Cross-Category Tea Polyphenols Evaluation Model Based on Feature Fusion of Electronic Nose and Hyperspectral Imagery

Tea polyphenols are important ingredients for evaluating tea quality. The rapid development of sensors provides an efficient method for nondestructive detection of tea polyphenols. Previous studies have shown that features obtained from single or multiple sensors yield better results in detecting interior tea quality. However, due to their lack of external features, it is difficult to meet the general evaluation model for the quality of the interior and exterior of tea. In addition, some features do not fully reflect the sensor signals of tea for several categories. Therefore, a feature fusion method based on time and frequency domains from electronic nose (E-nose) and hyperspectral imagery (HSI) is proposed to estimate the polyphenol content of tea for cross-category evaluation. The random forest and the gradient boosting decision tree (GBDT) are used to evaluate the feature importance to obtain the optimized features. Three models based on different features for cross-category tea (black tea, green tea, and yellow tea) were compared, including grid support vector regression (Grid-SVR), random forest (RF), and extreme gradient boosting (XGBoost). The results show that the accuracy of fusion features based on the time and frequency domain from the electronic nose and hyperspectral image system is higher than that of the features from single sensor. Whether based on all original features or optimized features, the performance of XGBoost is the best among the three regression algorithms (R2 = 0.998, RMSE = 0.434). Results indicate that the proposed method in this study can improve the estimation accuracy of tea polyphenol content for cross-category evaluation, which provides a technical basis for predicting other components of tea.

[1]  Aldo Roda,et al.  Electronic nose and chiral-capillary electrophoresis in evaluation of the quality changes in commercial green tea leaves during a long-term storage. , 2014, Talanta.

[2]  Huichun Yu,et al.  A selection method for feature vectors of electronic nose signal based on wilks Λ–statistic , 2014, Journal of Food Measurement and Characterization.

[3]  Hongmin Li,et al.  Rapid prediction of yellow tea free amino acids with hyperspectral images , 2019, PloS one.

[4]  Hongmei Zhang,et al.  Detection of bitterness and astringency of green tea with different taste by electronic nose and tongue , 2018, PloS one.

[5]  E. Combet,et al.  Determination of the Chemical Composition of Tea by Chromatographic Methods: A Review , 2015 .

[6]  Yong Yin,et al.  A sensor array optimization method of electronic nose based on elimination transform of Wilks statistic for discrimination of three kinds of vinegars , 2014 .

[7]  Jun Wang,et al.  Identification of green tea grade using different feature of response signal from E-nose sensors , 2008 .

[8]  Yuting Zhang,et al.  Combined feature extraction method for classification of EEG signals , 2017, Neural Computing and Applications.

[9]  Jiang Li,et al.  Automated detection of subpixel hyperspectral targets with adaptive multichannel discrete wavelet transform , 2002, IEEE Trans. Geosci. Remote. Sens..

[10]  Jingming Ning,et al.  Quantitative analysis and geographical traceability of black tea using Fourier transform near-infrared spectroscopy (FT-NIRS) , 2013 .

[11]  Dean Zhao,et al.  Discrimination of green tea quality using the electronic nose technique and the human panel test, comparison of linear and nonlinear classification tools , 2011 .

[12]  Qianqian Zhang,et al.  Detection of Type, Blended Ratio, and Mixed Ratio of Pu’er Tea by Using Electronic Nose and Visible/Near Infrared Spectrometer , 2019, Sensors.

[13]  Zhiguo Li,et al.  Quantitative evaluation of mechanical damage to fresh fruits , 2014 .

[14]  Andrew K. Skidmore,et al.  ESTIMATING BIOCHEMICAL PARAMETERS OF TEA ( CAMELLIA SINENSIS (L.)) USING HYPERSPECTRAL TECHNIQUES , 2012 .

[15]  Jazi Eko Istiyanto,et al.  Classification of Indonesia black teas based on quality by using electronic nose and principal component analysis , 2016 .

[16]  Yong Yin,et al.  A feature selection strategy of E-nose data based on PCA coupled with Wilks Λ-statistic for discrimination of vinegar samples , 2019, Journal of Food Measurement and Characterization.

[17]  Tianqi Chen,et al.  XGBoost: A Scalable Tree Boosting System , 2016, KDD.

[18]  Delores M. Etter,et al.  Image coding with the wavelet transform , 1995, Proceedings of ISCAS'95 - International Symposium on Circuits and Systems.

[19]  Hai-Bo Pan,et al.  A Rapid UPLC Method for Simultaneous Analysis of Caffeine and 13 Index Polyphenols in Black Tea. , 2017, Journal of chromatographic science.

[20]  N. Togari,et al.  Pattern recognition applied to gas chromatographic profiles of volatile components in three tea categories , 1995 .

[21]  K. R. Kashwan,et al.  Tea quality prediction using a tin oxide-based electronic nose: an artificial intelligence approach , 2003 .

[22]  Clement Atzberger,et al.  Comparative analysis of three chemometric techniques for the spectroradiometric assessment of canopy chlorophyll content in winter wheat , 2010 .

[23]  Angiras Modak,et al.  Fusion of Electronic Nose and Tongue Response Using Fuzzy based Approach for Black Tea Classification , 2013 .

[24]  Jun Wang,et al.  Identification of Tea Storage Times by Linear Discrimination Analysis and Back-Propagation Neural Network Techniques Based on the Eigenvalues of Principal Components Analysis of E-Nose Sensor Signals , 2009, Sensors.

[25]  Yong He,et al.  Theory and application of near infrared reflectance spectroscopy in determination of food quality , 2007 .

[26]  Bipan Tudu,et al.  A recurrent Elman network in conjunction with an electronic nose for fast prediction of optimum fermentation time of black tea , 2017, Neural Computing and Applications.

[27]  Wei Wang,et al.  Discriminant research for identifying aromas of non‐fermented Pu‐erh tea from different storage years using an electronic nose , 2018, Journal of Food Processing and Preservation.

[28]  Jun Wang,et al.  Detection of pest species with different ratios in tea plant based on electronic nose , 2019, Annals of Applied Biology.

[29]  Lekh Raj Juneja,et al.  L-theanine—a unique amino acid of green tea and its relaxation effect in humans , 1999 .

[30]  Yan Zhu,et al.  Evaluation of Aboveground Nitrogen Content of Winter Wheat Using Digital Imagery of Unmanned Aerial Vehicles , 2019, Sensors.

[31]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[32]  Anders Brandt,et al.  A signal processing framework for operational modal analysis in time and frequency domain , 2019, Mechanical Systems and Signal Processing.

[33]  Xiaolan Jiang,et al.  Effects of vitro sucrose on quality components of tea plants (Camellia sinensis) based on transcriptomic and metabolic analysis , 2018, BMC Plant Biology.

[34]  Shan Gai Efficient Color Texture Classification Using Color Monogenic Wavelet Transform , 2017, Neural Processing Letters.

[35]  Hong Ye,et al.  Recent advances in tea polysaccharides: Extraction, purification, physicochemical characterization and bioactivities. , 2016, Carbohydrate polymers.

[36]  Baijuan Wang,et al.  Discrimination of Unfermented Pu’er Tea Aroma of Different Years Based on Electronic Nose , 2017, Agricultural Research.

[37]  J. Liao,et al.  Adjusted Coefficients of Determination for Logistic Regression , 2003 .

[38]  Shukai Duan,et al.  Enhancing Electronic Nose Performance Based on a Novel QPSO-KELM Model , 2016, Sensors.

[39]  Changsheng Xie,et al.  A Method of Feature Extraction on Recovery Curves for Fast Recognition Application With Metal Oxide Gas Sensor Array , 2009, IEEE Sensors Journal.

[40]  Young-Sun Hwang,et al.  The characterization of caffeine and nine individual catechins in the leaves of green tea (Camellia sinensis L.) by near-infrared reflectance spectroscopy. , 2014, Food chemistry.

[41]  Akira Kotani,et al.  Attomole Catechins Determination by Capillary Liquid Chromatography with Electrochemical Detection , 2007, Analytical sciences : the international journal of the Japan Society for Analytical Chemistry.

[42]  E. Nishitani,et al.  Simultaneous determination of catechins, caffeine and other phenolic compounds in tea using new HPLC method , 2004 .

[43]  Mei Cheng,et al.  The modulatory effect of polyphenols from green tea, oolong tea and black tea on human intestinal microbiota in vitro , 2017, Journal of Food Science and Technology.

[44]  Rajib Bandyopadhyay,et al.  Estimation of Aroma Determining Compounds of Kangra Valley Tea by Electronic Nose System , 2012, PerMIn.

[45]  Xudong Sun,et al.  Enhanced cross-category models for predicting the total polyphenols, caffeine and free amino acids contents in Chinese tea using NIR spectroscopy , 2018, LWT.

[46]  Hongmei Lu,et al.  Identification of green tea varieties and fast quantification of total polyphenols by near-infrared spectroscopy and ultraviolet-visible spectroscopy with chemometric algorithms , 2015 .

[47]  Rishemjit Kaur,et al.  Towards biological plausibility of electronic noses: A spiking neural network based approach for tea odour classification , 2015, Neural Networks.

[48]  Bipan Tudu,et al.  Artificial flavor perception of black tea using fusion of electronic nose and tongue response: A Bayesian statistical approach , 2014 .

[49]  Teng Fei,et al.  Tea cultivar classification and biochemical parameter estimation from hyperspectral imagery obtained by UAV , 2018, PeerJ.

[50]  C. S. Ryu,et al.  Estimating catechin concentrations of new shoots in the green tea field using ground-based hyperspectral image , 2013, Remote Sensing.

[51]  Tao Cheng,et al.  Spectroscopic determination of leaf water content using continuous wavelet analysis , 2010, 2010 IEEE International Geoscience and Remote Sensing Symposium.

[52]  Dibyendu Dutta,et al.  Retrieval of tea polyphenol at leaf level using spectral transformation and multi-variate statistical approach , 2015, Int. J. Appl. Earth Obs. Geoinformation.

[53]  Ronald Rousseau,et al.  Requirements for a cocitation similarity measure, with special reference to Pearson's correlation coefficient , 2003, J. Assoc. Inf. Sci. Technol..

[54]  Nathan Hocker,et al.  Quantification of Antioxidant Properties in Popular Leaf and Bottled Tea by High-performance Liquid Chromatography (HPLC), Spectrophotometry, and Voltammetry , 2017 .

[55]  Zhuojun Jiang,et al.  Advances in Electronic Nose Development for Application to Agricultural Products , 2019, Food Analytical Methods.

[56]  Bipan Tudu,et al.  Preemptive identification of optimum fermentation time for black tea using electronic nose , 2008 .

[57]  Bipan Tudu,et al.  Electronic nose for black tea quality evaluation by an incremental RBF network , 2009 .

[58]  E. Basar,et al.  Wavelet entropy: a new tool for analysis of short duration brain electrical signals , 2001, Journal of Neuroscience Methods.

[59]  Dezheng Zhang,et al.  A Framework for the Multi-Level Fusion of Electronic Nose and Electronic Tongue for Tea Quality Assessment , 2017, Sensors.

[60]  Rishemjit Kaur,et al.  Enhancing electronic nose performance: A novel feature selection approach using dynamic social impact theory and moving window time slicing for classification of Kangra orthodox black tea (Camellia sinensis (L.) O. Kuntze) , 2012 .

[61]  Guohua Hui,et al.  Study of herbal tea beverage discrimination method using electronic nose , 2015, Journal of Food Measurement and Characterization.

[62]  Ilze Vermaak,et al.  Hyperspectral Imaging as a Rapid Quality Control Method for Herbal Tea Blends , 2017 .