Abstract
Crop breeders are looking for tools to facilitate the screening of genotypes in field trials. Remote sensing-based indices such as normalized difference vegetative index (NDVI) are sensitive to biomass and nitrogen (N) variability in crop canopies. The objectives of this study were (i) to determine if proximal sensor-based NDVI readings can differentiate the yield of winter wheat (Triticum aestivum L.) genotypes and (ii) to determine if NDVI readings can be used to classify wheat genotypes into grain yield productivity classes. This study was conducted in northeastern Colorado in 2010 and 2011. The NDVI readings were acquired weekly from March to June, during 2010 and 2011. The correlation between NDVI and grain yield was determined using Pearson’s product-moment correlation coefficient (r). The k-means clustering method was used to classify mean NDVI and mean grain yield into three classes. The overall accuracy between NDVI and yield classes was reported. The findings of this study show that, under dryland conditions, there is a reliable correlation between grain yield and NDVI at the early growing season, at the anthesis growth stage, and the mid-grain filling growth stage, as well as a poor association under irrigated conditions. Our results suggest that when the sensor is not saturated, i.e., NDVI < 0.9, NDVI could assess grain yield with fair accuracy. This study demonstrated the potential of using NDVI readings as a tool to differentiate and identify superior wheat genotypes.
Highlights
Conventional breeding methods rely heavily on grain yield as a trait to identify, select, and breed new crop varieties
A strong relationship was observed between grain yield and normalized difference vegetative index (NDVI) values across 24 genotypes of winter wheat
The results from this study suggest that NDVI could assess grain yield under dryland conditions, but show limitations under irrigated conditions
Summary
Conventional breeding methods rely heavily on grain yield as a trait to identify, select, and breed new crop varieties. Crop biomass, as measured by destructive sampling, is another trait often used in conventional breeding to identify total aboveground biomass and total N in crop tissue. The direct estimation of grain yield and biomass through destructive sampling is tedious, expensive, labor-intensive, and time-consuming [3,4]. Experience has demonstrated that sampling errors cause difficulty in detecting prominent differences among samples and destructive sampling reduces the plot area for estimating final biomass and grain yield. Proximal canopy sensing can be used to estimate crop N status and crop biomass without destructive sampling and has the potential to provide a fast, inexpensive, and accurate technique to estimate plant biomass production [5,6] and grain yield [7]
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