Abstract
Plant vigor is an important trait of field crops at early growth stages, influencing weed suppression, nutrient and water use efficiency and plant growth. High-throughput techniques for its evaluation are required and are promising for nutrient management in early growth stages and for detecting promising breeding material in plant phenotyping. However, spectral sensing for assessing early plant vigor in crops is limited by the strong soil background reflection. Digital imaging may provide a low-cost, easy-to-use alternative. Therefore, image segmentation for retrieving canopy cover was applied in a trial with three cultivars of winter wheat (Triticum aestivum L.) grown under two nitrogen regimes and in three sowing densities during four early plant growth stages (Zadok’s stages 14–32) in 2017. Imaging-based canopy cover was tested in correlation analysis for estimating dry weight, nitrogen uptake and nitrogen content. An active Greenseeker sensor and various established and newly developed vegetation indices and spectral unmixing from a passive hyperspectral spectrometer were used as alternative approaches and additionally tested for retrieving canopy cover. Before tillering (until Zadok’s stage 20), correlation coefficients for dry weight and nitrogen uptake with canopy cover strongly exceeded all other methods and remained on higher levels (R² > 0.60***) than from the Greenseeker measurements until tillering. From early tillering on, red edge based indices such as the NDRE and a newly extracted normalized difference index (736 nm; ~794 nm) were identified as best spectral methods for both traits whereas the Greenseeker and spectral unmixing correlated best with canopy cover. RGB-segmentation could be used as simple low-cost approach for very early growth stages until early tillering whereas the application of multispectral sensors should consider red edge bands for subsequent stages.
Highlights
Increasing the efficiency in using fertilizer and pesticides in cropping systems has become a crucial challenge in current crop production
Differences between sowing densities were observed on all days for dry weight (DW) and canopy cover (CC), for Nup on all days except on D4 but only on D4 for N content (NC)
Linear correlations were tested between image-based canopy cover (CC), the Greenseeker-normalized difference vegetation index (NDVI) as well as selected vegetation indices and spectral unmixing from the hyperspectral data, with the reference traits DW, NC and Nup for all dates (Table 3)
Summary
Increasing the efficiency in using fertilizer and pesticides in cropping systems has become a crucial challenge in current crop production. Spectral sensing has become a versatile tool for evaluating crop stands and determining fertilizer demand [1,2]. Sensors can be used either offline to support nitrogen management, or online, enabling fully automatic site-specific application of fertilizers [3,4]. Transferring the physical signal of the visible and infrared spectra into ready-to-use recommendations on fertilizing rates is not trivial. Fertilizer algorithms depend on the characteristics of crops and cultivars with respect to the morphology such as leaf angle, the target yield and most-importantly, on the current growth stage [6,7,8]
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