path recognition, and plant phenotyping. 3D environmental perception technologies have the potential to enhance the ability of agricultural robot systems to understand and adapt to the complex, unstructured agricultural environment. Furthermore, they can effectively address several challenges that traditional environmental perception technologies have struggled to overcome, such as partial sensor information loss, adverse weather conditions, and poor lighting conditions. Current research results have indicated that multi-sensor fusion-based 3D environmental perception systems outperform single-sensor-based systems. This superiority arises from the amalgamation of advantages from various sensors, which concurrently serve to mitigate individual shortcomings. [Conclusions and Prospects] The potential of 3D environmental perception technology for agricultural wheeled robots was discussed in light of the evolving demands of smart agriculture. Suggestions were made to improve sensor applicability, develop deep learning-based agricultural environmental perception technology, and explore intelligent high-speed online multi-sensor fusion strategies. Currently, the employed sensors in agricultural wheeled robots may not fully meet practical requirements, and the system's cost remains a barrier to widespread deployment of 3D environmental perception technologies in agriculture. Therefore, there is an urgent need to enhance the agricultural applicability of 3D sensors and reduce production costs. Deep learning methods were highlighted as a powerful tool for processing information obtained from 3D environmental perception sensors, improving response speed and accuracy. However, the limited datasets in the agriculture field remain a key issue that needs to be addressed. Additionally, multi-sensor fusion has been recognized for its potential to enhance perception performance in complex and changeable environments. As a result, it is clear that 3D environmental perception technology based on multi-sensor fusion is the future development direction of smart agriculture. To overcome challenges such as slow data processing speed, delayed processed data, and limited memory space for storing data, it is essential to investigate effective fusion schemes to achieve online multi-source information fusion with greater intelligence and speed.

Key words: wheeled robot, 3D environment perception, laser radar, vision sensors, multi-sensor fusion, autonomous navigation

陈睿韵, 田文斌, 鲍海波, 李端, 谢鑫浩, 郑永军, 谭彧. 农业轮式机器人三维环境感知技术研究进展[J]. 智慧农业(中英文), 2023, 5(4): 16-32.

CHEN Ruiyun, TIAN Wenbin, BAO Haibo, LI Duan, XIE Xinhao, ZHENG Yongjun, TAN Yu. Three-Dimensional Environment Perception Technology for Agricultural Wheeled Robots: A Review[J]. Smart Agriculture, 2023, 5(4): 16-32.

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基于多传感器融合的三维环境感知技术相关研究

作者	传感器方案	特点和效果
Underwood等^［83］	单线激光雷达、全景相机	将激光雷达扫描系统获取的三维点云投影至图像中，通过建立的3D模型估计果树冠层体积，进而预测单株产量
Reina等^［84］	多线激光雷达、双目相机、毫米波雷达	提出了一个立体相机与多线激光雷达的统计框架和一种立体相机与毫米波雷达融合方法用于障碍物检测，其中前者的检测准确率达到96.5%
Yasukawa等^［85］	深度相机、红外摄像机	基于红外摄像机和深度相机设计了一个番茄采摘机器人，前者用于检测番茄的果实，后者用于确定番茄的三维位置，检测正确率达到88.1%
Benet等^［86］	单线激光雷达、工业相机、IMU	融合工业相机、单线激光雷达和IMU的数据进行果树行识别与直线拟合，当机器人以2 m/s的速度自动跟踪果行时平均横向误差在0.1~0.4 m之间
Yan等^［87］	双目相机、深度相机、IMU	将以双目相机和IMU为基础的视觉惯性里程计与深度相机进行融合，完成温室环境中的实时定位并建立三维地图
褚福春^［88］	多线激光雷达、IMU	通过IMU提升激光雷达的定位精度，采集果园三维点云数据拟合出果树行直线，进而得到导航路径实现自主导航，0.8和1.0 m/s的速度下拟合的导航路径平均横向偏差分别为0.084和0.108 m
刘宇峰^［89］	单线激光雷达、双目相机	单线激光雷达与双目相机分别获取障碍物定位数据与尺寸测量数据，进而实现自主导航农机单/多障碍物避障，最终平均测量误差为0.03 m、平均定位误差小于0.04 m
何蒙^［90］	单线激光雷达、深度相机	在单线激光雷达获取周围环境点云数据的基础上使用深度相机剔除无效点，根据剩余目标位置实现棚架果园的导航。以0.3 m/s的速度行进时平均横向偏差在0.027 3~0.031 4 cm之间
林乙蘅^［91］	多线激光雷达、双目相机、INS、BDS	使用多传感器融合的方法检测道路两侧果树及障碍物信息，构建环境三维点云图，完成路径规划与路径追踪，其中直线路径跟踪精度在0.02 m以下

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应用场景	名称	功能简介
田间生产轮式机器人	播种机器人	依托轮式移动机构行进，利用播种机构进行播种作业
	田间管理机器人	利用传感系统和智能控制系统等，完成喷药和追肥等田间生产管理作业
	大田收获机器人	用于大田作物的智能收获
果园生产轮式机器人	除草机器人	通过环境感知和自主导航系统等完成果园作物间除草工作
	植保机器人	根据作物病虫害情况进行对靶喷药等智能植保作业
	收获采摘机器人	识别并定位成熟果实，并利用执行机构进行果实采摘
设施农业轮式机器人	育苗机器人	根据作物种苗的生长情况实现智能移栽等功能
设施农业轮式机器人	作物巡检机器人	依托轮式移动机构行进，实时巡检作物生长状况
畜牧养殖轮式机器人	饲喂机器人	用于畜禽的饲料投喂，使用轮式移动机构自主行进并投喂饲料
畜牧养殖轮式机器人	养殖巡检机器人	实时巡检养殖场的环境状况和畜禽的养殖状况
水产养殖轮式机器人	投饵机器人	用于部分场景下的水产品饵料投喂

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