Abstract
Crop monitoring throughout the growing season is key for optimized agricultural production. Satellite remote sensing is a useful tool for estimating crop variables, yet continuous high spatial resolution earth observations are often interrupted by clouds. This paper demonstrates overcoming this limitation by combining observations from two public-domain spaceborne optical sensors. Ground measurements were conducted in the Hula Valley, Israel, over four growing seasons to monitor the development of processing tomato. These measurements included continuous water consumption measurements using an eddy-covariance tower from which the crop coefficient (Kc) was calculated and measurements of Leaf Area Index (LAI) and crop height. Satellite imagery acquired by Sentinel-2 and VENµS was used to derive vegetation indices and model Kc, LAI, and crop height. The conjoint use of Sentinel-2 and VENµS imagery facilitated accurate estimation of Kc (R2 = 0.82, RMSE = 0.09), LAI (R2 = 0.79, RMSE = 1.2), and crop height (R2 = 0.81, RMSE = 7 cm). Additionally, our empirical models for LAI estimation were found to perform better than the SNAP biophysical processor (R2 = 0.53, RMSE = 2.3). Accordingly, Sentinel-2 and VENµS imagery was demonstrated to be a viable tool for agricultural monitoring.
Highlights
In Gadash 2019, the crop height and Leaf Area Index (LAI) and the Kc were lower compared to the other seasons
The field experiments conducted in Israel in 2018–2020 showed that Kc, LAI, and crop height in processing tomato differ from season to season but can be estimated correctly in near-real-time from satellite remote sensing imagery
While this study provided useful results from thirteen vegetation indices (VIs) to estimate Kc, LAI, and height in the processing tomato using Sentinel-2 and VENμS imagery, there is merit in future studies on other crops
Summary
Crop coefficient (Kc )-based estimation of crop water consumption is one of the most commonly used irrigation management methods [3,4]. One of Kc estimation’s most reliable sources is vegetation indices (VIs) derived from optical remote sensing [5,6,7,8,9,10,11,12,13,14]. Until recently, this method’s application was hampered by the insufficient amount of public domain imagery at a high revisit time with fine spatial resolution
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