| 光谱学与光谱分析 |
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| Study on Predicting Firmness of Watermelon by Vis/NIR Diffuse Transmittance Technique |
| TIAN Hai-qing,YING Yi-bin*,LU Hui-shan,XU Hui-rong,XIE Li-juan,FU Xia-ping,YU Hai-yan |
| College of Biosystems Engineering and Food Science, Zhejiang University, Hangzhou 310029,China |
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Abstract Watermelon is a popular fruit in the world and firmness (FM) is one of the major characteristics used for assessing watermelon quality. The objective of the present research was to study the potential of visible/near Infrared (Vis/NIR) diffuse transmittance spectroscopy as a way for the nondestructive measurement of FM of watermelon. Statistical models between the spectra and FM were developed using partial least square (PLS) and principle component regression (PCR) methods. Performance of different models was assessed in terms of correlation coefficients (r) of validation set of samples and root mean square errors of prediction (RMSEP). Models for three kinds of mathematical treatments of spectra (original, first derivative and second derivative) were established. Savitsky-Goaly filter smoothing method was used for spectra data smoothing. The PLS model of the second derivative spectra gave the best prediction of FM, with a correlation coefficient (r) of 0.974 and root mean square errors of prediction (RMSEP) of 0.589 N using Savitsky-Goaly filter smoothing method. The results of this study indicate that NIR diffuse transmittance spectroscopy can be used to predict the FM of watermelon. The Vis/NIR diffuse transmittance technique will be valuable for the nandestructive detection large shape and thick peel fruits’.
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Received: 2006-03-04
Accepted: 2006-06-19
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Corresponding Authors:
YING Yi-bin
E-mail: ybying@zju.edu.cn
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| Cite this article: |
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TIAN Hai-qing,YING Yi-bin,LU Hui-shan, et al. Study on Predicting Firmness of Watermelon by Vis/NIR Diffuse Transmittance Technique[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2007, 27(06): 1113-1117.
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| URL: |
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https://www.gpxygpfx.com/EN/Y2007/V27/I06/1113 |
[1] WANG Shu-mao, JIAO Qun-ying, JI Jun-jie(王书茂, 焦群英, 籍俊杰). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报), 1999, 15(3): 241.
[2] Diezma-Iglesias B, Ruiz-Altisent M, Barreiro P. Biosystems Engineering, 2004, 88(2): 221.
[3] REN Yu-lin, BING Chun-ting, LU Jia-hui, et al(任玉林, 邴春亭, 逯家辉, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 1996, 16(6): 31.
[4] Clark C J, McGlone V A, Requejo C, et al. Postharvest Biology and Technology, 2003, 29: 300.
[5] Dull G, Birth G, Leffler R. American Potato Journal, 1989, 66: 215.
[6] Herrera J, Guesalaga A, Agosin E. Measurement Science and Technology, 2003, 14: 689.
[7] Schaare P N, Fraser D G. Postharvest Biology and Technology, 2000, 20: 175.
[8] Xiaoli L, Yong H, Hui F. Journal of Food Engineering, 2007, 81: 357.
[9] Renfu Lu. Trans of the ASAE, 2001, 44(5): 1265.
[10] Peng Y, Renfu Lu. Trans. of ASAE, 2005, 48(1): 235.
[11] Greensill C V. Applied Engineering in Agriculture, 2001, 17(1): 69.
[12] YING Yi-bin, LIU Yan-de, FU Xia-ping(应义斌,刘燕德,傅霞萍). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2006,26(1):63.
[13] Ashenafi T A. Journal of Near Infrared Spectroscopy, 2006, 14: 67.
[14] Peiris K H S, Dull G G. Hort Science, 1999, 34(1): 114.
[15] LIU Yan-de, YING Yi-bin, FU Xia-ping(刘燕德, 应义斌, 傅霞萍). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2005, 25(11): 1793.
[16] LIU Yan-de, YING Yi-bin, FU Xia-ping, et al. Journal of Food Engineering, 2007, 80: 986.
[17] Peris A, Schenk A, Nicola I. Postharvest Biology and Tech, 2005, 35: 1.
[18] McGlone V A. J. Near Infrared Spectrosc., 2004, 12: 37.
[19] McGlone V A. Postharvest Biology and Technology, 2003, 28: 431.
[20] McGlone V A. Postharvest Biology and Technology, 2002, 25: 135.
[21] LIU Yan-de, YING Yi-bin. Trans. of ASAE, 2006, 49(1): 91.
[22] LIU Yan-de, YING Yi-bin(刘燕德,应义斌). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报),2004,20(1):189.
[23] YING Yi-bin, LIU Yan-de, TAO Yang. Applied Optics,2005, 44(25): 5224.
[24] YING Yi-bin, LIU Yan-de,WANG Jian-ping, et al. Trans. of American Society of Agricultural Engineers, 2005, 48(1): 229.
[25] LIU Yan-de, YING Yi-bin. Journal of Optical Engineering, 2005, 47(7): 1.
[26] Andrew M V, Robert B, Jordan R S, et al. Postharvest Biology and Technology, 2002, 26: 191. |
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