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比较基于无人机的技术和 RGB-D 重建方法在草地监测植物高度和生物量上的应用。

Comparing UAV-Based Technologies and RGB-D Reconstruction Methods for Plant Height and Biomass Monitoring on Grass Ley.

机构信息

Department of Grassland and Livestock, Norwegian Institute of Bioeconomy Research, NIBIO Særheim, Postvegen 213, 4353 Klepp Stasjon, Norway.

Institute of Agricultural Sciences, Consejo Superior Investigaciones Científicas (CSIC), Serrano 115b, 28006 Madrid, Spain.

出版信息

Sensors (Basel). 2019 Jan 28;19(3):535. doi: 10.3390/s19030535.

DOI:10.3390/s19030535
PMID:30696014
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6387457/
Abstract

Pastures are botanically diverse and difficult to characterize. Digital modeling of pasture biomass and quality by non-destructive methods can provide highly valuable support for decision-making. This study aimed to evaluate aerial and on-ground methods to characterize grass ley fields, estimating plant height, biomass and volume, using digital grass models. Two fields were sampled, one timothy-dominant and the other ryegrass-dominant. Both sensing systems allowed estimation of biomass, volume and plant height, which were compared with ground truth, also taking into consideration basic economical aspects. To obtain ground-truth data for validation, 10 plots of 1 m² were manually and destructively sampled on each field. The studied systems differed in data resolution, thus in estimation capability. There was a reasonably good agreement between the UAV-based, the RGB-D-based estimates and the manual height measurements on both fields. RGB-D-based estimation correlated well with ground truth of plant height ( R 2 > 0.80 ) for both fields, and with dry biomass ( R 2 = 0.88 ), only for the timothy field. RGB-D-based estimation of plant volume for ryegrass showed a high agreement ( R 2 = 0.87 ). The UAV-based system showed a weaker estimation capability for plant height and dry biomass ( R 2 < 0.6 ). UAV-systems are more affordable, easier to operate and can cover a larger surface. On-ground techniques with RGB-D cameras can produce highly detailed models, but with more variable results than UAV-based models. On-ground RGB-D data can be effectively analysed with open source software, which is a cost reduction advantage, compared with aerial image analysis. Since the resolution for agricultural operations does not need fine identification the end-details of the grass plants, the use of aerial platforms could result a better option in grasslands.

摘要

牧场在植物学上具有多样性,难以进行特征描述。采用非破坏性方法对牧场生物量和质量进行数字建模,可以为决策提供非常有价值的支持。本研究旨在评估空中和地面方法,使用数字草模型来描述草地牧场,估计植物高度、生物量和体积。对两个以提莫西草为主和以黑麦草为主的牧场进行了采样。这两种传感器系统都允许对生物量、体积和植物高度进行估计,并与地面真值进行了比较,同时也考虑了基本的经济方面。为了获得地面真值数据进行验证,在每个牧场上手动和破坏性地采集了 10 个 1m²的样本。所研究的系统在数据分辨率上有所不同,因此在估计能力上也有所不同。在两个牧场上,基于无人机的、基于 RGB-D 的估计值与手动高度测量值之间都有相当好的一致性。基于 RGB-D 的估计值与两个牧场的植物高度的地面真值( R 2 > 0.80 )以及提莫西草的干生物量( R 2 = 0.88 )相关性较好。基于 RGB-D 的黑麦草植物体积估计值高度一致( R 2 = 0.87 )。基于无人机的系统对植物高度和干生物量的估计能力较弱( R 2 < 0.6 )。无人机系统更经济实惠,操作更简单,可以覆盖更大的表面。基于地面的 RGB-D 相机技术可以生成高度详细的模型,但结果比基于无人机的模型更具变异性。与空中图像分析相比,基于地面的 RGB-D 数据可以有效地使用开源软件进行分析,这是一种降低成本的优势。由于农业作业的分辨率不需要精细识别草植物的末端细节,因此在草原上使用空中平台可能是更好的选择。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2095/6387457/265ed5033ae6/sensors-19-00535-g010.jpg
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