Genomic Bayesian functional regression models with interactions for predicting wheat grain yield using hyper‑spectral image data
Montesinos-Lopez, A.
Genomic Bayesian functional regression models with interactions for predicting wheat grain yield using hyper‑spectral image data [Electronic Resource] - United Kingdom : Biomed Central, 2017.
Peer review Open Access
Modern agriculture uses hyperspectral cameras that provide hundreds of reflectance data at discrete narrow bands in many environments. These bands often cover the whole visible light spectrum and part of the infrared and ultraviolet light spectra. With the bands, vegetation indices are constructed for predicting agronomically important traits such as grain yield and biomass. However, since vegetation indices only use some wavelengths (referred to as bands), we propose using all bands simultaneously as predictor variables for the primary trait grain yield; results of several multi-environment maize (Aguate et al. in Crop Sci 57(5):1–8, 2017) and wheat (Montesinos-López et al. in Plant Methods 13(4):1–23, 2017) breeding trials indicated that using all bands produced better prediction accuracy than vegetation indices. However, until now, these prediction models have not accounted for the effects of genotype × environment (G × E) and band × environment (B × E) interactions incorporating genomic or pedigree information.
Text in English
https://doi.org/10.1186/s13007-017-0212-4
Genomic features
Wheat
Vegetation index
Regression analysis
Yields
Genomic Bayesian functional regression models with interactions for predicting wheat grain yield using hyper‑spectral image data [Electronic Resource] - United Kingdom : Biomed Central, 2017.
Peer review Open Access
Modern agriculture uses hyperspectral cameras that provide hundreds of reflectance data at discrete narrow bands in many environments. These bands often cover the whole visible light spectrum and part of the infrared and ultraviolet light spectra. With the bands, vegetation indices are constructed for predicting agronomically important traits such as grain yield and biomass. However, since vegetation indices only use some wavelengths (referred to as bands), we propose using all bands simultaneously as predictor variables for the primary trait grain yield; results of several multi-environment maize (Aguate et al. in Crop Sci 57(5):1–8, 2017) and wheat (Montesinos-López et al. in Plant Methods 13(4):1–23, 2017) breeding trials indicated that using all bands produced better prediction accuracy than vegetation indices. However, until now, these prediction models have not accounted for the effects of genotype × environment (G × E) and band × environment (B × E) interactions incorporating genomic or pedigree information.
Text in English
https://doi.org/10.1186/s13007-017-0212-4
Genomic features
Wheat
Vegetation index
Regression analysis
Yields