Abstract
Pre-visual detection of crop disease is critical for food security. Field-based spectroscopic remote sensing offers a method to enable timely detection, but still requires appropriate instrumentation and testing. Soybean plants were spectrally measured throughout a growing season to assess the capacity of leaf and canopy level spectral measurements to detect non-visual foliage symptoms induced by Fusarium virguliforme (Fv, which causes sudden death syndrome). Canopy reflectance measurements were made using the Piccolo Doppio dual field-of-view, two-spectrometer (400 to 1630 nm) system on a tractor. Leaf level measurements were obtained, in different plots, using a handheld spectrometer (400 to 2500 nm). Partial least squares discriminant analysis (PLSDA) was applied to the spectroscopic data to discriminate between Fv-inoculated and control plants. Canopy and leaf spectral data allowed identification of Fv infection, prior to visual symptoms, with classification accuracy of 88% and 91% for calibration, 79% and 87% for cross-validation, and 82% and 92% for validation, respectively. Differences in wavelengths important to prediction by canopy vs. leaf data confirm that there are different bases for accurate predictions among methods. Partial least square regression (PLSR) was used on a late-stage canopy level data to predict soybean seed yield, with calibration, cross-validation and validation R2 values 0.71, 0.59 and 0.62 (p < 0.01), respectively, and validation root mean square error of 0.31 t·ha−1. Spectral data from the tractor mounted system are thus sensitive to the expression of Fv root infection at canopy scale prior to canopy symptoms, suggesting such systems may be effective for precision agricultural research and management.
Highlights
Remote and proximal sensing are increasingly applied in agriculture [1] for diverse applications, including estimation of yield [2], water content [3], crop nutrients [4,5,6], leaf area index (LAI; [7,8,9,10]), disease [11,12], pest [13,14,15,16] and soil properties [1]
When canopy symptoms are absent, destructive sampling is used to assess Fv presence on roots [30], pulling the root to look for root rot and cutting lower stems to distinguish from other disease [19,30] or quantitative real-time polymerase chain reaction-based detection [20,31]
The top Partial least squares discriminant analysis (PLSDA) classification of inoculation status for specific dates was based on canopy spectra utilized data from 18 July and 26 July both prior to appearance of canopy symptoms, producing 82% validation accuracy (Table 2)
Summary
Remote and proximal sensing are increasingly applied in agriculture [1] for diverse applications, including estimation of yield [2], water content [3], crop nutrients [4,5,6], leaf area index (LAI; [7,8,9,10]), disease [11,12], pest [13,14,15,16] and soil properties [1]. We test the capacity of tractor-based proximal spectral measurements to detect Fusarium virguliforme (Fv, which causes soybean sudden death syndrome) root infection and assess seed yield of soybeans. Sudden death syndrome (SDS) was among the top yield-suppressing diseases of soybean in the United States from 1996 to 2007 [18], with average annual crop loss in the US assessed to be around $100 million US [19]. The SDS disease cycle starts shortly after planting with infection of roots resulting in reduced root length, surface area, volume, and mass [23]. The primary field detection method for SDS is canopy symptoms. In cases of no apparent canopy symptoms, the pathogen can remain unnoticed in the soil, infected roots or plant residue as a potential risk for subsequent growing seasons. Risk of Fv infection has been studied [33], a nondestructive method to identify Fv infected soybeans prior to visual symptoms is needed
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