Unmanned aerial vehicle and proximal sensing of vegetation indices in olive tree (<i>Olea europaea</i>)

IF 2.4 4区 农林科学 Q2 AGRICULTURAL ENGINEERING Journal of Agricultural Engineering Pub Date : 2023-10-12 DOI:10.4081/jae.2023.1536
Eliseo Roma, Pietro Catania, Mariangela Vallone, Santo Orlando
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Abstract

Remote and proximal sensing platforms at the service of precision olive growing are bringing new development possibilities to the sector. A proximal sensing platform is close to the vegetation, while a remote sensing platform, such as unmanned aerial vehicle (UAV), is more distant but has the advantage of rapidity to investigate plots. The study aims to compare multispectral and hyperspectral data acquired with remote and proximal sensing platforms. The comparison between the two sensors aims at understanding the different responses their use can provide on a crop, such as olive trees having a complex canopy. The multispectral data were acquired with a DJI multispectral camera mounted on the UAV Phantom 4. Hyperspectral acquisitions were carried out with a FieldSpec® HandHeld 2™ Spectroradiometer in the canopy portions exposed to South, East, West, and North. The multispectral images were processed with Geographic Information System software to extrapolate spectral information for each cardinal direction’s exposure. The three main Vegetation indices were used: normalized difference vegetation index (NDVI), normalized difference red-edge index (NDRE), and modified soil adjusted vegetation index (MSAVI). Multispectral data could describe the total variability of the whole plot differentiating each single plant status. Hyperspectral data were able to describe vegetation conditions more accurately; they appeared to be related to the cardinal exposure. MSAVI, NDVI, and NDRE showed correlation r =0.63**, 0.69**, and 0.74**, respectively, between multispectral and hyperspectral data. South and West exposures showed the best correlations with both platforms.
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无人机与橄榄树植被指数近端遥感(<i>Olea europaea</i>)
为精确橄榄种植服务的遥感和近端传感平台为该部门带来了新的发展可能性。近端遥感平台距离植被较近,而无人机等遥感平台距离较远,但具有快速调查地块的优势。该研究旨在比较遥感和近端遥感平台获取的多光谱和高光谱数据。两种传感器之间的比较旨在了解它们对作物的不同使用反应,例如具有复杂树冠的橄榄树。多光谱数据由安装在无人机幻影4上的大疆多光谱相机获取。在暴露于南、东、西、北的冠层部分,使用FieldSpec®手持2™光谱仪进行高光谱采集。利用地理信息系统软件对多光谱图像进行处理,推断各基本方向曝光的光谱信息。采用归一化差异植被指数(NDVI)、归一化差异红边指数(NDRE)和改良土壤调整植被指数(MSAVI) 3种主要植被指数。多光谱数据能较好地描述整个样地区分各单株状态的总变率。高光谱数据能够更准确地描述植被状况;它们似乎与红衣主教的暴露有关。MSAVI、NDVI和NDRE在多光谱和高光谱数据间的相关r分别为0.63**、0.69**和0.74**。向南和向西暴露与两个平台的相关性最好。
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来源期刊
Journal of Agricultural Engineering
Journal of Agricultural Engineering AGRICULTURAL ENGINEERING-
CiteScore
2.30
自引率
5.60%
发文量
40
审稿时长
10 weeks
期刊介绍: The Journal of Agricultural Engineering (JAE) is the official journal of the Italian Society of Agricultural Engineering supported by University of Bologna, Italy. The subject matter covers a complete and interdisciplinary range of research in engineering for agriculture and biosystems.
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