A High-Throughput Phenotyping Pipeline for Rapid Evaluation of Morphological and Physiological Crop Traits Across Large Fields

In-situ monitoring of seasonal crop development is important to provide improved decision-making tools for farmers. In recent years, low altitude unmanned aerial vehicles (UAVs) coupled with ultra-high-resolution sensors have continued to advance the provision of detailed characterisation of in-seas...

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Bibliographic Details
Main Authors: Das, Sumanta, Massey-Reed, Sean Reynolds, Mahuika, Jenny, Watson, James, Cordova, Celso, Otto, Loren, Zhao, Yan, Chapman, Scott, George-Jaeggli, Barbara, Jordan, David, Hammer, Graeme L., Potgieter, Andries B.
Format: Conference Proceeding
Language:English
Subjects:
Autonomous aerial vehicles
crop phenology
Crops
Estimation
HTPP
Measurement
Pipelines
precision agriculture
Sensor phenomena and characterization
Temperature sensors
Unmanned aerial vehicle
vegetation indices
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Summary:In-situ monitoring of seasonal crop development is important to provide improved decision-making tools for farmers. In recent years, low altitude unmanned aerial vehicles (UAVs) coupled with ultra-high-resolution sensors have continued to advance the provision of detailed characterisation of in-season crop dynamics at a field scale. However, a 'bottleneck' still exists in many high-throughput plant phenotyping (HTPP) approaches to allow for accurate and timely extraction of information from multispectral sensors onboard UAVs. Here, we propose a pipeline for UAV data extraction using an executable software code i.e., 'Xtractori': The Xtractori was designed to handle BIG DATA generated from hyperspectral and multispectral sensors on board mobile tractors and/or drones. We used data from a high-resolution, six- band MicaSense Altum camera to capture images at three different winter crop sites during the 2021 cropping season across Australia. Vegetation indices (VIs) and canopy temperature were then extracted using Xtractori to evaluate the phenological development of different winter crops (wheat, barley, chickpea, canola, and oats). Results indicated a clear discrimination of phenological development including peak and saturation of different crops across environments. The VI-based phenology estimation was also closely related to the field phenology observation. Furthermore, VIs at peak crop development had a significant negative association with ΔT (canopy temperature - air temperature) (r= −0.45 to −0.88), suggesting this is likely an important crop development stage to differentiate crop stress. The study showed that including Xtractori in HTPP framework enabled the rapid and accurate extraction of sensing metrics and dynamic crop traits from multispectral data. This will aid researchers in enhancing their understanding and knowledge of seasonal crop growth dynamics across different environments.
ISSN:2153-7003
DOI:10.1109/IGARSS46834.2022.9884530