Digital Counts of Maize Plants by Unmanned Aerial Vehicles (UAVs)

Precision phenotyping, especially the use of image analysis, allows researchers to gain information on plant properties and plant health. Aerial image detection with unmanned aerial vehicles (UAVs) provides new opportunities in precision farming and precision phenotyping. Precision farming has creat...

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Bibliographic Details
Published in:Remote sensing (Basel, Switzerland) Switzerland), 2017-06, Vol.9 (6), p.544
Main Authors: Gnädinger, Friederike, Schmidhalter, Urs
Format: Article
Language:English
Subjects:
Agricultural production
Agronomy
Color
Corn
Counting
Cultivars
Developmental stages
drone
Emergence
Experimentation
Farm management
Farming
Fertilization
Ground cover
high-throughput
high-throughput phenomics
Image analysis
Image contrast
Image detection
Image enhancement
Image processing
Image retrieval
International conferences
Leaves
maize cultivation
Nitrogen
Parameters
Phenotyping
plant density
Planting
Planting density
planting distance
Precision farming
precision phenotyping
Remote sensing
Seeding
Spatial data
unmanned aerial system (UAS)
Unmanned aerial vehicles
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Summary:Precision phenotyping, especially the use of image analysis, allows researchers to gain information on plant properties and plant health. Aerial image detection with unmanned aerial vehicles (UAVs) provides new opportunities in precision farming and precision phenotyping. Precision farming has created a critical need for spatial data on plant density. The plant number reflects not only the final field emergence but also allows a more precise assessment of the final yield parameters. The aim of this work is to advance UAV use and image analysis as a possible high-throughput phenotyping technique. In this study, four different maize cultivars were planted in plots with different seeding systems (in rows and equidistantly spaced) and different nitrogen fertilization levels (applied at 50, 150 and 250 kg N/ha). The experimental field, encompassing 96 plots, was overflown at a 50-m height with an octocopter equipped with a 10-megapixel camera taking a picture every 5 s. Images were recorded between BBCH 13–15 (it is a scale to identify the phenological development stage of a plant which is here the 3- to 5-leaves development stage) when the color of young leaves differs from older leaves. Close correlations up to R2 = 0.89 were found between in situ and image-based counted plants adapting a decorrelation stretch contrast enhancement procedure, which enhanced color differences in the images. On average, the error between visually and digitally counted plants was ≤5%. Ground cover, as determined by analyzing green pixels, ranged between 76% and 83% at these stages. However, the correlation between ground cover and digitally counted plants was very low. The presence of weeds and blurry effects on the images represent possible errors in counting plants. In conclusion, the final field emergence of maize can rapidly be assessed and allows more precise assessment of the final yield parameters. The use of UAVs and image processing has the potential to optimize farm management and to support field experimentation for agronomic and breeding purposes.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs9060544