JP2022083761A - Information processing system - Google Patents

Abstract

To provide an information processing system capable of preventing information of a manager side from being disclosed to a consumer and simply showing information desired by the consumer.SOLUTION: An article information processing system using a code including a first area that changes according to a change in an external environment and a second area including an information area with article identification information recorded includes: a first input device 710 for transmitting change information of the first area and the article identification information and the like of the second area to an information processing device 100; and a second input device 720 for reading the article identification information of the second area, and transmitting the read information and the like to the information processing device 100. The respective input devices are located on a distribution route for an article provided with the code. The information processing device 100 transmits management information from the first area and the second area to a first output device 810 in receiving the information from the first input device 710, and transmits only a portion of the information to be outputted to the first output device 810 to a second output device 820 in receiving the information from the second input device 720.SELECTED DRAWING: Figure 10

Description

The present invention relates to an information processing system.

Indicators that infer the environment to which the code is exposed and management systems that utilize those indicators are known. Patent Document 1 describes "an input device that acquires image data of an indicator using a temperature indicating material, a storage device (database) that stores the relationship between the color density and temperature of each temperature indicating material, and the color of the temperature indicating material from the image data. The color density estimation unit that estimates the density, the material identification unit that specifies the temperature indicator material used for the indicator, and the color density of the temperature indicator material specified by the material identification unit from the relationship between the color density and temperature of each temperature indicator material. And the temperature relationship is selected, and the temperature estimation unit that estimates the maximum or minimum ultimate temperature from the color density and density relationship of the specified temperature indicating material and the color density estimated by the color density estimation unit. A processing device is provided, and a temperature evaluation system is described.

Japanese Unexamined Patent Publication No. 2018-202222

The technique described in Patent Document 1 collects the color tone information of the temperature indicating material attached to the article, acquires the color tone information, and places the article with a temperature evaluation device for estimating the maximum or minimum reached temperature of the article. It has a management device (for example, a management server) that manages the environment and a management terminal (input device) located at each site, and centrally manages the temperature indicator data acquired at each location in the distribution stage. .. As a result, the manager can acquire the maximum temperature reached or the minimum temperature reached in the distribution process of the article to be managed, and the worker at each base connects to the management server from the management terminal (input device). , Temperature control information until delivery of goods can be confirmed.

However, when the worker includes a consumer, the consumer does not need to confirm the temperature control information until the delivery of the article, and only the information on whether or not the article is properly controlled may be sufficient. Mostly. Furthermore, for consumers, it is only necessary to have a part of the traceability information of the production area information or a part of the information centrally managed by the manager such as the effective expiration date based on the temperature control information. Most. In addition, it is not necessary for the administrator to provide all the management information to the consumer. Most consumers only need management information about the products they purchase.

The present invention is an invention for solving the above-mentioned problems, and provides an information processing system capable of not disclosing the information on the manager side to the consumer and simply showing the information desired by the consumer. The purpose is to do.

In order to achieve the above object, the information processing system of the present invention has a code including a first region that changes in response to a change in the external environment and a second region that includes an information region that records article identification information that identifies an article. It is an information processing system for articles using the above, and reads the information processing device that manages the articles, the change information in the first area, and the article identification information in the second area, and the read information and the read position information thereof. The first input device that transmits the reading time to the information processing device, the article identification information in the second area is read, and the read information, the reading position information, and the reading time are sent to the information processing device. The first input device and the second input device include a second input device for transmitting, the first input device and the second input device are in the distribution channel of the article provided with the code, and the information processing device receives information from the first input device and receives information from the first input device. And, when the management information derived from the second area is transmitted to the first output device and the information is received from the second input device, only a part of the information to be output to the first output device is transmitted to the second output device. And. Other aspects of the invention will be described in embodiments described below.

According to the present invention, it is possible to provide an information processing system capable of not disclosing the information on the manager side to the consumer and simply showing the information desired by the consumer.

It is a schematic diagram before discoloration of the 1st code which concerns on this embodiment. It is a schematic diagram after discoloration of the 1st code which concerns on this embodiment. It is a figure explaining the discoloration of the discoloration cell of the 2nd code which concerns on this embodiment. It is a code before being exposed to the physical quantity change of the 2nd code which concerns on this embodiment. It is a code after being exposed to the physical quantity change of the 2nd code which concerns on this embodiment. It is a conceptual diagram explaining discoloration. It is a figure explaining process color. It is a figure explaining the outline of the information processing system which concerns on this embodiment. It is a block diagram of an information processing system including an information processing apparatus. It is a schematic diagram of the first relation held in the database. It is a schematic diagram of the second relation held in the database. It is a block diagram of the information processing system which concerns on this embodiment.

Hereinafter, the present invention will be described, but the present invention is not limited to the following contents, and can be arbitrarily modified and carried out within a range that does not significantly impair the effects of the present invention. The present invention can be implemented by combining different embodiments. In the following description, the same members will be designated by the same reference numerals in different embodiments, and duplicate description will be omitted.

First, a code applied to the information processing system according to the embodiment of the present invention will be described. Although a plurality of codes applied to this information processing system can be considered, in the following, as an example, first, the codes shown in FIGS. 1A and 1B (first code) will be described, and then FIGS. 2, 3A and 3A and FIGS. Another code (second code) shown in 3B will be described.

FIG. 1A is a schematic view of the first code 200 according to the present embodiment before discoloration. The QR code (registered trademark) displayed by the first code 200 is version 1 (21 × 21 cells), but it can be changed according to the content of the information to be input. The first region 130, which changes in response to changes in the external environment, is a color that can be visually regarded as not discolored in the initial stage of the distribution process of the product to which the code is attached, and is, for example, white or light gray. The first region 130 may be in one place or in a plurality of places. Reference colors are colored in the reference areas 140a to 140d. This reference color is used for color correction of the first region 130 depending on the shooting environment.

In this embodiment, an RGB (Red, Green, Blue) model is adopted as a color model for explanation. In the RGB model, the color of one pixel that makes up an image is a combination of numerical values between the darkest 0 and the brightest 255 for each of the three colors R (red), G (green), and B (blue). Be expressed. Hereinafter, the RGB components are indicated by enclosing them in square brackets such as [R, G, B], and for example, red [255,0,0], darkest black [0,0,0], and brightest white [255]. , 255, 255]. Each cell of the QR code is composed of a plurality of pixels.

Each reference color in the reference areas 140a to 140d is a fixed color (which does not change unlike the sensor color) colored with ordinary color ink or the like. Hereinafter, the following four reference colors will be illustrated, but the possible combinations of the reference colors are not limited to these four.
The reference area 140a is painted in red [255,0,0].
The reference area 140b is painted in green [0,255,0].
The reference area 140c is painted blue [0,0,255].
The reference area 140d is painted in gray [200,200,200].

Further, at least one of the entire background area 150 may be filled with white or black, which is a color different from the reference color. As a result, when the first code 200 is photographed, an image (color) in which completely white [255, 255, 255] appears in overexposure or completely black [0,0,0] appears in black out. It is possible to suppress the shooting of a saturated image). It is desirable that all four reference colors are darker than white when filled and brighter than black when filled. As a result, even if overexposure or underexposure occurs at the filled portion, the overexposure or underexposure does not occur in the reference colors of the reference areas 140a to 140d and the colors of the first area 130.

By making the shape of the reference regions 140a to 140d different from the circular shape of the first region 130, it is possible to immediately identify which region is the reference regions 140a to 140d with the naked eye. The shape of each region is not limited to the above-mentioned circular shape, and may be any shape.

The area of each of the first region 130 and the reference regions 140a to 140d may be represented by a plurality of pixels when imaged, and may have an area sufficient for calculating the average value of colors.

The second area 110 including the information area in which information is recorded can use a two-dimensional code such as a QR code, and if the code can input information in advance, the type and shape can be one-dimensional, monochrome, or color. Not limited.

By writing the ID number associated with the second area 110 in an arbitrary place of the first code 200, the serial ID 120 can visually manage the first code 200.

FIG. 1B is a schematic view of the first code 200 according to the present embodiment after discoloration. It is the same as FIG. 1 except for the first region 130 which changes according to the change of the external environment. In the first region 130, a color sensor such as a temperature detection ink whose color changes depending on the temperature is arranged. That is, the color of the first region 130 changes to reflect the surrounding environment. For example, the first region 130 includes environmental conditions such as temperature, temperature history, humidity, light, gas concentration, vibration, pH of liquid, various ion concentrations in liquid, various drug concentrations, various amino acid / protein concentrations, and viruses. The result of detecting the presence of bacteria is reflected as color information.

Next, the second code 30 which is a code different from the first code 200 will be described.
FIG. 2 is a schematic diagram of the second code 30. The second code 30 is formed based on a predetermined standard (described later), but is shown in FIG. 2 not based on the predetermined standard for simplification of illustration. The second code 30 is colored, specifically, for example, blue, and is displayed, for example, on a product (not shown) having a white background, for example. In the illustrated example, a dot pattern is used to express blue color. For example, a low density dot pattern indicates the lightest blue, a medium density dot pattern indicates a medium dark blue, and a high density dot pattern indicates the darkest blue. The white inside the part surrounded by the broken line is the background color. The second code 30 can be displayed by printing with monochrome, for example, blue ink.

The second code 30 is a mechanically readable code. Mechanically readable means, for example, one that can be imaged by an image pickup device such as an optical camera, a digital camera, or an optical reader. The second code 30 includes, for example, a one-dimensional bar code and a two-dimensional bar code such as a QR code.

The second code 30 is created by a predetermined standard that at least defines a second area 10 in which information is recorded and an unused area 11 that is not used for reading information. As a result, the first area 130, which is a discolored cell, can be arranged in the unused area 11 without affecting the recorded information. In the case of a one-dimensional bar code, the predetermined standard is, for example, ISO / IEC 15420: 2000, and in the case of a two-dimensional bar code (for example, QR code), the predetermined standard is, for example, ISO / IEC 18004.

The second code 30 is composed of a plurality of first unit cells 20a, and is composed of a second region 10 in which information is recorded and a plurality of second unit cells 21a including a first region 130 that changes color according to a physical quantity. It is configured to include an unused area 11. That is, the second code 30 is configured to include the first region 130 as in the first code 200. The first area 130 in the second code 30 is included in the above-mentioned unused area 11. Of these, the second region 10 includes the upper second region 10 and the lower error correction region 12 of the second code 30 in the illustrated example, and is unused in the center of the second code 30. It is a part other than the area 11. Although the unused area 11 is located in the center of the second code 30 in FIG. 2, the unused area 11 does not necessarily have to be arranged in the center and is not required for information recording in a predetermined standard. The used area 11 can be arranged.

The first unit cell 20a and the second unit cell 21a are both substantially square, that is, one first unit cell 20a and one second unit cell 21a form a substantially square by one or a plurality of print dots. ing. A plurality of first unit cells 20a and second unit cells 21a are arranged vertically and horizontally in the second code 30. In the illustrated example, 11 first unit cells 20a are arranged in the vertical direction and 11 in the horizontal direction. Three second unit cells 21a are arranged in the vertical direction and three in the horizontal direction.

As described above, in addition to the second region 10, an error correction region 12 for restoring the information of the second region 10 when the second code 30 is contaminated may be included. Further, the first region 130 is included in the unused region 11. By including the first region 130 in the unused region 11, even if the first region 130 is discolored, the information in the second region 10 can be prevented from being affected.

The information recorded in the second area 10 includes, for example, a URL, a serial number peculiar to each second code 30, and the like. Further, the second code 30 is exposed to various physical quantities, and the physical quantities include, for example, temperature, humidity, light, gas concentration, vibration and the like.

FIG. 3A is a second code 30 before being exposed to a change in physical quantity. Further, FIG. 3B is a second code 30 after being exposed to a change in physical quantity. 3A and 3B are QR codes of version 5 (37 × 37 cells) as an example, but can be changed according to the content of the information to be input. For example, in a factory or the like, a second code 30 shown in FIG. 3A is displayed on a product (not shown). In the example of FIG. 3A, the first region 130 is white, which is the same as the background color. The second code 30 is exposed to various physical quantities until the product displaying the second code 30 is delivered to the consumer. Therefore, the ink forming the first region 130 changes color according to the physical quantity, and in the illustrated example, the color is developed. As a result, as shown in FIG. 3B, the first region 130 becomes visible, and changes in physical quantities can be grasped.

According to the second code 30, although the ink in the first region 130 is discolored and developed according to the physical quantity, the discoloration is inconspicuous, so that it is difficult to give the user a sense of discomfort at the time of visual recognition. Further, since the first region 130 changes color according to the physical quantity change to which the second code 30 is exposed, the physical quantity to which the second code 30 is exposed can be grasped based on the color of the first region 130.

The first region 130 (first region 130 in the first code 200) of FIG. 1 and the first region 130 (first region 130 in the second code 30) of FIG. 2 are formed of a material that changes color according to a physical quantity. .. The first code 200 and the second code 30 are used separately, such that when the first code 200 is used, the second code 30 is not used, but both first regions 130 are used, for example. The larger the physical quantity, the darker it becomes, and the smaller the physical quantity, the thinner it becomes. In the present embodiment, in order to grasp the physical quantity that affects the quality of the product, the first region 130 in FIG. 1 and the first region 130 in FIG. 2 correspond to the integrated physical quantity which is the product of the physical quantity and the elapsed time. Discolors. The discoloration of the first region 130 of FIG. 1 and the first region 130 of FIG. 2 will be described with reference to FIG.

FIG. 4 is a conceptual diagram illustrating the discoloration of the first region 130. Discoloration starts when the physical quantity exceeds the set physical quantity, and stops when the physical quantity falls below the set physical quantity (however, the discoloration is irreversible and irreversible). The amount deviating from the set physical quantity is defined as the "deviation physical quantity", and the time during which the deviation physical quantity occurs is defined as the "deviation time". The larger the deviant physical quantity or the longer the deviant time, the larger the amount of discoloration in the first region 130. Therefore, the larger the area (= deviation time × deviation temperature) of the rectangle showing the integrated physical quantity shown by the diagonal line in FIG. 4, the larger the amount of discoloration in the first region 130. By using such an integrated physical quantity as a physical quantity, it is possible to grasp the physical quantity that affects the quality of the product.

As the ink that changes color based on the magnitude of the temperature, for example, an inorganic thermochromic material made of a metal complex salt or an organic material such as a leuco dye or a thermochromic liquid crystal can be used. Among these, it is preferable to use an ink containing a leuco dye, a developer and a decoloring agent, which changes color according to the product of temperature and elapsed time.

As the leuco dye, an electron-donating compound that develops a color by reacting with an electron-accepting color developer can be used. For example, triphenylmethanephthalide, fluorane, phenothiazine, indrillphthalide, leukooramine, spiropyran, rhodamine lactam, triphenylmethane, triazene, spirophthalanxanthene, naphtholactam, Azomethine-based or the like can be used.

As the color developer, an electron-accepting compound that reacts with an electron-donating leuco dye to change the molecular structure of the leuco dye can be used. Specific examples of the color developer include benzyl 4-hydroxybenzoate, 2,2'-biphenol, 1,1-bis (3-cyclohexyl-4-hydroxyphenyl) cyclohexane, and 2,2-bis (3-cyclohexyl-). 4-Hydroxyphenyl) Propane, bisphenol A, bisphenol B, bisphenol C, bisphenol E, bisphenol F, bisphenol G, bis (4-hydroxyphenyl) sulfide, 1,1-bis (4-hydroxyphenyl) cyclohexane, 1,1 -Bis (4-hydroxy-3-methylphenyl) cyclohexane, α, α, α'-tris (4-hydroxyphenyl) -1-ether-4-isopropylbenzene, etc., paraoxybenzoic acid ester, gallic acid ester, etc. Phenols, metal salts of carboxylic acid derivatives, salicylic acid and salicylic acid metal salts, sulfonic acids, sulfonates, phosphoric acids, metal phosphate metals, acidic phosphoric acid esters, acidic phosphoric acid ester metal salts, phosphites, sulphite Acid metal salts and the like can also be used.

The decolorizing agent is an additive that decolorizes the leuco dye. As the decolorizing agent, a compound that dissociates the bond between the leuco dye and the developing agent can be used. As the decolorizing agent, a compound that does not exhibit color-developing property with respect to the leuco dye and has a polarity sufficient to dissolve the leuco dye or the color-developing agent is preferable. Examples of such decoloring agents include hydroxy compounds, ester compounds, peroxy compounds, carbonyl compounds, aromatic compounds, aliphatic compounds, halogen compounds, amino compounds, imino compounds, N-oxide compounds, hydroxyamine compounds, and nitro compounds. Examples thereof include azo compounds, diazo compounds, azi compounds, ether compounds, fats and oils, sugars, peptides, nucleic acids, alkaloids, steroids and the like.

Returning to FIG. 2, the plurality of first unit cells 20a include a process color cell 20b having any process color of the process of color change in the first region 130. The case where the first region 130 is composed of ink whose color density increases as the integrated physical quantity increases will be described below as an example. When the first region 130 changes color from white to dark blue, the process color cell 20b is, for example, light blue (light blue). This will be described with reference to FIG.

FIG. 5 is a diagram illustrating process colors. Equations (1) and (2) show vectors of the final color and the actually measured color with the starting color as the origin.
Final color (R, G, B) = (R _f ? R _i , G _f ? G _i , B _f ? _Bi ) ... Equation (1)
Measured color (r, g, b) = (rm? R _i , _{g m} ? Gi, b _m ? _{Bi )} ... Equation (2)

From the equations (1) and (2), the lengths of the vectors from the start color to the final color and the measured color (absolute value of R and absolute value of r, respectively) are the equations (3) and (4). It is represented by.

The length from the measured color (rm, g _m , b _{m )} to the correction color ( _{rc, g c, b c ) in} which a perpendicular line is hung on the vector of the equation (1) is expressed by the equation (5). To.

The inner product of the vectors of the equations (3) and (4) is represented by the equation (6).

The ratio of the vector length from the start color to the correction color (the above equation (4)) to the length of the vector from the start color to the final color (the above equation (3)) is the ratio of the equation (5) and the equation (6). Is substituted into the equations (3) and (4), and the equation (7) is calculated.

In this embodiment, the formula (7) is defined as the color development density. The process color is any color whose color density calculated by the equation (7) is larger than 0% and smaller than 100%. It is defined that the larger the color density, the darker the color, and the smaller the color density, the lighter (lighter) the color. As described above, when the color of the first region 130 changes from white to dark blue, the color density of white is (R _i , Gi, Gi ₎ and the color density of dark blue is (R _f , G _f , G ₎ . It is indicated by _f ). Therefore, the process color cell 20b is any process color whose color density calculated by the equation (7) is larger than 0% and smaller than 100%.

For the determination of whether or not the color is a process color, for example, R, G, and B of the first region 130 are actually measured to determine the actually measured color, and the ink displaying the first region 130 is analyzed to cause discoloration. This can be done by determining the component and the discoloration process resulting from that component.

Returning to FIG. 2, the ratio of the area occupied by the unused area 11 is 30% or less with respect to the total area of the second code 30. By reducing the area occupied by the unused area 11, the first area 130 can be made difficult to recognize. Further, the ratio of the area occupied by the first region 130 is 10% or less with respect to the total area of the second code 30. By reducing the area occupied by the first region 130, the first region 130 can be made difficult to recognize. When there are a plurality of first regions 130, it is preferably 10% or less with respect to the entire second code 30. Further, when there are a plurality of first regions 130, it is preferable that the plurality of first regions 130 are formed so as to be separated from each other. As a result, discoloration in the first region 130 can be made inconspicuous.

The first unit cell 20a preferably has two or more colors. That is, each first unit cell 20a has a single color, but there are two or more single-colored first unit cells 20a having different colors (that is, two or more colors when focusing on the color), which is four colors in the illustrated example. .. As a result, the color of the first unit cell 20a can be increased to make the first region 130 less noticeable. Among them, the second region 10 is composed of the first unit cell 20a having two or more colors, of which one or more colors are process colors. Preferably, the second region 10 is composed of a first unit cell 20a having three or more colors, of which two or more colors are process colors.

In the illustrated example, the second region 10 is composed of a first unit cell 20a of four colors, two of which are process colors. Specifically, the first unit cell 20a includes a white first unit cell 20a1, a process color dot pattern first unit cell 20a2, and a process color high-density dot pattern first unit cell 20a3. , The same color as dark blue, and further includes a first unit cell 20a4 with a high density dot pattern. Of these, white is the same as the background color and is the starting color of the first region 130. Further, dark blue is the final color of the first region 130. As described above, the process color is a color between the start color and the final color, and the process color cell 20b includes the first unit cells 20a2 and 20a3. By doing so, the first region 130 can be made inconspicuous by the first unit cell 20a.

The second unit cell 21a includes a cell that does not change color according to a physical quantity. The cell that does not change color according to the physical quantity is preferably the same color as the first unit cell 20a. In the illustrated example, the unused region 11 includes second unit cells 21a1,21a2, 21a3, 21a4 having the same color as the first unit cells 20a1, 20a2, 20a3, 20a4, respectively. That is, the first unit cell 20a1 and the second unit cell 21a1 have the same color, the first unit cell 20a2 and the second unit cell 21a2 have the same color, and the first unit cell 20a3 and the second unit cell 21a3 have the same color. The first unit cell 20a4 and the second unit cell 21a4 have the same color. As a result, the first region 130 can be surrounded by the first unit cell 20a and the second unit cell 21a having the same color as the first unit cell 20a, and the first region 130 can be made inconspicuous.

Among them, in the unused area 11, there are two or more second unit cells 21a having the same color as the first unit cell 20a, and in the illustrated example, there are eight other than the first area 130. As a result, the number of the second unit cells 21a of the same color can be increased to make the first region 130 less conspicuous. Further, the two or more second unit cells 21a have two or more colors, and in the illustrated example, they have four colors. As a result, the color of the second unit cell 21a can be increased to make the first region 130 less noticeable.

It is preferable that the first unit cell 20a and the second unit cell 21a have similar colors. In the present embodiment, the similar color is a combination of colors different only in lightness, saturation or shade, and a combination of colors having different tones but the same hue. It is preferable that the first unit cell 20a and the second unit cell 21a have the same color except that the shades are different. The degree of shading can be determined based on the magnitude of the color development density calculated by the above formula (7). As a result, the entire first unit cell 20a and the second unit cell 21a can be expressed in similar colors, and the discoloration of the first region 130 can be made less noticeable.

FIG. 6 is a diagram illustrating an outline of the information processing system 1000 according to the present embodiment. Although FIG. 6 illustrates international distribution including import / export of products, it can also be applied to domestic distribution that is completed domestically from production to consumers. The information processing system 1000 makes it possible for the consumer who receives the product to grasp the physical quantity in the distribution process of the product such as wine. The first code 200 is displayed, for example, on a label attached to the wine, a box containing the wine, or the like if the product is wine. Although FIG. 6 will be described by taking the first code 200 as an example, the second code 30 has the same operation mode.

The information processing system 1000 is a portable terminal 40 (input / output device) having both an input device (for example, an image pickup device such as a camera) that mechanically reads the information of the first code 200 and an output device that outputs information from a designated URL or the like. ) And the information processing apparatus 100. The specific configuration of the information processing apparatus 100 will be described later with reference to FIG. The mobile terminal 40 (input / output device) is a terminal (input / output device) having an image pickup function, and is, for example, an information communication terminal. The mobile terminal 40 (input / output device) is used to upload the change of the first area 130 of the first code 200 and the input information of the second area 110 to the information processing device 100 during product distribution. FIG. 6 shows an example of a mobile terminal 40 (input / output device) capable of inputting and outputting with one terminal, but a dedicated input device and output device can also be used.

At the time of product pickup, the person in charge of product transportation (for example, the driver) uses the mobile terminal 40 (input / output device) to image the first code 200 displayed on the product. As a result, the input information including the image of the first code 200 is uploaded to the information processing apparatus 100. Details will be described later, but the temperature at the time of reading and the integrated physical quantity (FIG. 4) are determined based on the first code 200. At this time, in addition to the product identification information (article identification information), the imaging time, imaging position, and the like are also uploaded as input information.
The article identification information is, for example, GTIN (Global Trade Item Number), EAN (European Article Number) code, and UPC (Universal Product Code). It is preferable that the article identification information is associated with information about the article such as the manufacturer, the seller, the date of manufacture, the expiration date, and the like.

Similarly, each person in charge at the export warehouse, the customs clearance warehouse, and the import warehouse uses the mobile terminal 40 (input / output device) to image the first code 200 displayed on the product. As a result, each input information is uploaded to the information processing apparatus 100. Then, the information processing apparatus 100 determines the physical quantity to which the product is exposed based on the uploaded input information. The specific determination method will be described later with reference to FIG. 7.

On the other hand, the consumer can access the URL (web) recorded in the first code 200 by reading the first code 200 of the product using the mobile terminal 40 (input / output device). The reading can be performed using, for example, a dedicated application running on the mobile terminal 40 (input / output device).

The mobile terminal 40 on the manager side such as the person in charge of product transportation corresponds to the first input device 710 and the first output device 810 shown in FIG. 10 described later. On the other hand, the mobile terminal 40 on the consumer side corresponds to the second input device 720 and the second output device 820 shown in FIG. In FIG. 6, the mobile terminal 40 is shown as a smartphone or a tablet terminal, but the present invention is not limited to this, and the mobile terminal 40 may be a dedicated read reader as an input device, a personal computer or the like as an output device, or the like. ..

FIG. 7 is a block diagram of an information processing system 1000 including an information processing device 100. Although not shown, the information processing apparatus 100 includes, for example, a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), an HDD (Hard Disk Drive), an I / F (interface), and the like. Be prepared for it. The information processing apparatus 100 is embodied by the CPU executing a predetermined control program stored in the ROM.

The information processing device 100 is an information processing device described in the first code 200, and includes a reception unit 101, an image analysis unit 102, a storage unit 103 (database), and a determination unit 104.

The reception unit 101 receives the information acquired by the terminal 50 (input device) via the Internet 52. The information acquired by the terminal 50 (input device) is, for example, image data or reading information of the acquired code. The image analysis unit 102 analyzes the acquired image of the first code 200. The image analysis unit 102 includes an information analysis unit 102a and a color analysis unit 102b.

The information analysis unit 102a determines the information recorded in the second region 110 of the first code 200. As described above, the information includes a URL, a serial number peculiar to each first code 200, and the like. The determined information is output to the determination unit 104.

The color analysis unit 102b determines the color of the first region 130. The determined color is quantified into each component of R, G, and B. The position of the first region 130 may be determined, for example, by comparing the acquired images with each other, or may be recorded in advance in the second region 10. The determined color is output to the determination unit 104.

In the present embodiment, the example in which the information processing apparatus 100 includes an image analysis unit has been described, but the terminal 50 (input device) may include an image analysis unit. When the terminal 50 (input device) includes an image analysis unit, the terminal 50 (input device) transmits the information described in the first code 200 and the color information of the first area 130 to the reception unit of the information processing device 100. do. The reception unit receives the information described in the code and the color information of the discolored cell.

The storage unit 103 (database) has a first relationship 103a between the color and the physical quantity of the first area 130, and a second relationship 103b between the information acquired by the terminal 50 (input device) and the ink type of the first area 130. Holds relationships that include ,. In the illustrated example, the physical quantity is, as an example, an integrated physical quantity which is the product of the physical quantity and the elapsed time as described above. The elapsed time can be the time since the last reading. By using the integrated physical quantity, it is possible to determine a physical quantity change that affects the product during distribution.

The terminal 50 corresponds to the first input device 710 shown in FIG. 10 described later. On the other hand, the consumer terminal 51 corresponds to the second input device 720 and the second output device 820 shown in FIG.

FIG. 8 is a schematic diagram of the first relationship 103a held in the storage unit 103 (database). The first relationship 103a is held for each type of ink in the first region 130. As a result, even if the physical quantity is the same, the physical quantity can be determined from the color development density that differs depending on the type of ink. As an example, the first relationship 103a when the type of ink in the first region 130 (for example, a color-developing component) is A1 is shown. Further, the above integrated physical quantity is shown as a physical quantity. Further, in the illustrated example, the color density calculated by the above formula (7) is used to express the color of the first region 130. The first relationship 103a is not limited to the illustrated example, and may be, for example, a table or the like.

The larger the integrated physical quantity, the larger the color density. Therefore, the longer the time that the first code 200 is exposed to the high temperature, the larger the color density of the first region 130 changes. For example, if the product is wine, its quality does not change much when exposed to high temperatures momentarily. However, even at high temperatures, if exposed for a long time, the quality will deteriorate. Therefore, by determining the integrated physical quantity based on the color of the first region 130, it is possible to grasp the physical quantity that affects the quality, for example, when exposed to a high temperature for a long time.

FIG. 9 is a schematic diagram of the second relationship 103b held in the storage unit 103 (database). The second relationship 103b is not limited to the illustrated example. As an example, FIG. 8 shows a serial ID unique to each first code 200 recorded in the second area 110.

The second relationship 103b associates the serial ID with the type of ink in the first region 130. Thereby, the serial ID of the first code 200 captured can be specified, and the type of ink in the first region 130 can be specified based on the specified serial ID. By specifying the type of ink, the physical quantity can be determined using an appropriate first relationship 103a (see FIG. 8).

Returning to FIG. 7, the determination unit 104 is based on the received information, the color of the first region 130, and the relationship (first relationship 103a and second relationship 103b) held in the storage unit 103 (database). The physical quantity to which the first code 200 is exposed (for example, an integrated physical quantity) is determined. Specifically, the determination unit 104 determines the type of ink in the first region 130 from the read serial ID and the second relationship 103b. Further, the determination unit 104 determines the first relationship 103a corresponding to the ink in the determined first region 130. The determination unit 104 determines the physical quantity to which the first code 200 is exposed based on the determined first relationship 103a and the actual color (for example, color development density) of the first region 130.

For example, when the product is wine, for example, the temperature determined from the first code 200 at the time of collection is 22 ° C., for example, the temperature determined from the first code 200 of the export warehouse is 17 ° C. In this case, it can be said that the product was placed in an appropriate temperature range at least at the time of each reading at the collection and export warehouse. However, with this information alone, the physical quantity between the pickup and the export warehouse is unknown.

Therefore, in the present embodiment, an integrated physical quantity is used as the physical quantity. Therefore, the color of the discolored cell first area 130 at the time of collection, the color of the first area 130 in the export warehouse, and the storage unit 103 (database) can be used to determine the integrated physical quantity between the collection and the export warehouse. As a result, by comparing the integrated physical quantity with the threshold value of the integrated physical quantity that affects the quality of wine, it is possible to grasp the possibility of wine quality change from collection to export warehouse, for example. This makes it possible to show consumers whether or not the product has been distributed under proper quality control. In this embodiment, the integrated physical quantity is used as the physical quantity, but the physical quantity may be used instead of the integrated physical quantity.

The consumer can access the URL (web) recorded in the first code 200 by reading the first code 200 of the product using the consumer terminal 51 (input / output device). The reading can be performed using, for example, a dedicated application running on the consumer terminal 51 (input / output device).

According to the information processing apparatus 100 and the information processing system 1000, the physical quantity change to which the first code 200 is exposed can be determined based on the color of the first region 130 of the first code 200. As a result, the information processed by the information processing apparatus 100 via the first code 200 is provided to the manager and the consumer. A method of providing information to managers and consumers will be described with reference to FIG.

FIG. 10 is a configuration of the information processing system 1000 according to the present embodiment. The information processing system 1000 is a first input device 710 on the administrator side, a second input device 720 on the consumer side, an information processing device 100, and a first output device 810 on the administrator side that displays information from the information processing device 100. , A second output device 820 on the consumer side is included.

The first input device 710 includes a first input unit 711 that reads change information of the first area 130 of the first code 200, article identification information of the second area 110, and inputs the information, and also includes a first input unit. The first communication unit 712 that transmits the change information of the first area 130 of the first code 200 input to the 711, the position information of the input location or the first input device 710, the input time, and the article identification information is included. Become.

The second input device includes a second input unit 721 for inputting information associated with the second area 110 of the first code 200, and is linked to the second area 110 input to the input unit of the first code 200. It includes a second communication unit 722 that transmits the attached information, the input location or the position information of the second input device 720, and the input time.

The information processing device 100 includes a storage unit 103 (database) for storing information transmitted from the first input device 710 on the administrator side and the second input device 720 on the consumer side, and an information processing unit 600 for analysis. Consists of.

In the storage unit 103 (database), a determination criterion based on the first relation 103a and the second relation 103b, the first relation 103a and the second relation 103b, the color information of the first area 130 already acquired, and the first code Since the analysis method of the acquired image is different in 200 or the second code 30, the specification of the code for determining them from the image, the ID of the product / carrier / trader input in advance to specify the reader and the read product. , The reader / time / position entered in the past for statistical analysis, the management entered by the reader, comments on the product, the consumer who received the product, information on the external system linked with the temperature detection system, etc. are stored. ing.

The information processing unit 600 identifies the color density estimation unit 610 for estimating the color density of the first region 130 from the image read by the first input device 710 or the second input device 720, and the environment detection material used in the code. From the relationship between the color density and the degree of environmental change for each material identification unit 620 and environmental detection material, the relationship between the color density and the degree of environmental change of the environmental detection material specified by the material identification unit 620 is selected, and the selected environment detection Environmental change estimation unit 630 that estimates the maximum or minimum environmental change from the color density of the material and the color density estimated by the color density estimation unit 610, and the quality of the pre-life of the article based on the environmental change. Quality prediction unit 640 that predicts, management condition calculation unit 650 that calculates management conditions of goods based on remaining life, statistical analysis unit 660 that derives the occurrence rate of management defects from collected management information, demand from the distribution volume of goods It has a demand forecasting unit 670 for forecasting.

There are two types of output devices, a first output device 810 on the administrator side and a second output device 820 on the consumer side, and the first output device 810 is a first region 130 and a second region 130 of the first code 200. The management information derived from the area 110 is output, and the second output device 820 on the consumer side outputs only a part of the information output from the first output device 810. By separating the output information between the consumer and the administrator, it is possible to make the information on the management side non-disclosure to the consumer and simply show only the information that the consumer wants.

The information output from the first output device 810 is specifically the contents of all articles (article information registered in the article management information) and the distribution channels of all articles (delivery of articles derived by concatenating location information). Route), distribution time of all goods (delivery time derived by the difference in input time), supply chain supplier of all goods (traceability information of inputter), recipient of all goods (inputter information at the time of receipt), all Change history of the first area 130 of the first code 200 of the article, statistical analysis result of distribution management of all articles, quality history of all articles, quality forecast of all articles, recommended usage of all articles, demand forecast of all articles, And so on. Here, the quality prediction of all articles is, for example, the product life including the degree of deterioration, the degree of freshness, the degree of maturity, the degree of putrefaction, the expiration date and the expiration date calculated from the temperature history information. The recommended usage of all articles is, for example, the recommended usage of a product derived from quality prediction. The demand forecast for all goods is calculated, for example, by statistically analyzing the input person information at the time of receipt.
The information output from the second output device 820 is already possessed by the contents of the received goods (the goods information registered in the goods management information), the manufacturer or the manufacturer of the received goods (the manager side associated with the goods management information). Manufacturer and manufacturer information), seller of received goods (sales source information already owned by the manager associated with goods management information), analysis results of distribution management of received goods, quality prediction of received goods, receipt Recommended usage of goods, etc. The analysis result of the distribution management of the received goods is, for example, the determination result of the management state obtained by analyzing the change history of the first area 130 of the first code 200 given to the received goods. The quality prediction of the received goods is, for example, the product life including the degree of deterioration, the degree of freshness, the degree of maturity, the degree of putrefaction, the expiration date and the expiration date calculated from the temperature history information. The recommended usage of the received goods is, for example, the recommended usage of the product derived from the quality prediction.
As described above, the value of providing information can be enhanced by distinguishing the information output by the first output device and the second output device.

In FIG. 10, the information processing system 1000 has been described as a configuration including the second input device 720 and the second output device 820, but the present invention is not limited thereto. That is, the configuration may not include the terminal on the consumer side. This is because the terminal on the consumer side is a terminal managed by the consumer himself / herself.

That is, in the information processing system 1000 provided with the information processing device 100 for managing the article, the first region 130 used for managing the article, which changes according to the change in the external environment, and the article identification for identifying the article. The code 200) including the second area 110 including the information area in which the information is recorded is read, the change information of the first area 130, and the article identification information of the second area 110 are read, and the read information and the reading position thereof are read. A first input device 710 for transmitting information and its reading time to the information processing device 100 is provided, the first input device is in a distribution channel of an article provided with a code, and the information processing device 100 is a first input. Upon receiving the information including the change information of the first area of the device 710, the management information derived from the first area 130 and the second area 110 is transmitted to the first output device 810, and the first from a terminal different from the first input device 710. When the information not including the change information of the area 130 is received, only a part of the information output to the first output device 810 is transmitted to the terminal. As a result, by separating the output information between the consumer and the administrator, it is possible to make the information on the management side non-disclosure to the consumer and simply show only the information that the consumer wants.

When the worker includes a consumer, the consumer does not need to confirm the temperature control information or the like until the delivery of the article, but only the information on whether the article is properly controlled. Further, for the consumer, only a part of the production area information of the traceability information or a part of the information centrally managed by the manager such as the effective expiration date based on the temperature control information is sufficient. Also, it is not necessary for the administrator to provide all the management information to the consumer. Consumers only need management information for the products they purchase. Therefore, according to the information processing system 1000 of the present embodiment, it is possible to provide an information processing system capable of not disclosing the information on the manager side to the consumer and simply showing only the information desired by the consumer.

11 Unused area 12 Error correction area 20a, 20a1, 20a2, 20a3, 20a4 1st unit cell 20b Process color cell 21a, 21a1,21a2, 21a3, 21a4 2nd unit cell 30 2nd code 40 Mobile terminal (input / output device)
50 terminals (input device)
51 Consumer terminal (input / output device)
52 Internet 100 Information processing device 101 Reception unit 102 Image analysis unit 102a Information analysis unit 102b Color analysis unit 103 Storage unit (database)
103a 1st relationship 103b 2nd relationship 104 Decision unit 110 2nd area 130 1st area 600 Information processing unit 610 Color density estimation unit 620 Material identification unit 630 Environmental change degree estimation unit 640 Quality prediction unit 650 Management condition calculation unit 660 Statistical analysis 670 Demand forecasting unit 710 1st input unit 711 1st input unit 712 1st communication unit 720 2nd input device 721 2nd input unit 722 2nd communication unit 810 1st output device 820 2nd output device 1000 Information processing system

Claims (7)

An information processing system for articles using a code including a first area that changes in response to changes in the external environment and a second area that includes an information area that records article identification information that identifies the article.
An information processing device that manages the article and
A first input device that reads change information in the first region and the article identification information in the second region, and transmits the read information, the read position information, and the read time to the information processing device. When,
It is provided with a second input device that reads the article identification information in the second region, reads the read information, reads the read position information, and transmits the read time to the information processing device.
The first input device and the second input device are in the distribution channel of the article provided with the code.
The information processing device is
Upon receiving the information from the first input device, the management information derived from the first area and the second area is transmitted to the first output device.
An information processing system characterized in that when information is received from the second input device, only a part of the information output to the first output device is transmitted to the second output device. The color of the first region changes depending on any of temperature, temperature history, humidity, light, gas concentration, vibration, liquid pH, ion concentration in liquid, drug concentration, amino acid / protein concentration, and virus / bacteria. The information processing system according to claim 1, wherein the area is a domain. The information processing system according to claim 1, wherein the second region is a two-dimensional code. The information processing system according to claim 1, wherein the code is a color two-dimensional code including the first region and the second region. The information transmitted to the first output device is information related to all articles.
The information processing system according to claim 1, wherein the information transmitted to the second output device is information related to the received article. The information transmitted to the first output device includes the contents of all goods, the distribution channel of all goods, the distribution time of all goods, the supply chain supplier of all goods, the recipient of all goods, and the first area of all goods. Change history, statistical analysis results of distribution management of all goods, quality history of all goods, quality prediction of all goods, recommended usage of all goods, demand forecast of all goods.
The information transmitted to the second output device is the content of the received goods, the manufacturer or producer of the received goods, the seller of the received goods, the analysis result of the distribution management of the received goods, the quality prediction of the received goods, and the recommendation of the received goods. The information processing system according to claim 1, wherein the method of use is used. An information processing system for articles using a code including a first area that changes in response to changes in the external environment and a second area that includes an information area that records article identification information that identifies the article.
An information processing device that manages the article and
A first input device that reads change information in the first region and the article identification information in the second region, and transmits the read information, the read position information, and the read time to the information processing device. And, with
The first input device is in the distribution channel of the article having the code.
The information processing device is
Upon receiving the information including the change information of the first region of the first input device, the management information derived from the first region and the second region is transmitted to the first output device.
Information processing characterized in that when information that does not include change information in the first region is received from a terminal different from the first input device, only a part of the information output to the first output device is transmitted to the terminal. system.

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