Abstract
Hyperspectral imaging covering the spectral range of 384–1034 nm combined with chemometric methods was used to detect Sclerotinia sclerotiorum (SS) on oilseed rape stems by two sample sets (60 healthy and 60 infected stems for each set). Second derivative spectra and PCA loadings were used to select the optimal wavelengths. Discriminant models were built and compared to detect SS on oilseed rape stems, including partial least squares-discriminant analysis, radial basis function neural network, support vector machine and extreme learning machine. The discriminant models using full spectra and optimal wavelengths showed good performance with classification accuracies of over 80% for the calibration and prediction set. Comparing all developed models, the optimal classification accuracies of the calibration and prediction set were over 90%. The similarity of selected optimal wavelengths also indicated the feasibility of using hyperspectral imaging to detect SS on oilseed rape stems. The results indicated that hyperspectral imaging could be used as a fast, non-destructive and reliable technique to detect plant diseases on stems.
Highlights
Crop diseases are major threats to crop growth, resulting in crop yield and quality loss [1,2,3].Timely and proper disease control is crucial for crop safe and efficient production
The results indicated the repeatability of optimal wavelength selection by 2nd derivative spectra and principal component analysis (PCA) loadings between different sample sets
Hyperspectral imaging combined with chemometrics was applied to detect Sclerotinia sclerotiorum (SS) on oilseed rape stems
Summary
Crop diseases are major threats to crop growth, resulting in crop yield and quality loss [1,2,3].Timely and proper disease control is crucial for crop safe and efficient production. Sclerotinia sclerotiorum (SS) is one of the most serious diseases on oilseed rape. It can infect all aboveground parts of the oilseed rape plants, including leaves, stems, flowers and pods [4,5]. Stems are the most sensitive parts to SS, which cause the most severe consequences. The ascospores of SS are generated from the apothecia in the soil or the seeds. Treating soil and seeds with fungicides is the most effective method to prevent SS. Due to the complicated structure of soil, and the fact that some of ascospores are dispersed more widely from other fields into surrounding crops, full prevention of SS on oilseed rape is quite difficult
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