An autonomous spraying robot architecture for sucker management in large-scale hazelnut orchards

IF 4.2 2区 计算机科学 Q2 ROBOTICS Journal of Field Robotics Pub Date : 2023-06-15 DOI:10.1002/rob.22217
Martina Lippi, Matteo Santilli, Renzo Fabrizio Carpio, Jacopo Maiolini, Emanuele Garone, Valerio Cristofori, Andrea Gasparri
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Abstract

In this work, motivated by the precision agriculture (PA) paradigm, we address the problem of managing hazelnut suckering plants on a per-plant basis in a large-scale orchard. Suckering plants, or shortly, suckers, are basal shoots that grow at the base of a tree and compete with the tree itself for nutrients and water. Generally, in large-scale orchards, suckers are treated with the application of herbicide through spraying tractors that continuously spray the crops while navigating the whole orchard. This approach however does not consider the individual needs of each plant and it is definitely not environmentally-friendly since a lot of unnecessary solution is being drained in the soil. For this reason, we propose a novel fully autonomous sucker management architecture that is able to detect the presence of suckers for each plant, by relying on a You Only Look Once (YOLO)-based recognition system, reconstruct them in three-dimension and estimate the amount of herbicide solution needed for the specific plant, based on a data-driven approach. The herbicide solution is applied using a ground robot equipped with an RGB-D camera and a spraying system. This approach allows to significantly reduce pollution and waste. Experimental results both for individual components and for the entire architecture in a real-world (1:1 scale) hazelnut orchard located in Caprarola, Italy, are provided to corroborate the proposed architecture.

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用于大型榛子园吸盘管理的自主喷洒机器人体系结构
在这项工作中,受精准农业(PA)模式的启发,我们解决了在大规模果园中按株管理榛子吸盘植物的问题。吸吮植物,简称吸盘,是生长在树木基部的基生芽,与树木本身争夺养分和水分。一般来说,在大规模果园里,吸盘植物是通过喷洒除草剂来处理的,喷洒除草剂的拖拉机会在整个果园里不停地喷洒作物。然而,这种方法并没有考虑到每种植物的不同需求,而且由于大量不必要的溶液被排入土壤中,因此绝对不环保。为此,我们提出了一种新型的全自动吸盘管理架构,该架构能够通过基于 "只看一眼"(YOLO)的识别系统检测每种植物是否存在吸盘,并根据数据驱动方法对吸盘进行三维重建,估计特定植物所需的除草剂溶液量。除草剂溶液通过配备 RGB-D 摄像头和喷洒系统的地面机器人进行喷洒。这种方法可以大大减少污染和浪费。在意大利卡普拉罗拉真实世界(1:1 比例)的榛子果园中,针对单个组件和整个架构的实验结果都证实了所提出的架构。
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来源期刊
Journal of Field Robotics
Journal of Field Robotics 工程技术-机器人学
CiteScore
15.00
自引率
3.60%
发文量
80
审稿时长
6 months
期刊介绍: The Journal of Field Robotics seeks to promote scholarly publications dealing with the fundamentals of robotics in unstructured and dynamic environments. The Journal focuses on experimental robotics and encourages publication of work that has both theoretical and practical significance.
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