Abstract
A near-infrared (NIR) hyperspectral imaging system was developed in this study. NIR hyperspectral imaging combined with multivariate data analysis was applied to identify rice seed cultivars. Spectral data was exacted from hyperspectral images. Along with Partial Least Squares Discriminant Analysis (PLS-DA), Soft Independent Modeling of Class Analogy (SIMCA), K-Nearest Neighbor Algorithm (KNN) and Support Vector Machine (SVM), a novel machine learning algorithm called Random Forest (RF) was applied in this study. Spectra from 1,039 nm to 1,612 nm were used as full spectra to build classification models. PLS-DA and KNN models obtained over 80% classification accuracy, and SIMCA, SVM and RF models obtained 100% classification accuracy in both the calibration and prediction set. Twelve optimal wavelengths were selected by weighted regression coefficients of the PLS-DA model. Based on optimal wavelengths, PLS-DA, KNN, SVM and RF models were built. All optimal wavelengths-based models (except PLS-DA) produced classification rates over 80%. The performances of full spectra-based models were better than optimal wavelengths-based models. The overall results indicated that hyperspectral imaging could be used for rice seed cultivar identification, and RF is an effective classification technique.
Highlights
Rice is one of the most common food crops in China and many other countries
NIR hyperspectral imaging combined with multivariate data analysis was applied to identify rice seed cultivars
Spectral information was exacted from hyperspectral images of rice seeds, and different classification models were built
Summary
Rice is one of the most common food crops in China and many other countries. The yield and quality of rice, which are mainly influenced by rice variety and growing conditions, are the biggest concerns of rice planting regions and consumers. Traditional techniques used for rice variety identification like HPLC [2], or GC-MS [3] are time consuming and difficult to apply. Some new techniques such as machine vision and visible/near-infrared spectroscopy have been developed and applied to determine rice varieties. Visible/near infrared spectroscopy has been proven to be efficient in determining rice quality and variety [6,7,8,9]. Machine vision and visible/near-infrared spectroscopy both acquire partial information about the sample, so a technique that acquires both spatial information and spectral information should be developed
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