Abstract
Timely and accurate monitoring has the potential to streamline crop management, harvest planning, and processing in the growing table beet industry of New York state. We used unmanned aerial system (UAS) combined with a multispectral imager to monitor table beet (Beta vulgaris ssp. vulgaris) canopies in New York during the 2018 and 2019 growing seasons. We assessed the optimal pairing of a reflectance band or vegetation index with canopy area to predict table beet yield components of small sample plots using leave-one-out cross-validation. The most promising models were for table beet root count and mass using imagery taken during emergence and canopy closure, respectively. We created augmented plots, composed of random combinations of the study plots, to further exploit the importance of early canopy growth area. We achieved a R2 = 0.70 and root mean squared error (RMSE) of 84 roots (~24%) for root count, using 2018 emergence imagery. The same model resulted in a RMSE of 127 roots (~35%) when tested on the unseen 2019 data. Harvested root mass was best modeled with canopy closing imagery, with a R2 = 0.89 and RMSE = 6700 kg/ha using 2018 data. We applied the model to the 2019 full-field imagery and found an average yield of 41,000 kg/ha (~40,000 kg/ha average for upstate New York). This study demonstrates the potential for table beet yield models using a combination of radiometric and canopy structure data obtained at early growth stages. Additional imagery of these early growth stages is vital to develop a robust and generalized model of table beet root yield that can handle imagery captured at slightly different growth stages between seasons.
Highlights
New York is a sentinel center of production for table beet (Beta vulgaris spp. vulgaris: Family Chenopodiaceae) in the USA, ranking second behind Wisconsin [1], and is undergoing exponential industry growth
We exclusively investigate the predictive power of unmanned aerial system (UAS) multispectral imagery for table beet yield components
The performance of the 2018 area-augmented root count and mass models assessed on the 2019 data is promising, especially considering the slight differences in growth stages, in both cases
Summary
New York is a sentinel center of production for table beet (Beta vulgaris spp. vulgaris: Family Chenopodiaceae) in the USA, ranking second behind Wisconsin [1], and is undergoing exponential industry growth. Table beet roots of various sizes are used for different products, with distinct processing and packaging needs This motivates the stakeholders, hoping to meet yield and beet diameter distribution targets, to obtain early crop management inputs which may be relevant to strategic planning, a reduction in waste, maximization of financial gain, and potential within-season intervention. Olson et al [19,20] more recently found that pairing of UAS-derived multispectral vegetation indices and canopy height can provide improved sugar beet yield predictions when compared to vegetation indices alone Their modeling used imagery from multiple growth stages across two different seasons at two different sites. The best sugar beet root yield model was for combined NDVI and crop height at one site in Remote Sens. From imagery and to evaluate model performance on independent data
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