Abstract
BackgroundTimely and accurate estimates of canopy chlorophyll (Chl) a and b content are crucial for crop growth monitoring and agricultural management. Crop canopy reflectance depends on many factors, which can be divided into the following categories: (i) leaf effects (e.g., leaf pigments), (ii) canopy effects (e.g., Leaf Area Index [LAI]), and (iii) soil background reflectance (e.g., soil reflectance). The estimation of leaf variables, such as Chl contents, from reflectance at the canopy scale is usually less accurate than that at the leaf scale. In this study, we propose a Visible and Near-infrared (NIR) Angle Index (VNAI) to estimate the Chl content of soybean canopy, and soybean canopy Chl maps are produced using visible and NIR unmanned aerial vehicle (UAV) remote sensing images. The VNAI is insensitive to LAI and can be used for the multi-stage estimation of crop canopy Chl content.ResultsEleven previously used vegetation indices (VIs) (e.g., Pigment-specific Normalized Difference Index) were selected for performance comparison. The results showed that (i) most previously used Chl VIs were significantly correlated with LAI, and the proposed VNAI was more sensitive to Chl content than LAI; (ii) the VNAI-based estimates of Chl content were more accurate than those based on the other investigated VIs using (1) simulated, (2) real (field), and (3) real (UAV) datasets.ConclusionsMost previously used Chl VIs were significantly correlated with LAI whereas the proposed VNAI was more sensitive to Chl content than to LAI, indicating that the VNAI may be more strongly correlated with Chl content than these previously used VIs. Multi-stage estimations of the Chl content of cropland obtained using the VNAI and broadband remote sensing images may help to obtain Chl maps with high temporal and spatial resolution.
Highlights
And accurate estimates of canopy chlorophyll (Chl) a and b content are crucial for crop growth monitoring and agricultural management
Crop canopy reflectance depends on many factors, which can be divided into the following categories: (i) leaf effects, (ii) canopy biophysical effects (e.g., Leaf Area Index [Leaf area index (LAI)], leaf inclination angle), and (iii) soil background reflectance [32,33,34]
For Chl-Cab, the results indicate that the correlation coefficients increased in the following order: VNAI > Transformed Chlorophyll Absorption Reflectance Index (TCARI)/OSAVI_RE > Pigment-specific Normalized Difference Index (PSND) > Normalized Difference Red-edge Version 2 (NDRE2) > CI(red edge) > Normalized Difference Red-edge Version 1 (NDRE1) > TCARI/Optimized Soil-adjusted vegetation indices (VIs) (OSAVI) > Normalized Difference VI (NDVI) > OSAVI > RDV I > Two-band Enhanced VI (EVI2) > Enhanced VI (EVI)
Summary
And accurate estimates of canopy chlorophyll (Chl) a and b content are crucial for crop growth monitoring and agricultural management. The estimation of leaf variables, such as Chl contents, from reflectance at the canopy scale is usually less accurate than that at the leaf scale. We propose a Visible and Near-infrared (NIR) Angle Index (VNAI) to estimate the Chl content of soybean canopy, and soybean canopy Chl maps are produced using visible and NIR unmanned aerial vehicle (UAV) remote sensing images. The VNAI is insensitive to LAI and can be used for the multi-stage estimation of crop canopy Chl content. Visible and NIR bands are crucial for estimating crop parameters [11]. Crop spectral reflectance in the NIR region is much higher than that in the visible band [12]. The features described above can be detected by using broadband satellite remote sensing, and many broadband satellite-based remote sensing vegetation indices (VIs) have been developed to monitor vegetation parameters
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