Robotic Fertilisation Using Localisation Systems Based on Point Clouds in Strip-Cropping Fields

Ulloa, Christyan Cruz; Krus, Anne; Barrientos, Antonio; Cerro, Jaime del; Valero, Constantino

doi:10.3390/agronomy11010011

Cited by 13 publications

(10 citation statements)

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“… • Acquisition of vegetable characteristics in cultivation rows through a lidar system in Krus et al (2020) . • The platform location system within the crop using a point cloud processing based system described in Cruz Ulloa et al (2021) . …”

Section: Methodsmentioning

confidence: 99%

“…• The platform location system within the crop using a point cloud processing based system described in Cruz Ulloa et al (2021) .…”

Section: Methodsmentioning

confidence: 99%

“…On the other hand, the main applications of laser-type sensors are reconstructing vegetative environments for their analysis using clustering techniques and point cloud processing. ( Krus et al, 2020 ; Mesas-Carrascosa et al, 2020 ; Cruz Ulloa et al, 2021 ; Schunck et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

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Trend Technologies for Robotic Fertilization Process in Row Crops

et al. 2022

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The development of new sensory and robotic technologies in recent years and the increase in the consumption of organic vegetables have allowed the generation of specific applications around precision agriculture seeking to satisfy market demand. This article analyzes the use and advantages of specific optical sensory systems for data acquisition and processing in precision agriculture for Robotic Fertilization process. The SUREVEG project evaluates the benefits of growing vegetables in rows, using different technological tools like sensors, embedded systems, and robots, for this purpose. A robotic platform has been developed consisting of Laser Sick AG LMS100 × 3, Multispectral, RGB sensors, and a robotic arm equipped with a fertilization system. Tests have been developed with the robotic platform in cabbage and red cabbage crops, information captured with the different sensors, allowed to reconstruct rows crops and extract information for fertilization with the robotic arm. The main advantages of each sensory have been analyzed with an quantitative comparison, based on information provided by each one; such as Normalized Difference Vegetation Index index, RGB Histograms, Point Cloud Clusters). Robot Operating System processes this information to generate trajectory planning with the robotic arm and apply the individual treatment in plants. Main results show that the vegetable characterization has been carried out with an efficiency of 93.1% using Point Cloud processing, while the vegetable detection has obtained an error of 4.6% through RGB images.

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Section: Methodsmentioning

confidence: 99%

“…• The platform location system within the crop using a point cloud processing based system described in Cruz Ulloa et al (2021) .…”

Section: Methodsmentioning

confidence: 99%

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Trend Technologies for Robotic Fertilization Process in Row Crops

et al. 2022

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“…The original point cloud data obtained from LiDAR scans of the target tree were extracted using MATLAB. The data were sorted using scanning angles of −45–225° in 0.5° increments by converting polar coordinates to Cartesian coordinates [ 28 , 38 , 39 ]. The (x) values of the points that exceeded the horizontal distance between the LiDAR device the and tree trunk (2 m) were excluded from the dataset.…”

Section: Methodsmentioning

confidence: 99%

CMPC: An Innovative Lidar-Based Method to Estimate Tree Canopy Meshing-Profile Volumes for Orchard Target-Oriented Spray

Zhai

Wang

et al. 2021

Sensors

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Canopy characterization detection is essential for target-oriented spray, which minimizes pesticide residues in fruits, pesticide wastage, and pollution. In this study, a novel canopy meshing-profile characterization (CMPC) method based on light detection and ranging (LiDAR)point-cloud data was designed for high-precision canopy volume calculations. First, the accuracy and viability of this method were tested using a simulated canopy. The results show that the CMPC method can accurately characterize the 3D profiles of the simulated canopy. These simulated canopy profiles were similar to those obtained from manual measurements, and the measured canopy volume achieved an accuracy of 93.3%. Second, the feasibility of the method was verified by a field experiment where the canopy 3D stereogram and cross-sectional profiles were obtained via CMPC. The results show that the 3D stereogram exhibited a high degree of similarity with the tree canopy, although there were some differences at the edges, where the canopy was sparse. The CMPC-derived cross-sectional profiles matched the manually measured results well. The CMPC method achieved an accuracy of 96.3% when the tree canopy was detected by LiDAR at a moving speed of 1.2 m/s. The accuracy of the LiDAR system was virtually unchanged when the moving speeds was reduced to 1 m/s. No detection lag was observed when comparing the start and end positions of the cross-section. Different CMPC grid sizes were also evaluated. Small grid sizes (0.01 m × 0.01 m and 0.025 m × 0.025 m) were suitable for characterizing the finer details of a canopy, whereas grid sizes of 0.1 m × 0.1 m or larger can be used for characterizing its overall profile and volume. The results of this study can be used as a technical reference for the development of a LiDAR-based target-oriented spray system.

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“…The task of harvesting chrysanthemum at a specific maturity stage usually requires shortening the reasoning time on small devices, which poses a serious challenge to computer vision algorithms. Although some methods are specially designed for mobile CPUs [4,29,30], the depth-wise separable convolution techniques adopted by these methods are not compatible with industrial integrated circuit (IC) design, examples of which include application-specific integrated circuits (ASICs) and edge computing systems. In view of this, a lightweight network based on feature fusion is proposed in this paper, which can be deployed on a mobile GPU [31] without compromising performance.…”

Section: Introductionmentioning

confidence: 99%

Detecting the Early Flowering Stage of Tea Chrysanthemum Using the F-YOLO Model

Nyalala

Chen

2021

Agronomy

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Detecting the flowering stage of tea chrysanthemum is a key mechanism of the selective chrysanthemum harvesting robot. However, under complex, unstructured scenarios, such as illumination variation, occlusion, and overlapping, detecting tea chrysanthemum at a specific flowering stage is a real challenge. This paper proposes a highly fused, lightweight detection model named the Fusion-YOLO (F-YOLO) model. First, cutout and mosaic input components are equipped, with which the fusion module can better understand the features of the chrysanthemum through slicing. In the backbone component, the Cross-Stage Partial DenseNet (CSPDenseNet) network is used as the main network, and feature fusion modules are added to maximize the gradient flow difference. Next, in the neck component, the Cross-Stage Partial ResNeXt (CSPResNeXt) network is taken as the main network to truncate the redundant gradient flow. Finally, in the head component, the multi-scale fusion network is adopted to aggregate the parameters of two different detection layers from different backbone layers. The results show that the F-YOLO model is superior to state-of-the-art technologies in terms of object detection, that this method can be deployed on a single mobile GPU, and that it will be one of key technologies to build a selective chrysanthemum harvesting robot system in the future.

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Robotic Fertilisation Using Localisation Systems Based on Point Clouds in Strip-Cropping Fields

Cited by 13 publications

References 46 publications

Trend Technologies for Robotic Fertilization Process in Row Crops

Trend Technologies for Robotic Fertilization Process in Row Crops

CMPC: An Innovative Lidar-Based Method to Estimate Tree Canopy Meshing-Profile Volumes for Orchard Target-Oriented Spray

Detecting the Early Flowering Stage of Tea Chrysanthemum Using the F-YOLO Model

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