Abstract:Visible/near-infrared (380~1 030 nm) hyperspectral imaging technique was used to realize SPAD visualization of pumpkin leaves in the present study. Downy mildew could be diagnosed rapidly according to significant positive correlation between downy mildew epidemic and chlorophyll content. Leaves uninfected and infected with different level downy mildew were used to acquire hyperspectral images and extract spectral information. Competitive adaptive reweighted sampling (CARS) was applied to select optimal wavelengths and finally 10 optimal wavelengths were obtained. Partial least squares regression (PLSR) was employed to establish SPAD prediction model. Results showed that, through the analysis of calibration of 48 samples and prediction of 23 samples, CARS-PLSR could obtain good results with RC=0.918, RMSECV=3.932; RCV=0.846, RMSECV=5.254; RP=0.881, and RMSEP=3.714. Regression model was gained based on the relationship between SPAD and spectral of pumpkin leaves. While SPAD of each pixel was calculated with PLSR regression equation, then SPAD distribution map of pumpkin was visualized using imaging processing technology. Final downy mildew infection could be diagnosed based on SPAD distribution map. This study provided a theoretical reference for effective monitoring plant growth and downy mildew epidemic.
赵艳茹,余克强,李晓丽,何 勇* . 基于高光谱成像的南瓜叶片叶绿素分布可视化研究 [J]. 光谱学与光谱分析, 2014, 34(05): 1378-1382.
ZHAO Yan-ru, YU Ke-qiang, LI Xiao-li, HE Yong* . Study on SPAD Visualization of Pumpkin Leaves Based on Hyperspectral Imaging Technology . SPECTROSCOPY AND SPECTRAL ANALYSIS, 2014, 34(05): 1378-1382.
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