果园自主导航兼自动对靶喷雾机器人

doi:10.12133/j.smartag.SA202207008

摘要/Abstract

摘要：

为同时实现果园智能植保机自主导航及自动对靶喷雾，研制了一种果园自主导航兼自动对靶喷雾机器人。首先采用单个3D LiDAR（Light Detection and Ranging）采集果树信息确定兴趣区（Region of Interest，ROI），对ROI内点云进行2D化处理得到果树质心坐标，通过随机一致性（Random Sample Consensus，RANSAC）算法得到果树行线，并确定果树行中间线（导航线），进而控制机器人沿导航线行驶。通过编码器及惯性测量单元（Inertial Measurement Unit，IMU）确定机体速度及位置，IMU矫正采集到的果树分区冠层信息，最后通过程序判断分区冠层的有无控制喷头是否喷雾。结果表明，机器人自主导航时最大横向定位偏差为21.8 cm，最大航向偏角为4.02°，相比于传统连续喷雾机施药液量、空中漂移量及地面流失量分别减少20.06%、38.68%及51.40%。本研究通过单个3D LiDAR、编码器及IMU在保证喷雾效果的前提下，实现了喷雾机器人自主导航及自动对靶喷雾，降低了农药使用量及飘失量。

关键词: 自主导航, 对靶喷雾, LiDAR, 随机一致性算法, 机器人, 惯性测量单元

Abstract:

To realize the autonomous navigation and automatic target spraying of intelligent plant protect machinery in orchard, in this study, an autonomous navigation and automatic target spraying robot for orchards was developed. Firstly, a single 3D light detection and ranging (LiDAR) was used to collect fruit trees and other information around the robot. The region of interest (ROI) was determined using information on the fruit trees in the orchard (plant spacing, plant height, and row spacing), as well as the fundamental LiDAR parameters. Additionally, it must be ensured that LiDAR was used to detect the canopy information of a whole fruit tree in the ROI. Secondly, the point clouds within the ROI was two-dimension processing to obtain the fruit tree center of mass coordinates. The coordinate was the location of the fruit trees. Based on the location of the fruit trees, the row lines of fruit tree were obtained by random sample consensus (RANSAC) algorithm. The center line (navigation line) of the fruit tree row within ROI was obtained through the fruit tree row lines. The robot was controlled to drive along the center line by the angular velocity signal transmitted from the computer. Next, the ATRS's body speed and position were determined by encoders and the inertial measurement unit (IMU). And the collected fruit tree zoned canopy information was corrected by IMU. The presence or absence of fruit tree zoned canopy was judged by the logical algorithm designed. Finally, the nozzles were controlled to spray or not according to the presence or absence of corresponding zoned canopy. The conclusions were obtained. The maximum lateral deviation of the robot during autonomous navigation was 21.8 cm, and the maximum course deviation angle was 4.02°. Compared with traditional spraying, the automatic target spraying designed in this study reduced pesticide volume, air drift and ground loss by 20.06%, 38.68% and 51.40%, respectively. There was no significant difference between the automatic target spraying and the traditional spraying in terms of the percentage of air drift. In terms of the percentage of ground loss, automatic target spraying had 43% at the bottom of the test fruit trees and 29% and 28% at the middle of the test fruit trees and the left and right neighboring fruit trees. But in traditional spraying, the percentage of ground loss was, in that sequence, 25%, 38%, and 37%. The robot developted can realize autonomous navigation while ensuring the spraying effect, reducing the pesticides volume and loss.

Key words: automatic navigation, automatic target spraying, LiDAR, random sample consensus algorithm, robot, IMU

中图分类号:

TP242

刘理民, 何雄奎, 刘伟洪, 刘紫嫣, 韩虎, 李扬帆. 果园自主导航兼自动对靶喷雾机器人[J]. 智慧农业(中英文), 2022, 4(3): 63-74.

LIU Limin, HE Xiongkui, LIU Weihong, LIU Ziyan, HAN Hu, LI Yangfan. Autonomous Navigation and Automatic Target Spraying Robot for Orchards[J]. Smart Agriculture, 2022, 4(3): 63-74.

参考文献

1	刘理民, 何雄奎, 刘亚佳. 多功能果园作业平台安全性研究进展[J]. 农业工程, 2020, 10(12): 7-13.
1	LIU L, HE X, LIU Y. Research progress on safety of multifunctional orchard operating platform[J]. Agricultural Engineering, 2020, 10(12): 7-13.
2	周良富, 薛新宇, 周立新, 等. 果园变量喷雾技术研究现状与前景分析[J]. 农业工程学报, 2017, 33(23): 80-92.
2	ZHOU L, XUE X, ZHOU L, et al. Research situation and progress analysis on orchard variable rate spraying technology[J]. Transactions of the CSAE, 2017, 33(23): 80-92.
3	MAO W, LIU H, HAO W, et al. Development of a combined orchard harvesting robot navigation system[J]. Remote Sensing, 2022, 14(3): ID 675.
4	PEREZ-RUIZ M, UPADHYAYA K S. GNSS in precision agricultural operations[M]. London: IntechOpen, 2012.
5	何雄奎. 高效植保机械与精准施药技术进展[J]. 植物保护学报, 2022, 49(1): 389-397.
5	HE X. Research and development of efficient plant protection equipment and precision spraying technology in China: A review[J]. Journal of Plant Protection, 2022, 49(1): 389-397.
6	何雄奎. 中国精准施药技术和装备研究现状及发展建议[J]. 智慧农业(中英文), 2020, 2(1):133-146.
6	HE X. Research progress and developmental recommendations on precision spraying technology and equipment in China[J]. Smart Agriculture, 2020, 2(1): 133-146.
7	郭成洋. 果园智能车辆自动导航系统关键技术研究[D]. 杨凌: 西北农林科技大学, 2020.
7	GUO C. Key technologies of automatic vehicles navigation system in orchard[D]. Yangling: Northwest A&F University, 2020.
8	LI M, IMOU K, WAKABAYASHI K, et al. Review of research on agricultural vehicle autonomous guidance[J]. International Journal of Agricultural and Biological Engineering, 2009, 2(3): 1-16.
9	VROCHIDOU E, OUSTADAKIS D, KEFALAS A, et al. Computer vision in self-steering tractors[J]. Machines, 2022, 10(2): ID 129.
10	RADCLIFFE J, COX J, BULANON D M, et al. Machine vision for orchard navigation[J]. Computers in Industry, 2018, 98: 165-171.
11	闫成功, 徐丽明, 袁全春, 等. 基于双目视觉的葡萄园变量喷雾控制系统设计与试验[J]. 农业工程学报, 2021, 37(11): 13-22.
11	YAN C, XU L, YUAN Q, et al. Design and experiments of vineyard variable spraying control system based on binocular vision[J]. Transactions of the CSAE, 2021, 37(11): 13-22.
12	HESS W, KOHLER D, RAPP H, et al. Real-time loop closure in 2D LIDAR SLAM. Proceedings[C]// IEEE International Conference on Robotics and Automation. Piscataway, New York, USA: IEEE, 2016.
13	SANTOS L C, AGUIAR A S, SANTOS F N, et al. Navigation stack for robots working in steep slope vineyard[M]. Berlin, Germany: Springer Publisher, 2021.
14	JIANG S, WANG S, YI Z, et al. Autonomous navigation system of greenhouse mobile robot based on 3D LiDAR and 2D LiDAR SLAM[J]. Frontiers in Plant Science, 2022, 13: ID 815218.
15	刘伟洪, 何雄奎, 刘亚佳, 等. 果园行间3D LiDAR导航方法[J]. 农业工程学报, 2021, 37(9): 165-174.
15	LIU W, HE X, LIU Y, et al. Navigation method between rows for orchard based on 3D LiDAR[J]. Transactions of the CSAE, 2021, 37(9): 165-174.
16	FRANK D L, STARCHER S, CHANDRAN R S. Comparison of mating disruption and insecticide application for control of peach tree borer and lesser peachtree borer (Lepidoptera: Sesiidae) in Peach[J]. Insects, 2020, 11(10): ID 658.
17	姜红花, 白鹏, 刘理民, 等. 履带自走式果园自动对靶风送喷雾机研究[J]. 农业机械学报, 2016, 47(S1): 189-195.
17	JIANG H, BAI P, LIU L, et al. Caterpillar self-propelled and air-assisted orchard sprayer with automatic target spray system[J]. Transactions of the CSAM, 2016, 47(S1): 189-195.
18	姜红花, 刘理民, 柳平增, 等. 面向精准喷雾的果树冠层体积在线计算方法[J]. 农业机械学报, 2019, 50(7): 120-129.
18	JIANG H, LIU L, LIU P, et al. Online calculation method of fruit trees canopy volume for precision spray[J]. Transactions of the CSAM, 2019, 50(7): 120-129.
19	刘理民. 基于果树冠层探测的变量喷雾技术研究与试验[D]. 泰安: 山东农业大学, 2019.
19	LIU L. Research and experiment of variable spray technology based on fruit trees canopy detecting[D]. Taian: Shanong Agricultural University, 2019.
20	李龙龙, 何雄奎, 宋坚利, 等. 基于变量喷雾的果园自动仿形喷雾机的设计与试验[J]. 农业工程学报, 2017, 33(1): 70-76.
20	LI L, HE X, SONG J, et al. Design and experiment of automatic profiling orchard sprayer based on variable air volume and flow rate[J]. Transactions of the CSAE, 2017, 33(1): 70-76.
21	ZHANG S, GUO C, GAO Z, et al. Research on 2D laser automatic navigation control for standardized orchard[J]. Applied Sciences (Switzerland), 2020, 10(8): ID 2763.
22	窦汉杰, 翟长远, 王秀, 等. 基于LiDAR的果园对靶变量喷药控制系统设计与试验[J]. 农业工程学报, 2022, 38(3): 11-21.
22	DOU H, ZHAI C, WANG X, et al. Design and experiment of the orchard target variable spraying control system based on LiDAR[J]. Transactions of the CASE, 2022, 38(3): 11-21.
23	刘理民, 张晓辉, 石光智, 等. 多态自动对靶风送式喷雾试验台的设计与试验[J]. 江苏农业科学, 2019, 47(13): 260-263.
24	刘理民, 王金宇, 毛文华, 等. 基于传感器融合阵列的果树冠层信息采集方法[J]. 农业机械学报, 2018, 49(S1): 347-353, 359.
24	LIU L, WANG J, MAO W, et al. Canopy information acquisition method of fruit trees based on fused sensor array[J]. Transactions of the CSAM, 2018, 49(S1): 347-353, 359.
25	李龙龙, 何雄奎, 宋坚利, 等. 果园仿形变量喷雾与常规风送喷雾性能对比试验[J]. 农业工程学报, 2017, 33(16): 56-63.
25	LI L, HE X, SONG J, et al. Comparative experiment on profile variable rate spray and conventional air assisted spray in orchards[J]. Transactions of the CSAE, 2017, 33(16): 56-63.
26	GIL E, ESCOLà A, ROSELL J R, et al. Variable rate application of plant protection products in vineyard using ultrasonic sensors[J]. Crop Protection, 2007, 26(8): 1287-1297.

[1]	朱衍俊, 杜文圣, 王春颖, 刘平, 李祥. 自然环境中鲜食葡萄快速识别与采摘点自动定位方法[J]. 智慧农业(中英文), 2023, 5(2): 23-34.
[2]	胡松涛, 翟瑞芳, 王应华, 刘志, 朱剑忠, 任荷, 杨万能, 宋鹏. 基于多源数据的马铃薯植株表型参数提取[J]. 智慧农业(中英文), 2023, 5(1): 132-145.
[3]	段罗佳, 杨福增, 闫彬, 史帅旗, 秦纪凤. 苹果生产智能底盘与除草及收获装备技术研究进展[J]. 智慧农业(中英文), 2022, 4(3): 24-41.
[4]	杨亮, 熊本海, 王辉, 陈睿鹏, 赵一广. 家畜饲喂机器人研究进展与发展展望[J]. 智慧农业(中英文), 2022, 4(2): 86-98.
[5]	黄梓宸, SUGIYAMA Saki. 日本设施农业采收机器人研究应用进展及对中国的启示[J]. 智慧农业(中英文), 2022, 4(2): 135-149.
[6]	范道全, 张美娜, 潘健, 吕晓兰. 基于靶标叶面积密度参数的变量喷雾控制系统开发与性能试验[J]. 智慧农业(中英文), 2021, 3(3): 60-69.
[7]	阳旭, 胡松涛, 王应华, 杨万能, 翟瑞芳. 利用多时序激光点云数据提取棉花表型参数方法[J]. 智慧农业(中英文), 2021, 3(1): 51-62.
[8]	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.
[9]	周航, 张顺路, 翟毅豪, 王松, 张春龙, 张俊雄, 李伟. 天然橡胶割胶机器人视觉伺服控制方法与割胶试验[J]. 智慧农业（中英文）, 2020, 2(4): 56-64.
[10]	李扬, 张萍, 苑进, 刘雪美. 白芦笋采收机器人视觉定位与采收路径优化方法[J]. 智慧农业（中英文）, 2020, 2(4): 65-78.
[11]	冯青春, 王秀, 邱权, 张春凤, 李斌, 徐瑞峰, 陈立平. 畜禽舍防疫消毒机器人设计与试验[J]. 智慧农业（中英文）, 2020, 2(4): 79-88.
[12]	郭威, 吴华瑞, 朱华吉. 设施温室影像采集与环境监测机器人系统设计及应用[J]. 智慧农业（中英文）, 2020, 2(3): 48-60.
[13]	李道亮, 刘畅. 人工智能在水产养殖中研究应用分析与未来展望[J]. 智慧农业（中英文）, 2020, 2(3): 1-20.
[14]	冯青春, 陈建, 成伟, 王秀. 面向番茄植株相近色目标识别的多波段图像融合方法[J]. 智慧农业（中英文）, 2020, 2(2): 126-134.
[15]	刘守阳, 金时超, 郭庆华, 朱艳, Baret Fred. 基于数字化植物表型平台（D3P）的田间小麦冠层光截获算法开发[J]. 智慧农业（中英文）, 2020, 2(1): 87-98.