Abstract
This study aimed to understand the spectral changes induced by Podosphaera xanthii, the causal agent of powdery mildew, in cucumber leaves from the moment of inoculation until visible symptoms are apparent. A principal component analysis (PCA) was applied to the spectra to assess the spectral separability between healthy and infected leaves. A spectral ratio between infected and healthy leaf spectra was used to determine the best wavelengths for detecting the disease. Additionally, the spectra were used to compute two spectral variables [i.e., the red-well point (RWP) and the red-edge inflexion point (REP)]. A linear support vector machine (SVM) classifier was applied to certain spectral features to assess how well these features can separate the infected leaves from the healthy ones. The PCA showed that a good separability could be achieved from 4 days post-inoculation (DPI). The best model to fit the RWP and REP wavelengths corresponded to a linear model. The linear model had a higher adjusted R2 for the infected leaves than for the healthy leaves. The SVM trained with five first principal components scores achieved an overall accuracy of 95% at 4 DPI (i.e., two days before the visible symptoms). With the RWP and REP parameters, the SVM accuracy increased as a function of the day of inoculation, reaching 89% and 86%, respectively, when symptoms were visible at 6 DPI. Further research must consider a higher number of samples and more temporal repetitions of the experiment.
Highlights
The Canadian greenhouse crops are the most significant and fastest-growing segment of Canadian horticulture
A few studies assessed these features for detecting biotrophic diseases such as cucumber powdery mildew with Red-Well Point (RWP), Red-Edge Inflexion Point (REP), or Principal Component Analysis (PCA) score; we compared our results with studies on necrotic diseases, such as late blight (Phytophthora infestans) on potatoes
In this study, we determined which spectral variables and at which time from disease inoculation powdery mildew can be detected on cucumber leaves
Summary
The Canadian greenhouse crops are the most significant and fastest-growing segment of Canadian horticulture. The province of Ontario has the highest greenhouse crop production, with 69% of the total production in Canada (AAFC, 2020) Such as with other crops, fungal diseases can affect greenhouse crops and be a significant limiting production factor (Kather et al, 2017). The biotrophic pathogen does not kill the host cells to obtain nutrients (Spanu and Panstruga, 2017) It induces leaf chlorophyll degradation and internal structural damage of colonized cells. Chlorophyll variations can be detected in the visible spectral domain (400 to 700 nm) (Mutanga and Skidmore, 2007), while the internal leaf structure changes can be detected in the near-infrared spectral domain (700 to 1300 nm) (Knipling, 1970; Delalieux et al, 2007) Another interesting spectral domain is the red-edge region, a transition zone located between 660 to 780 nm (Horler et al, 1983). The transition zone is between the maximal chlorophyll absorbance in the red wavelength and the strong near-infrared reflectance due to leaf mesophyll scattering
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