Abstract
Assessing crop yield trends over years is a key step in site specific management, in view of improving the economic and environmental profile of agriculture. This study was conducted in a 11.07 ha area under Mediterranean climate in Northern Italy to evaluate the spatial variability and the relationships between six remotely sensed vegetation indices (VIs) and grain yield (GY) in five consecutive years. A total of 25 satellite (Landsat 5, 7, and 8) images were downloaded during crop growth to obtain the following VIs: Normalized Difference Vegetation Index (NDVI), Enhanced Vegetation Index (EVI), Soil Adjusted Vegetation Index (SAVI), Green Normalized Difference Vegetation Index (GNDVI), Green Chlorophyll Index (GCI), and Simple Ratio (SR). The surveyed crops were durum wheat in 2010, sunflower in 2011, bread wheat in 2012 and 2014, and coriander in 2013. Geo-referenced GY and VI data were used to generate spatial trend maps across the experimental field through geostatistical analysis. Crop stages featuring the best correlations between VIs and GY at the same spatial resolution (30 m) were acknowledged as the best periods for GY prediction. Based on this, 2–4 VIs were selected each year, totalling 15 VIs in the five years with r values with GY between 0.729** and 0.935**. SR and NDVI were most frequently chosen (six and four times, respectively) across stages from mid vegetative to mid reproductive growth. Conversely, SAVI never had correlations high enough to be selected. Correspondence analysis between remote VIs and GY based on quantile ranking in the 126 (30 m size) pixels exhibited a final agreement between 64% and 86%. Therefore, Landsat imagery with its spatial and temporal resolution proved a good potential for estimating final GY over different crops in a rotation, at a relatively small field scale.
Highlights
Investigation of problems associated with agricultural yield, before harvesting, most commonly involves observing in-season growth variations, scouting areas at different fertility, and defining optimum soil sampling design according to needs of individual field
A total of 25 satellite (Landsat 5, 7, and 8) images were downloaded during crop growth to obtain the following vegetation indices (VIs): Normalized Difference Vegetation Index (NDVI), Enhanced Vegetation Index (EVI), Soil Adjusted Vegetation Index (SAVI), Green Normalized Difference Vegetation Index (GNDVI), Green Chlorophyll Index (GCI), and Simple Ratio (SR)
The lower grain yield (GY) was referred to DW 2010 and BW 2012 that showed the same mean data, whereas the higher GY was related to BW 2014
Summary
Investigation of problems associated with agricultural yield, before harvesting, most commonly involves observing in-season growth variations, scouting areas at different fertility, and defining optimum soil sampling design according to needs of individual field. All this helps to increase the agricultural economic yield. Surplus N drains into groundwater affecting the quality of drinking water, or seeps into superficial water bodies determining eutrophication [3] This scenario makes it necessary to adopt efficient crop production methods assuring minimum environmental impact and concurrent optimization of crop yields [4]. This, consists in evaluating the relationship between spectral vegetation indices during growth and final crop yield [5,6]
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