用于温室喷雾剂三维目标检测的固态激光雷达的静态和动态性能评估

IF 1.2 4区 农林科学 Q3 AGRICULTURAL ENGINEERING
Zhihong Zhang, Jianing Long, Qinghui Lai, Qingmeng Zhu, Hao He, Ramón Salcedo, Tingting Yan
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引用次数: 0

摘要

重点介绍了用于目标检测的廉价固态激光雷达测量精度的综合评估。开发了一种静态和动态条件下获取不同形状物体点云的算法。利用伪彩色图像评估规则形状的纸盒和不规则的人造植物的表面。将固态激光雷达集成到温室可变速率喷雾应用中的建议。摘要一个有效的温室变喷系统需要准确的植物冠层结构参数,以保证适当的农药用量调整。传统的激光系统集成到喷雾系统中可以提供精确的植物点云数据,但仍然存在较高的费用。本研究考察了最近推出的具有成本效益的高分辨率固态激光雷达(英特尔RealSense L515)的性能及其在温室喷雾应用中的潜力。此外,还针对该固态激光雷达开发了一种专门的点云获取算法,以获取目标的几何参数。为了评估激光雷达传感器在温室喷雾应用中的适用性,使用五个不同大小的规则形状的纸箱和三个具有复杂几何形状的人工植物来评估激光雷达传感器和算法的性能。分析了物体与激光雷达传感器之间的水平距离(0.5、1.0、1.5、2.0、2.5和3.0 m)、激光雷达传感器相对于地面的倾斜角(45°、60°和75°)、激光雷达传感器距离地面的高度(0.3 ~ 0.8 m,间隔0.5 m)以及激光雷达传感器的前进速度(0.1、0.3、0.6和0.9 m s-1)等因素。结果表明,该激光雷达传感器的最佳探测距离为1.0 m。增加或减少物体相对于激光雷达传感器的探测距离会降低测量精度。激光雷达传感器的高度和倾斜角度会影响几何变量的精度。然而,从固态激光雷达获得的几何参数显示出与人工测量结果良好的对应关系。总体检验的均方根误差(RMSE)和变异系数(CV)在X(长度)方向上分别为14.3 mm和14.3%,在Y(宽度)方向上分别为14.3 mm和14.3%,在Z(高度)方向上分别为10.8 mm和10.8%。使用固态激光雷达测量的物体和使用RGB相机获得的图像的轮廓边缘相似度得分超过0.90。这些发现表明,所提出的固态激光雷达和专门设计的算法可以有效地用于获取物体的几何参数,并开发用于温室应用的精确可变速率喷涂系统。关键词:冠层结构测量,点云,精准农业,精准喷雾技术,可变速率喷雾系统
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Static and Dynamic Performance Evaluation of a Solid-State LiDAR for 3D Object Detection in Greenhouse Spray Applications
Highlights Comprehensive evaluation of the measurement accuracy of an inexpensive solid-state LiDAR for object detection. Development of an algorithm to acquire point clouds of objects with various shapes under both static and dynamic conditions. Utilization of pseudo-color images to assess the surfaces of regular-shaped cartons and irregular artificial plants. Proposal for integrating the solid-state LiDAR into variable-rate spray applications for greenhouses. Abstract. An effective variable-rate spraying system for greenhouses requires accurate canopy structure parameters of plants to ensure proper pesticide dosage adjustment. While conventional laser systems integrated into spray systems can provide precise point cloud data of plants, they still present a high expense. This study examines the performance of a recently introduced, cost-effective, and high-resolution solid-state LiDAR (Intel RealSense L515) in relation to its potential for greenhouse spray applications. Additionally, a specialized point cloud acquisition algorithm was developed for this solid-state LiDAR to obtain the geometrical parameters of objects. To assess the LiDAR sensor's suitability for greenhouse spray applications, the performance of the LiDAR sensor and the algorithm was evaluated using five different sized regular-shaped cartons and three artificial plants with complex geometry. Various factors were analyzed, such as the horizontal distances between objects and the LiDAR sensor (0.5, 1.0, 1.5, 2.0, 2.5, and 3.0 m), the tilt angle of the LiDAR sensor relative to the ground (45°, 60°, and 75°), the height of the LiDAR sensor from the ground (ranging from 0.3 to 0.8 m with 0.5 m distance intervals), and the forward speed of the LiDAR sensor (0.1, 0.3, 0.6, and 0.9 m s-1). The findings revealed that the optimal detection distance for this LiDAR sensor is 1.0 m. Increasing or decreasing the detection distance of the object relative to the LiDAR sensor diminished the measurement accuracy. The accuracy of the derived geometrical variables was affected by the height and tilt angle of the LiDAR sensor. Nevertheless, the geometrical parameters obtained from the solid-state LiDAR showed a favorable correspondence with the results of manual measurements. The highest root mean square error (RMSE) and coefficient of variation (CV) for the overall test were 14.3 mm and 14.3% in the X (length) direction, 14.3 mm and 14.3% in the Y (width) direction, and 10.8 mm and 10.8% in the Z (height) direction, respectively. The contour Edge Similarity Score for objects measured using the solid-state LiDAR and images obtained with an RGB camera exceeded 0.90. These findings suggest that the proposed solid-state LiDAR and the specifically designed algorithm could be effectively adapted to acquire the geometrical parameters of objects and to develop precise variable-rate spraying systems for greenhouse applications. Keywords: Canopy structure measurements, Point cloud, Precision agriculture, Precision spray technology, Variable-rate spraying systems.
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