Background: In agriculture, information about the spatial distribution of crop height is valuable for applications such as biomass and yield estimation, or increasing field work efficiency in terms of fertilizing, applying pesticides, irrigation, etc. Established methods for capturing crop height often comprise restrictions in terms of cost and time efficiency, flexibility, and temporal and spatial resolution of measurements. Furthermore, crop height is mostly derived from a measurement of the bare terrain prior to plant growth and measurements of the crop surface when plants are growing, resulting in the need of multiple field campaigns. In our study, we examine a method to derive crop heights directly from data of a plot of full grown maize plants captured in a single field campaign. We assess continuous raster crop height models (CHMs) and individual plant heights derived from data collected with the low-cost 3D camera Microsoft® Kinect® for Xbox One™ based on a comprehensive comparison to terrestrial laser scanning (TLS) reference data. Results: We examine single measurements captured with the 3D camera and a combination of the single measurements, i.e. a combination of multiple perspectives. The quality of both CHMs, and individual plant heights is improved by combining the measurements. R2 of CHMs derived from single measurements range from 0.48 to 0.88, combining all measurements leads to an R2 of 0.89. In case of individual plant heights, an R2 of 0.98 is achieved for the combined measures (with R2 = 0.44 for the single measurements). The crop heights derived from the 3D camera measurements comprise an average underestimation of 0.06 m compared to TLS reference values. Conclusion: We recommend the combination of multiple low-cost 3D camera measurements, removal of measurement artefacts, and the inclusion of correction functions to improve the quality of crop height measurements. Operating low-cost 3D cameras under field conditions on agricultural machines or on autonomous platforms can offer time and cost efficient tools for capturing the spatial distribution of crop heights directly in the field and subsequently to advance agricultural efficiency and productivity. More general, all processes which include the 3D geometry of natural objects can profit from low-cost methods producing 3D geodata.
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机译:背景:在农业中,有关作物高度空间分布的信息对于生物量和产量估算等应用或在施肥,施用农药,灌溉等方面提高田间工作效率具有重要价值。成熟的捕获作物高度的方法通常会受到限制在成本和时间效率,灵活性以及测量的时间和空间分辨率方面。此外,作物高度主要来自于植物生长之前裸露地形的测量以及植物生长时作物表面的测量,因此需要进行多次田间运动。在我们的研究中,我们研究了一种直接从一次田间运动中捕获的完整玉米植株地块数据直接得出作物高度的方法。我们基于与地面激光扫描(TLS)参考数据的全面比较,评估了连续栅格作物高度模型(CHM)和单个植物高度,这些数据是从低成本3D相机Microsoft®Kinect®for Xbox One™收集的数据中得出的。结果:我们检查了3D相机捕获的单个测量值以及单个测量值的组合,即多个视角的组合。通过组合测量,可以提高CHM的质量以及单个工厂的高度。从单次测量得出的CHM的R2在0.48至0.88的范围内,将所有测量结果组合起来得出的R2为0.89。在单个工厂高度的情况下,组合测量的R2为0.98(单个测量的R2 = 0.44)。与TLS参考值相比,从3D相机测量得出的作物高度平均低估了0.06 m。结论:我们建议结合使用多个低成本3D相机测量,去除测量伪像以及包括校正功能以提高作物高度测量的质量。在农业机械或自主平台上的田间条件下运行低成本3D摄像机可以提供节省时间和成本的工具,以直接在田间捕获作物高度的空间分布,从而提高农业效率和生产力。更一般而言,包括自然对象的3D几何体在内的所有过程都可以从生成3D地理数据的低成本方法中受益。
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