Abstract
This study innovatively proposes a feature fusion technique to determine fatty acid content during rice storage. Firstly, a self-developed olfactory visualization sensor was used to capture the odor information of rice samples at different storage periods and a portable spectroscopy system was employed to collect the near-infrared (NIR) spectra during rice storage. Then, principal component analysis (PCA) was performed on the pre-processed olfactory visualization sensor data and the NIR spectra, and the number of the best principal components (PCs) based on the single technique model was optimized during the backpropagation neural network (BPNN) modeling. Finally, the optimal PCs were fused at the feature level, and a BPNN detection model based on the fusion feature was established to achieve rapid measurement of fatty acid content during rice storage. The experimental results showed that the best BPNN model based on the fusion feature had a good predictive performance where the correlation coefficient (RP) was 0.9265, and the root mean square error (RMSEP) was 1.1005 mg/100 g. The overall results demonstrate that the detection accuracy and generalization performance of the feature fusion model are an improvement on the single-technique data model; and the results of this study can provide a new technical method for high-precision monitoring of grain storage quality.
Highlights
4A that covariance contribution rate of the thePC1 largest, 55.53%, indicating indicating it can explain of thevariable original information
Performance of backpropagation neural network (BPNN) Models Built on Olfactory Visualization Sensor Data
We believe that the number of the best principal components (PCs) of the BPNN
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. It is feasible to use the NIR spectroscopy technology to indirectly achieve the rapid determination of the fatty acid value during rice storage At present, this technology has been widely used for detection and analysis in many fields [12,13,14,15,16,17,18,19], including the detection of food storage quality [20,21,22]. This study fuses the olfactory sensor and NIR spectroscopy techniques that have been successfully applied in the detection of grain storage quality to establish a more fault-tolerant fusion detection model to achieve rapid detection of rice fatty acid content during storage with high precision.
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