Abstract
Hyperspectral imaging was used to identify and to visualize the coffee bean varieties. Spectral preprocessing of pixel-wise spectra was conducted by different methods, including moving average smoothing (MA), wavelet transform (WT) and empirical mode decomposition (EMD). Meanwhile, spatial preprocessing of the gray-scale image at each wavelength was conducted by median filter (MF). Support vector machine (SVM) models using full sample average spectra and pixel-wise spectra, and the selected optimal wavelengths by second derivative spectra all achieved classification accuracy over 80%. Primarily, the SVM models using pixel-wise spectra were used to predict the sample average spectra, and these models obtained over 80% of the classification accuracy. Secondly, the SVM models using sample average spectra were used to predict pixel-wise spectra, but achieved with lower than 50% of classification accuracy. The results indicated that WT and EMD were suitable for pixel-wise spectra preprocessing. The use of pixel-wise spectra could extend the calibration set, and resulted in the good prediction results for pixel-wise spectra and sample average spectra. The overall results indicated the effectiveness of using spectral preprocessing and the adoption of pixel-wise spectra. The results provided an alternative way of data processing for applications of hyperspectral imaging in food industry.
Highlights
Coffee is one of the most popular beverage in the world
The sample average spectra based models showed good results with no significant differences. These results indicated that the preprocessing of pixel-wise spectra and images had little influence on sample average spectra based models
The spectral and spatial preprocessing of hyperspectral images all resulted in the changes of pixel-wise spectra, and the corresponding sample average spectra
Summary
Coffee is one of the most popular beverage in the world. Coffee variety is among the key factors influencing the coffee quality and price. One of the main advantages of hyperspectral imaging is to form and visualize the distribution maps of the samples It reveals the physical attributes and the chemical compositions within or between samples. Applying the calibration model to the pixels with physical attributes and chemical compositions beyond the range of the calibration set would result in inaccurate prediction values. Another crucial factor which would lead to an inaccurate prediction is the uneven sample surface and shapes. When predicting physical attributes and chemical compositions of pixels, the differences of pixel-wise spectra caused by sample shape should be considered. Studies have been reported to conduct spectral data analysis based on pixel-wise spectra[19,20,21,22,23]
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