Full text: Technical Commission VIII (B8)

  
  
  
  
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155. Tea polyphenols 2% 
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| RMSEP = 4.30 
os | P=08 | 
RMSEP/mean = 3.0% 
120 ‘ 
120 130 140 150 160 
Measured (mg g ‘) 
Figure 3. Relationships between the predicted and measured 
total tea polyphenols using a hybrid of neural networks and 
SPA variable selections, according to the test dataset (n=16). 
Total tea polyphenols 
      
  
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i **^— enm that are significantly differt svith the 
~~ 9 minimum value through F-test (p«0.05i 
= 8 i * — eras that are NOT significantly differt wi te 
È i minimum value through F-test (p» 0.05) 
2 7 1 (O Optimal number of wavelength 
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Figure 4. Choice ofthe optimal number of wavelength (circled 
positions) by successive projections algorithm for the prediction 
of tea polyphenols. The criterion is to find a minimum number 
of wavelengths for which the errors is not significantly larger 
than the lowest one. This is determined by an F-test. 
4. DISCUSSION AND CONCLUSION 
The utility of reflectance spectroscopy for predicting tea 
quality-related biochemicals at canopy level is demonstrated in 
this paper (figure 2 and 3). In previous studies, some phenolic 
substances of tea, including total tea polyphenols, catechins, 
epigallocatechin gallate (EGCG) and epicatechin (EC) have 
been successfully estimated using near infrared spectra for dried 
tea powders and dried leaves (Chen et al., 2008; Luypaert et al., 
2003). Our results revealed that foliar chemical concentrations 
of tea (total tea polyphenols) can be retrieved not only from the 
spectra of dried powders, but also for living tea plant material. 
Prediction accuracy decreased using canopy spectra, compared 
to reported results using powder spectra. The variability of 
spectra reflectance of dried tea powders are mainly correlated 
with the amounts of chemical compounds, as the effect of 
absorption by water is reduced considerably and the effect of 
leaf cell structure could be impaired (Curran et al, 2001; 
Kokaly and Clark, 1999). At the canopy level, reflectance 
variability is due to additional factors such as LAI (leaf area 
index), foliar water content and canopy architecture (Gitelson 
  
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B8, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
et al., 2003; Kokaly et al., 2009). This may be the main reason 
of relatively lower prediction accuracy for tea plants. 
Our study showed that partial least squares regression is an 
effective method to retrieve biochemical parameters from 
canopy spectral reflectance of tea plant (figure 2). Predictive 
models based on partial least squares regression produced 
satisfactory accuracy. This results is consistent with those of 
Darvishzadeh et al. (2008) who in a field experimental study on 
green grass reported a better predictive performance of PLS 
regression analysis compared with for biophysical and 
biochemical parameters estimation. PLS has the potential to 
exploit the rich information content of hyperspectral data. 
It also demonstrated that the quality of tea can be predicted with 
satisfactory accuracy from the hyperspectral data at canopy 
level, using artificial neural networks in combination with 
successive projections algorithm (figure 3). Based on the 
optimal wavelengths selected by the successive projections 
algorithm, neural networks worked well for the prediction of 
total tea polyphenols using the canopy spectra of tea plants: the 
relative root mean square errors (RMSEP/mean) were less than 
10% on an independent test dataset. The goal of SPA solution 
is to find a small representative set of spectral variables with an 
emphasis on the minimization of collinearity (figure 4). Our 
results confirm recent studies that have successfully applied the 
successive projections algorithm for the predicting biochemical 
concentrations in vegetation science (Liu and He, 2009). 
Considering that data collected in the field or in a greenhouse 
were under natural atmospheric and illumination conditions, this 
research has demonstrated that there is potential to use 
reflectance spectra to predict in situ tea quality in space and 
time. As our experiment was carried out at canopy level using 
field spectrometer, when using airborne or spaceborne 
hyperspectral remote sensing, the retrieval of biochemical 
parameters for tea plants may be more difficult, as biochemical 
absorption features may be affected by complex environmental 
factors such as atmospheric and topographic effects . 
The following conclusions were drawn from this study: 
(1) Our results suggest that biochemical components (total tea 
polyphenols) of tea quality can be quantitatively estimated from 
canopy spectroscopy. The canopy spectra may have the 
potential to predict the foliar biochemical concentration of tea. 
(2) When up-scaling to canopy level, predicting total tea 
polyphenols was achieved with lower accuracy compared to 
reported results in literatures in which dried or ground powder 
spectra have been used. 
(3) partial least squares regression is able to locate surrogate 
spectral features for estimating the concentration of fresh leaf 
biochemicals of tea. 
(4) A novel integrated approach proposed in our study, 
involving a forward selection algorithm (successive projections 
algorithm) to choose the optimal number of wavelengths and 
neural networks can be used for a better simulation of nonlinear 
relationship between biochemical concentration and spectral 
signatures of tea canopy. 
In summary, the successful chemical estimation from canopy 
spectra shows the possibility of using hyperspectral remote 
sensing (air or space-borne sensors) to predict tea quality 
quantitatively and non-destructively at landscape or regional 
scales before its plucking, based on the methodology described 
in this paper. 
  
   
Inte 
Referenc 
Araujo, 
Card, D.I 
Cho, M. 
Curran, F 
Curran, F 
Darvishz: 
Davey, ! 
Gitelson, 
Knox, N. 
Kokaly, 
Lera, G 
Lin, G.F 
Liu, F. ai 
More, 
Mutanga, 
  
	        
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