한국작물학회지 (KOREAN JOURNAL OF CROP SCIENCE)

  • 제53권3호
  • /
  • Pages.244-250
  • /
  • 2008
  • /
  • 0252-9777(pISSN)
  • /
  • 2287-8432(eISSN)
한국작물학회 (The Korean Society of Crop Science)
권호 표지

정조 상태에서 백미에 대한 완전미율의 비파괴 예측

Non-Destructive Prediction of Head Rice Ratios using NIR Spectra of Hulled Rice

  • 발행 : 2008.09.30
PDF 다운로드
⟨ 이전 논문 다음 논문 ⟩

초록

도정하지 않은 정조의 81 시료로부터 스펙트럼을 수집하고, 백미 완전미도정수율 예측 희귀모델을 개발하기 위해 검량식을 작성한 결과 스펙트럼을 8 nm 간격으로 지정하고, 1차미분 방법으로 검량식을 작성한 완전미율의 결정계수는 MPLS에서 0.8353, PLS 방법에서 0.8416, PCR에서 0.5277를 나타냈다. 스펙트럼을 20 nm 간격으로 지정하고 1차미분 방법으로 검량식을 작성하였다. 완전미율의 결정계수는 MPLS에서 0.8144, PLS 방법에서 0.8354, PCR에서 0.6809를 나타냈다. 스펙트럼을 8 nm 간격으로 지정하고 2차미분 방법으로 검량식을 작성하였다.완 전미율의 결정계수는 MPLS 방법에서 0.7994, PLS에서 0.8017, PCR에서 0.4473을 나타냈다. 스펙트럼을 20 nm 간격으로 지정하고 2차미분 방법으로 검량식을 작성하였다. 완전미율의 결정계수는MPLS 방법에서 0.8004, PLS에서 0.8493, PCR에서 0.6609을 나타냈다.

The purpose of this study was to measure fundamental data required for the prediction of milling ratios, and to develop regression models to predict the head rice ratio of milled rice using NIR spectra of hulled rice. A total of 81 rice samples used in this study were collected from Jeongeup, Jeonbuk province in 2006. NIR spectra were measured using one mode of measurement, reflection. The reflectance spectra were measured in the wavelength region of 400-2500 nm with an NIR spectrophotometer "NIRSystems 6500" (Foss, Silverspring, USA). Calibration equations were developed by the modified partial least squares (MPLS), partial least squares (PLS), and principal components regression (PCR). Math treatments were 1-4-4-1, 1-10-10-1, 2-4-4-1, and 2-10-10-1. The software used was WinISI (Infrasoft International, State College, USA). Automatic head rice production and quality checking system used was "SY2000-AHRPQCS" (Ssangyong, Korea). The calibration was made with the first derivative and the spectrum designated was in 8 nm interval. The determination coefficients of head rice ratios were 0.8353, 0.8416 and 0.5277 for the MPLS, PLS and PCR, respectively. Those obtained with 20 nm interval were 0.8144, 0.8354 and 0.6908 for the MPLS, PLS and PCR, respectively. The calibration was made with second derivative that spectrum designated was 8 nm in interval. The determination coefficients of head rice ratios were 0.7994, 0.8017 and 0.4473 for the MPLS, PLS and PCR, respectively. Those with 20 nm interval were 0.8004, 0.8493 and 0.6609 for the MPLS, PLS and PCR, respectively. These results indicate that the accuracy of determination coefficient for MPLS and PLS is higher than that of PCR.

키워드

참고문헌

  1. Begona, D. L. R, M. Adela, M. Sagrario, and S. Begona. 1995. Determination of the quality of fresh silages by near infrared reflectance spectroscopy. Near infrared spectroscopy: The future waves. 537-541
  2. Berardo, N., C. Cunico, A. Tava, and M. Odoardi. 1995, Broad calibration for measuring nutritive value of fresh forage species. Leaping ahead with near infrared spectroscopy. 231-234
  3. Clarke, M. A., E. R. Arias, and C. McDonald-Lewis. 1992. Near infra-red analysis in the sugarcane factory. Sugary Azucar. pres. at Ruspam Commun. Inc. USA
  4. Dardenne, P., R. Agneessens, and G. Sinnaeve. 1995, Fresh forage analysis by near infrared spectroscopy. Near infrared spectroscopy: The future waves. 531-536
  5. Hymowitz, T., J. W. Dudley, F. I. Collins, and C. M. Brown. 1974. Estimation of protein and oil concentration in corn, soybean, and oat seed by near infrared light reflectance. Crop Sci. 14 : 713-715 https://doi.org/10.2135/cropsci1974.0011183X001400050031x
  6. Kwon, Y. R., M. H. Baek, D. C. Choi, J. S. Choi, and Y. G. Choi. 2005. Determination of calibration curve for total nitrogen contents analysis in fresh rice leaf using the visible and near infrared spectroscopy system. Korean J. crop sci. 50 : 394-399
  7. Kwon, Y. R., S. H. Cho, Y. E. Song, J. H. Lee, and C. H. Cho. 2006. Nondestructive measurement of chemical compositions in polished rice and brown rice using NIR Spectra of hulled rice acquired in trabsmittance and reflectance modes. Korean J. crop sci. 51 : 451-457
  8. Marten, G. C., J. L. Halgerson, and J. H. Cherney. 1983. Quality prediction of small grain forage by near infrared reflectance spectroscopy. Crop Sci, 23 : 94-96 https://doi.org/10.2135/cropsci1983.0011183X002300010027x
  9. Moon, S. S., B. K. Min, and D. C. Kim. 1998. Accuracy of near reflectance spectroscopy in quality evaluation of domestic rice. Korean J. Food Sci. Technol/ 26(6) : 718-725
  10. Murray, I. and P. C. Williams. 1987. Chemical principals of near-infrared technology. Pages 17-34 in: Near-Infrared technology in the agricultural and food industries. P. C. Williams and K. H. Norris, eds. American Association of Cereal Chemistries: st. Paul MN
  11. Rubenthaler, G. L. and B. L. Bruinsma. 1979. Lysine estimation in cereals by near infrared reflectance. Crop Sci. 19 : 1039-1042
  12. Shenk, J. S., I. Landa, M. R. Hoover, and H. O. Westerhaus. 1981. Description and evalution of a near infrared reflectance spectro-computer for forage and grain analysis. Crop Sci. 21 : 355-358 https://doi.org/10.2135/cropsci1981.0011183X002100030001x
  13. Stephen, R. D., K. S. Mckenzie, and B. Webb. 1996 Quality characteristics in rice by Near-Infrared Reflectance Analysis of whole-grain milled samples. Cereal Chem. 73(2) : 257-263
  14. Williams, P. C., H. M. Corderiro, and M. F. T. Harnden. 1991. Analysis of oat bran products by near infrared reflectance spectroscopy. Cereal Foods World. 36 : 571-574