JP6225597B2 - Information code generation method, information code, information code reader, and information code utilization system - Google Patents

Description

  The present invention relates to an information code generation method, an information code, an information code reader, and an information code utilization system.

  At present, the use of information codes is diversified, and a technique for arranging photographs and drawings in the code area has also been proposed. For example, in the technique of Patent Document 1, an inversely converted bit string obtained by inversely converting a bit string that forms an area to be read as a single value in a two-dimensional code is obtained, and the inversely converted bit string is converted based on the format information of the two-dimensional code. By generating a two-dimensional code, a special two-dimensional code having a design area composed of a single gradation value is generated.

Japanese Patent No. 5057560

  In the technique disclosed in Patent Document 1, for example, in the case of a special two-dimensional code in which the design area is composed of white modules, a design composed of gradation values in a range that is read as white is formed in the design area. In this way, the special two-dimensional code and the given design data are synthesized. On the other hand, in the case where the design area is a special two-dimensional code composed of, for example, a black module, the special two-dimensional code is formed so that a design composed of gradation values in a range read as black is formed in the design area. And given design data. However, in the technique of Patent Document 1, there is no idea that the design area once set is used by a method different from the data recording area, and the convenience is impaired in this respect.

  On the other hand, the inventor of the present application has come up with a new method of using an information code, in which a desired sound data is recorded in a code area, and the sound data is read to generate music corresponding to the sound data. . However, if such sound data is recorded in the data recording area by a general method, it cannot be distinguished from a normal information code by appearance, so the special data at the corner is visually buried, and the special data It becomes difficult for the user to recognize that there is.

  The present invention has been made to solve the above-described problems, and an area expressed by a method different from the data recording area can be used as a recording area for sound data, and special data is included in the code area. It is an object of the present invention to provide a configuration in which a user can easily visually recognize that the is recorded.

1st invention is the information code generation method which produces | generates the information code which arranged the cell used as the unit which displays information inside a predetermined code area | region with an information code production | generation apparatus,
A specific pattern area in which a specific pattern having a predetermined shape is arranged inside the code area, a data recording area for recording data by a plurality of types of the cells, and a data recording method by the data recording area A sound information display area for expressing a plurality of sounds by a predetermined figure by different methods is provided.

2nd invention is the information code which arranged the cell used as the unit which displays information inside the predetermined code field,
A specific pattern area in which a specific pattern having a predetermined shape is arranged inside the code area, a data recording area for recording data by a plurality of types of the cells, and a data recording method by the data recording area There is provided a sound information display area in which a plurality of sounds are represented by predetermined figures in different ways.

A third invention is an information code reader for reading an information code in which cells serving as units for displaying information are arranged in a predetermined code area,
The information code includes a specific pattern area in which a specific pattern having a predetermined shape is arranged inside the code area, a data recording area in which data is recorded by a plurality of types of cells, and data by the data recording area And a sound information display area for expressing a plurality of sounds by a predetermined figure by a method different from the recording method of
An imaging unit capable of imaging the information code;
When the information code is imaged by the imaging unit, a data recording area reading unit that reads data recorded in the data recording area based on the content of the data recording area in the code image of the imaged information code When,
A recording sound identifying unit that identifies a plurality of sounds recorded in the sound information display area based on the predetermined graphic represented in the sound information display area in the code image;
It is characterized by having.

A fourth invention is an information code generation device for generating an information code in which cells serving as units for displaying information within a predetermined code area are arranged;
An information code reader for reading the information code generated by the information code generator;
An information code using system comprising:
The information code generation device includes:
A specific pattern area in which a specific pattern having a predetermined shape is arranged inside the code area, a data recording area for recording data by a plurality of types of the cells, and a data recording method by the data recording area The information code is generated in a configuration provided with a sound information display area that expresses a plurality of sounds by a predetermined figure by different methods,
The information code reader is
An imaging unit capable of imaging the information code;
When the information code is imaged by the imaging unit, a data recording area reading unit that reads data recorded in the data recording area based on the content of the data recording area in the code image of the imaged information code When,
A recording sound identifying unit that identifies a plurality of sounds recorded in the sound information display area based on the predetermined graphic represented in the sound information display area in the code image;
It is characterized by having.

  According to the first aspect of the present invention, it is possible to use an area expressed by a method different from the data recording area as a recording area for sound data and that special data is recorded in the code area. Can be easily recognized visually.

  According to the second aspect of the present invention, it is possible to secure an area (empty area) where the data to be decoded is not recorded by the cell at a position other than the data recording area and the specific pattern area in the code area, and the contents of the empty area Can be used later as sound information different from the data to be decoded. Since the empty area is an area where data to be decoded is not recorded by the cell, the sound information display area is not easily affected by the cell, and the sound information display area can be configured more freely.

  According to the invention of claim 3, the pitch of each sound can be grasped by grasping the position of each predetermined figure corresponding to each sound, and the melody recorded in the sound information display area is read by the reading device. An information code that can be transmitted to the side can be realized.

  According to the invention of claim 4, it is possible to realize an information code capable of transmitting a plurality of sound performance methods expressed in the sound information display area to the reader side.

  According to the invention of claim 5, at least any one of the performance sound source, the performance speed, and the number of pitches that can be performed can be transmitted to the reader, and a more free melody can be used. It becomes easy.

  According to the invention of claim 6, it is easy for the user of the information code to visually recognize the performance method of a plurality of sounds recorded in the sound information display area by looking at the entry position, and the reading device is able to recognize the entry position. An information code that makes it easy to grasp the performance method by recognition can be realized.

  According to the invention of claim 7, since the performance method can be specified by the color or shape of the predetermined figure, it becomes easy to use a more free melody without using a lot of complicated data for specifying the performance method.

  According to the eighth aspect of the present invention, it is possible to realize an information code in which the position of the sound information display area can be more accurately specified by reading position data.

  According to the ninth aspect of the present invention, the number of steps of the sound information display area can be arbitrarily set on the generation side, and an information code that can grasp the set number of steps on the reading side can be realized.

  According to the invention of claim 10, the user can use the area expressed by a method different from the data recording area as the recording area of the sound data, and the special data is recorded in the code area. Can be easily recognized visually.

  According to the eleventh aspect of the present invention, it is possible to secure an area (empty area) where the data to be decoded is not recorded by the cell at a position other than the data recording area and the specific pattern area inside the code area, and the contents of the empty area Can be used later as sound information different from the data to be decoded. Since the empty area is an area where data to be decoded is not recorded by the cell, the sound information display area is not easily affected by the cell, and the sound information display area can be configured more freely.

  According to the invention of claim 12, the pitch of each sound can be grasped by grasping the position of each predetermined figure corresponding to each sound, and the melody recorded in the sound information display area is read by the reading device. An information code that can be transmitted to the side can be realized.

  According to the thirteenth aspect of the present invention, it is possible to realize an information code that can transmit a plurality of sound performance methods expressed in the sound information display area to the reader side.

  According to the invention of claim 14, at least any one of the performance sound source, the performance speed, and the number of pitches that can be performed can be transmitted to the reader, and a more free melody can be used. It becomes easy.

  According to the fifteenth aspect of the present invention, it is easy for the user of the information code to visually recognize the performance method of a plurality of sounds recorded in the sound information display area by looking at the entry position, and the reading device can check the entry position. An information code that makes it easy to grasp the performance method by recognition can be realized.

  According to the invention of claim 16, since the performance method can be specified by the color or shape of the predetermined figure, it becomes easier to use a more free melody without using a lot of complicated data for specifying the performance method.

  According to the seventeenth aspect of the present invention, it is possible to realize an information code in which the position of the sound information display area can be more accurately specified by reading position data.

  According to the eighteenth aspect, the number of steps of the sound information display area can be arbitrarily set on the generation side, and an information code that can grasp the set number of steps on the reading side can be realized.

  According to the nineteenth aspect of the present invention, it is possible to realize a reading apparatus that reads an information code including a sound information display area expressed by a method different from that of the data recording area. In particular, the realization of this reader makes it possible to use the information code in a form that allows the user to easily recognize that special data is recorded in the code area. It becomes easy to raise.

  According to the twentieth aspect, an area (empty area) where the data to be decoded is not recorded by the cell is secured in a position other than the data recording area and the specific pattern area in the code area, and this empty area is used as the sound information display area. With the information code used as a reading target, the contents of the data recording area of the information code and the sound information display area can be used afterwards.

  According to the invention of claim 21, the pitch of each sound can be grasped by grasping the position of each predetermined figure corresponding to each sound, and the melody recorded in the sound information display area can be more reliably confirmed. It is possible to realize a configuration that is easy to grasp.

  According to the eleventh aspect of the present invention, it is possible to realize a reading apparatus that can specifically grasp the performance method of a plurality of sounds expressed in the sound information display area.

  According to the invention of claim 23, it is possible to grasp at least one of the performance sound source, the performance speed, and the number of pitches that can be performed, and a method for playing a plurality of sounds expressed in the sound information display area. A reading device that can be specified in more detail can be realized.

  According to the invention of claim 24, the performance method can be grasped more accurately by analyzing the entry area provided in the peripheral area of the sound information display area.

  According to the invention of claim 25, the performance method of each sound can be specified more accurately by recognizing the color or shape of each predetermined graphic representing each sound.

  According to the twenty-sixth aspect, the position of the sound information display area in the code image can be more accurately specified based on the position data obtained from the reading result of the data recording area.

  According to the invention of claim 28, the number of steps of the sound information display area arbitrarily set on the generation side can be specified more accurately on the reading side, and the melody can be grasped according to the number of steps assumed at the time of generation. An obtained reading device can be realized.

  According to the invention of claim 28, the user can use the area expressed by a method different from the data recording area as the recording area of the sound data, and the special data is recorded in the code area. Can be easily recognized visually.

  According to the invention of claim 29, it is possible to secure an area (empty area) in which the data to be decoded is not recorded by the cell at a position other than the data recording area and the specific pattern area in the code area, and the contents of the empty area Can be used later as sound information different from the data to be decoded. Since the empty area is an area where data to be decoded is not recorded by the cell, the sound information display area is not easily affected by the cell, and the sound information display area can be configured more freely.

  According to the invention of claim 30, by causing the reading device to recognize the position of each predetermined figure represented in the information code, the reading device can recognize the pitch of each sound, and as a result, the sound information of the information code It is possible to realize a configuration capable of satisfactorily transmitting the melody recorded in the display area to the reading device.

  According to the thirty-first aspect of the invention, it is possible to satisfactorily transmit a plurality of sound performance methods expressed in the sound information display area to the reader side through the information code.

  According to the invention of claim 32, it is possible to satisfactorily transmit at least one of the performance sound source, the performance speed, and the number of pitches that can be performed to the reader side through the information code, and play the melody. It is possible to further restrain the restrictions on doing.

  According to the invention of claim 33, the user who uses the information code visually recognizes the playing method of a plurality of sounds recorded in the sound information display area by looking at the entry position entered in the information code. On the reader side, it becomes easier to grasp the performance method more accurately by recognizing the entry position.

  According to the invention of claim 34, when the information code is generated, the performance method can be specified by the color or shape of the predetermined figure, so that it is more free without using a lot of complicated data for specifying the performance method. Easy to use melodies.

  According to the thirty-fifth aspect of the present invention, the position of the sound information display area can be more accurately specified at the time of reading due to the presence of the position data recorded in the information code.

  According to the invention of claim 36, the number of steps of the sound information display area can be arbitrarily set on the generation side, and the reading device can grasp the melody according to the number of steps assumed at the time of generation.

FIG. 1 is a schematic diagram schematically illustrating an information code utilization system according to the first embodiment of the present invention. FIG. 2 is a block diagram schematically illustrating an electrical configuration of an information code reading device that constitutes the information code utilization system of FIG. FIG. 3 is an explanatory diagram for conceptually explaining the data configuration of the information code used in the information code utilization system of FIG. FIG. 4 is an explanatory diagram for explaining another type of code corresponding to the information code used in the information code utilization system of FIG. FIG. 5 illustrates the correspondence between the arrangement of each data word in the information code generated by the information code generation apparatus constituting the information code utilization system in FIG. 1 and the arrangement of each data word in another type of code. It is explanatory drawing to do. FIG. 6 is an explanatory diagram conceptually illustrating the format data of the information code used in the information code utilization system of FIG. FIG. 7 is a flowchart illustrating the flow of information code generation in the information code generation device constituting the information code utilization system of FIG. FIG. 8 is a flowchart illustrating the flow of reading an information code in the information code reading device constituting the information code utilization system of FIG. FIG. 9 is a schematic diagram schematically showing an information code used in the information code utilization system of FIG. FIG. 10 is an explanatory diagram showing an example of use of the information code of FIG. FIG. 11 is an explanatory diagram conceptually illustrating the configuration of the information code in FIG. 9, particularly the positional relationship in the empty area. FIG. 12 is an explanatory diagram for explaining data related to the sound information display area provided in the information code of FIG. FIG. 13 is an explanatory diagram illustrating an information code used in the information code utilization system according to the first modification of the first embodiment. FIG. 14 is an explanatory diagram illustrating an information code used in the information code utilization system according to the second modification of the first embodiment. FIG. 15 is an explanatory diagram illustrating an information code used in the information code utilization system according to the third modification of the first embodiment. FIG. 16 is an explanatory diagram for explaining an information code used in the information code utilization system according to the second embodiment, and FIG. 16 (A) is a diagram showing a state in which an empty area is left blank. ) Is a diagram showing a state in which a sound information display area is provided in an empty area. FIG. 17 is an explanatory diagram for explaining an information code used in the information code utilization system according to the third embodiment, and FIG. 17 (A) is a diagram showing a state in which an empty area is left blank, and FIG. ) Is a diagram showing a state in which a sound information display area is provided in an empty area. 18A is an explanatory diagram conceptually showing the data structure of the data to be decoded in the information code of FIG. 16, and FIG. 18B conceptually shows the data structure of the data to be decoded in the information code of FIG. It is explanatory drawing shown, FIG. 19A is an explanatory diagram for explaining an information code used in an information code utilization system according to another embodiment, and FIG. 19B explains an information code different from FIG. 19A. It is explanatory drawing. FIG. 20 illustrates the correspondence between the arrangement of each data word in the information code generated by the information code generation apparatus constituting the information code utilization system in FIG. 1 and the arrangement of each data word in another type of code. FIG. 6 is a diagram illustrating a correspondence relationship different from that in FIG. 5.

[First embodiment]
Hereinafter, a first embodiment embodying the present invention will be described with reference to the drawings.
An information code utilization system 1 shown in FIG. 1 is generated by an information code generation device 2 that generates an information code 100 in which cells serving as units for displaying information are arranged in a predetermined code area, and an information code generation device 2. The information code reading device 10 for reading the information code 100 is provided.

(Information code generator)
The information code generation device 2 is configured as an information processing device such as a personal computer, for example, and includes a control unit 3 including a CPU, an operation unit 4 including a keyboard, a mouse, and other input devices, a ROM, a RAM, and an HDD. A storage unit 5 including a storage device such as a nonvolatile memory, a display unit 6 including a known display device (liquid crystal display or other display device), and a communication interface for performing wired communication or wireless communication with an external device. And a printing unit 8 (printing apparatus) that has the same hardware configuration as a known printer and can print the information code 100 or the like based on print data from the control unit 3. Yes.

(Information code reader)
Next, the overall configuration of the information code reader 10 will be described. As shown in FIG. 2, the information code reader 10 is configured as a code reader capable of reading a two-dimensional code in hardware or a portable information processing terminal such as a mobile phone or a smartphone, and is not illustrated. An outer case is formed by the case, and various electronic components are accommodated in the case.

  The information code reader 10 mainly includes an optical system such as an illumination light source 21, a light receiving sensor 23, a filter 25, and an imaging lens 27, and a micro memory such as a memory 35, a control circuit 40, an operation switch 42, and a liquid crystal display device 46. A computer (hereinafter referred to as “microcomputer”) system and a power system such as a power switch 41 and a battery 49 are configured. These are mounted on a printed wiring board (not shown) or housed in a case (not shown).

  The optical system includes an illumination light source 21, a light receiving sensor 23, a filter 25, an imaging lens 27, and the like. The illumination light source 21 functions as an illumination light source capable of emitting illumination light Lf, and includes, for example, a red LED and a diffusion lens, a condensing lens, and the like provided on the emission side of the LED. In the present embodiment, illumination light sources 21 are provided on both sides of the light receiving sensor 23, and the illumination light Lf can be irradiated toward the reading object R through a reading port (not shown) formed in the case. It is configured. As the reading object R, for example, various objects such as a resin material and a metal material are conceivable, and an information code 100 (described later) as shown in FIG. 1 is formed on the reading object R by printing or the like. ing.

  The light receiving sensor 23 corresponds to an example of an “imaging unit” that can image the information code 100 (described later), and is configured to receive the reflected light Lr irradiated and reflected on the reading object R and the information code 100. Thus, for example, an area sensor in which light receiving elements, which are solid-state imaging elements such as C-MOS and CCD, are two-dimensionally arranged corresponds to this. The light receiving sensor 23 is mounted on a printed wiring board (not shown) so that incident light incident through the imaging lens 27 can be received by the light receiving surface 23a.

  The filter 25 is an optical low-pass filter that allows passage of light having a wavelength less than or equal to the wavelength of the reflected light Lr, for example, and can block passage of light exceeding the wavelength, and a reading port (not shown) formed in the case. And the imaging lens 27. Thereby, unnecessary light exceeding the wavelength equivalent of the reflected light Lr is prevented from entering the light receiving sensor 23. Further, the imaging lens 27 is constituted by, for example, a lens barrel and a plurality of condensing lenses accommodated in the lens barrel. In the present embodiment, the imaging lens 27 is provided at a reading port (not shown) formed in the case. The incident reflected light Lr is collected, and a code image of the information code 100 is formed on the light receiving surface 23 a of the light receiving sensor 23.

  The microcomputer system includes an amplification circuit 31, an A / D conversion circuit 33, a memory 35, an address generation circuit 36, a synchronization signal generation circuit 38, a control circuit 40, an operation switch 42, an LED 43, a buzzer 44, a liquid crystal display device 46, and a communication interface 48. Etc. This microcomputer system is configured around a control circuit 40 and a memory 35 that can function as a microcomputer (information processing apparatus), and the image signal of the information code 100 captured by the optical system described above is signaled in hardware and software. It can be processed.

  An image signal (analog signal) output from the light receiving sensor 23 of the optical system is input to the amplification circuit 31 and amplified by a predetermined gain, and then input to the A / D conversion circuit 33, and the digital signal is converted from the analog signal. Is converted to The digitized image signal, that is, image data (image information) is input to the memory 35 and stored in the image data storage area of the memory 35. The synchronization signal generation circuit 38 is configured to generate a synchronization signal for the light receiving sensor 23 and the address generation circuit 36. The address generation circuit 36 is based on the synchronization signal supplied from the synchronization signal generation circuit 38. Thus, the storage address of the image data stored in the memory 35 can be generated.

  The memory 35 is composed of a semiconductor memory device or the like, and corresponds to, for example, a RAM (DRAM, SRAM, etc.) or a ROM (EPROM, EEPROM, etc.). In addition to the above-described image data storage area, the RAM of the memory 35 is configured to be able to secure a work area and a reading condition table that are used by the control circuit 40 in each processing such as arithmetic operation and logical operation. . The ROM stores in advance a predetermined program that can execute a reading process and the like that will be described later, and a system program that can control each piece of hardware such as the illumination light source 21 and the light receiving sensor 23.

  The control circuit 40 is a microcomputer capable of controlling the entire information code reader 10, and includes a CPU, a system bus, an input / output interface, and the like, and has an information processing function. Various input / output devices (peripheral devices) are connected to the control circuit 40 via a built-in input / output interface. In this embodiment, a power switch 41, an operation switch 42, an LED 43, a buzzer 44, A liquid crystal display device 46, a communication interface 48, and the like are connected. In addition, a host computer HST corresponding to the host system of the information code reader 10 can be connected to the communication interface 48.

  The power supply system includes a power switch 41, a battery 49, and the like. When the power switch 41 managed by the control circuit 40 is turned on and off, the conduction of the drive voltage supplied from the battery 49 to each device and each circuit described above is established. Or shut off is controlled. The battery 49 is a secondary battery that can generate a predetermined DC voltage, and corresponds to, for example, a lithium ion battery.

(Information code)
Next, the information code 100 used in the information code using system of FIG. 1 will be described with reference to FIGS. The example of FIG. 1 and the example of the right side of FIG. 5 are slightly different in the cell arrangement and the size of the specific pattern, but the basic idea is the same and has the same characteristics. The information code 100 shown in FIG. 1 and FIG. 5 is generated by, for example, the information code generation device 2 described above, and has a configuration in which cells 102 serving as units for displaying information are arranged inside a predetermined code area. It has become. In the information code 100 of FIGS. 1 and 5, the “code region” is a rectangular region that can include all of the plurality of dark cells arranged. Specifically, three position detection patterns (cutout symbols) ) The smallest square area or rectangular area including all 104. In the example of FIGS. 1 and 5, the plurality of cells 102 are configured by either a rectangular (for example, a square outer diameter) light (white) cell or a dark (black) cell, Within the code area, these cells 102 are arranged in a matrix around an empty area 110 described later. The light color cell and the dark color cell are not limited to the white cell and the black cell, respectively. When the dark color cell is configured with a predetermined lightness, the light color cell only needs to have a higher lightness. In the information code 100, a light or dark margin area is formed around the code area so as to surround the code area. In the examples of FIGS. A margin area (for example, another color having a lightness higher than that of a white or dark cell) is arranged adjacent to the periphery of the code area.

  The information code 100 includes data in a specific pattern area in which a specific pattern having a predetermined shape is arranged inside a rectangular code area (for example, a square shape or a rectangular shape), and a plurality of types of cells 102. A data recording area for recording and an error correction code recording area for recording an error correction code by a plurality of types of cells 102 are provided. As shown in FIGS. 1 and 5, the specific pattern of the information code 100 is, for example, a known predetermined model number of a QR code (registered trademark) (in the example of FIG. 5, a predetermined model number of a QR code standardized by JIS or the like). ), The position detection pattern (cutout symbol) 104 as the specific pattern is arranged at each of the three corners of the code area in the examples of FIGS. ing. In addition, a timing pattern, alignment pattern, and the like similar to the QR code may be provided as the specific pattern. In this way, in the information code 100, a specific pattern having a predetermined shape (position detection pattern 104 in the example of FIG. 1) is arranged at a predetermined position. It should be noted that, within the code area, positions other than the empty area 110, which will be described later, are configured by such specific pattern areas, recording areas (areas consisting of either data recording areas or error correction code recording areas), and the like. Yes.

  The number of rows and columns of cells of the information code 100, the shape and position of a specific pattern, the position of format information, the codeword candidate position (address for specifying the arrangement order of codewords), etc. You may grasp. For example, a plurality of model numbers may be provided in the type of the information code 100. In this case, the number of rows and columns of cells, the shape and position of a specific pattern, the position of format information, and a code word are arranged for each model number. The candidate position (address) may be determined in advance. If the model number information for specifying the model number is arranged at a predetermined position (reserved area) in the code area, the reader device can determine the number of rows and columns of cells of the information code 100 based on the model number information. It becomes possible to grasp the shape and position of the specific pattern, the position of the format information, and the candidate position (address) of the code word. Note that the present invention is not limited to this method, and any other method may be used as long as the reader can grasp the method.

  In the code area, the cell 102 is an area where the data to be decoded is not recorded and is not subject to error correction by the error correction code at positions other than the specific pattern area, data recording area, and error correction code recording area. An empty area 110 that is an area is provided in a size larger than the size of the single cell 102. In the examples of FIGS. 1 and 5 and the like, the data recording area and the error correction code recording area are arranged in an annular and rectangular shape along the periphery of the code area, and the center of the code area (the center of the code area is defined). The empty area 110 is formed in a circular shape in a predetermined area. The “area where the decoding target data is not recorded by the cell 102” means an area in which data to be decoded (decoding target data) is not recorded in the data recorded in the data recording area. The empty area 110 is an area in which such decryption target data is not recorded. More specifically, the empty area 110 is an area where a code word such as a data code word and an error correction code word, which will be described later, is not recorded, and an area where no format information is recorded. The empty area 110 is an “area that is not subject to error correction by the error correction code”, that is, an area in which error correction using the error correction code recorded in the error correction code recording area is not performed. It has become. Therefore, even if some information (additional information to be described later) is recorded in the empty area 110, error correction for the information is performed by the error correction code in the error correction code recording area existing around the empty area 110. Absent.

  In the following description, a configuration corresponding to the predetermined model number as shown in the right diagram of FIG. 5 is associated with another model number (Ver. Number) having a smaller size than the predetermined model number as illustrated in the left diagram of FIG. An example in which the position of each code word of the information code 100 in the right diagram of FIG. 5 and the position of each code word of the other code 120 in the left diagram of FIG. 5 are associated by the arrangement conversion table as shown in the lower diagram of FIG. Will be described as a representative example. In this example, the amount of data that can be stored in the other type code 120 in the left diagram of FIG. 5 can be expressed with the empty area 110 provided by the information code 100 as shown in the right diagram of FIG. Conversely, when the information code 100 shown in the right diagram of FIG. 5 is read, each code word of the information code 100 can be read as a code word of another type code 120 as shown in the left diagram of FIG. .

  Further, in the right diagram of FIG. 5, each codeword area arranged around the empty area 110 is conceptually indicated by a one-dot chain line frame, a broken line frame, or the like. An area (predetermined position 105) for recording format information is conceptually indicated by a predetermined type of hatching. In the right diagram of FIG. 5, in the area where the format information is recorded and the area where the code word is recorded, only the squares are shown, and the specific arrangement of light cells and dark cells is omitted. Further, in the example of the right diagram in FIG. 5, the interior of the empty area 110 (the central part of the code area) is also assigned to correspond to the cell arrangement, but the configuration of the empty area 110 is free, and FIG. It may be configured as described above, or may be other configurations.

  The format information (format information) is configured as shown in FIG. 6, for example, and is recorded in a specific format configuration at a predetermined position 105 (a predetermined type of hatching position) in the information code 100 shown in FIG. This format information includes correction level information for specifying an error correction level and mask number information for specifying a mask number. The correction level information is information for specifying an error correction level used in the information code 100, and corresponds to an error correction level used in the other type code 120 in the case of being converted into the other type code 120 and read, for example. The mask number is information for specifying which mask type is the mask applied to the codeword area of the information code 100 (area in which the data codeword and error correction codeword are recorded).

  As shown in FIG. 6, the format information is recorded in a state reflecting a predetermined type of mask pattern (specific mask), and the format information is identified by identifying the mask type of the format information in the same manner as a known QR code. 5 It is possible to detect that a specific code type (type provided with a free area 110) as shown in the right figure. For example, when the model 1 is configured as a QR code of a known standard, data (cell array) expressed when the model 1 mask is applied to the format information as shown in FIG. 6 is recorded at a predetermined position. However, when configured as the model 2, data (cell array) expressed when the model 2 mask is applied to the format information as shown in FIG. 6 is recorded at a predetermined position. . On the other hand, in the information code 100 of this embodiment shown in FIG. 5 (special type code having a free area 110), a specific mask of a different type from the models 1 and 2 (FIG. 6) for the format information as shown in FIG. Then, the data (cell array) expressed when the frame QR is used is recorded at a predetermined position 105. Then, in any of the types 1 and 2 of the known standard and the type of the information code 100, a check digit corresponding to the correction level (correction level information) and mask number (mask number information) to be recorded is added. Format information is configured, on which various types of masks can be applied. Specifically, mask processing is performed by a known method using various types of mask patterns, and the bit pattern after the mask processing is recorded at a predetermined position 105. Therefore, when the format information is recorded at the predetermined position 105 after applying a specific mask (example for frame QR in FIG. 6) to the format information like the information code 100, the information recorded at the predetermined position 105 in this way is recorded. If the mask process is canceled and decoded based on the specific mask, the check digit is matched, so that the type of the information code 100 can be specified. On the contrary, even if the data at the predetermined position 105 of the information code 100 is removed based on the masks of the model 1 and model 2, the check digit does not match. be able to.

  In this information code 100, after detecting a specific pattern (position detection pattern 104, etc.) and specifying the code area, code direction, and each cell position in the same manner as the known QR code, the same as the known QR code. By decoding the predetermined position 105 where the format information is recorded by the method, it is possible to identify the type of the information code 100 (special type having the empty area 110) according to the type of the mask that has been successfully decoded. Then, the error correction level used in the information code 100 can be specified by the decoded format information, and applied to the code word area of the information code 100 (the area where the data code word and the error correction code word are recorded by the cell). It is possible to specify the mask type.

  Further, in the present configuration, the decoding target data is not recorded by the cell and the error correction code is not recorded at a position other than the specific pattern area, the data recording area, and the error correction code recording area in the code area. The empty area 110 is provided in a size larger than the size of a single cell. A sound information display area 120 is provided inside the empty area 110. The sound information display area 120 represents a plurality of sounds by a predetermined figure 121 by a method different from the data recording method by the data recording area.

  The content recorded in the information code 100 has, for example, a configuration as shown in FIG. 3, header data (frame QR header) is set at the beginning of the data array, and input data (decryption target data) after the header data. ) Continues. In the example of FIG. 3, input data (data to be decoded) is compressed by, for example, a known method and converted into a data word (data code word). However, such compression may not be performed. The header data used in the information code 100 is also referred to as a “frame QR header” in the following description. Further, in this specification, such an area for recording data words (data code words) of header data and input data (data to be decoded) and an area for recording the above-described format information correspond to “data recording areas”. To do. Further, in the example of FIG. 3, as header data (frame QR header), another type code 120 (a code type used for decoding the information code 100, which will be described later), and the information code 100 according to the arrangement conversion table (FIG. 5). Information (identified as Ver. Number in FIG. 3) and identification information that can specify the format in the empty area are recorded.

  More specifically, as header data, for example, information (canvas utilization format information) for specifying the utilization format of the empty area 110, position information, and the like are recorded in addition to the type (Ver. Number) of other types of codes. Yes. Specifically, information as shown in FIG. 12 is recorded, information for specifying the utilization format of the empty area 110 (canvas utilization format information), information for identifying the position of the image area, and the position of the sound information display area. Information for specifying, information for specifying the number of steps of the sound information display area, and the like are recorded. The information (canvas utilization format information) for identifying the utilization format of the empty area 110 includes information on whether or not to include a mark sheet area, information on whether or not to include an image area, and an area for recognizing symbol information such as characters and numbers. Information on whether or not to include the sound information display area is recorded. In addition, when information indicating whether or not to include a mark sheet area is recorded, information specifying the position of the “mark sheet area” (the coordinates of the mark sheet area in the code area are The specified mark sheet area position information) is recorded. Similarly, when information indicating whether or not an image area is included is recorded, information specifying the position of the “image area” (the coordinates of the image area in the code area are The specified image position information) is recorded. Further, when information indicating “including an OCR area” is recorded as information indicating whether or not an OCR area for recognizing symbol information such as characters and numbers is included, information for specifying the position of the “OCR area” ( OCR area position information for specifying the coordinates of the OCR area in the code area) is recorded. Therefore, when these areas are included, at the time of reading, the specific position of the area can be specified by position information for specifying the area.

  Furthermore, when information indicating whether or not to include a sound information display area is recorded, information specifying the position of the “sound information display area” (in the code area) (Score position information for specifying the coordinates of the sound information display area) is recorded. In addition, information for specifying the position of musical score columns, information for specifying a sound source that plays the sound recorded in the sound information display area, and the number of pitches (number of scales) recorded in the sound information display area Information to specify, information to specify the performance speed of playing the sound recorded in the sound information display area (for example, information to specify the time between sounds, information to specify the performance time of all sounds) It is to be recorded. As other information, URL information, e-mail address information, and the like are also recorded.

  In this configuration, as shown in FIG. 9, the sound information display area 120 represents the height of each of a plurality of sounds by the position of a predetermined figure 121 corresponding to each sound. For example, in the sound information display area 120 of FIG. 9, a plurality of lines (specifically, 10 lines) extending in parallel in the horizontal direction are arranged at equal intervals in the vertical direction, and each line corresponds to the pitch of the sound. doing. The information specifying the musical score column position is information (step number data) specifying whether to use these 10 line areas as a 1-stage area or a 2-stage area. . For example, if the information specifying the musical score column position is “1”, it indicates that the area of 10 lines is used as the area of the first line, and the position of the lowest line in the sound information display area 120 Is the lowest sound, and the upper line is used so that the sound is higher. If the information specifying the score column position is “2”, the upper five line area is used as the upper area, and the lower five line area is used as the lower area. Indicates use. In this case, in the area of the upper five lines (upper area), the position of the uppermost line is used as the highest sound, and the lower line is used so that the sound is lower. In the lower five line area (lower area), the position of the uppermost line is set to the highest sound (the same sound as the height of the uppermost line in the upper stage). Use so that the sound is low.

  Further, in this configuration, one or a plurality of sound sources are specified by “information for specifying a sound source” recorded as shown in FIG. 12, and the sound recorded in the sound information display area 120 by the sound source is read by the reading device 10. Can be played. For example, when “piano” is recorded as “information for identifying a sound source”, the sound recorded in the sound information display area 120 is played with the sound source of the piano. In addition, as “information for specifying the performance speed”, for example, information for specifying the time between sounds, information for specifying the performance time of all sounds, and the like are recorded. The sound recorded in the sound information display area 120 can be played at the performance speed specified by the information. In addition, as shown in FIG. 12, information for designating “the number of pitches that can be played” (for example, information for designating whether the pitch is five or ten) is recorded. The reader 10 can play the sound recorded in the sound information display area 120 with the number of sounds specified by the “number of playable sounds”. Note that the number of sounds can be recognized as the position of each sound if the area of 10 lines is used as a one-stage area, for example, if it is recorded as 10 sounds. In addition, when the area of five lines is used as a one-stage area and is used as an upper and lower two-stage area, for example, if recorded as five sounds, the position of each line can be recognized as the position of each sound.

  In the data configuration shown in FIG. 3, an error correction code word (ECC word) that becomes an error correction code follows the input data (data word that is data to be decoded). In the information code 100, an area for recording the error correction code is an error correction code recording area. Note that a method for generating an error correction code (error correction code word) based on a data word (in the example of FIG. 3, header data and input data (data to be decoded)) is a known two-dimensional code (such as a QR code). A method defined in the standard can be used. For example, as a method for generating an error correction codeword based on a data word (data codeword), an error correction codeword generation method (JISX0510: 2004, 8.5 error correction) defined in JISX0510: 2004 is used. be able to. Note that the method of generating the error correction codeword is not limited to this, and various known methods can be used.

  Further, in the information code 100, each data word (data code word) representing the data to be decoded (data code word) and an error correction code word are arranged in the code area based on predetermined arrangement position information. In this configuration, as shown in FIG. 5, the arrangement candidate positions of the respective code words are determined in advance within the code area of the information code 100, and a number (address) is assigned to each arrangement candidate position. The arrangement position information is information for specifying which arrangement candidate position each code word constituting the recording contents shown in FIG. 3 should be arranged. In the example of the right diagram in FIG. 5, the arrangement candidate positions Nos. 1 to 25 are schematically illustrated. In each arrangement candidate position, the first and last bit portions are numbered and clearly shown. In the right diagram of FIG. 5, the arrangement candidate positions after the 26th are omitted.

  Specifically, in the model number of the other type code 120 (known QR code) (the model number of the other type code 120 specified by the header data shown in FIG. 3), the code word in each order is included in the other type code 120. Whether or not to be arranged at a position is determined in advance by a known standard or the like, and when the other-type code 120 is decoded, the code words in each order are decoded based on the arrangement determined in this way. For example, in the example of the other type code 120 shown in the left diagram of FIG. 5, the 0th code word is arranged at the lower right, the first code word is arranged thereon, and the second code word is arranged thereon. The arrangement position of each code word is determined in advance. Therefore, when decoding this other type code 120, the 0th code word, the 1st code word, the 2nd code word, the 3rd code word, etc. based on the arrangement determined in this way. It will be deciphered in order.

  On the other hand, in the arrangement position information (arrangement conversion table) shown in FIG. 5, the numbers of the arrangement positions (arrangement positions of the code words in each order) determined in advance by the other-type code 120 in this way are pre- Each number is associated with a number of a determined candidate position (position candidate position of each code word). Specifically, “the arrangement position of the first code word in the other type code 120 corresponds to the first arrangement candidate position of the information code 100”, “the arrangement position of the second code word in the other type code 120 is information. Information such as “corresponding to the second arrangement candidate position of the code 100” and “the arrangement position of the third code word in the other type code 120 corresponds to the third arrangement candidate position of the information code 100” is, for example, table data Each code word is recorded, and the arrangement position of each numbered code word in the other type code 120 is associated with each arrangement candidate position of the information code 100. Thus, when the information code 100 is decoded, the code word (code word at each address) in each placement candidate position in the code area is associated with the placement position information (placement conversion table). The other-type code 120 may be rearranged at each arrangement position, and the other-type code 120 rearranged in this way may be decoded by a known method. For example, when the information code 100 is decoded using the arrangement conversion table shown in the lower diagram of FIG. 5, the code word at the first arrangement candidate position of the information code 100 is changed to the arrangement position of the first code word in the other type code 120. The code word at the second placement candidate position of the information code 100 is placed at the placement position of the second code word in the other code 120, and the code word at the Nth placement candidate position of the information code 100 is placed in the other kind. The code 120 is rearranged in such a manner as to be arranged at the arrangement position of the M-th code word associated with the N-th arrangement candidate position, and the other type code (re-arranged in this way) QR code) may be decoded by a known method. As for the above-described arrangement position information (arrangement conversion table), data (common arrangement conversion table) common to the information code generation apparatus 2 that generates the information code 100 and the information code reading apparatus 10 that reads the information code 100 are respectively provided. It is desirable to be provided.

(Information code generation process)
Next, an information code generation process and an information code generation method will be described with reference to FIG. In the following, a case where the other type code 120 is a QR code (registered trademark) and the information code 100 has a specific pattern similar to the QR code as shown in FIG. 5 will be described as an example. In this example, the information code 100 having the empty area 110 is also referred to as “frame QR”.

  The information code generation process of FIG. 7 is a process performed by the information code generation device 2 and is started by a predetermined operation on the operation unit 4, for example. In this processing, first, data to be encoded from outside (decoding target data), attribute data, and code type data (information code 100 is generated, or a general two-dimensional code (for example, a general QR code) is generated. (Data specifying whether to generate) (S1). In this configuration, the control unit 3 and the operation unit 4 correspond to an example of a “data acquisition unit” and function to acquire data to be decoded (input data from the outside). Further, the present invention is not limited to such an example. For example, the control unit 3 and the communication unit 7 may be configured as a “data acquisition unit” and function to acquire data input from outside through communication as decryption target data. Good.

  After acquiring the data in S1, a method for compressing the acquired data is determined by a known method (S2), and the compressed data (decoded data) is expressed by a plurality of data words (data code words). (S3). Then, after S3, it is determined whether or not the code type data acquired in S1 is the type (frame QR) of the information code 100 having the free space 110. If the code type data acquired in S1 is the type of the information code 100 having the free area 110 (frame QR), the process proceeds to Yes in S4, and the type of the information code 100 having the free area 110 (frame QR). ) Is generated and set at the head of the data array including a plurality of data words as shown in FIG. 3 (S5). As described above, the header data in FIG. 3 includes information (version number information and the like) that can specify the type (model number) of the other type code 120 shown in the right diagram of FIG. Information for specifying the utilization format of the information, information for specifying each position of the image area, the sound information display area, and the like) are recorded. On the other hand, when the code type data acquired in S1 is not the type (frame QR) of the information code 100 having the free area 110 (data for selecting a general two-dimensional code (for example, model 1 or model 2 is selected). If (data), the process proceeds to No in S4.

  When the process proceeds to No in S4, an error correction code is generated by a known method based on the configuration of the data word (data code word) generated in S3, and a plurality of error correction words (error correction) representing the error correction code are generated. Codeword) is generated (S6). On the other hand, when proceeding from S4 to S5, an error correction code is generated by a known method based on the configuration of the final data word (a plurality of data code words representing header data and input data) generated in S3 and S5. Then, a plurality of error correction words (error correction code words) representing the error correction code are generated (S6).

  After S6, it is determined whether or not the code type data acquired in S1 is the type (frame QR) of the information code 100 having the free area 110 (S7), and the code type data acquired in S1 is If it is not the type (frame QR) of the information code 100 having the free area 110, the process proceeds to No in S7, and a two-dimensional code (for example, QR code) is generated by a known method. When the process proceeds to No in S7, the model number of the two-dimensional code having a size capable of storing the data word (data code word) generated in S3 and the error correction word (error correction code word) generated in S6 (in this example, In a plurality of standardized known QR code model numbers, a model number of a size that can store the data word generated in S3 and the error correction word generated in S6) is determined, and the arrangement predetermined by the model number is determined. According to the pattern, the data word generated in S3 and the error correction word generated in S6 are arranged (S9).

  On the other hand, if the code type data acquired in S1 is the type (frame QR) of the information code 100 having the free area 110, the process proceeds to Yes in S7, and the data word (data) generated in S3 and S5 (Code word), the error correction word (error correction code word) generated in S6, and the empty area, the model number of the information code 100 that can be stored is determined (S10). Note that the size of the empty area may be a predetermined fixed size, or may be designated by an input or the like by the user before S10. Further, the size of the empty area may be specified by the number of rows and the number of columns, or may be specified by information such as how many words it corresponds to, or how many cells it corresponds. In the example of FIGS. 5 and 8, for example, in a plurality of model numbers (sizes) determined in advance by the type of the information code 100, the data word (data code word) generated in S3 and S5 and the error correction generated in S6 A model number of a size that can store a word (error correction code word) and an empty area is determined. When a plurality of model numbers can be used in the type of the information code 100, the number of rows and the number of columns, the shape and layout of a specific pattern, the layout of format data, and the layout candidate position of each code word are provided for each model number. It should be determined. Also, in any model number, the arrangement candidate positions of the respective code words are determined in order from the outer circumference side as shown in the right diagram of FIG. 5 (for example, the arrangement candidate positions are set in a spiral shape from the outer circumference side to the inside). The placement candidate position of each code word is determined so that the placement candidate position with a smaller number is located outside, and a portion where the code word is not placed (that is, a portion that is not used) among the prepared placement candidate positions. If it uses, it becomes easy to ensure a large empty area | region by the center part. In addition, when there are a plurality of model numbers having a size capable of storing the data word (data code word) generated in S3 and S5, the error correction word (error correction code word) generated in S6, and the empty area, The smallest model number (size) may be determined from among them, or the user may be able to specify any model number (size) from among them. When the information code 100 is generated, a predetermined size (number of rows and columns), a specific pattern arrangement, and each arrangement position position of the codeword are used in the model number thus determined. The arrangement position of each code word is determined according to the above-described arrangement conversion table. In the following, an example in which the model number as shown in the right diagram of FIG. 5 is determined in S10 will be specifically described.

  After S10, the data word (data code word) generated in S3 and S5 and the error correction word (error correction code word) generated in S6 are arranged based on the arrangement position information (arrangement conversion table) described above. It will be. In the information code generation device 2, the above-described arrangement position information (arrangement conversion table) is stored in the storage unit 5, and in this arrangement conversion table, as described above, each arrangement position (each (Order position of code word) is associated with a predetermined candidate position (position candidate position of each code word) in information code 100, respectively. In the process of S11, the code words to be recorded (the data words (data code words) generated in S3 and S5 and the error correction words (error correction code words) generated in S6) are shown in the left of FIGS. Is represented by another code 120 (a two-dimensional code having a size smaller than that of the information code 100 and a size capable of storing the data word generated in S3 and S5 and the error correction word generated in S6). After specifying the arrangement position of each code word (code word in each order), the code word in each order is associated with the arrangement position of the code word in each order by arrangement position information (arrangement conversion table). It arrange | positions in each arrangement | positioning candidate position in the information code 100. FIG. For example, in the arrangement position information (arrangement conversion table) in FIG. 5, the arrangement position of the first code word in the other type code 120 is associated with the first arrangement candidate position of the information code 100. The first code word of the code words to be recorded (the data word generated in S3 and S5 and the error correction word generated in S6) is arranged at the first arrangement candidate position in the information code 100. In addition, since the second code word arrangement position in the other-type code 120 and the second arrangement candidate position of the information code 100 are associated with each other, the second code word in the code words to be recorded Is placed at the second candidate position in the information code 100. In this way, the arrangement position (an arrangement position of the Nth code word) in the other type code 120 in which the Nth code word is arranged in the codeword to be recorded and the Mth arrangement candidate position of the information code 100 are as follows. If they are associated, the Nth codeword among the codewords to be recorded is arranged at the Mth arrangement candidate position in the information code 100.

  That is, only the data word generated in S3 and S5 and the error correction word generated in S6 can be expressed by another type code 120 (configured as a known QR code) smaller than the information code 100. When the data word generated in S3, S5, the error correction word generated in S6, and the empty area 110 are stored, it must be expressed by the information code 100 having a larger size. Therefore, in the present embodiment, the data word generated in S3 and S5, the error correction word generated in S6, and the empty area 110 are represented by the information code 100 having a size larger than the other type code 120, and S3 and S5. The data word generated in step S6 and the error correction word generated in step S6 are stored in the arrangement of the code words when expressed by another type code 120 (known QR code) and the information code 100 having a size larger than this. In this case, the correspondence relationship with each arrangement of codewords can be specified by a predetermined arrangement conversion table.

  In this configuration, the “arrangement conversion table” as shown in FIG. 5 corresponds to an example of “arrangement position information for specifying each arrangement position when a plurality of data words expressing the data to be decoded are arranged in the code area”. The arrangement conversion table (arrangement position information) includes data words in each order when the data to be decoded is expressed by a plurality of data words, and each arrangement position in the code area of the data words in each order. Are configured as information determined in association with each other. The storage unit 5 corresponds to an example of an “arrangement position information recording unit” and functions to record data (arrangement position information) of such an arrangement conversion table.

  After S9 or S11, a mask pattern to be applied to the code word whose placement location has been determined in S9 or S11 is determined by a known predetermined method (for example, a known method used in QR code), and the determined mask. Masking is performed by a known mask processing method so that the pattern is reflected in the code word whose location is determined in S9 or S11 (S12). Then, the check digit is calculated based on the mask pattern information (mask number) and error correction level information set in S12, and the format information including the error correction level, mask number, and check digit is generated as shown in FIG. (S13). Note that data such as a mask number and an error correction level to be recorded as format information may be input in S1.

  If the code type data acquired in S1 is the type (frame QR) of the information code 100 having the free area 110, the process proceeds to Yes in S14, and the format information generated in S13 includes the above-described format information. Mask processing is performed to reflect the specific mask (frame QR mask) (see FIG. 6). On the other hand, if the code type data acquired in S1 is not the type (frame QR) of the information code 100 having the vacant area 110, the process proceeds to No in S14 and has a mask pattern different from the mask pattern set in S16. Set the mask (model 1 mask or model 2 mask). After masking the format information in S15 or S16, the format information after the mask processing is arranged at a predetermined position 105 in the code area (S17).

  After the specific pattern area, the data recording area, and the error correction area are thus configured, the constituent elements of the empty area 110 are arranged (S18). In the example of FIG. 9, the positions of the areas such as the image area, the sound information display area (musical score area), the mark sheet area, and the OCR area are specified as shown in FIGS. Specific figures, patterns, symbols, etc. are displayed at positions (see FIG. 11) specified by each position data as shown in FIG. Specifically, the mark sheet image data of the mark sheet area 140 is arranged at the position (position 140a in FIG. 11) designated by the information specifying the position of the “mark sheet area” in FIG. 12, and the position of the “image area” is set. The person image data of the image area 130 and the like are arranged at a position (position 130a in FIG. 11) designated by the information to be specified. Further, the graphic data of the OCR area 150 is arranged at the position (position 150a in FIG. 11) designated by the information specifying the position of the “OCR area”. Further, the musical score image of the sound information display area 120 is arranged at a position (position 120a in FIG. 11) designated by information specifying the position of the “sound information display area”. Such data specifying the position of the area and data specifying the specific contents in the area may be stored in advance in the storage unit 5 of the generating device 2 by data input from the outside, etc. You may make it request | require data transmission with respect to an external device at the time of an area | region production | generation.

  After the information code 100 or other two-dimensional code is generated in this way, the code is printed by the printing unit 8 (S19). In S19, instead of printing, the display unit 6 may display the information code 100 or the like, and the data of the information code 100 generated by the processing up to S17 is stored in an external device (for example, a portable terminal or a computer). Or other information equipment). For example, when the information code 100 as shown in FIG. 9 is generated by the process of FIG. 7, for example, as shown in FIG. You may make it print so that it may attach to a business card.

  In this configuration, the control unit 3 of the information code generation device 2 corresponds to an example of a “data recording area generation unit”. When the empty area 110 is provided inside the code area of the information code 100, the control section 3 is located at a predetermined position in the code area. Based on the arrangement position information recorded in the arrangement position information recording unit, the format information is recorded in a specific format configuration, and each data word representing the decoding target data (input data) acquired by the data acquisition unit is expressed. A data recording area is generated so as to be arranged. In addition, in the “data recording area generation unit” configured by the control unit 3, when the empty area 110 is provided inside the code area, the cell array at the predetermined position 105 reflects a predetermined type of mask pattern (specific mask). Is configured.

(Information code reading process)
Next, processing when the information code 100 shown in the right diagram of FIG. 1 and FIG. 5 is read by the information code reader 10 of FIG. 2 will be described. The reading process in FIG. 8 is executed, for example, when a predetermined operation (for example, operation of the operation switch 42) is performed by the user. First, as shown in S40 of FIG. A two-dimensional code in the area is imaged to obtain a captured image of the two-dimensional code, and the shape of the two-dimensional code (code outer shape) is detected. Specifically, the recognition of the position detection pattern 104 and the outer shape of the two-dimensional code are tried by a known method. For example, the position detection pattern 104 is detected by a known method for detecting a 1: 1: 3: 1: 1 waveform, which is performed with a QR code (registered trademark), and the outer shape of the imaged two-dimensional code is displayed as a QR code. Detection is performed by a known method performed by (registered trademark). At this time, when the information code 100 is imaged in S40, the outer shape of the information code 100 is detected. The processing method in S40 may be another method as long as it can detect the shape of the specific pattern and the outer shape of the two-dimensional code.
In this configuration, the light receiving sensor 23 corresponds to an example of an “imaging unit” and functions to image the information code 100 generated by the information code generation device 2.

  After S40, the information (format information) at the predetermined position 105 of the information code 100 is decoded, and the type and mask correction level of the imaged information code are acquired (S41). Specifically, for example, as described above, the information recorded at the predetermined position 105 is attempted to be decrypted by canceling the mask processing based on the above-described specific mask (frame QR mask). When the check digit matches when the mask processing is canceled by the above-described method for canceling the mask of the specific mask (that is, calculated based on the correction level data and the mask number data when the predetermined position 105 is decoded) When the check digit matches the check digit recorded at the predetermined position 105), it can be specified that the type of the information code 100 (the type having the free area 110), and error correction included in the format information The level and mask number can also be acquired. When the mask process can be canceled based on the specific mask as described above (that is, when it is recognized that the information code 100 is the type (frame QR)), the process proceeds to Yes in S42. On the other hand, when the mask processing can be canceled by a mask other than a specific mask (frame QR mask) such as the mask for model 1 and the mask for model 2 shown in FIG. 6, the process proceeds to No in S42. When the mask processing can be canceled by another mask, the two-dimensional code imaged in S40 is a known QR code, so when proceeding to No in S42, the QR code is decoded by a known method. The decryption result will be output. In FIG. 8, the process in the case of No in S42 is omitted.

  When the process proceeds to Yes in S42, first, the data recorded in the data recording area is decoded (S43). Specifically, the mask of the entire code (specifically, the area of the code word) is canceled based on the mask number included in the format information acquired in S41. Then, based on the header data (frame QR header) provided at the beginning of the data word, the original code size (the model number and format of the other type code 120) is specified, and the diagram is converted according to the same layout conversion table as in FIG. 5 Return from the information code 100 as shown in the right figure to the original code (another code 120) as shown in the left figure. Specifically, the code word (data code word and error correction code word) of each arrangement candidate position of the information code 100 is arranged in the other type code 120 associated with each arrangement candidate position in the arrangement conversion table. Reposition to the position. By performing the arrangement conversion in this way, another type code 120 in which the data code word and the error correction code word arranged in the information code 100 are recorded is obtained. Since the other type code 120 is a known QR code, the data is decoded by a method similar to the known QR code (that is, error correction calculation is performed by a known method based on the error correction code word). Decode the data code word).

  In this configuration, the control circuit 40 corresponds to an example of a “determination unit”, and when the information code 100 is captured by the imaging unit, it is determined whether or not the predetermined position 105 of the code area has a specific format configuration. To function. Specifically, it functions to determine whether or not a predetermined type of mask pattern (specific mask) is reflected at the predetermined position 105.

  The control circuit 40 corresponds to an example of a “data recording area reading unit” and a “decoding unit”. When the information code 100 is captured by the imaging unit, the data recording area in the code image of the captured information code 100 And functions to read data recorded in the data recording area based on the contents of the error correction code recording area. Specifically, when the determination unit determines that the predetermined position 105 has a specific format configuration (more specifically, when a predetermined type of mask pattern is reflected at the predetermined position 105), the correspondence information recording unit The position of each data word in the code area is specified based on the correspondence information (arrangement conversion table) recorded in (1), and the decoding target data is decrypted.

  The arrangement conversion table corresponds to an example of “correspondence information”, and a data word in each order represented by each arrangement position in the code area is determined in advance in another type code 120 different from the information code 100. It is configured as information for determining each corresponding position in the other type code 120 when expressed in (for example, a method defined in a known standard or the like). Then, when the determination unit determines that the predetermined position 105 has a specific format configuration, the control circuit 40 corresponding to the decoding unit converts the data word in each order represented by each arrangement position of the code area to the correspondence information The other-type code 120 functions in such a manner as to be replaced with each corresponding position in the other-type code 120 defined in (1).

  After S44, it is determined whether or not the information code 100 is in a format that uses the sound information display area (music box format) (S45). Specifically, in the canvas utilization data as shown in FIG. 12, information indicating that the sound information display area is used is recorded (for example, whether music is “use” as shown in FIG. 12). Judging. If the format using the sound information display area (music box format) is designated, the process proceeds to Yes in S45, and if it is not designated, the process proceeds to No in S45.

  When the process proceeds to Yes in S45, each position information included in the header data (frame QR header) as shown in FIG. 12 is read (S46). Specifically, the information for specifying the position of the “mark sheet area”, the information for specifying the position of the “image area”, the information for specifying the position of the “OCR area”, and the position of the “sound information display area” are described above. Read specific information. Furthermore, information for specifying the position of the musical score column, information for specifying the sound source playing the sound recorded in the sound information display area, and the number of pitches (scale number) recorded in the sound information display area Information for specifying, information for specifying a performance speed for playing a sound recorded in the sound information display area, information for specifying a URL, information for specifying an e-mail address, and the like are also read.

  After S46, information on each position acquired in S46 is acquired (S47). Specifically, the image of the image area 130 specified by the information of the image position, the information of the musical score position and the image of the sound information display area 120 specified by the information of the musical score column position, and the information of the mark sheet position are specified. The image of the mark sheet image area 140 and the image of the OCR image area 150 specified by the information of the OCR position are extracted. Then, processing corresponding to each image is performed.

  For example, for the image in the image area 130, the image is cut out and saved in a predetermined image format (for example, a bitmap format). Further, based on the image of the mark sheet image area 140 specified by the information on the mark sheet position, the specified content on the mark sheet is specified. Further, the entry content is specified based on the image of the OCR image area 150 specified by the OCR position information.

  In addition, regarding the image of the sound information display area 120, the sound information display area 120 is treated as a musical score, and the position of each predetermined figure 121 shown in the sound information display area 120 is specified. Specifically, a graphic 121 having a predetermined shape (black circle shape or black long circular shape in the example of FIG. 9) for identifying a sound is extracted from the sound information display area 120, and the vertical position of each predetermined graphic 121 is determined. Identify. Thereby, the pitch of each predetermined figure 121 is specified. In the sound information display area 120 of FIG. 9, the horizontal direction is the time axis and the vertical direction is the pitch of the sound, and each predetermined figure 121 is determined by the distance of each predetermined figure 121 from the left end of the sound information display area 120. The timing at which the sound of the figure 121 is played is specified. Then, in the reading device 10, in accordance with the image of the sound information display area 120 specified in this way, the sound content specified by the sound source, the number of sounds, and the reproduction speed acquired in S46, in order from the predetermined graphic 121 on the left side. A sound will be emitted. In this way, the melody expressed in the sound information display area 120 can be played.

In this configuration, after S47, the data acquired in S47 is output or stored (S48). When outputting or recording in this manner, a melody represented by the sound information display area 120 may be played from a speaker. Alternatively, music expressed in the sound information display area 120 may be output or recorded as data.
Further, in this configuration, the OCR area 150 can be an area for recording birthdays, visit dates, etc. In the mark sheet area 140, it can be determined whether the recorded contents of the OCR area 150 are birthdays or visit dates. It can be specified by the entry position. Further, in the reading apparatus 10 of this configuration, in S47, the image data in the image area 130, the data specifying the specified contents in the mark sheet area 140, the data specifying the recorded contents in the OCR image area 150, and the sound information display area 120 are displayed. If the electronic data of music recorded in is acquired, these data may be registered in association with each other. For example, when a personal name or the like is recorded in the data recording area, the personal name and each data acquired in S47 may be registered in association with each other as personal data specified by the personal name.

  The control circuit 40 corresponds to an example of a recording sound specifying unit, and specifies a plurality of sounds recorded in the sound information display area based on a predetermined graphic displayed in the sound information display area 120 in the code image. To function.

[Modification 1 of the first embodiment]
In the representative example of the first embodiment, the information code as illustrated in FIG. 9 is illustrated, but the configuration of the information code including the sound information display area is not limited to such an example. For example, it is good also as a structure like FIG. In the example of FIG. 13 as well, the sound information display area 120 similar to that of the first embodiment is provided in the empty area 110. And also in this sound information display area 120, the height of each of a plurality of sounds is expressed by the position of a predetermined figure corresponding to each sound.

  In the configuration of FIG. 13, an area for recording performance method designation data is provided in a peripheral area of the sound information display area 120 by a method different from the data recording method by the data recording area. In the configuration of FIG. 13, an entry area 160 is provided around the sound information display area 120 to specify the contents of a plurality of sound performance methods recorded in the sound information display area 120 by the entry position. In this entry area 160, the performance speed (reproduction speed) of a plurality of sounds recorded in the sound information display area 120 is specified by the entry position. Specifically, the performance speed (reproduction speed) is set to five levels, and it can be specified by filling the entry frame provided in the entry area 160 which of the five performance speeds is set. ing. In the reader 10, for example, the relationship between each entry position and the performance speed (reproduction speed) is grasped in advance, and the sound information display area 120 is displayed at the performance speed (reproduction speed) corresponding to the filled entry position. Play music.

  In addition, data specifying the relationship between each entry position and the performance speed (reproduction speed) may be recorded in the data recording area. In this case, the reading apparatus 10 has a fill position in the entry area 160. Which performance speed (reproduction speed) is to be supported is specified by the contents of the data recording area, and the music in the sound information display area 120 may be played at the specified performance speed (reproduction speed).

[Modification 2 of the first embodiment]
Moreover, it is good also as a structure like FIG. Also in the example of FIG. 14, the sound information display area 120 is provided inside the empty area 110. And also in this sound information display area 120, the height of each of a plurality of sounds is expressed by the position of a predetermined figure corresponding to each sound.

  Also in the configuration of FIG. 14, an area for recording performance method designation data is provided in a peripheral area of the sound information display area 120 by a method different from the data recording method by the data recording area. In the configuration of FIG. 14, entry areas 160, 170, and 180 that specify the contents of a plurality of sound performance methods recorded in the sound information display area 120 by the entry positions are provided in the peripheral area of the sound information display area 120. ing.

  In the entry area 160, the performance speed (reproduction speed) of a plurality of sounds recorded in the sound information display area 120 is specified by the entry position, as in the first modification. Specifically, the performance speed (reproduction speed) is set to five levels, and it can be specified by filling the entry frame provided in the entry area 160 which of the five performance speeds is set. ing.

  In the entry area 170, a performance sound source of a plurality of sounds recorded in the sound information display area 120 is specified by the entry position. Specifically, the performance sound source can be selected from the following three types: piano, music box, and guitar. Which of the three types of performance sound source is to be set is indicated in the entry frame provided in the entry area 170. It can be specified by filling. Note that the method for the reader 10 to know which sound source corresponds to the fill position may be the same as the method for grasping which performance speed the fill position corresponds to in the first modification.

  In the entry area 180, the number of pitches that can be played with the data recorded in the sound information display area 120 is specified by the entry position. Specifically, the number of pitches that can be played can be selected from two types of five tones and ten tones, and the entry region 180 indicates which of the two types is set. It can be specified by filling the filled-in entry frame. It should be noted that the method in which the reading device 10 grasps which sound number (sound pitch) corresponds to the filling position is the same as the method of grasping which playing speed corresponds to the filling position in the first modification. do it.

[Modification 3 of the first embodiment]
Moreover, it is good also as a structure like FIG. Also in the example of FIG. 15, the sound information display area 120 is provided inside the empty area 110. In the sound information display area 120, a plurality of performance methods are associated with at least one of the colors and shapes of the predetermined figures 123 representing the plurality of sounds in the sound information display area 120. It is configured to select from color candidates or a plurality of shape candidates. For example, the pitch of the sound is specified by the color expressed by the predetermined graphic 123, and the type of sound (for example, a sound source) can be specified by the shape of the predetermined graphic 123. The reading device 10 stores a shape of a predetermined figure and a sound type (sound source such as piano, guitar, music box, etc.) in association with each other, and each color and sound pitch are stored in association with each other. ing. When the reading apparatus 10 performs in accordance with such a sound information display area 120, the position of each figure 123 is extracted, and each figure is sequentially arranged from the upper row (the upper line in each of the five lines extending in the horizontal direction). A sound corresponding to 123 may be emitted. In each row, the corresponding sounds may be emitted in order from the left figure 123.

[Second Embodiment]
Next, a second embodiment will be described with reference to the drawings.
The information code utilization system of the second embodiment is the same as that of the first embodiment with respect to the hardware configuration, and the configuration shown in FIGS. 1 and 2 described above is used.

  In the information code utilization system of the second embodiment, the information code 200 as shown in FIG. 16B is generated by the information code generation device 2 (see FIG. 1 and the like). Even in this configuration, a specific pattern area in which a specific pattern 204 having a predetermined shape is arranged inside a code area in which a plurality of cells 202 are arranged in a matrix, and data in which data is recorded by a plurality of types of cells A recording area and a sound information display area 120 are provided. In the data recording area, a free area 210 is configured with the same display content as the free area 110 of the first embodiment.

  In this configuration, except for the configuration in the empty area 210, it is configured as a known QR code (registered trademark). First, as shown in FIG. 16A, a specific pattern area and data A recording area and an error correction code recording area for recording an error correction code by a plurality of types of cells are provided. The recording method of the data code word in the data recording area and the recording method of the error correction code word in the error correction code recording area are the same as those of the known QR code (registered trademark), for example, a method defined in JISX0510 The arrangement of the position detection pattern 204 in the code area, the arrangement of the data code word in the data recording area, and the arrangement of the error correction code word in the error correction code recording area are determined.

  However, as shown in FIG. 16A, an information code 200 ′ is generated in which the code word of the partial area AR is configured as a code word expressed only by white cells, and is thus expressed only by white cells. When the area AR is the empty area 210, the sound information display area 120 similar to that of the first embodiment is provided in the empty area 210, which is different from the original data display as shown in FIG. However, the data error in the empty area 210 may be corrected using a known error correction code recorded in the error correction code recording area.

  Further, in the information code 200 shown in FIG. 16B, the position of the empty area 210 is specified in advance, and therefore, when the design and information are added and displayed in the empty area 210, the error position due to this display is set in advance. I know that. Therefore, the error correction code in the error correction code recording area can be configured to perform erasure correction using the position of the empty area 210 as the error position. In this case, information indicating the position of the vacant area 210 is recorded in the data recording area in advance, or stored in the reading apparatus 10 (FIG. 1) in advance, so that the reading apparatus 10 can read the vacant area at the time of reading. The position of 210 (that is, the position of the data code word in which an error has occurred) can be specified, and the reader 10 can determine the position of the data code word existing in the empty area 210 whose position is specified in this way. In order to correct the error, the erasure correction may be performed using the error correction code recorded in the error correction code recording area.

  Further, when a part of the existing QR code (registered trademark) is configured as the empty area 210 as shown in FIG. 16, the identification information as shown in FIG. 18A is included in the data recorded in the data recording area. Just keep it. FIG. 18A conceptually shows the structure of the data to be decrypted recorded in the data recording area. In this example, data of a predetermined structure (%% MUSIC %%) is present at the beginning of the data to be decrypted. It is attached. With this configuration, the reading device 10 performs an analysis process of a free area when the identification information (%% MUSIC %%) is detected from the data to be decoded recorded in the data recording area. On the contrary, when the identification information identification information (%% MUSIC %%) cannot be detected, a normal decoding process is performed. In this example, it is desirable that data in the data recording area include data as shown in FIG. 12 in addition to normal data. Further, the data shown in FIG. 18 (A) indicates the data to be decoded that is arranged before the end terminal in the data recorded in the data recording area, and the padding that is arranged after the end terminal. The code is omitted. In this configuration, for example, the entire area of the padding code can be displayed with only white cells, and this area can be handled as the empty area 210.

  Moreover, the example of identification information is not restricted to this example, For example, you may make it use a mode number for exclusive use as a mode number. For example, in the QR code standard, 1: numerical mode, 2: alphanumeric mode, 3: concatenation mode, etc. are defined, and 14: free area analysis mode is provided as one of such mode numbers. Also good. In such an example, when the mode number “14” is set, the free area analysis process may be performed.

[Third Embodiment]
Next, a third embodiment will be described.
The information code utilization system of the third embodiment is the same as that of the first embodiment in terms of hardware configuration, and the configuration as shown in FIGS. 1 and 2 is used.

  In the information code utilization system of the third embodiment, the information code 300 as shown in FIG. 17B is generated by the information code generation device 2 (see FIG. 1 and the like). Even in this configuration, a specific pattern having a predetermined shape (an L-shaped alignment pattern 304a and light cells and dark cells are alternately arranged one by one inside a code region in which a plurality of cells 302 are arranged in a matrix. A specific pattern area in which timing cells 304b) constituting an L-shaped area along the boundary of the code area are arranged, and a data recording area for recording data by a plurality of types of cells are provided. , A free area 310 in which at least one of data recording and design display can be performed by a method different from the method of recording data in a data recording area at a position other than the specific pattern area, A predetermined size larger than the cell size is provided.

  In this configuration, except for the configuration of the empty area 310, it is configured as a known data matrix code. First, as shown in FIG. 17A, inside the code area, a specific pattern area, a data recording area, An error correction code recording area for recording an error correction code by a plurality of types of cells is provided. The recording method of the data code word in the data recording area and the recording method of the error correction code word in the error correction code recording area are the same as the known data matrix code, and the alignment pattern 304a and timing cell 304b in the code area are the same. The arrangement of the data code word in the data recording area and the arrangement of the error correction code word in the error correction code recording area are determined in accordance with, for example, the ECC200 version.

  However, as shown in FIG. 17A, an information code 300 ′ in which a code word of a partial region is configured as a code word represented only by white cells is generated, and thus the region represented only by white cells. With AR as a free area 310, a sound information display area 120 and the like similar to those of the first embodiment are provided in the free area 310 as shown in FIG. When the sound information display area 120 or the like similar to that of the first embodiment is provided in the empty area 310 as shown in FIG. 17B, the configuration is different from the original data display as shown in FIG. The data error in the empty area 310 may be known by performing a known error correction using an error correction code recorded in the error correction code recording area.

  In the information code 300 shown in FIG. 17B, the position of the empty area 310 is specified in advance. Therefore, when a design or information is added to the empty area 310 and displayed, the error position by this display is set in advance. I know that. Therefore, the error correction code in the error correction code recording area can be configured to perform erasure correction using the position of the empty area 310 as the error position. In this case, information indicating the position of the empty area 310 is recorded in the data recording area in advance, or is stored in the reading apparatus 10 (FIG. 1) in advance, so that the reading apparatus 10 can read the empty area at the time of reading. The position of 310 (that is, the position of the data code word in which an error has occurred) can be specified, and the reader 10 can determine the position of the data code word existing in the empty area 310 in which the position is specified in this way. In order to correct the error, the erasure correction may be performed using the error correction code recorded in the error correction code recording area.

  Further, when a part of the existing data matrix code is configured as the empty area 310 as shown in FIG. 17, the identification information as shown in FIG. 18B is included in the data recorded in the data recording area. Good. FIG. 18B conceptually shows the structure of the decryption target data recorded in the data recording area. In this example, data of a predetermined structure (%% MUSIC %%) is present at the beginning of the decryption target data. It is attached. With this configuration, the reader 10 performs an analysis process for the free area 310 when this identification information (%% MUSIC %%) is detected from the data to be decoded recorded in the data recording area. Conversely, when the identification information (%% MUSIC %%) cannot be detected, a normal decoding process is performed. In this example, it is desirable that the data in the data recording area includes position data for specifying the position of the image display area (image of the person to be registered) and other accompanying information in addition to the normal data. .

  Moreover, the example of identification information is not restricted to this example, For example, you may make it use a codeword for exclusive use. As data matrix code specifications, for example, when 0 to 128 are defined as ASCII characters and 233 as a connection mode, “234” may be newly defined as a special code word for image display area recognition. . In such an example, when the code word “234” is included in the data in the data recording area, the analysis process for the empty area 310 may be performed. In addition, when there is an unused code word, the unused code word is included as identification information, and when the unused code word is included in the data in the data recording area, the analysis of the empty area 310 is performed. Processing may be performed.

[Other Embodiments]
The present invention is not limited to the embodiments described with reference to the above description and drawings. For example, the following embodiments are also included in the technical scope of the present invention.

  In the above embodiment, the position data indicating the position of the sound information display area 120 is included in the information code 100, but the present invention is not limited to such an example. For example, the information code generation device 2 may be configured to generate the information code so that the sound information display area 120 is arranged at a predetermined position in the empty area. In this case, information for specifying a predetermined position (information such as position data of the sound information display area 120 shown in FIG. 12) may be stored in the storage unit 5. Further, in this case, the information code reading device 10 stores the specific information (information such as the position data of the sound information display area 120 shown in FIG. 12) in the memory 35 in the same manner as the information code generation device 2. You just have to. Then, in the information code reading device 10, in S <b> 47 of FIG. 8, such specific information is read from the memory 35 to specify the sound information display area 120, and the subsequent processing may be performed. In this case, the position data of the sound information display area 120 shown in FIG. 3 may not be included in the header data.

  The present invention can also be configured as a display device capable of displaying any one, plural, or all of the information codes described above. Moreover, it can also be configured as a printing apparatus capable of printing any one, plural or all of the information codes described above. Furthermore, it can also be configured as a computer-readable program for generating any one, plural or all of the information codes described above. Moreover, it can also be comprised as a recording medium which recorded the program for producing | generating the 1 or several or all the information code mentioned above. Furthermore, it can also be grasped as an information code medium (a printed material, a formed material formed by direct marking, etc.) to which one or a plurality of or all information codes are attached. Moreover, it can also be grasped as a display image on which one, a plurality, or all of the information codes described above are displayed.

  1 and the like show an example in which the information code generation device 2 and the information code reading device 10 are configured as separate devices, but the information code generation device 2 may be configured as the information code reading device 10. Good.

  In the above embodiment, an example in which the empty area 110 is provided in the center of the code area has been described, but the arrangement of the empty areas 110 is not limited to this example. For example, an empty area may be provided near the periphery of the code area.

  In the above embodiment, a QR code is taken as an example of the other type code, and a specific pattern of the QR code is given as an example of the specific pattern used in the information code 100. However, other types of two-dimensional codes may be used. For example, a data matrix code may be used as the other type code, and a specific pattern used in the information code 100 may be used as the specific pattern of the data matrix code.

  An example of an information code provided with an empty area in the code area and a sound information display area in the empty area is not limited to the example in the above embodiment. For example, as shown in FIG. 19 (A) and FIG. 19 (B), two or more information codes are provided, and data expressed by light cells or dark cells is arranged between the information codes, or a light / dark pattern is provided. The information code 400 (add-in code) that is integrally connected may be configured by arranging these designs, and the empty area 410 may be provided in the information code 400. The above-described sound information display area 120 (FIG. 1 and the like) and other related areas 130, 140 and 150 (FIG. 1 and the like) may be provided in the empty area 410.

  The correspondence in the arrangement conversion table set as shown in FIG. 5 can be arbitrarily changed as shown in FIG. For example, when the arrangement conversion table set as shown in FIG. 5 in the information code generation device 2 and the information code reading device 10 is changed as shown in FIG. 20, in the generated information code 100, the 22nd to 23rd codes The arrangement of words is from the arrangement shown in the right figure of FIG. 5 (the arrangement recorded in the arrangement candidate positions 22 to 23) to the arrangement shown in the right figure of FIG. 13 (the arrangement recorded in the arrangement candidate positions 42 to 43). As a result, the position and shape of the empty area 110 also change. In this case, the arrangement candidate positions Nos. 22 to 23 may be empty areas, or arrangement positions of other code words. That is, in this configuration, the position and shape of the empty area 110 can be adjusted by adjusting the arrangement conversion table, and the degree of freedom in configuring the empty area can be further increased.

DESCRIPTION OF SYMBOLS 1 ... Information code utilization system 2 ... Information code production | generation apparatus 10 ... Information code reader 23 ... Light receiving sensor (imaging part)
40... Control circuit (data recording area reading unit, recording sound specifying unit)
100 ... Information code 102 ... Cell 104 ... Position detection pattern (specific pattern)
110: Free area 120 ... Sound information display area

Claims (36)

An information code generation method for generating, by an information code generation device, an information code in which cells serving as units for displaying information within a predetermined code area are arranged,
A specific pattern area in which a specific pattern having a predetermined shape is arranged inside the code area, a data recording area for recording data by a plurality of types of the cells, and a data recording method by the data recording area An information code generation method characterized by providing a sound information display area for expressing a plurality of sounds by a predetermined figure by different methods. Inside the code area, an empty area, which is an area where data to be decoded is not recorded by the cell, is provided at a position larger than the size of the single cell at a position other than the specific pattern area and the data recording area. ,
The information code generation method according to claim 1, wherein the sound information display area is provided inside the empty area.   3. The information code generation method according to claim 1, wherein, in the sound information display area, each pitch of a plurality of sounds is expressed by a position of the predetermined figure corresponding to each sound. .   A structure in which performance method designating data for designating a performance method of a plurality of sounds expressed in the sound information display area is recorded in the data recording area, or data recording by the data recording area in a peripheral area of the sound information display area The information code generation method according to any one of claims 1 to 3, wherein the information code is generated with a configuration in which an area for recording the performance method designation data is provided by a method different from the method. .   5. The information code generation method according to claim 4, wherein the performance method designation data is data for designating at least one of a performance sound source, a performance speed, and a number of pitches that can be played.   The information code is generated with a configuration in which an entry area for specifying the contents of a plurality of sound playing methods recorded in the sound information display area by an entry position is provided in a peripheral area of the sound information display area. The information code generation method according to claim 4 or 5.   At least one of the colors or shapes of each of the predetermined figures representing a plurality of sounds in the sound information display area is selected from a plurality of color candidates or a plurality of shape candidates respectively associated with a plurality of types of performance methods. The information code generation method according to any one of claims 1 to 3, wherein the information code generation method is selected.   8. The information code generation method according to claim 1, wherein position data indicating a position of the sound information display area is recorded in the data recording area. Wherein the data recording area, information code generation method according to claim 8, characterized in that for recording the number data indicating the number of stages in the sound information display region of which position is specified by the position data. An information code in which cells serving as units for displaying information are arranged in a predetermined code area,
A specific pattern area in which a specific pattern having a predetermined shape is arranged inside the code area, a data recording area for recording data by a plurality of types of the cells, and a data recording method by the data recording area An information code comprising a sound information display area for expressing a plurality of sounds by a predetermined figure in different ways. Inside the code area, an empty area, which is an area where data to be decoded is not recorded by the cell, is provided at a position larger than the size of the single cell at a position other than the specific pattern area and the data recording area. And
The information code according to claim 10, wherein the sound information display area is provided inside the empty area.   The information code according to claim 10 or 11, wherein in the sound information display area, each height of a plurality of sounds is expressed by a position of the predetermined figure corresponding to each sound. .   A structure in which performance method designating data for designating a performance method of a plurality of sounds expressed in the sound information display area is recorded in the data recording area, or data recording by the data recording area in a peripheral area of the sound information display area 13. The information code according to claim 10, wherein an area for recording the performance method designation data is provided by a method different from the method.   14. The information code according to claim 13, wherein the performance method designating data is data designating at least one of a performance sound source, performance speed, and number of pitches that can be performed.   14. An entry area for specifying contents of a plurality of sound playing methods recorded in the sound information display area by an entry position in a peripheral area of the sound information display area. Item 15. The information code according to Item 14.   At least one of the colors or shapes of the predetermined figures representing a plurality of sounds in the sound information display area is selected from a plurality of color candidates or a plurality of shape candidates respectively associated with a plurality of types of performance methods. The information code according to any one of claims 10 to 12, wherein the information code is selected.   The information code according to any one of claims 10 to 16, wherein position data indicating a position of the sound information display area is recorded in the data recording area. The data recording area, information code according to claim 17, characterized in that stage number data indicating the number of stages in the sound information display area located by said location data is identified is recorded. An information code reading device for reading an information code in which cells serving as units for displaying information are arranged inside a predetermined code area,
The information code includes a specific pattern area in which a specific pattern having a predetermined shape is arranged inside the code area, a data recording area in which data is recorded by a plurality of types of cells, and data by the data recording area And a sound information display area for expressing a plurality of sounds by a predetermined figure by a method different from the recording method of
An imaging unit capable of imaging the information code;
When the information code is imaged by the imaging unit, a data recording area reading unit that reads data recorded in the data recording area based on the content of the data recording area in the code image of the imaged information code When,
A recording sound identifying unit that identifies a plurality of sounds recorded in the sound information display area based on the predetermined graphic represented in the sound information display area in the code image;
An information code reading device comprising: Inside the code area, an empty area, which is an area where data to be decoded is not recorded by the cell, is provided at a position larger than the size of the single cell at a position other than the specific pattern area and the data recording area. And
The information code reading device according to claim 19, wherein the sound information display area is provided inside the empty area. In the sound information display area, the information code is expressed by the position of the predetermined figure corresponding to each sound, and the height of each of the plurality of sounds.
The recorded sound specifying unit specifies the height of each of a plurality of sounds recorded in the sound information display area based on the position of the predetermined figure represented in the sound information display area. 21. The information code reading device according to claim 19 or 20. The information code has a configuration in which performance method designation data for designating a performance method of a plurality of sounds expressed in the sound information display area is recorded in the data recording area, or the data recording is recorded in a peripheral area of the sound information display area. It is configured to provide an area for recording the performance method designation data by a method different from the data recording method by area,
The recording sound specifying unit specifies a performance method specified by the performance method specification data based on the recorded contents of the data recording area or the recorded contents of the surrounding area. The information code reader according to one item.   23. The information code reading device according to claim 22, wherein the performance method designation data is data for designating at least one of a performance sound source, a performance speed, and the number of pitches that can be played. The information code is provided in a surrounding area of the sound information display area with an entry area for specifying the contents of a plurality of sound performance methods recorded in the sound information display area by an entry position;
The information according to claim 22 or 23, wherein the recording sound specifying unit analyzes the entry area in the code image of the information code and specifies a performance method specified in the entry area. Code reader. The information code includes a plurality of color candidates or a plurality of color candidates each associated with a plurality of types of performance methods, wherein at least one of the colors or shapes of the predetermined figures expressing a plurality of sounds in the sound information display area. It is selected from the shape candidates,
The recording sound specifying unit specifies a sound playing method corresponding to each predetermined graphic based on the color or shape of each of the predetermined graphic displayed in the sound information display area. The information code reading device according to any one of claims 19 to 21. In the information code, position data indicating the position of the sound information display area is recorded in the data recording area,
The said recording sound specific | specification part specifies the position of the said sound information display area based on the said position data recorded on the said data recording area, The any one of Claims 19-25 characterized by the above-mentioned. Information code reader. The information code in the data recording area, number data indicating the number of stages in the sound information display area located by said position data is specified is recorded,
The recording sound identification unit information code reading apparatus according to claim 26, wherein identifying the number of stages in the sound information display area based on the number data recorded in the data recording area. An information code generation device for generating an information code in which cells serving as units for displaying information within a predetermined code area are arranged;
An information code reader for reading the information code generated by the information code generator;
An information code using system comprising:
The information code generation device includes:
A specific pattern area in which a specific pattern having a predetermined shape is arranged inside the code area, a data recording area for recording data by a plurality of types of the cells, and a data recording method by the data recording area The information code is generated in a configuration provided with a sound information display area that expresses a plurality of sounds by a predetermined figure by different methods,
The information code reader is
An imaging unit capable of imaging the information code;
When the information code is imaged by the imaging unit, a data recording area reading unit that reads data recorded in the data recording area based on the content of the data recording area in the code image of the imaged information code When,
A recording sound identifying unit that identifies a plurality of sounds recorded in the sound information display area based on the predetermined graphic represented in the sound information display area in the code image;
An information code utilization system characterized by comprising:   The information code generation device includes, in the code area, a free area that is an area in which data to be decoded is not recorded by the cell at a position other than the specific pattern area and the data recording area. 29. The information code utilization system according to claim 28, wherein the information code is generated with a configuration in which the sound information display area is provided inside the empty area. The information code generation device generates the information code in a configuration in which the height of each of a plurality of sounds is expressed by the position of the predetermined figure corresponding to each sound in the sound information display area,
The recording sound specifying unit of the information code reader specifies the height of each of the plurality of sounds recorded in the sound information display area based on the position of the predetermined figure represented in the sound information display area. 30. The information code utilization system according to claim 28 or claim 29. The information code generation device is configured to record performance method designation data for designating a performance method of a plurality of sounds expressed in the sound information display area in the data recording area, or in a peripheral area of the sound information display area. The information code is generated in a configuration in which an area for recording the performance method designation data is provided by a method different from the data recording method by the data recording area,
The recording sound specifying unit of the information code reading device specifies a performance method specified by the performance method specifying data based on the recorded contents of the data recording area or the recorded contents of the surrounding area. The information code utilization system according to any one of claims 30.   32. The information code utilization system according to claim 31, wherein the performance method designating data is data designating at least one of a performance sound source, performance speed, and number of pitches that can be performed. The information code generating device is configured to provide an entry area in the surrounding area of the sound information display area, wherein an entry area for specifying the contents of a plurality of sound playing methods recorded in the sound information display area by an entry position is provided. Produces
32. The recording sound specifying unit of the information code reader analyzes the entry area in the code image of the information code, and specifies a performance method specified in the entry area. Item 33. The information code utilization system according to Item 32. The information code generation device may include a plurality of color candidates or at least one of colors or shapes of the predetermined figures representing a plurality of sounds in the sound information display area, respectively, associated with a plurality of types of performance methods, or Generate the information code with a configuration selected from a plurality of shape candidates,
The recording sound specifying unit of the information code reading device performs a sound playing method corresponding to each predetermined figure based on the color or shape of each of the plurality of predetermined figures displayed in the sound information display area. The information code utilization system according to any one of claims 28 to 30, wherein the information code utilization system is specified. The information code generation device generates the information code in a configuration in which position data indicating a position of the sound information display area is recorded in the data recording area.
35. The recording sound specifying unit of the information code reader specifies the position of the sound information display area based on the position data recorded in the data recording area. The information code utilization system according to any one of the above. It said information code generating device, wherein the data recording area, and generates the information code recorded constitutes a stage number data indicating the number of stages in the sound information display area located by said position data is specified,
The recording sound specifying unit of the information code reading apparatus according to claim 35, wherein identifying the number of stages in the sound information display area based on the number data recorded in the data recording area Information code utilization system.

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