Classification Technique for Using Near Infrared Spectroscopy to Detect Dry Juice Sac of Mandarin Fruit cv. Sai Nam Pueng
Keywords:
Mandarin, Chemometrics, NIRs, Dry juice sac, PCAAbstract
The use of chemometrics to analyze NIRs spectral data of Mandarin fruit Citrus reticulata cv. Sai Nam Pueng for dry juice sac detection was investigated. The total of 200 fruits (75 normal and 125 abnormal fruits) were acquired the spectral data using NIRSystem 6500 with fiber optic probe in the wavelength region from 700–1100 nm prior to determine the reference laboratory data including moisture content (MC), total soluble solid (TSS) and titratable acidity (TA). Then, the principal component analysis (PCA) and multiple linear regression - discriminant analysis (MLR-DA) were used to classify fruit with this symptom. It was found that Savitzky-Golay smoothing (10 nm average for left and right sides) and second derivative (10 nm average for left and right sides) were used as spectra pre-treatment method for the optimal PCA and MLR-DA model performances of MC, TSS and TA. The effective wavelengths in MLR-DA were at 826, 924, 962, 978, 1008 and 1028 nm. The precision of MLR-DA was 96%. There were only 4% of un-classify samples which were 1–25% of dry juice sac fruits and normal fruits. Therefore, MLR-DA could be the efficient method to classify a dry juice sac of Mandarin using non-destructive technique NIRs.
References
Gomez, A.H., He, Y. and Pereira, A.G. 2006. Non-destructive measurement of acidity, soluble solids and firmness of Satsuma Mandarin using Vis/NIR- spectroscopy techniques. Journal of Food Engineering 77: 313–319.
Jannok, P., Y. Kamitani and S. Kawano. 2014. Development of a common calibration model for determining the Brix value of intactapple, pear and persimmon fruits by near infrared spectroscopy. Journal of Near Infrared Spectroscopy. 22: 367–373.
Kawano, S., Fujiwara, T. and Iwamoto, M. 1993. Nondestructive determination of sugar content in satsuma Mandarin using NIR transmittance. Journal of the Japanese Society for Horticultural Science 62: 465–470.
Kawano, S., Abe, H. and Iwamoto, M. 1995. Development of a calibration equation with temperature compensation for determining the Brix value in intact peaches. Journal of Near Infrared Spectroscopy. 3: 211–218.
Muenmanee, N., Joomwong, A. Natwichai, J. and Boonyakiat, D. 2016. Assessment of Internal Quality of Japanese Pumpkin (Cucurbita Maxima) Using Near Infrared Spectroscopy. Pakistan Journal of Biotechnology. 13(1): 55–65.
Nakajima, Y. 1976. Studies on Dry Juice Sacs of Hyuganatsu (Citrus tamurana Hort. ex Tanaka) in Late Stages of Fruit Development. Journal of the Japanese Society for Horticultural Science. 44(4): 338–346.
Osborne, B.G. and Fearn, T. 1986. Near Infrared spectroscopy in Food Analysis. In R.A. Meyers (ed), Encyclopedia of Analytical Chemistry. John Wiley and Sons Ltd, Chichester. Pp. 114.
Saranwong, S. 2003. Nondestructive determination of harvesting maturity of mango for fresh consuming by near infrared spectroscopy. Ph.D. thesis. Chiang Mai University, Chiang Mai. 179 pp.
Slaughter, D.C., Barrett, D. and Boersig, M. 1996. Nondestructive determination of soluble solids in tomatoes using NIR spectroscopy. Journal of Food Science. 61(4): 695–697.
Timkhun, P., Kitchaicharoen, M., Panchon, K and Nothana, P. 2013. Non-Destructive Determination of Dry Juice Sac in Tangerines (Sri-Tong). Agricultural Science Journal. 44(3(Supply)): 45–48.
Wongzeewasakun, K., Changrue, V., Muenmanee, N. and Theanjumpol, P. 2017. Possibility of using near infrared spectroscopy technique to detect dry juice sac of Mandarin cv. Sai Nam Pueng. Agricultural Science Journal. 48(3(Supply)): 295–298.
William P.C. and Norris K. 1998. Near Infrared Spectroscopy. Journal of Near Infrared Spectroscopy. 6: 3–17.
