论文信息 - Sugar “Imaging” of Fruit Using a Low Cost Charge-Coupled Device Camera

Sugar “Imaging” of Fruit Using a Low Cost Charge-Coupled Device Camera

Sugar “imaging” of fruit has previously been reported using NIR filters and relatively expensive (high signal-to-noise) charge-coupled device (CCD) instrumentation. In a bid to use lower cost CCD instrumentation (criterion of less than AU $5,000 total component costs), the signal-to-noise constraint on calibration model performance was investigated by artificially degrading spectra from a 15-bit AtoD system. A low cost 8-bit CCD camera was then used in conjunction with a filter wheel in a transmittance configuration employing three 50 W halogen lamps. Multiple linear regregression calibrations were developed based on absorbance data of five wavelengths (830, 850, 870, 905 and 930 nm) relevant to sugar and water. Calibration models for the sucrose concentration of solutions on a cellulose matrix were poor (R2 = 0.4) when based on individual pixel data, but acceptable (R2 = 0.98, RMSECV = 1.1) (n = 20, mean = 13.9% total soluble sugars (TSS), SD = 6.04) when based on an average of a 23 × 23 pixel block (i.e. 529 pixels). For a calibration based on melon tissue TSS, using spectral data averaged over groups of 529 pixels, results were poorer than expected (R2 = 0.4, RMSEP = 1.74 (n = 163, mean = 9.45, SD = 2.07% TSS). Predicted TSS output for all pixel blocks from an image was used to generate a false colour image. We conclude that this application requires a higher level of signal-to-noise (for example, 10-bit, > 60 dB CCD).

[1] Junichi Sugiyama,et al. Near-infrared imaging spectroscopy based on sugar absorption band for melons. , 2002, Journal of agricultural and food chemistry.

[2] J. Sugiyama. Visualization of sugar content in the flesh of a melon by near-infrared imaging. , 1999, Journal of agricultural and food chemistry.

[3] K. Walsh,et al. A remote acceptance probe and illumination configuration for spectral assessment of internal attributes of intact fruit , 2000 .

[4] P. Martinsen,et al. Measuring soluble solids distribution in kiwifruit using near-infrared imaging spectroscopy , 1998 .

[5] A. Peirs,et al. Starch Index Determination of Apple Fruit by Means of a Hyperspectral near Infrared Reflectance Imaging System , 2003 .

[6] K. Peiris,et al. Spatial variability of soluble solids or dry-matter content within individual fruits, bulbs, or tubers : Implications for the development and use of NIR spectrometric techniques , 1999 .

[7] W. F. McClure,et al. Design of a High-Speed Fiber Optic Blueberry Sorter , 1975 .

[8] K. Walsh,et al. Short-Wavelength Near-Infrared Spectra of Sucrose, Glucose, and Fructose with Respect to Sugar Concentration and Temperature , 2003, Applied spectroscopy.

[9] J. Guthrie,et al. Application of commercially available, low-cost, miniaturised NIR spectrometers to the assessment of the sugar content of intact fruit , 2000 .