JP2012226710A - Information code, information code generation apparatus, information code generation program and information code reader - Google Patents

Abstract

PROBLEM TO BE SOLVED: To increase the quantity of information to be stored while facilitating reading of an information code.SOLUTION: An information code 40 comprises a plurality of cells 24 including a white cell 24 and cells 24 in any other color than white. The colored cell 24 is formed by one color or mixture of two or more colors selected from among a plurality of element colors. Each of all colors formed by a mixed color combining two or more colors and each of original colors not to be mixed are different from each other, and the plurality of element colors include a plurality of colors, other than white and black, to be black in mixing all the colors, and black. The black cell 24 formed by mixing all the plurality of element colors, the black cell 24 formed by mixing a plurality of colors other than black, and the black cell 24 formed in black that is an element color without mixture, have densities different from each other.

Description

  The present invention relates to an information code obtained by encoding information, an information code generation device, an information code generation program, and an information code reading device.

  Conventionally, an information code such as a QR code (registered trademark) is known. In such an information code, information is generally expressed by an arrangement of a white module and a black module.

  There is a limit to the amount of information that can be expressed in a black and white module. Therefore, various techniques have been proposed to increase the amount of information held by the information code. For example, Patent Document 1 proposes an information code using cyan, magenta, and yellow, which are three subtractive primary colors. The information code of Patent Document 1 is formed by superimposing codes for each of the three primary colors of subtractive color mixing, and is decomposed into three primary color codes by the reading device and decoded. As a result, the information code of Patent Document 1 can increase the amount of information that can be held as compared with the monochrome information code.

  Further, in Patent Document 2, the density of each primary color of the three subtractive primary colors is classified into a plurality of stages, a character string or the like is associated with the classified primary color combinations, and each data string is classified based on the correspondence. There has been proposed a technique of converting into a color of a combination of density primary colors and encoding.

JP-A-5-174204 JP 2002-342702 A

  However, the technique of Patent Document 1 has a limit of three times the amount of information with respect to the black and white information code.

  In the technique of Patent Document 2, it is necessary to use a newly devised code system instead of the existing code system. In addition, it is difficult to read the information code, for example, an advanced reading technique is required to determine the density of each color with high accuracy.

  The present invention has been made in view of the above, and an information code that allows easy increase in the amount of information, an information code generation device that generates the information code, an information code generation program, and an information code that reads the information code An object is to provide a reader.

  In order to achieve the above object, a first feature of the information code according to the present invention includes a plurality of modules including a white module and a colored module other than white, and the colored module is a subtractive color mixture. A black module formed by mixing one or two or more colors selected from the above element colors with the three primary colors and black as the element colors, and formed by all the mixed colors of the subtractive three primary colors and black as the element colors And a black module formed by subtractive color mixing of the three primary colors and a black module formed by black of the element color without color mixing have different densities.

  A second feature of the information code according to the present invention is that the element colors are the three subtractive primary colors and black, the black formed by all the subtractive primary colors and black, and the three subtractive primary colors. The object is to provide a reference mark that presents a reference color for at least one of the black colors formed by color mixing.

  A third feature of the information code according to the present invention includes a plurality of modules including a black module and a module other than black, and the black module is formed at any one of a plurality of levels of density. There is in being.

  A feature of the information code generation device according to the present invention is an information code generation device that generates an information code including a plurality of modules including a white module and a colored module other than white, and the colored module includes: A unit code generation unit that generates a unit code that is a code having a white module and a module of the element color corresponding to each of the three primary colors of subtractive color and black that are element colors used for forming; By superimposing unit codes corresponding to element colors, a module in which white and the element color overlap is a module of the element color, and a module in which two or more element colors overlap is a module in which they are mixed, A unit for synthesizing unit codes corresponding to each element color to generate the information code, The generation unit includes a black module formed by mixing all three subtractive primary colors and black, which are the element colors, a black module formed by mixing the three subtractive primary colors, and the element without color mixing. The purpose is to set the density of each element color so that the black module formed of the black color has different density.

  In the feature of the information code generation device according to the present invention, the combining unit includes the subtractive three primary colors and black, which are the element colors, the black formed by all the three subtractive primary colors and black, and the subtractive color mixture. Preferably, a reference mark that indicates a reference color for at least one of the black colors formed by mixing the three primary colors is added to the information code.

  A feature of the information code generation program according to the present invention is an information code generation program that generates an information code including a plurality of modules including a white module and a colored module other than white, and the colored module is Generating a unit code, which is a code composed of a white module and a module of the element color, corresponding to each of the three subtractive primary colors and black, which are element colors used for forming, and each element color By superimposing corresponding unit codes, a module in which white and the element color overlap is a module of the element color, and a module in which two or more element colors overlap is a module in which the element colors are mixed. Generating the information code by synthesizing unit codes corresponding to In the step of generating and generating the plurality of unit codes, the module is formed by mixing the three primary colors of the subtractive color and the black module formed by all the mixed colors of the subtractive mixed colors and black as the element colors, and the subtractive mixed primary colors. The purpose is to set the density of each element color so that the black module and the black module formed of black of the element color without color mixture have different densities.

  In the characteristic of the information code generation program according to the present invention, in the step of generating the information code, the subtractive three primary colors and black, which are the element colors, and the black formed by all the three subtractive primary colors and black It is preferable to add to the information code a reference mark that presents a reference color for at least one black color formed by mixing the three primary colors of subtractive color mixing.

  The information code reading device according to the present invention is characterized in that the information code reading device reads the information code of the present invention, based on the image data obtained by imaging the information code, and the color in the information code, and the information code The information code is decomposed into unit codes for each element color based on the detection unit for detecting the density of the black region in the image, the color in the information code detected by the detection unit, and the density of the black region It is provided with a decomposing unit and a decoding unit that decodes each unit code and obtains information indicated by the information code by synthesizing information obtained by decoding each unit code.

  A feature of the information code reading program for reading the information code according to the present invention is a step of detecting a color in the information code and a density of a black region in the information code based on image data obtained by imaging the information code. And decomposing the information code into unit codes for each element color based on the color in the information code and the density of the black area, decoding each unit code, and decoding each unit code And obtaining the information indicated by the information code by combining the information obtained in this manner.

  According to the first feature of the information code according to the present invention, the colored module is formed by a mixed color of one color or two or more colors selected from the three subtractive primary colors and the black color as the element colors. The black color formed by mixing all of the element colors, the black color formed by mixing the three subtractive primary colors, and the black element color having no color mixture have different densities. Thereby, even when black is used as the element color, the element color of each module can be determined in the reader. For this reason, it is possible to increase the amount of information that can be retained by using black as the element color for generating a cell colored with an information code. Further, the reading apparatus does not require fine density determination and does not require advanced reading technology. In addition, an existing code system can be used for generating and decoding information codes. For this reason, it is easy to read the information code.

  According to the second feature of the information code according to the present invention, since the reference mark that presents the reference color is provided, the reading error in the reading device can be reduced.

  According to the third feature of the information code according to the present invention, since the black module is formed at any one of a plurality of levels, the black module can handle a plurality of values, and the information The amount of information held by the code can be increased.

  According to the characteristics of the information code generation device according to the present invention, the subtractive mixed primary colors and black are used as the element colors, and the black is formed by all the mixed colors of the subtractive colors and the subtractive mixed primary colors. The information code of the present invention can be generated by setting the density of each element color so that the black color and the non-mixed element color black have different densities.

  According to the characteristics of the information code generation program according to the present invention, the subtractive mixed primary colors and black are used as the element colors, and the black is formed by all the mixed colors of the element colors and the subtractive mixed primary colors are formed. The information code of the present invention can be generated by setting the density of each element color so that the black color and the non-mixed element color black have different densities.

  According to the feature of the information code reader according to the present invention, the color in the information code and the density of the black region in the information code are detected based on the image data obtained by imaging the information code, and based on the detection result. The information code is broken down into unit codes for each element color. Then, the information code of the present invention can be easily decoded by decoding each unit code according to an existing code decoding method and synthesizing the obtained information.

It is a block diagram which shows the function structure of the information code generation apparatus which concerns on 1st Embodiment. It is a figure which shows the hardware structural example of an information code production | generation apparatus. It is a figure for demonstrating QR Code. It is a flowchart for demonstrating operation | movement of an information code production | generation apparatus. (A) is a diagram showing an example of a unit code corresponding to black of the element colors, (b) is a diagram showing an example of a unit code corresponding to cyan, and (c) is a unit code corresponding to magenta. FIG. 4D is a diagram illustrating an example of a unit code corresponding to yellow. It is a figure which shows notionally a mode that a unit code is superimposed. It is a table | surface which shows the color formed by superimposition of an element color. It is a figure which shows the information code which concerns on 1st Embodiment. It is a block diagram which shows the function structure of the information code reader which concerns on 1st Embodiment. It is a figure which shows the hardware structural example of an information code reader. It is a flowchart for demonstrating the procedure of the reading process in an information code reader. It is a flowchart for demonstrating the procedure of the reading process of an information code reader. It is a figure which shows an example of presentation of a reference color. It is a figure which shows the information code which concerns on 2nd Embodiment.

  Embodiments of the present invention will be described below with reference to the drawings. Throughout the drawings, the same or equivalent parts and components are denoted by the same or equivalent reference numerals.

(First embodiment)
FIG. 1 is a block diagram illustrating a functional configuration of the information code generation device according to the first embodiment. As shown in FIG. 1, the information code generation device 1 includes an input unit 2, a unit code generation unit 3, and a synthesis unit 4.

  The input unit 2 receives input of information to be encoded and supplies it to the unit code generation unit 3.

  The unit code generation unit 3 generates unit codes corresponding to the four primary colors (cyan, magenta, yellow) and black, which are element colors, based on the information to be encoded. The unit code is a code corresponding to each element color constituting the information code of the first embodiment. The unit code generation unit 3 divides the information to be coded, assigns the divided information to each element color, and generates each unit code expressing the divided information. In the first embodiment, a QR code that is a two-dimensional code will be described as an example of the information code generated by the information code generation device 1. The unit code generation unit 3 generates a QR code corresponding to each element color as a unit code based on a predetermined rule.

  The unit code generator 3 sets the density of each element color to “2” for cyan, magenta, and yellow, and “1/3” for black when the maximum density is “1”. To do. By setting the density in this way, the three primary colors (cyan, magenta, yellow) which are formed by mixing all of the element colors (cyan, magenta, yellow, black) and the subtractive color mixture of the element colors excluding black. The black color formed by the color mixture of () and the black component color without color mixture have different densities. The black color of the element color without color mixture has a density of “1/3”, whereas the black color density of cyan, magenta, and yellow is “2/3” due to all the mixed colors of the four color elements. The density of black is “3/3 (= 1)” (maximum density). Note that the above density setting is an example, and the present invention is not limited to this.

  The synthesizing unit 4 generates a color information code by superimposing and synthesizing unit codes corresponding to the element colors generated by the unit code generating unit 3.

  Next, a specific hardware configuration of the information code generation device 1 will be described. The information code generation device 1 is configured by a personal computer or the like. FIG. 2 is a diagram illustrating a hardware configuration example of the information code generation device 1.

  As shown in FIG. 2, the information code generation device 1 includes a CPU 11, a RAM 12, a ROM 13, a storage device 14, and an input device 15.

  The CPU 11 is a central processing unit that comprehensively controls the information code generation device 1 as a whole.

  The RAM 12 is used as a work area for the CPU 11 during temporary data storage and computation.

  The ROM 13 stores an operating system (OS) that is a control program of the CPU 11.

  The storage device 14 is composed of a hard disk or the like, and stores an information code generation program 16. When the CPU 11 executes the information code generation program 16, the functions of the unit code generation unit 3 and the synthesis unit 4 in FIG. 1 are realized.

  The input device 15 includes a keyboard, a mouse, and the like, and fulfills the function of the input unit 2 in FIG.

  Here, a known QR code will be described with reference to FIG. As shown in FIG. 3, the QR code 20 includes a data area 21, position detection patterns 22 a, 22 b, 22 c, and a peripheral area 23.

  The data area 21 is an area where information is recorded. The data area 21 is configured by arranging a plurality of rectangular cells (modules) 24 vertically and horizontally. Each cell 24 is displayed in white or black according to the information to be encoded according to a predetermined rule.

  The position detection patterns 22a, 22b, and 22c are used for alignment when the QR code 20 is imaged in a reading device that reads the QR code 20. The position detection patterns 22a, 22b, and 22c are arranged at three corners of the QR code 20. The position detection patterns 22a, 22b, and 22c include a black outer frame 25, a white inner frame 26, and a black central portion 27.

  The peripheral area 23 is an area provided to distinguish the QR code 20 from its surroundings. The peripheral area 23 is a white area surrounding the data area 21 and the position detection patterns 22a, 22b, and 22c.

  Next, the operation of the information code generation device 1 will be described.

  FIG. 4 is a flowchart for explaining the operation of the information code generation device 1. First, in step S10, upon receiving information to be encoded from the input unit 2, the unit code generation unit 3 generates unit codes corresponding to the four element colors. To divide. For example, when information about a company including company name, address, telephone number, and website URL is to be encoded, the unit code generation unit 3 converts the information to be encoded into company name, address, telephone number, URL. It is divided into four. Here, it is assumed that the company name, address, phone number, and URL information are information that cannot be stored by the known black and white QR code 20 as shown in FIG.

  Next, in step S20, the unit code generation unit 3 assigns the divided information to the four element colors, and generates a unit code corresponding to each element color according to the encoding rules in the existing QR code. Here, when assigning the divided information to each element color, the unit code generation unit 3 assigns the information in the predetermined color order from the head of the original information.

  5A shows an example of a unit code 30K corresponding to black of the element colors, FIG. 5B shows an example of a unit code 30C corresponding to cyan, and FIG. 5C. FIG. 5 is a diagram illustrating an example of a unit code 30M corresponding to magenta, and FIG. 5D is a diagram illustrating an example of a unit code 30Y corresponding to yellow. The unit codes 30K, 30C, 30M, and 30Y are obtained by displaying the black display portions of the well-known QR codes as shown in FIG. 1 with the element colors corresponding to each. That is, in the unit codes 30K, 30C, 30M, and 30Y, each cell 24 is displayed in the corresponding element color or white. Further, the position detection patterns 22a, 22b, and 22c of the unit codes 30K, 30C, 30M, and 30Y are also displayed using corresponding element colors.

  For example, if the above example is used, the unit code 30K is obtained by encoding the company name “KK Co., Ltd.” according to the rules of the QR code. The unit code 30C is obtained by encoding the address “Tokyo Metropolitan XX Ward ◯ 1-1-1” according to the rules of the QR code. It is assumed that the unit code 30M is obtained by coding a telephone number “03-xxx-xxxx-xxx” according to the rules of the QR code. The unit code 30Y is obtained by encoding the URL “http://www.xxx.co.jp/” according to the rules of the QR code.

  Next, in step S30, the synthesizing unit 4 generates an information code synthesized by superimposing the unit codes 30K, 30C, 30M, and 30Y. FIG. 6 is a diagram conceptually illustrating a state in which the unit codes 30K, 30C, 30M, and 30Y are overlapped. When the combining unit 4 superimposes the unit codes 30K, 30C, 30M, and 30Y as shown in FIG. 6, the cell 24 where the white color and the element color overlap is set as the element color, and the cell 24 where two or more element colors overlap each other. Is a mixed color. In addition, the synthesis unit 4 sets the cell 24 where only white is overlapped to be white, and the position detection patterns 22a, 22b, and 22c are set to black having a density “1” obtained by mixing all element colors. The colors (composite colors) formed by such superposition are 16 kinds of color numbers C-1 to C-16 shown in FIG. In FIG. 7, for example, the color number C-6 indicates that green is a composite of cyan and yellow. A combination of element colors corresponding to each of the color numbers C-1 to C-16 is uniquely determined.

  An example of the information code generated by combining the unit codes 30K, 30C, 30M, and 30Y by the combining unit 4 as described above is shown in FIG. As shown in FIG. 8, each cell 24 of the data area 21 in the information code 40 is formed to be white or colored other than white. The color of the colored cell 24 is formed by one color selected from four element colors or a mixed color of two or more colors.

  Here, for black displayed in the information code 40, as shown in FIGS. 7 and 8, there are three types of color numbers C-9, C-8, and C-16 having different densities (composite color densities). is there. The black color (C-9: gray) of the element color without color mixture has a density of “1/3”, and the black color (C-8: dark gray) of the three primary colors (cyan, magenta, yellow) of the subtractive color mixture has the density. “2/3”, black (C-16), which is a mixture of all four element colors, has a density of “3/3 (= 1)” (maximum density).

  The image data of the information code 40 generated by the information code generation device 1 is sent to, for example, a printing device, and the information code 40 is printed on a paper medium or the like in the printing device.

  Next, an information code reader for reading the information code 40 will be described.

  FIG. 9 is a block diagram showing a functional configuration of the information code reader. As shown in FIG. 9, the information code reading device 50 includes an imaging unit 51, a detection unit 52, a decomposition unit 53, a decoding unit 54, and a display unit 55.

  The imaging unit 51 captures the information code 40 and generates image data including R, G, and B components.

  The detection unit 52 detects the color in the information code 40 and the density of the black region in the information code 40 based on the image data obtained by imaging the information code 40.

  The decomposition unit 53 decomposes the information code 40 into unit codes 30K, 30C, 30M, and 30Y for each element color based on the color in the information code 40 and the density of the black region in the information code 40.

  The decoding unit 54 decodes (decodes) the unit codes 30K, 30C, 30M, and 30Y, synthesizes information obtained by decoding the unit codes 30K, 30C, 30M, and 30Y, and shows the information indicated by the information code 40 To get.

  The display unit 55 displays information obtained by the decoding unit 54 decoding the information code 40.

  Next, a specific hardware configuration of the information code reader 50 will be described. The information code reading device 50 is constituted by a mobile phone terminal with a camera function, for example. FIG. 10 is a diagram illustrating a hardware configuration example of the information code reading device 50.

As shown in FIG. 10, the information code reading device 50 includes a CPU 61, a RAM 62, a ROM 63, an imaging device 64, a storage device 65, and a display device 66.
The CPU 61 is a central processing unit that controls the entire information code reader 50 in an integrated manner.

  The RAM 62 is used as a work area for the CPU 61 during temporary data storage and calculation.

The ROM 63 stores an OS that is a control program for the CPU 61.
The imaging device 64 includes a CCD (Charge Coupled Device) and the like, images a subject, and generates image data including R, G, and B components. The imaging device 64 fulfills the function of the imaging unit 51 of FIG.

The storage device 65 includes a hard disk and stores an information code reading program 67. When the CPU 61 executes the information code reading program 67, the functions of the detection unit 52, the decomposition unit 53, and the decoding unit 54 in FIG. 9 are realized.
The display device 66 is composed of a liquid crystal display or the like, and fulfills the function of the display unit 55 of FIG.

  Next, the operation of the information code reading device 50 will be described.

  The imaging unit 51 captures the information code 40 and generates image data. The detection unit 52 detects the color in the information code 40 and the density of the black region in the information code 40 based on the image data obtained by imaging the information code 40. Here, the position detection patterns 22a, 22b, and 22c of the information code 40 are black having a density “1” obtained by mixing all the element colors. The detection unit 52 can detect the density accurately by detecting the density of the black region in the information code 40 with reference to the position detection patterns 22a, 22b, and 22c. The position detection patterns 22a, 22b, and 22c function as reference marks in the claims.

  Based on the detection result of the detection unit 52, the decomposition unit 53 decomposes the information code 40 into unit codes 30K, 30C, 30M, and 30Y for each element color. From the relationship between the composite color and the element color shown in FIG. 7, the separation unit 53 can separate the information code 40 into unit codes 30K, 30C, 30M, and 30Y.

  Then, the decoding unit 54 decodes the unit codes 30K, 30C, 30M, and 30Y, synthesizes the obtained information, and acquires information indicated by the information code 40.

  An example of the processing procedure for decomposing and decoding the information code 40 into the unit codes 30K, 30C, 30M, and 30Y in the information code reader 50 as described above will be described with reference to the flowcharts of FIGS.

  First, in step S110, the detection unit 52 sets 1 to the variable i.

  Next, in step S <b> 120, the detection unit 52 detects the color of the i-th cell 24 in the data area 21 of the information code 40. When the i-th cell 24 is black, the detecting unit 52 also detects the black density. In addition, what is necessary is just to determine arbitrarily the order of the cell 24 from which the detection part 52 detects a color.

  Next, in step S130, the decomposition unit 53 determines whether the density of the black component in the i-th cell 24 is “1/3” or “1” based on the detection result of the detection unit 52 in step S120. to decide.

  The density of the black component determined here is the density of the composite color when the color (composite color) displayed in the cell 24 is black (color numbers C-9, C-8, C-16). When the color displayed in the cell 24 is other than black, the density of black included as an element color in the composite color is obtained. The density of the black component is “1/3” as shown in FIG. 7, which are color numbers C-9 to C-15, and these include black as the element color. Further, the density of the black component is “1” in color number C-16, which is formed by a mixed color of the element colors black, cyan, magenta, and yellow having the density “1/3”. Is. Therefore, when it is determined that the density of the black component included in the color of the i-th cell 24 is “1/3” or “1” (step S130: YES), black is included as the element color, and thus step S140. The decomposition unit 53 assigns black to the i-th cell 24 in the black layer. Next, in step S150, the separation unit 53 removes the black component of the element color from the color component of the i-th cell 24 in the information code 40. Thereafter, the process proceeds to step S170.

  On the other hand, the density of the black component contained in the cell 24 is “2/3” because, as shown in FIG. 7, the composite color is black (dark gray) with the density “2/3”. 8. This does not include black in the element color. Black of color number C-8 is formed by a mixture of cyan, magenta, and yellow. The density of the black component is “0” in the color numbers C-1 to C-7, and the element color does not include black. Therefore, when it is determined that the density of the black component contained in the color of the i-th cell 24 is neither “1/3” nor “1”, that is, “2/3” or “0” (step S130: NO) ), Since black is not included as the element color, in step S160, the decomposition unit 53 assigns white to the i-th cell 24 in the black layer. Thereafter, the process proceeds to step S170.

  In step S <b> 170, the detection unit 52 determines whether or not the variable i is I indicating that it is the last cell 24 in the data area 21. If i = I (step S170: YES), the process proceeds to step S190. If i = I is not satisfied (step S170: NO), in step S180, the detection unit 52 adds 1 to the variable i. Thereafter, the process returns to step S120.

  In step S190, the decomposition unit 53 sets 1 to the variable i.

  Next, in step S <b> 200, the decomposition unit 53 determines whether or not a cyan component is included in the i-th cell 24 of the information code 40. When it is determined that the cyan component is included in the i-th cell 24 (step S200: YES), the decomposition unit 53 assigns cyan to the i-th cell 24 in the cyan layer in step S210. Thereafter, the process proceeds to step S230.

  If it is determined that the cyan component is not included in the i-th cell 24 (step S200: NO), in step S220, the decomposition unit 53 assigns white to the i-th cell 24 in the cyan layer. Thereafter, the process proceeds to step S230.

  In step S230, the decomposing unit 53 determines whether or not the i-th cell 24 of the information code 40 includes a magenta component. When it is determined that the m-th component is included in the i-th cell 24 (step S230: YES), in step S240, the decomposition unit 53 assigns magenta to the i-th cell 24 in the magenta layer. Thereafter, the process proceeds to step S260.

  If it is determined that the m-th component is not included in the i-th cell 24 (step S230: NO), the decomposition unit 53 assigns white to the i-th cell 24 in the magenta layer in step S250. Thereafter, the process proceeds to step S260.

  In step S260, the decomposition unit 53 determines whether or not the i-th cell 24 of the information code 40 includes a yellow component. When it is determined that the yellow component is included in the i-th cell 24 (step S260: YES), in step S270, the decomposition unit 53 assigns yellow to the i-th cell 24 in the yellow layer. Thereafter, the process proceeds to step S290.

  When it is determined that the yellow component is not included in the i-th cell 24 (step S260: NO), the decomposition unit 53 assigns white to the i-th cell 24 in the yellow layer in step S280. Thereafter, the process proceeds to step S290.

  In step S290, the decomposition unit 53 determines whether or not the variable i is I indicating that it is the last cell 24 in the data area 21 of the information code 40. If i = I (step S290: YES), the process proceeds to step S310. If i = I is not satisfied (step S290: NO), in step S300, the decomposition unit 53 adds 1 to the variable i. Thereafter, the process returns to step S200.

  As described above, the unit codes 30K, 30C, 30M, and 30Y shown in FIG. 5 are restored to the black layer, cyan layer, magenta layer, and yellow layer.

  In step S310, the decrypting unit 54 decrypts each unit code 30K, 30C, 30M, 30Y. The unit codes 30K, 30C, 30M and 30Y can be decoded by a normal QR code decoding method. Using the above-described example, the decrypting unit 54 decrypts the unit code 30K to obtain information on the company name “corporation OO”. The decrypting unit 54 decrypts the unit code 30C to obtain information “Tokyo Metropolitan Area XX1-1-1” as an address. The decrypting unit 54 decrypts the unit code 30M to obtain information “03-xxx-xxx-xxx”, which is a telephone number. Further, the decrypting unit 54 decrypts the unit code 30Y to obtain information “http://www.xxx.co.jp/” which is a URL.

  In step S320, the decrypting unit 54 synthesizes information obtained by decrypting the unit codes 30K, 30C, 30M, and 30Y. At this time, the decoding unit 54 combines the information corresponding to the unit codes 30K, 30C, 30M, and 30Y in the color order in which the divided information is assigned when the information code 40 is generated by the information code generation device 1. To match. Using the above example, when the information code generator 1 assigns information arranged in the order of company name, address, telephone number, and URL in the order of unit codes 30K, 30C, 30M, and 30Y, the decrypting unit 54 Information obtained by decoding is synthesized in the order of unit codes 30K, 30C, 30M, and 30Y. Thereby, the decoding part 54 can obtain information arranged in the order of company name, address, telephone number, and URL.

  As described above, the information held in the information code 40 is obtained. The decoding unit 54 displays information obtained by decoding the information code 40 in this manner on the display unit 55 and notifies the user.

  As described above, in the information code 40 of the first embodiment, black is used as the element color for forming the colored cell 24 in addition to the three primary colors of subtractive color mixture. Here, the black color formed by all the mixed colors of the element colors, the black color formed by the mixed primary colors of the subtractive colors, and the black of the element color without mixed colors have different densities. Thereby, even if black is used as the element color, the information code reader 50 can determine the element color of each cell 24 of the information code 40. Therefore, according to the information code 40, it is possible to increase the amount of information that can be held by using black as the element color for generating the colored cell 24 in addition to the three subtractive primary colors.

  Further, in the information code 40, the information code reader 50 has only three levels of density discrimination, and other than that, fine density discrimination is not required, and an advanced reading technique is unnecessary. An existing code system such as a QR code can be used to generate and decode the information code 40. For this reason, the information code 40 is easy to read. In addition, the information code 40 can be generated and read by incorporating the information code generation program 16 and the information code reading program 67 into an existing mobile phone terminal or the like.

  In the information code generation device 1, the black color formed by mixing all the element colors as described above, the black color formed by mixing the three primary colors of subtractive color, and the black element color having no color mixture are different from each other. By setting the density of each element color so as to be the density, the information code 40 can be generated.

  The information code reader 50 detects the color in the information code 40 and the density of the black area in the information code 40 based on the image data obtained by imaging the information code 40, and the information code 40 based on the detection result. Is broken down into unit codes 30K, 30C, 30M, and 30Y for each element color. The information code reading device 50 can easily decode the information code 40 by decoding each unit code 30K, 30C, 30M, 30Y according to an existing code decoding method and synthesizing the obtained information.

  In the first embodiment, the position detection patterns 22a, 22b, and 22c of the information code 40 are reference patterns indicating a black reference color having a density “1” obtained by mixing all element colors. Other reference colors may be presented on the detection patterns 22a, 22b, and 22c. For example, each element color (cyan, magenta, yellow, black), a black color formed by mixing all the element colors, or a black color formed by mixing the three primary colors of the subtractive color mixture is shown. Can be.

  An example of the presentation of the reference color is shown in FIG. In FIG. 13, the center portions 27 of the position detection patterns 22a, 22b, and 22c are set as cyan, magenta, and yellow reference colors, respectively, and the outer frame 25 is formed by a mixture of all element colors (cyan, magenta, yellow, and black). The black reference color. When the information code 40 is printed on a printing medium, the color of the information code 40 may be different depending on the type of printing medium and printing apparatus used. The information code reading device 50 determines each color in the data area 21 based on the reference color presented in the information code 40 as described above, so that the information code 40 is printed regardless of the type of printing medium or the like. Reading error is reduced, and accurate reading is possible.

  Further, in the information code 40, the position detection patterns 22a, 22b, and 22c are provided with a function as a reference pattern for presenting a reference color. However, the present invention is not limited thereto, and a separate reference pattern may be provided.

  In the first embodiment, the information code 40 using all four element colors (cyan, magenta, yellow, and black) is shown. However, depending on the information amount to be encoded, element colors of three colors or less are used. Can be configured.

  Further, the present invention is not limited to the QR code but can be applied to other two-dimensional codes, bar codes, and the like.

(Second Embodiment)
FIG. 14 is a diagram illustrating an information code according to the second embodiment. As shown in FIG. 14, the information code 70 includes a data area 71 and a peripheral area 72.

  The data area 71 is an area where information is recorded. The data area 71 is configured by arranging a plurality of rectangular cells 24 vertically and horizontally. Each cell 24 is displayed in white or black depending on the information to be encoded. In black, the maximum density is “1”, and four levels of density “2/5”, “3/5”, “4/5”, and “1” are set. It is formed at any one of the four levels. For example, a value “0” corresponds to the white cell 24, and values “1” to “4” correspond to the black cell 24 according to the density. With such an array of cells 24, the information code 70 expresses information.

  The peripheral area 72 is an area provided to distinguish the information code 70 from its surroundings. The peripheral area 72 is a white area surrounding the data area 71.

  The information code 70 is generated by an apparatus having the same configuration as the information code generating apparatus 1 shown in FIG. Here, when the information code 70 is generated, a program for generating the information code 70 is used as the information code generation program 16. The CPU 11 assigns one of white and black of each density to each cell 24 according to the information code generation program 16 based on the information to be encoded, and generates image data of the information code 70.

  The generated image data of the information code 70 is sent to, for example, a printing apparatus, and the information code 70 is printed on a paper medium or the like in the printing apparatus.

  The black cell 24 may be formed by mixing two or more colors selected from three subtractive primary colors and black. For example, the black cell 24 having the density “1” can be formed by a mixture of cyan, magenta, yellow having the density “1/5” and black having the density “2/5”. The black cell 24 having the density “4/5” can be formed by mixing the cyan color having the density “1/10” and the black color having the density “7/10”. The black cell 24 having the density “3/5” can be formed by mixing cyan, magenta, and yellow having the density “1/5”. Here, the black of the above density “4/5” is a mixture of black and a slight amount of cyan. Such a color is also very close to black and is considered black. That is, as black forming the black cells 24, those formed by mixing four colors of cyan, magenta, yellow and black, those formed by mixing three colors of cyan, magenta and yellow, black and slight Some may be formed by mixing colors with other colors, and some may be formed by black without mixing colors.

  Note that the density of the black cell 24 is not limited to the four levels of density as described above, but may be a plurality of levels.

  The information code 70 is read by an apparatus having the same configuration as the information code reading apparatus 50 shown in FIG. Here, when the information code 70 is read, a program for reading and decoding the information code 70 is used as the information code reading program 67. The CPU 61 detects the color and density of each cell 24 from the image data obtained by the imaging unit 51 imaging the information code 70, and decodes the information code 70 according to the information code reading program 67 using the detection result. .

  As described above, in the information code 70, the black cells 24 are formed at any one of a plurality of levels of density. As a result, the black cell 24 can handle a plurality of values, and the amount of information held by the information code 70 can be increased.

  The cells 24 other than black are not limited to white, and other colors may be used. A plurality of colors other than black may be used, and a corresponding value may be set for each color.

  The present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the components without departing from the scope of the invention in the implementation stage. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiments. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

DESCRIPTION OF SYMBOLS 1 Information code generation apparatus 2 Input part 3 Unit code generation part 4 Synthesis | combination part 11, 61 CPU
12,62 RAM
13,63 ROM
14, 65 Storage device 15 Input device 16 Information code generation program 20 QR code 21, 71 Data area 22a, 22b, 22c Position detection pattern 30K, 30C, 30M, 30Y Unit code 40, 70 Information code 51 Imaging unit 52 Detection unit 53 Decomposition unit 54 Decoding unit 55 Display unit 64 Imaging device 66 Display device 67 Information code reading program

Claims (6)

A plurality of modules including a white module and a non-white colored module;
The colored module is formed by one or two or more mixed colors selected from the element colors using the subtractive three primary colors and black as the element colors,
A black module formed by mixing all three primary colors of subtractive color and black, which are the element colors, a black module formed by mixing three primary colors of subtractive color, and a black module of the element color without mixing colors An information code characterized in that the density of the formed black module is different from each other.   Criteria for at least one of the subtractive three primary colors and black, which are the element colors, black formed by all subtractive three primary colors and black, and black formed by subtractive three primary colors The information code according to claim 1, further comprising a reference mark for presenting a color. A plurality of modules including a black module and a non-black module are provided.
The information module according to claim 1, wherein the black module is formed at any one of a plurality of levels. An information code generation device that generates an information code including a plurality of modules including a white module and a colored module other than white,
A unit code for generating a unit code which is a code having a white module and a module of the element color corresponding to each of the three subtractive primary colors and black which are element colors used to form the colored module A generator,
By overlapping unit codes corresponding to each element color, a module in which white and the element color overlap is a module of the element color, and a module in which two or more element colors overlap is a module in which they are mixed. A synthesis unit that synthesizes unit codes corresponding to the element colors and generates the information code,
The unit code generation unit includes a black module formed by mixing all three subtractive primary colors and black as the element colors, a black module formed by mixing the three subtractive primary colors, and no color mixing. The information code generation device is characterized in that the density of each element color is set so that the black module formed of black of the element color has a density different from each other. An information code generation program for generating an information code composed of a plurality of modules including a white module and a colored module other than white,
Generating a unit code, which is a code composed of a white module and a module of the element color, corresponding to each of the three subtractive primary colors and black, which are element colors used to form the colored module; ,
By overlapping unit codes corresponding to each element color, a module in which white and the element color overlap is a module of the element color, and a module in which two or more element colors overlap is a module in which they are mixed. And causing the computer to execute a step of generating the information code by synthesizing unit codes corresponding to the element colors,
In the step of generating the plurality of unit codes, a black module formed by mixing all three subtractive primary colors and black as the element colors, and a black module formed by mixing the three subtractive primary colors An information code generation program that sets the density of each element color so that the black module formed of black of the element color without color mixing has a different density from each other. An information code reader for reading the information code according to claim 1 or 2,
A detection unit that detects a color in the information code and a density of a black region in the information code based on image data obtained by imaging the information code;
A decomposition unit that decomposes the information code into unit codes for each element color based on the color in the information code detected by the detection unit and the density of the black region;
An information code reading device comprising: a decoding unit that decodes each unit code and obtains information indicated by the information code by synthesizing information obtained by decoding the unit codes.