KR20170013176A - Discrimination method of country-of-origin of agricultural products by a color sensor based on virus and discrimination system for country-of-origin of agricultural products including a color sensor - Google Patents

Abstract

The present invention relates to a method for detecting country-of-origin of agricultural products by using a virus-based discoloration sensor and an apparatus for determining country-of-origin of agricultural products including a virus-based discoloration sensor. The method for detecting country-of-origin of agricultural products by using a virus-based discoloration sensor comprises the following steps: allowing the virus-based discoloration sensor, which has a bundle of nanofiber formed by M13 bacteriophage and arranged on a base material, to prepare a sample color change value between a changed color, generated as the discoloration sensor is exposed to elements included in sample agricultural products for each country-of-origin, and a natural color of the discoloration sensor; obtaining a color change value for analysis between the changed color and the natural color of the discoloration sensor with respect to the agricultural products to be analyzed; and determining country-of-origin of the agricultural products to be analyzed in accordance with a degree of similarity of the color change value for analysis to the color change value of the samples.

Description

TECHNICAL FIELD The present invention relates to a method for discriminating the origin of a crop by a virus-based discoloration sensor and a method for discriminating a source of a crop including a virus-based discoloration sensor. -ORIGIN OF AGRICULTURAL PRODUCTS INCLUDING A COLOR SENSOR}

The present invention relates to a method for discriminating the origin of a crop by a virus-based discoloration sensor and a discriminating apparatus for a country of origin including a virus-based discoloration sensor. More particularly, the present invention relates to a method for discriminating the origin of a crop, A method for discriminating the origin of a crop by a discoloration sensor, and a discriminating apparatus for a country of origin including a virus-based discoloration sensor.

Due to the opening of FTAs with the world, imports of agricultural products are becoming more active, and imported agricultural products, especially Chinese agricultural products, are being supplied more cheaply than Korean agricultural products, and agricultural conditions in the country are getting worse. Consumers are increasingly distrustful about the origin of their crops as the number of cases where the origin of the country is not falsely displayed or not is used in order to obtain commercial profit by using the price difference between Korean and imported crops.

The general procedure for identification of origin is to collect samples for analysis and then to pre-process samples such as drying, cutting, crushing and acid treatment so as to be suitable for the analytical conditions of each analytical instrument, . As an analysis device for identification of the country of origin, a near infrared ray spectrometer, an X-ray fluorescence analyzer, a mass analyzer, an element analyzer, an electronic nose, an image magnifier, etc. are used. And the origin is determined by synthesizing the results.

However, there is a disadvantage in that the reliability of the result of the identification method of origin is not high, and the analysis can not be performed directly on site and takes a long time for analysis. Therefore, it is necessary to have a real - time field analyzer that can be analyzed in a short time by a simple method and can be directly analyzed on the spot.

An object of the present invention is to provide a method for discriminating the origin of crops by a virus-based color fading sensor, which is capable of analyzing in a short time and discriminating the origin of crops in real time.

Another object of the present invention is to provide a real-time field analyzer capable of analyzing in a short time by a simple method and directly analyzing in the field, and a device for discriminating the origin of a crop by a virus-based discoloration sensor.

For the purpose of the present invention, a method for determining the origin of a crop by a virus-based discoloration sensor is characterized in that a virus-based discoloration sensor in which a bundle of nanofibers formed by M13 bacteriophages is arranged on a base substrate is exposed to components contained in sample crops Preparing a sample color change value between the changed color and the unique color of the color change sensor, obtaining a color change value for analysis between the change color and the unique color for the color change sensor of the agricultural crop for analysis, And discriminating the country of origin of the crop for analysis according to the similarity of the color change value for analysis.

In one embodiment, in each of the sample color change value and the analysis color change value, the color change value includes a color space element value of the color code data, and the color code data includes at least one of an RGB method, a CMYK method, HSV method, the color space element value is a value corresponding to a color space element of the color model, and the similarity degree is a difference between a sample color space element value and a color space element value for analysis have.

In one embodiment, the sample color change value is a sample color space element value selected from a plurality of sample color space element values having a high degree of origin classification according to multivariate analysis, and the color change value for analysis is a degree of origin classification May be the color space element value for analysis corresponding to the same color space element as the sample color space element selected to be large. At this time, the multivariate analysis may be performed by a principal component analysis (PCA) method.

In one embodiment, the color change sensor includes at least two regions that represent different colors, and the color change value at each of the sample color change value and the analysis color change value is a color change ≪ / RTI >

In one embodiment, each of the color change values appearing in each region of the color fading sensor includes a color space element value of color code data, and the color code data is any one of RGB, CMYK, CMY, and HSV Model, the color space element value is a value corresponding to a color space element of the color model, and the similarity may be a difference between a sample color space element value and an analysis color space element value. In this case, the sample color change value is a sample color space element value selected to have a high degree of origin classification according to multivariate analysis among the sample color space element values of each color sensor, May be an analysis color space element value corresponding to a color space element which is the same as the sample color space element selected to have a high degree of origin classification among the color space element values for analysis of each color sensor.

In one embodiment, the M13 bacteriophage may be a protein whose amino acid sequence WHWQ is expressed on its surface.

In one embodiment, the obtaining of the color change value for analysis includes heating the crop for analysis to expose the color fading sensor to the vapor emitted by the agricultural crop for analysis, obtaining an image of the fading color sensor changed by the crop for analysis And deriving an analysis color change value between the change color for the change sensor and the unique color of the color change sensor using the image.

In one embodiment, the crop may be red pepper powder, onion, perilla or sesame seeds.

Another object of the present invention is to provide an apparatus for discriminating the origin of a crop by a virus-based color change sensor, comprising: a sensing unit having a virus-based color change sensor in which a nanofiber bundle formed by M13 bacteriophages is arranged on a base substrate; An image obtaining unit connected to the sensing unit and obtaining an image of a color fading sensor exposed to a component included in the analysis crop, and a sensor that is the same as the color fading sensor, The color change value for analysis of the crop for analysis is stored in the same manner as the method for obtaining the sample color change value, The origin of the agricultural crop for analysis is determined according to the similarity of the color change value for analysis to the change value It comprises an end portion.

In one embodiment, the sample portion may include a heating portion for heating the agricultural crop.

In one embodiment, in each of the sample color change value and the analysis color change value, the color change value includes a color space element value of the color code data, and the color code data includes at least one of an RGB method, a CMYK method, HSV method, wherein the color space element value is a value corresponding to a color space element of the color model, and the sample color variation value is selected from among the sample color space element values in a multivariate analysis And the color change value for analysis is a color space element value for analysis corresponding to a color space element that is the same as the sample color space element selected to have a large degree of origin classification , The similarity may be a difference between a sample color space element value and a color space element value for analysis.

In one embodiment, the color fading sensor includes regions divided into at least two regions, the fiber bands disposed in each of the regions have different thicknesses of the nanofiber bundles, and the sample color change value and the analysis color change Wherein each of the color change values appearing in each of the regions of the color change sensor includes a color space element value of the color code data, Wherein the color space element value is determined according to a color model of any one of an RGB system, a CMYK system, a CMY system, and an HSV system, the color space element value being a value corresponding to a color space element of a color model, Among the sample color space element values for each region, a sample color space element value determined to have a high degree of origin classification according to multivariate analysis , The color change value for analysis is an analysis color space element value corresponding to a color space element that is the same as the sample color space element selected to have a high degree of origin classification among the color space element values for analysis of each color of the color sensor, The similarity may be the difference between the sample color space element value and the color space element value for analysis.

According to the method for discriminating the origin of crops by the virus-based discoloration sensor of the present invention and the apparatus for discriminating the origin of crops including the virus-based discoloration sensor, it is possible to directly analyze the country of origin of the crops in a short time with high portability and simple method . The reliability of the result of the country of origin analysis using the country of origin discriminating device of the crop can be improved.

1 is a view for explaining an apparatus for discriminating the origin of a crop according to the present invention.
FIG. 2 is a view for explaining a color fading sensor included in the sensor unit of FIG. 1. FIG.
FIG. 3 is a conceptual diagram for explaining an M13 bacteriophage constituting the color fading sensor of FIG. 2. FIG.
FIG. 4 is a conceptual diagram for explaining a sensor for deriving a sample color change value per crop source country in the present invention.
FIGS. 5 to 9 are graphs showing sample color change graphs according to the type of crops by country of origin.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the term "comprises" or "having ", etc. is intended to specify that there is a feature, step, operation, element, part or combination thereof described in the specification, , &Quot; an ", " an ", " an "

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

1 is a view for explaining an apparatus for discriminating the origin of a crop according to the present invention.

Referring to FIG. 1, a crop origin discriminating apparatus 700 includes a sample unit 100, a sensing unit 200, an image obtaining unit 300, and a determining unit 500.

The sample part 100 is an area in which a crop for analysis is disposed and the sample part 100 can be disposed in a chamber CH sealed together with the sensing part 200. [ The components included in the analytical crop in the sample unit 100 are provided to the sensing unit 200 and the color of the color sensor 210 (see FIG. 2) of the sensing unit 200 Can be changed.

The component included in the analysis crop provided to the sensing unit 200 in the sample unit 100 may be "steam ". The steam at this time is generated from the crop for analysis and may be the volatile component of the agricultural crop itself or it may be steam obtained from the crop for analysis through gasification of the crop for analysis. In the following, "steam" is defined as a term including both of the above.

In one embodiment, the sample section 100 may include a heating section 110 for vaporizing components contained in the analytical crop or for promoting the release of volatile components. The heating section 110 may be a hot-plate for heating the crop for analysis.

The sensing unit 200 includes a discoloration sensor 210. The discoloration sensor 210 of the sensing unit 200 will be described in detail with reference to FIGS. 2 and 3. FIG.

FIG. 2 is a view for explaining a color fading sensor included in the sensor unit of FIG. 1, and FIG. 3 is a conceptual diagram for explaining an M13 bacteriophage constituting the color fading sensor of FIG.

Referring to FIGS. 2 and 3 together with FIG. 1, the discoloration sensor 210 is a virus-based discoloration sensor in which nanofiber bundles formed by M13 bacteriophages (VNP) are arranged on a base substrate.

The discoloration sensor 210 includes M13 bacteriophage VNP and the M13 bacteriophage VNP is arranged in a smectic manner to form a plurality of nanofiber bundles. The structure of the nanofibers connected to each other in a helical structure in the direction of the arrow.

Specifically, M13 bacteriophage (VNP) is a tubular bacteriophage having a diameter of about 6.6 nm and a length of about 880 nm, and is a protein particle that is expressed through a constant gene. For this reason, almost all of the M13 bacteriophages (VNP) have the same size and shape. The M13 bacteriophage (VNP) contains about 2700 pairs of proteins (protein VIII, hereinafter referred to as pVIII) and four to five pairs of proteins (pIII, pVI, pVII, pIX) at both ends.

The M13 bacteriophage (VNP) in the present invention may be a bacteriophage in which a receptor (RCT) that contains at least one of the components contained in the agricultural crops on its surface is expressed on the surface.

The receptor (RCT) of the M13 bacteriophage (VNP) is a modification of the protein pVIII of the circular bacteriophage, and may include a protein comprising the amino acid sequence WHWQ. By introducing a specific nucleotide sequence into the circular bacteriophage, the amino acid sequence as described above is expressed to become a protein containing the amino acid sequence, and can be an M13 bacteriophage (VNP) contained in the discoloration sensor 210 of the present invention. For example, the component of the analytical crop that binds to a receptor (RCT) comprising the protein may be an aromatic compound.

The nanofiber structure of the discoloration sensor 210 as described above is a structure in which nanofiber bundles of M13 bacteriophage (VNP) are helically pulled in one direction and connected to each other.

In one embodiment, the color fading sensor 210 according to the present invention may be implemented in a form that represents different colors for each region as shown in FIG. That is, by setting different thicknesses of the nanofiber bundles in at least two regions of the color fading sensor 210, the observer can visually recognize different colors according to the regions of the color fading sensor 210. The thickness of the nanofiber bundle can be determined by controlling the pulling speed, the concentration of the manufacturing solution, and the like in the process of manufacturing the discoloration sensor 210.

When the discoloration sensor 210 is exposed to components contained in the analysis crops in the sample unit 100, the arrangement of the nanofiber bundles formed by the M13 bacteriophage (VNP) constituting the discoloration sensor 210 changes. Such a change in the arrangement changes the length of the wavelength that reflects the incident light, and the color of the color fading sensor 210 changes. However, although the color change of the color change sensor 210 actually occurs, it can not be visually confirmed and the difference can not be distinguished.

The inventors of the present invention have found that when the discoloration sensor 210 having such characteristics is exposed to steam containing a volatile component or a vaporized component of the crop itself such as red pepper powder, garlic, onion, sesame, (RCT) of the M13 bacteriophage (VNP) to change the color of the discoloration sensor 210, and this color change is different depending on the origin of the crop, for example, Korea and China . In particular, the receptor (RCT) contained in the M13 bacteriophage (VNP) of the present invention has a characteristic of reacting with at least some of the components contained in each of red pepper powder, garlic, onion, There is an advantage in that it can be used for discriminating the origin of various crops only by the kind of discoloration sensor 210 and it can be confirmed that different color change is shown for each country of origin only by one kind of discoloration sensor 210. [ The present inventors have invented a crop source discriminating apparatus 700 by quantifying the color change of the color fading sensor 210 based on the above results.

Referring again to FIG. 1, the image obtaining unit 300 obtains an image of the color fading sensor 210 whose color has changed in the sensing unit 200. The image acquiring unit 300 may include a digital camera. The image captured by the image acquisition unit 300 is transmitted to the determination unit 500 connected to the image acquisition unit 300.

The determination unit 500 is connected to the image acquisition unit 300 and determines the origin of the agricultural crop for analysis using the image transmitted from the image acquisition unit 300.

Specifically, the determination unit 500 stores a sample color change value for a sample crop according to the country of origin of the crop as a population, obtains a color change value for analysis of the crop for analysis based on the image, The origin of the crop for analysis is determined according to the degree of similarity of the color change value for analysis.

The sample color change value for the sample crop according to the crop origin that has already been stored in the determination unit 500 can be determined by the inventors of the present application in such a manner that the color change sensor 210 detects a change The color change is quantified and converted into data based on the finding that the color changes.

In one embodiment, the sample color change value for the sample crop according to the crop origin that is already stored in the determination unit 500 may include the color space element value of the color code data. The color code data is determined according to a color model of one of an RGB method, a CMYK method, a CMY method, and an HSV method, and the color space element value may be a value corresponding to a color space element of the color model .

The RGB system, the CMY system and the HSY system have three color space elements, and the CMYK system has four color space elements. In one example, the color model the color code of the case containing the three color space components, such as RGB may be expressed as "E _1, E _2, E _3", wherein E _1, E ₂ and E ₃ each color space Where E ₁ , E _2, and E ₃ are each a natural number greater than or equal to 1, and the maximum value can be determined as the color model is represented by 8 bits, 16 bits, and so on .

At this time, the sample color change value for the sample crop according to the crop origin, which is already stored in the determination unit 500, is a sample color space element value selected to have a high degree of origin classification according to multivariate analysis among the sample color space element values . The multivariate analysis may be by Principal Component Analysis (PCA).

In multivariate analysis, the color change of the color change sensor 210, which is different depending on the country of origin of the crop, can be mathematically processed in consideration of the mutual relationship between the color changes, The origin of the crop having an unknown origin can be discriminated on the basis of the relationship.

FIG. 4 is a conceptual diagram for explaining a sensor for deriving a sample color change value per crop source country in the present invention.

In one embodiment, as shown in FIG. 4, the discoloration sensor 210 for obtaining a sample color change value for a sample crop according to the country of origin of the crop is not a single band, but two or more bands having different thicknesses of nanofiber bundles , It is possible to obtain an image corresponding to the number of regions of the sensor for one sensor, and color code data can be generated for each of the images. However, in order to secure the reliability of data, when the sensor is composed of different bands and is divided into n regions (n is a natural number of 2 or more) In this case, m × n color code data can be generated for one crop for analysis. These color code data can be used independently of the entire mxn pieces, and average data of the color change appearing in the m subareas in each area can be used.

In this case, each of the color change values appearing in each region of the color fading sensor 210 includes a color space element value of the color code data, and the color space element value may be a value corresponding to the color space element of the color model. At this time, the sample color change value may be a sample color space element value selected to have a high degree of origin classification according to multivariate analysis among the sample color space element values for each region of the color shift sensor.

In the first band, the second band and the third band corresponding to each of the three regions of the discoloration sensor 210 partitioned into the three regions, color change And the color of the image is calculated using the RGB color model. The results are shown in Tables 1 and 2 below.

Table 1 is for 20 kinds of red pepper powder from Korea, and Table 2 is for 20 kinds of red pepper powder from China.

In the following Tables 1 and 2, three sub-regions are selected for each of the first to third bands for each sample, but one ΔRGB value is derived for each band because the sub- This is because it is a value obtained by averaging the values.

Sample No. The first band The second band Third band ΔR ΔG ΔB ΔR ΔG ΔB ΔR ΔG ΔB One 19.66 57.64 -67.48 59.98 -18.31 50.92 -57.21 -33.15 40.76 2 1.66 26.52 -124.12 -0.98 -55.47 46.14 -79.67 -61.99 10.98 3 0.23 28.44 -97.84 20.23 -43.89 24.01 -52.22 -42.69 4.84 4 7.92 17.75 -80.86 28.03 -41.67 8.45 -61.30 -45.33 15.78 5 0.69 25.27 -91.68 13.73 -41.09 34.11 -54.41 -45.95 8.87 6 30.36 50.56 -92.67 43.49 -15.28 60.30 -83.32 -37.38 50.48 7 33.71 30.27 -107.17 37.51 -42.40 34.86 -101.57 -47.21 29.96 8 5.95 33.68 -152.34 -16.07 -69.52 101.34 -112.16 -72.61 33.68 9 2.72 34.56 -135.74 6.48 -60.96 55.51 -100.36 -54.32 34.54 10 26.78 85.40 -55.07 -36.22 -27.30 83.44 -69.49 -19.85 106.16 11 10.44 64.14 -58.79 -22.33 -46.68 57.33 -68.74 -46.93 59.82 12 -8.77 29.47 -5.63 -2.01 -36.87 25.38 -26.37 -35.20 4.41 13 1.26 45.39 -24.21 -2.78 -38.20 53.03 -16.97 -16.02 22.21 14 -6.63 63.73 0.90 -10.82 -42.59 69.90 -55.68 -46.20 51.75 15 9.85 56.81 2.76 10.54 -24.14 60.39 -17.94 -20.90 34.19 16 0.23 54.27 8.21 10.82 -34.06 55.78 -25.14 -29.63 33.92 17 12.38 53.06 -19.01 -31.59 -42.30 49.69 -23.74 -21.46 34.83 18 5.45 23.10 -146.04 -0.63 -62.50 71.60 -92.18 -60.51 24.39 19 -10.42 38.42 -3.99 -8.75 -46.53 40.27 -43.18 -45.83 18.38 20 -12.70 30.19 -5.03 -6.00 -41.45 31.38 -32.51 -39.03 10.47

Sample No. The first band The second band Third band ΔR ΔG ΔB ΔR ΔG ΔB ΔR ΔG ΔB One 0.05 36.22 -106.56 32.42 -39.62 26.21 -42.27 -19.61 8.79 2 32.68 -18.81 -7.50 1.76 13.48 -43.01 -29.43 -26.80 2.96 3 0.22 19.66 -78.26 16.04 -28.28 20.97 -46.74 -21.27 8.76 4 11.44 35.58 -31.66 47.75 -4.73 20.61 -14.87 -10.99 21.41 5 0.05 23.10 -67.37 8.01 -33.32 19.37 -52.60 -25.94 12.60 6 35.61 -32.21 27.16 15.57 13.11 -89.91 -73.03 -50.51 23.22 7 1.36 34.53 -130.68 6.78 -57.75 52.54 -86.33 -59.07 21.85 8 8.17 22.03 -79.89 51.39 -33.00 9.42 -55.84 -43.20 10.30 9 1.85 38.28 -144.34 3.81 -66.18 59.19 -99.97 -72.01 25.69 10 8.51 31.45 -1.72 8.00 -17.01 35.23 1.45 -2.49 12.83 11 10.68 28.90 -3.36 18.71 -15.92 19.91 6.97 -0.98 8.91 12 6.03 41.54 2.72 9.99 -35.97 29.60 2.69 -7.80 13.32 13 3.23 34.85 1.43 13.31 -26.84 29.32 0.25 -8.01 11.36 14 4.22 40.22 2.47 14.68 -33.84 31.03 1.18 -11.93 14.24 15 -8.57 22.17 8.15 5.07 -38.38 23.11 -5.96 -22.64 8.07 16 -15.14 23.91 17.57 0.97 -42.84 28.04 -6.57 -29.92 4.77 17 1.93 30.39 -134.76 -7.48 -57.80 77.12 -91.67 -56.07 29.12 18 15.83 44.79 -8.55 8.41 -27.80 54.12 0.11 -12.99 26.51 19 -18.05 22.94 15.73 5.65 -45.45 17.16 -7.00 -31.20 -0.39

The RGB color model data (R, G, B) for the red pepper powder calculated as shown in Table 1 and the red pepper powder samples as shown in Table 2 can be obtained.

Next, the color code data is set as a value independent of the color space elements of the color model, and values corresponding to the color space elements of the color model are set as color space element values. That is, in one color code data, the data is converted into independent data for each color space element of the color code data, and the thus converted independent data is set as a variable between the color space elements of the color code data and the unique color of the color fading sensor .

Among the sampled color space element values thus derived, a sample color space element value determined to have a high degree of origin classification according to multivariate analysis is regarded as a sample color change value for a population. For example, multivariate analysis uses principal component analysis (PCA).

In the present invention, for each of the sample crops included in the population through principal component analysis (PCA), at least one of the color components of the color code data, which affects the color change according to the crop origin, The main component can be derived. The variables corresponding to the principal component in each of the sample crops included in the population thus derived are converted into coordinate data, and such coordinate data can be used as a population sample color change value according to the crop origin. That is, two-dimensional coordinate data having one of the derived principal components as x coordinate and the other as y coordinate or three-dimensional coordinate data having x, y, and z coordinates as respective ones is set as a sample color change value according to the place of origin of the crop .

In the case where the discoloration sensor 210 includes two or more areas, the sample color change value may be a sample color space factor selected from a plurality of sample color space element values of the discoloration sensor 210, Lt; / RTI >

Specifically, the inventors of the present application used a sensor partitioned into three bands including an M13 bacteriophage (VPN), and using a color model in an RGB manner, 20 kinds of Korean red pepper powder and 19 kinds of red pepper powder The PCA of the color change was used to derive the main component and the two - dimensional coordinate data were calculated based on this data. The results showed that Korean red pepper powder and Chinese red pepper powder had the selectivity. The results are shown in Fig.

FIGS. 5 to 9 are graphs showing sample color change graphs according to the type of crops by country of origin.

FIG. 5 (a) is a graph obtained by deriving two principal components and calculating two-dimensional coordinate data for red pepper powder, and FIG. 5 (b) is a graph obtained by deriving three principal components and calculating three-dimensional coordinate data for red pepper powder.

In Figures 5 (a) and 5 (b), the black dots are for Korean and the white dots are for Chinese.

6 to 9, it can be seen that, in each of garlic, onion, sesame and perilla, there is a discriminative power capable of discriminating between Korean and Chinese acids. As a result, .

In each of FIGS. 6 to 9, the black dots are for Korean and the white dots are for Chinese. Fig. 6 is for garlic, Fig. 7 for onion, Fig. 8 for sesame, and Fig. 9 for perilla.

6 to 9, when a sample color space element value is included as a sample color change value, when they are plotted as coordinate data, it is confirmed that there is a sorting power between the Korean and Chinese crops in each crop have. That is, it can be confirmed that the sample color change values of the Korean crops are similar to each other, and the sample color change values of the Chinese crops are similar to each other.

The three-dimensional coordinate data of FIG. 6 is obtained by PCA analysis using the data shown in Tables 3 and 4 below.

Table 3 shows 30 kinds of domestic garlic and Table 4 shows 29 kinds of Chinese garlic.

Sample No. The first band The second band Third band ΔR ΔG ΔB ΔR ΔG ΔB ΔR ΔG ΔB One 60.13 0.00 -66.70 -14.57 -23.76 53.65 -8.32 21.07 32.72 2 25.63 0.03 -19.38 0.57 4.21 14.27 -5.46 7.73 22.50 3 46.13 -4.58 -25.13 3.36 9.14 7.56 -5.98 10.11 21.08 4 22.85 -27.63 -27.78 -32.33 -28.81 24.60 -28.62 -5.66 7.83 5 62.58 -15.24 -21.36 -16.94 -38.14 59.22 -11.78 18.35 38.94 6 -1.24 1.54 -27.83 34.21 8.13 -43.58 -5.82 17.89 26.72 7 34.39 1.20 -65.18 3.95 23.50 -1.19 -4.91 10.51 15.22 8 25.11 6.92 -42.33 5.69 4.26 -0.91 -18.67 -13.57 22.01 9 44.03 -0.78 -95.94 10.53 40.92 2.46 -7.48 13.16 32.18 10 27.33 -6.02 -6.54 25.30 13.89 -12.45 -3.81 16.45 16.56 11 54.02 -0.52 -76.54 -18.40 -26.76 78.28 -12.56 12.98 24.98 12 37.79 -3.76 -117.96 -39.59 -48.91 36.92 -31.69 1.91 20.75 13 34.26 6.08 -58.36 8.29 28.25 4.69 -7.49 7.13 24.20 14 -0.61 1.49 -31.38 23.65 -14.68 -16.73 -3.94 21.56 27.89 15 -5.36 -0.55 -1.27 0.67 -1.88 0.50 -2.92 -2.01 -3.34 16 2.37 -2.41 5.18 4.62 -0.02 -0.21 0.87 -0.06 -1.08 17 1.08 0.00 -6.52 2.36 0.25 1.53 -0.86 -0.18 -0.76 18 -11.13 -0.06 6.27 0.91 4.71 -4.24 -0.89 -2.70 -5.09 19 5.75 -3.75 2.71 0.11 21.43 20.57 -1.23 2.30 4.36 20 -22.44 -6.49 58.34 3.98 15.14 -16.57 2.01 -7.32 -13.14 21 -29.71 0.00 59.85 5.03 16.62 -51.40 2.85 -8.74 -14.99 22 18.81 0.00 -55.64 -0.33 -1.78 25.36 -2.33 8.38 11.75 23 19.15 0.00 -49.42 0.10 -3.10 19.94 -2.49 7.56 11.23 24 10.01 0.13 -29.26 -0.61 -3.21 10.94 -1.65 4.83 6.73 25 1.73 0.00 -7.62 1.94 -1.93 4.53 0.31 1.99 0.80 26 18.35 0.00 -44.68 -0.45 -2.11 30.42 -4.02 7.93 11.26 27 7.02 -1.60 -14.99 1.46 4.62 6.74 0.39 4.13 8.40 28 13.28 -16.66 21.24 10.79 35.30 0.39 6.05 31.72 6.74 29 -43.52 1.27 34.51 15.60 21.06 -50.45 -22.14 -34.05 5.46 30 13.16 -0.08 -12.34 -5.92 -1.76 10.33 -3.21 21.42 15.80

Sample No. The first band The second band Third band ΔR ΔG ΔB ΔR ΔG ΔB ΔR ΔG ΔB One 40.00 -39.21 -44.85 -40.94 -56.22 29.56 -31.01 -2.42 17.83 2 54.48 -16.22 17.70 -12.06 -25.31 57.94 -8.19 18.92 33.08 3 8.66 3.69 -2.58 4.74 8.70 7.94 -3.19 4.14 12.50 4 33.56 -0.12 -17.62 8.82 2.97 15.65 -8.17 16.28 32.17 5 -12.80 -2.33 12.63 2.00 13.18 11.28 0.75 -0.42 -3.96 6 41.83 -0.97 -40.27 -1.01 -7.87 3.77 -6.65 10.35 29.78 7 -4.64 -17.68 -4.77 -14.92 17.98 12.57 -20.74 -8.52 -4.39 8 82.30 0.69 -92.39 -27.36 -39.87 92.65 -10.63 26.02 45.17 9 -12.11 13.56 -47.50 40.19 2.67 11.09 20.34 -21.20 -1.60 10 52.61 -2.06 -27.94 -5.67 -17.11 40.67 -9.11 15.69 31.57 11 16.94 0.00 -34.29 -0.96 -1.71 24.84 -2.17 5.75 8.60 12 16.62 1.08 -29.93 -2.66 -10.58 18.88 -2.93 5.47 10.81 13 19.13 2.94 -38.99 -0.71 -10.91 12.48 -4.42 8.09 14.19 14 9.64 -0.36 -24.79 0.25 -5.47 19.26 -1.83 4.99 7.35 15 16.70 0.09 -34.36 -0.65 -8.24 21.98 -3.78 8.19 11.50 16 -4.05 -0.16 5.24 3.03 4.15 -0.05 0.25 -2.36 -4.49 17 14.78 0.00 -35.17 -2.33 -1.15 19.80 -2.99 4.01 5.88 18 11.74 -0.43 -13.49 -0.93 -12.03 12.43 -2.89 3.22 4.83 19 -5.20 -0.10 12.30 2.99 4.31 -2.06 2.41 -1.49 -6.87 20 13.00 0.00 -20.47 -0.94 -5.78 3.53 -0.19 2.30 6.50 21 9.67 0.96 -18.75 -1.14 -12.58 -1.63 -2.55 2.74 8.89 22 5.06 0.50 -34.58 -11.35 44.88 44.00 -4.01 -1.00 3.98 23 14.55 -3.05 -26.58 0.03 3.12 7.69 -1.54 5.30 5.12 24 9.42 -3.21 -21.21 -2.41 -9.78 8.07 -4.10 4.40 8.23 25 4.91 0.17 -12.64 -1.30 4.29 3.47 -3.61 2.73 6.36 26 7.27 -16.94 1.69 0.69 -1.47 3.14 -2.83 4.61 8.02 27 21.67 -0.11 -33.85 -5.84 -8.44 20.08 -1.19 14.55 14.00 28 11.23 -1.12 -15.49 -2.87 -2.32 15.36 8.02 20.00 -0.90 29 4.58 -0.24 -29.52 -3.02 -15.27 17.83 -3.55 18.30 21.72

The three-dimensional coordinate data of FIG. 7 are obtained by PCA analysis using the data shown in Tables 5 and 6 below.

Table 5 shows 23 domestic onions and Table 4 shows 22 Chinese onions.

Sample No. The first band The second band Third band ΔR ΔG ΔB ΔR ΔG ΔB ΔR ΔG ΔB One 19.69 67.61 -95.41 79.58 -11.53 -107.03 -8.48 25.70 45.32 2 -13.08 41.56 -16.94 36.99 5.39 -48.03 -3.99 5.87 21.03 3 -0.82 50.20 -45.30 42.71 1.94 -94.01 -7.20 8.85 24.31 4 -13.88 41.45 -17.12 33.18 4.55 -51.07 -4.86 6.51 19.22 5 -9.99 29.10 -11.29 32.47 10.51 -40.26 -4.24 4.85 17.42 6 -3.23 59.86 -47.61 57.78 6.17 -103.89 -7.11 14.20 30.93 7 -10.48 53.00 -53.39 42.31 0.03 -88.44 -6.66 11.22 28.87 8 -7.17 34.06 -25.41 29.88 4.61 -58.73 -5.23 6.95 15.01 9 -4.51 37.03 -27.12 30.53 -0.03 -60.15 -3.20 8.17 15.13 10 -6.03 50.61 -34.47 51.94 2.00 -91.92 -4.28 8.14 20.13 11 13.06 61.06 -74.89 57.75 -6.42 -108.88 -9.56 20.31 39.12 12 1.44 54.97 -49.69 52.04 -6.04 -77.46 -7.74 14.65 32.76 13 -1.27 54.52 -55.46 47.68 4.82 -78.93 -6.96 9.29 31.12 14 4.56 64.97 -71.76 60.83 3.39 -110.65 -9.01 13.72 30.17 15 -4.97 36.92 -29.91 31.06 -0.06 -85.50 -3.25 9.05 17.04 16 14.09 49.61 -71.72 54.36 -3.78 -94.23 -9.08 17.03 30.03 17 -9.30 42.24 -24.01 38.08 4.78 -74.99 -5.76 8.33 22.02 18 5.48 45.05 -52.51 38.55 -6.54 -67.70 -6.82 13.43 24.17 19 14.10 37.88 -63.88 37.46 -13.14 -53.27 -8.30 14.48 23.41 20 7.83 66.01 -73.93 65.32 -5.59 -97.04 -8.82 20.65 37.47 21 31.09 52.76 -97.75 58.13 -17.00 -79.76 -12.10 23.22 37.71 22 -7.06 58.25 -42.04 53.86 -0.16 -105.21 -9.30 15.34 30.96 23 6.83 50.02 -60.94 46.81 -3.96 -91.82 -8.00 17.13 27.23

Sample No. The first band The second band Third band ΔR ΔG ΔB ΔR ΔG ΔB ΔR ΔG ΔB One -9.08 16.99 31.48 -9.08 16.99 31.48 -9.08 16.99 31.48 2 -7.98 12.41 31.06 -7.98 12.41 31.06 -7.98 12.41 31.06 3 -3.43 8.83 18.47 -3.43 8.83 18.47 -3.43 8.83 18.47 4 -6.12 8.15 20.86 -6.12 8.15 20.86 -6.12 8.15 20.86 5 -6.09 9.80 17.43 -6.09 9.80 17.43 -6.09 9.80 17.43 6 -3.79 6.84 14.35 -3.79 6.84 14.35 -3.79 6.84 14.35 7 -4.51 9.95 23.51 -4.51 9.95 23.51 -4.51 9.95 23.51 8 -10.36 20.80 40.55 -10.36 20.80 40.55 -10.36 20.80 40.55 9 -9.58 11.41 28.33 -9.58 11.41 28.33 -9.58 11.41 28.33 10 -5.60 4.86 14.99 -5.60 4.86 14.99 -5.60 4.86 14.99 11 -4.90 8.31 18.97 -4.90 8.31 18.97 -4.90 8.31 18.97 12 -7.22 6.57 21.30 -7.22 6.57 21.30 -7.22 6.57 21.30 13 -8.18 14.87 33.47 -8.18 14.87 33.47 -8.18 14.87 33.47 14 -10.77 13.02 27.81 -10.77 13.02 27.81 -10.77 13.02 27.81 15 -6.46 4.03 15.36 -6.46 4.03 15.36 -6.46 4.03 15.36 16 -9.81 9.01 22.05 -9.81 9.01 22.05 -9.81 9.01 22.05 17 -5.18 9.60 21.49 -5.18 9.60 21.49 -5.18 9.60 21.49 18 -4.67 9.10 15.98 -4.67 9.10 15.98 -4.67 9.10 15.98 19 -3.74 6.62 11.60 -3.74 6.62 11.60 -3.74 6.62 11.60 20 -5.43 8.10 18.21 -5.43 8.10 18.21 -5.43 8.10 18.21 21 -7.83 14.01 29.53 -7.83 14.01 29.53 -7.83 14.01 29.53 22 -5.72 10.19 17.77 -5.72 10.19 17.77 -5.72 10.19 17.77

The three-dimensional coordinate data of FIG. 8 are obtained by PCA analysis using the data shown in Tables 7 and 8 below.

Table 7 shows 30 domestic sesame seeds and Table 8 shows 30 Chinese sesame seeds.

Sample No. The first band The second band Third band ΔR ΔG ΔB ΔR ΔG ΔB ΔR ΔG ΔB One -2.53 -5.29 2.69 5.11 0.75 -7.35 -3.09 1.54 0.06 2 -4.48 -5.33 -2.19 -2.73 -2.36 -3.40 -4.15 -2.66 -2.26 3 -6.26 -9.53 -4.57 -4.25 -3.91 -4.79 -5.01 -3.62 -2.67 4 -4.07 -4.95 -2.01 -2.51 -2.55 -4.22 -3.58 -1.50 -1.20 5 -3.73 -4.03 -1.93 -2.15 -1.99 -4.50 -3.36 -0.83 -0.68 6 -5.06 -6.88 -2.86 -2.66 -2.34 -2.87 -3.73 -1.83 -1.04 7 -3.42 -8.04 -3.45 3.04 1.95 -9.74 -9.23 -0.63 -0.29 8 -1.47 -24.07 -7.96 -6.89 -0.26 -8.90 -10.27 -9.50 -3.72 9 -3.13 -5.13 -0.15 0.25 -1.49 -5.56 -2.25 -0.65 -0.98 10 -3.56 -4.74 -1.58 -0.20 -2.27 -6.33 -1.84 1.23 0.11 11 -6.21 -7.77 -1.95 -3.56 -4.40 -4.70 -5.63 -1.59 0.09 12 -2.89 -3.91 -1.93 -1.19 -1.99 -2.83 -1.52 0.55 -0.17 13 -2.55 -4.27 -1.95 -1.79 -2.00 -2.90 -1.35 0.53 -0.55 14 -2.53 -2.86 -3.07 -0.93 -2.07 -3.95 -1.74 0.57 -0.46 15 -2.54 -3.23 -3.10 -0.17 -1.81 -4.52 -1.66 0.74 -0.52 16 -2.05 -4.80 -0.21 -0.17 -1.70 -4.11 -0.82 2.48 0.58 17 -3.09 -4.97 0.24 -0.24 -1.77 -4.62 -1.68 0.03 -0.38 18 -6.00 -8.75 -0.89 -2.29 -3.66 -7.51 -1.37 2.65 -0.07 19 -3.51 -6.43 0.43 0.71 -2.77 -7.44 -1.31 2.52 1.68 20 -9.90 -11.88 -4.98 -4.86 -6.20 -11.40 -7.23 -3.42 -4.79 21 -3.31 -5.19 -2.01 -3.54 -3.12 -3.31 -2.03 1.17 -0.20 22 -9.25 -12.64 2.62 -1.19 -7.38 -16.60 -2.47 3.30 -0.97 23 -10.14 -12.95 1.93 -2.81 -6.72 -15.00 -4.41 1.26 -0.86 24 -3.56 -6.09 3.47 1.67 -3.14 -10.26 0.32 4.64 2.31 25 -2.78 -3.58 -1.93 2.86 -1.20 -7.31 -1.16 2.02 1.13 26 -3.83 -5.52 -1.10 -0.91 -2.46 -4.55 -1.26 2.09 1.14 27 -3.21 -5.47 -1.03 -0.11 -2.30 -5.35 -0.43 2.11 -0.28 28 -1.32 -2.61 0.28 0.19 -0.94 -2.75 0.98 3.31 1.83 29 -2.23 -3.81 -2.43 0.82 -1.49 -7.07 -1.37 2.79 0.30 30 -1.01 -2.91 0.98 3.14 -0.83 -8.23 -0.30 4.50 1.90

Sample No. The first band The second band Third band ΔR ΔG ΔB ΔR ΔG ΔB ΔR ΔG ΔB One 0.98 -4.64 8.93 11.34 3.36 -9.63 0.58 0.33 0.60 2 -3.87 -4.16 -2.07 -2.46 -1.95 -2.66 -3.00 -2.19 -2.67 3 -3.91 -4.15 -2.57 -1.89 -2.24 -3.59 -3.45 -1.72 -2.13 4 2.36 -14.19 -8.48 -6.59 -3.15 -0.76 -5.81 -3.76 -0.65 5 -3.61 -8.42 -2.45 -1.30 0.98 -3.44 -3.28 -2.15 -1.77 6 -5.95 -9.99 -4.30 -5.18 -1.47 -5.20 -6.08 -4.06 -4.14 7 0.29 -5.10 -1.63 2.47 0.98 -4.79 -2.97 0.62 1.15 8 -3.15 -3.94 -2.59 -1.84 -2.38 -4.61 -2.43 0.69 -0.79 9 -2.72 -3.97 -0.27 -0.65 -1.86 -4.27 -2.14 0.17 -0.55 10 -5.66 -7.16 -0.30 -1.52 -3.30 -6.20 -4.15 -0.89 -0.79 11 0.50 -3.75 3.03 2.27 3.14 2.86 1.70 7.33 10.09 12 -2.81 -3.56 -1.30 -1.03 -2.40 -4.60 -2.63 -0.53 -0.27 13 -3.40 -3.58 -2.52 -0.25 -2.18 -6.44 -2.24 0.45 -0.24 14 -3.50 -4.44 -0.85 -1.49 -1.85 -3.36 -2.12 -1.20 -1.48 15 -1.74 -3.02 -1.44 1.57 -1.76 -6.96 -1.16 1.65 0.27 16 -0.93 -2.44 -1.32 0.07 -1.88 -5.59 -2.19 -0.69 -0.93 17 -4.04 -8.11 -0.34 1.11 -3.05 -9.59 -2.43 2.03 -1.30 18 -2.70 -6.13 -0.32 1.41 -4.22 -10.19 -1.00 1.97 0.27 19 -6.90 -8.56 -2.22 -2.90 -5.43 -8.34 -5.19 -1.33 -1.11 20 -2.87 -4.77 -0.35 1.10 -1.60 -6.80 -0.25 2.86 0.40 21 -3.54 -5.58 -1.80 -0.56 -2.55 -6.55 -1.90 0.63 -0.39 22 -5.87 -10.10 4.18 0.89 -5.06 -14.00 -0.59 4.30 1.21 23 -5.75 -7.95 -1.47 1.83 -5.37 -16.23 -0.71 4.34 -0.42 24 -2.74 -4.79 0.18 0.54 -1.65 -6.05 0.08 3.17 1.62 25 -2.07 -2.17 -3.91 -0.66 -1.85 -5.70 -1.58 2.13 1.12 26 -2.89 -2.05 -1.98 1.28 -1.73 -6.28 -1.44 1.60 0.83 27 -1.69 -3.22 -3.04 -0.71 -1.81 -3.49 -0.19 1.98 -0.14 28 -2.18 -3.31 -1.67 -0.22 -1.72 -4.16 -0.09 2.18 0.85 29 -1.59 -2.35 -2.17 -0.28 -1.68 -6.17 0.51 2.66 0.61 30 -1.53 -2.86 -0.20 -0.16 -2.22 -6.41 -0.31 2.17 0.67

The three-dimensional coordinate data of FIG. 9 is obtained by PCA analysis using the data of Tables 9 and 10 below.

Table 9 is for 30 species of domestic perilla and Table 10 is for 30 kinds of domestic perilla species.

Sample No. The first band The second band Third band ΔR ΔG ΔB ΔR ΔG ΔB ΔR ΔG ΔB One -8.44 -17.18 12.86 0.68 -1.45 -4.18 5.62 12.49 8.69 2 -9.83 -16.82 5.08 0.06 -3.02 -9.87 1.64 6.18 0.49 3 -7.41 -13.70 1.25 -5.20 -2.76 -2.76 2.55 5.32 0.50 4 0.94 -5.67 6.83 6.49 7.56 3.43 7.97 10.30 11.51 5 -4.37 -8.61 -1.35 -1.88 -2.23 -4.32 -1.99 -0.16 -1.32 6 -7.99 -10.20 1.12 -1.72 -1.15 -2.94 -2.12 -0.75 -0.21 7 -5.15 -8.27 -3.43 -4.40 -2.26 -0.29 -3.33 1.33 -0.73 8 -2.33 -6.14 5.30 5.76 0.65 -8.51 -0.89 2.59 2.85 9 -2.27 -4.74 -2.87 0.38 -1.37 -6.07 -3.21 0.87 0.67 10 -3.30 -4.16 -2.68 -2.29 -2.76 -7.20 -3.28 0.29 1.10 11 -3.96 -8.06 -4.91 0.54 0.45 -5.87 -2.66 1.08 0.23 12 -1.31 -3.18 -6.49 3.86 -0.54 -6.92 -2.90 -1.15 0.54 13 5.09 -2.28 16.30 15.12 6.66 -10.11 12.60 19.83 17.49 14 7.34 -3.90 15.41 17.02 9.86 -7.68 13.23 25.85 23.04 15 2.50 -4.81 8.58 12.41 4.23 -10.03 6.21 11.92 10.46 16 4.90 -3.87 12.81 14.65 6.82 -8.77 10.33 17.67 17.28 17 4.75 -3.35 4.90 12.87 6.44 -10.01 4.71 12.13 14.23 18 7.10 2.30 10.09 9.04 3.52 -8.96 12.99 19.88 13.04 19 9.35 -0.36 14.28 18.30 11.25 -4.58 14.85 24.46 21.10 20 -5.02 -10.91 4.22 -1.01 -3.95 -10.80 0.28 4.83 0.07 21 -2.26 -8.10 6.43 8.08 2.45 -9.81 1.01 6.96 5.09 22 -2.28 -6.91 -0.07 5.50 -3.32 -16.46 0.03 7.77 2.08 23 -3.22 -6.64 -3.36 2.44 -7.41 -19.08 -1.61 1.23 -5.97 24 0.05 -7.89 5.92 3.92 0.60 -6.99 2.18 5.79 2.67 25 -1.38 -2.80 -2.74 2.31 -1.21 -7.87 -2.11 2.19 0.02 26 0.23 -1.73 -7.10 6.45 1.37 -10.62 -3.61 2.21 -0.59 27 -3.41 -2.85 -4.77 2.10 -1.86 -10.48 -0.99 0.07 -1.10 28 -3.67 -3.10 -5.98 1.08 -2.78 -9.87 -4.90 -0.54 -1.41 29 -1.29 0.50 -6.83 1.72 -1.95 -6.15 -4.35 -2.21 -0.24 30 1.78 2.78 -5.19 3.11 0.59 -4.87 0.36 2.15 0.36

Sample No. The first band The second band Third band ΔR ΔG ΔB ΔR ΔG ΔB ΔR ΔG ΔB One -10.75 -14.09 -2.08 -6.28 -8.63 -10.31 -3.06 0.25 -6.45 2 -3.81 -8.78 1.13 -2.01 -2.09 -4.97 1.15 6.69 4.26 3 -2.49 -7.18 5.22 -0.80 0.87 -0.78 3.80 8.57 4.03 4 -2.65 -5.49 2.74 -3.47 -0.96 -1.64 -0.87 5.09 1.01 5 -5.45 -10.02 2.78 -1.08 -1.79 -3.17 -0.86 2.21 3.23 6 -3.84 -8.08 2.65 -1.55 -0.70 -1.87 -1.66 2.34 2.31 7 -0.37 -2.30 -0.93 -1.24 -1.48 -0.52 -2.08 1.75 2.77 8 -4.08 -5.16 -10.22 -10.48 -8.85 -7.92 -4.08 -4.20 7.08 9 2.57 0.90 -8.30 8.24 3.65 -7.16 0.50 3.72 4.58 10 -2.68 -4.06 -5.86 7.81 1.00 -10.71 -1.64 2.56 2.55 11 -2.84 -4.45 -4.91 0.24 -1.07 -5.56 -4.32 0.14 0.17 12 -2.97 -5.65 0.43 -0.38 0.29 -2.83 -1.61 2.62 3.30 13 -0.38 -8.28 8.27 6.58 2.14 -6.04 5.86 10.88 8.27 14 -9.25 -12.35 -0.92 -4.19 -9.94 -14.45 -4.13 0.04 -5.71 15 2.76 -3.25 6.29 9.92 2.92 -8.93 4.96 10.49 10.33 16 5.54 -1.05 7.21 13.40 5.20 -10.81 6.49 13.49 15.30 17 0.55 -5.91 1.45 8.72 2.56 -11.33 1.54 8.05 6.02 18 2.89 -0.65 6.00 8.23 1.30 -10.48 4.46 9.25 4.36 19 13.24 4.37 18.32 15.91 9.71 -6.44 17.17 26.30 19.45 20 -1.65 -7.29 5.60 5.85 -3.23 -11.64 1.71 4.10 1.67 21 4.00 -1.69 4.88 10.89 4.59 -6.89 4.06 8.82 9.06 22 5.75 -5.22 7.27 9.86 6.11 -5.81 5.91 13.16 12.23 23 11.49 0.49 15.42 20.50 10.30 -11.95 17.41 25.53 16.90 24 3.34 -1.16 3.32 7.14 2.22 -11.02 2.73 6.33 2.03 25 -3.16 -5.99 -1.59 1.20 -1.35 -5.80 -1.53 1.59 -0.20 26 -2.79 -3.03 -2.70 6.76 1.59 -7.35 -3.05 1.10 0.71 27 -2.45 -1.11 -10.24 -2.38 -1.71 -8.01 -5.36 -3.47 -2.46 28 -1.94 -2.16 -5.25 -2.61 -2.10 -2.70 -5.14 -2.07 -1.65 29 1.36 0.98 -1.84 -0.86 0.32 -0.19 -0.54 2.11 0.74 30 -5.32 -8.68 -0.84 -0.04 -6.23 -13.77 -1.76 3.17 -1.99

As described above, the determination unit 500 includes all the information on a plurality of crops, and can retrieve and analyze the information according to the type of the crop placed in the sample unit 100, The discriminating device 700 can be used for discriminating the origin of various kinds of crops. Alternatively, the determination unit 500 may include only information on one type of crop, and the crop identification system 700 may be limited to a specific crop analysis apparatus.

Referring to FIG. 1 again, the above-described sample color change value is stored in the determination unit 500, and the color change sensor (not shown) of the sensing unit 200 is detected by the vapor generated from the agricultural crops disposed in the sample unit 100 210 are changed in color, the image obtaining unit 300 takes an image, and the obtained image is transmitted to the determining unit 500.

The color change value for analysis between the change colors of the image based on the unique color of the color fading sensor 210 is changed by the image transferred to the determination unit 500 in the change color of the color change sensor 210 by the agricultural crop for analysis Can be obtained. The color change value for analysis between the change color of the color change sensor 210 and the unique color of the color change sensor 210 changed by exposure to the component included in the analysis crop is substantially the same as the sample color change value stored in the determination unit 500 . ≪ / RTI >

Wherein the color change value for analysis by the agricultural crop for analysis comprises the color space element value of the color code data and the color code data is determined according to the color model wherein the color space element value corresponds to the color space element of the color model Value, and the analytical color change value is determined based on the same color model as the color model used to determine the sample color change value. The color change value for analysis is the color space element value for analysis corresponding to the color space element which is the same as the sample color space element selected to have a high degree of origin classification. That is, when a sample color change value is a multivariate analysis, for example, through principal component analysis, when a specific sample color space element has a large degree of origin classification, the specific sample color space element is a main component for the classification of origin. Values corresponding to the principal component are selected from among the element values to be the color change value for analysis according to the present invention.

The source of the agricultural crop for analysis is determined by comparing the analytical color change value with the sample color change value for the specified agricultural crop as described above. The similarity between the color change value for analysis and the sample color change value is used as a criterion for the origin of the sample. By using the fact that the sample color change value is classified according to the country of origin, the analysis color change value is similar to the sample color change value indicating the specific country of origin It can be determined that the agricultural crop for analysis belongs to the country of origin.

In one embodiment, when the sample color change value includes the sample color space element value, the color change value for analysis also includes the color space element value for analysis, so that the similarity between the sample color space element value and the color space element value for analysis To determine the origin of the crop for analysis.

In one embodiment, the sample color change value includes a sample color space element value, and three-dimensional coordinate data (also referred to as a " color space element value ") is selected based on three principal components derived as a principal component using a principal component analysis 5 to FIG. 9), a color change value for analysis is determined using the color space element value for analysis corresponding to the three principal components derived for the sample color space element value, and the color change value for analysis And may be three-dimensional coordinate data. At this time, the three-dimensional coordinate data derived from the analytical color change value is compared with the three-dimensional coordinate data corresponding to the sample color change value, and it is judged whether it is close to the Korean agricultural product group or the Chinese agricultural product group. It can be judged as a country of origin corresponding to a group close to the data.

In the above description, the color model has been described using the RGB system as an example. However, even if another color model is used, the origin of the crop can be determined as the same result. The apparatus for discriminating origin of crops is advantageous in that it is small in size and portable, and can determine the origin of agricultural crops in real time based on the data stored in the judging unit 500 in the field.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the present invention as defined by the following claims. It can be understood that it is possible.

700: Country of Origin Determination of Crops
100: sample part 200: sensing part
210: Discoloration sensor VNP: M13 bacteriophage
RCT: Receptor 300: Image acquisition unit
500:

Claims (14)

Preparing a sample color change value between a changed color and a unique color of the color change sensor by exposing a virus-based color change sensor having a nanofiber bundle formed by the M13 bacteriophages to a component included in a sample crop of each country of origin;
Obtaining a color change value for analysis between the change color and the unique color for the color change sensor of the agricultural crop for analysis; And
And determining a country of origin of the agricultural crop for analysis according to the similarity of the color change value for analysis to the sample color change value.
A method for determining the origin of crops by a virus - based color fading sensor.
The method according to claim 1,
Wherein, in each of the sample color change value and the analysis color change value, the color change value includes a color space element value of the color code data,
Wherein the color code data is determined according to a color model of any one of an RGB method, a CMYK method, a CMY method, and an HSV method, the color space element value is a value corresponding to a color space element of the color model,
Wherein the similarity is a difference between a sample color space element value and a color space element value for analysis.
A method for determining the origin of crops by a virus - based color fading sensor.
3. The method of claim 2,
Wherein the sample color change value is a sample color space element value selected from a plurality of sample color space element values having a high degree of origin classification according to multivariate analysis,
Wherein the color change value for analysis is an analysis color space element value corresponding to a color space element equal to a sample color space element selected to have a high degree of origin classification.
A method for determining the origin of crops by a virus - based color fading sensor.
The method of claim 3,
Wherein the multivariate analysis is by principal component analysis (PCA)
A method for determining the origin of crops by a virus - based color fading sensor.
The method according to claim 1,
Wherein the color change sensor includes at least two regions that represent different colors,
The color change value in each of the sample color change value and the analysis color change value is
And color change values appearing in each region of the color change sensor.
A method for determining the origin of crops by a virus - based color fading sensor.
6. The method of claim 5,
Wherein each color change value appearing in each region of the color change sensor includes a color space element value of color code data,
Wherein the color code data is determined according to a color model of any one of an RGB method, a CMYK method, a CMY method, and an HSV method, the color space element value is a value corresponding to a color space element of the color model,
Wherein the similarity is a difference between a sample color space element value and a color space element value for analysis.
A method for determining the origin of crops by a virus - based color fading sensor.
The method according to claim 6,
Wherein the sample color change value is a sample color space element value selected to have a high degree of origin classification according to multivariate analysis among sample color space element values for each region of the color shift sensor,
Wherein the color change value for analysis is an analysis color space element value corresponding to a color space element that is the same as the sample color space element selected to have a high degree of origin classification among the color space element values for analysis of each color of the color sensor. ,
A method for determining the origin of crops by a virus - based color fading sensor.
The method according to claim 1,
Wherein the M13 bacteriophage has a protein comprising an amino acid sequence WHWQ on its surface.
A method for determining the origin of crops by a virus - based color fading sensor.
The method according to claim 1,
The step of obtaining the color change value for analysis
Heating the crop for analysis to expose the discoloration sensor to the vapor emitted by the crop for analysis;
Obtaining an image of the discoloration sensor changed by an agricultural crop for analysis; And
And deriving an analysis color change value between the change color for the change sensor and the unique color of the color change sensor using the image,
A method for determining the origin of crops by a virus - based color fading sensor.
The method according to claim 1,
The crops are red pepper, onion, perilla or sesame seeds,
A method for determining the origin of crops by a virus - based color fading sensor.
A sensing unit having a virus-based discoloration sensor in which nanofiber bundles formed by M13 bacteriophages are arranged on a base substrate;
A sample part connected to the sensing part and provided with agricultural crops for analysis;
An image obtaining unit connected to the sensing unit to obtain an image of a color fading sensor exposed to components included in the analysis crop; And
A sample color change value between the changed color and the unique color of the color change sensor is exposed to a component included in the sample crop by country of origin in the same sensor as the color change sensor and the same method as the method of obtaining the sample color change value, And a determination unit for determining the country of origin of the agricultural crop for analysis according to the degree of similarity of the color change value for analysis with respect to the sample color change value.
An apparatus for discriminating the origin of a crop by a virus - based discoloration sensor.
12. The method of claim 11,
Characterized in that the sample portion includes a heating portion for heating the agricultural crop for analysis.
An apparatus for discriminating the origin of a crop by a virus - based discoloration sensor.
12. The method of claim 11,
Wherein, in each of the sample color change value and the analysis color change value, the color change value includes a color space element value of the color code data,
Wherein the color code data is determined according to a color model of any one of an RGB method, a CMYK method, a CMY method, and an HSV method, the color space element value is a value corresponding to a color space element of the color model,
Wherein the sample color change value is a sample color space element value selected from a plurality of sample color space element values having a high degree of origin classification according to multivariate analysis,
Wherein the color change value for analysis is a color space element value for analysis corresponding to a color space element that is the same as the sample color space element selected to have a high degree of origin classification,
Wherein the similarity is a difference between a sample color space element value and a color space element value for analysis.
An apparatus for discriminating the origin of a crop by a virus - based discoloration sensor.
12. The method of claim 11,
Wherein the color fading sensor includes regions divided into at least two regions, the fiber bands disposed in each of the regions have different thicknesses of the nanofiber bundles,
Wherein the color change value in each of the sample color change value and the analysis color change value includes color change values appearing in each region of the color change sensor, Element value,
Wherein the color code data is determined according to a color model of any one of an RGB method, a CMYK method, a CMY method, and an HSV method, the color space element value is a value corresponding to a color space element of the color model,
Wherein the sample color change value is a sample color space element value selected to have a high degree of origin classification according to multivariate analysis among sample color space element values for each region of the color shift sensor,
Wherein the color change value for analysis is a color space element value for analysis corresponding to a color space element that is the same as the sample color space element selected to have a high degree of origin classification among the color space element values for analysis for each region of the color shift sensor,
Wherein the similarity is a difference between a sample color space element value and a color space element value for analysis.
An apparatus for discriminating the origin of a crop by a virus - based discoloration sensor.

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