JP6526884B2 - Information holding medium and information processing system - Google Patents

Description

  The present invention relates to an information holding medium and an information processing system.

  Conventionally, a plurality of pieces of identification information that can be used in the game are held as the corresponding concavo-convex portion, and when the game device is mounted on the mounting portion, whether the switch provided on the mounting portion is pressed by the concavo-convex portion An information holding medium is known which causes a game device to read a combination of concavities and convexities and to read identification information corresponding thereto (for example, Patent Document 1).

  The uneven portion in the information holding medium described in Patent Document 1 has a data signal portion and a synchronous signal portion arranged in parallel, and is formed of a combination of a concave portion and a convex portion, respectively. When is inserted, each convex portion in the concavo-convex portion presses the switch.

JP 2010-221004 A

  The synchronization signal portion in the concavo-convex portion of the information holding medium described in Patent Document 1 merely indicates the timing for specifying whether the convex portion in the data signal portion has pressed the switch, and the information itself is any information Does not represent. Therefore, if the synchronization signal portion can be eliminated and the second data signal portion can be further provided instead, the amount of information that can be expressed by the uneven portion can be increased. However, when the convex portion is continuous, the determination of the boundary between the first convex portion and the second convex portion is performed only when the switch is turned off, so the moving speed of the uneven portion relative to the switch can be increased quickly. Then, there is a possibility that the front convex portion and the rear convex portion may be erroneously recognized as one convex portion.

  An object of the present invention is to provide an information holding medium and an information processing system capable of relatively reducing erroneous recognition of held information.

  An information storage medium according to the present invention includes a medium base, and a plurality of unit data portions arranged in a first direction and a second direction intersecting the first direction and provided on the medium base. A mark for forming a digital code in the arrangement of the unit data parts is provided in a part of the unit data parts, and in the arrangement in the second direction of the unit data part train extending in the first direction, The mark patterns of the first direction permutations of two adjacent unit data part sequences are different from each other.

  Further, in the information holding medium according to the present invention, the unit data section sequence may include at least one mark.

According to the present invention, there is provided an information holding medium, comprising: a medium base; and a plurality of unit data portions arranged in a first direction and a second direction intersecting the first direction and provided on the medium base. And a mark for forming a digital code in the arrangement of the unit data units is provided in a part of the unit data units, and an arrangement of the unit data units in the second direction extending in the first direction. The mark pattern of the first direction permutation of the start end side unit data part sequence in the second is different from the mark pattern of the first direction permutation of the end side unit data part sequence and the mark pattern of the opposite direction to the first direction It features. According to the present invention, there is provided an information holding medium, comprising: a medium base; and a plurality of unit data portions arranged in a first direction and a second direction intersecting the first direction and provided on the medium base. And a mark for forming a digital code in the arrangement of the unit data units is provided in a part of the unit data units, and an arrangement of the unit data units in the second direction extending in the first direction. Unlike the mark pattern of the first direction sequence of the end side unit data portion sequence, the mark pattern of the first direction sequence of the start side side unit data portion sequence in the second embodiment is provided on the medium base and extends in the second direction The semiconductor device may further include an existing groove, and the unit data portion may be provided on a bottom surface of the groove.

  Further, in the information storage medium according to the present invention, the mark pattern of the first direction permutation of the unit data section sequence excluding the start end unit data section sequence and the end unit data section sequence is the end unit data section. It may be different from the mark pattern of the first direction permutation of the column.

  Further, the information holding medium according to the present invention may further include a guided portion provided on the medium base and extending in the second direction.

  In the information storage medium according to the present invention, the guided portion may be a groove, and the unit data portion may be provided in the groove.

  In the information holding medium according to the present invention, the mark may be a convex portion formed on the surface of the medium substrate.

  Further, an information processing system according to the present invention includes the information holding medium, and an information reading device for reading a digital code formed in an array of the unit data part of the information holding medium, the information reading device comprising: A mounting portion to which the information holding medium is mounted with relative movement of the information holding medium in the second direction, and an arrangement in a direction parallel to the first direction of the information holding medium mounted to the mounting portion And a plurality of detection units provided in the mounting unit for detecting the marks provided in the unit data unit of the information holding medium and outputting signals corresponding to the detection results, and synchronization from the plurality of detection units A data string is generated based on a unit signal having a plurality of signals output as one unit as one unit, and the data string is sequentially obtained based on the group of the data string sequentially obtained from the arrangement of the unit data portion of the information storage medium. Recognizing processing section Tarukodo, characterized by having a.

  Further, an information processing system according to the present invention includes the information holding medium, and an information reading device for reading a digital code formed in an array of the unit data part of the information holding medium, the information reading device comprising: A mounting portion to which the information holding medium is mounted with relative movement of the information holding medium in the second direction, and an arrangement in a direction parallel to the first direction of the information holding medium mounted to the mounting portion And a plurality of detection units provided in the mounting unit for detecting the marks provided in the unit data unit of the information holding medium and outputting signals corresponding to the detection results, and synchronization from the plurality of detection units A data string is generated based on a unit signal having a plurality of signals output as one unit as one unit, and the data string is sequentially obtained based on the group of the data string sequentially obtained from the arrangement of the unit data portion of the information storage medium. A processing unit that recognizes a Tal code, the mark pattern of the first direction permutation of the end-side unit data division sequence of the information storage medium is a specific mark pattern, and the processing unit is configured to When a specific data string obtained from a specific mark pattern is detected, processing for recognizing the digital code is executed, and the specific mark pattern is obtained from an inverted specific mark pattern inverted in the direction opposite to the first direction. An error processing is performed when an inverted specific data string to be detected is detected.

  Further, in the information processing system according to the present invention, the information holding medium further includes a guided portion provided on the medium base and extending in the second direction, and the information reading apparatus The mounting portion may be provided with a guide portion which engages with the guided portion of the information holding medium to guide the relative movement of the information holding medium in the second direction.

  Further, in the information processing system according to the present invention, the guided portion of the information holding medium is a groove, and the guide portion of the information reading device is the second one of the information holding medium mounted on the mounting portion. It may be a ridge extending in a direction parallel to two directions.

  Further, in the information processing system according to the present invention, the mark of the information holding medium is a convex portion formed on the surface of the medium substrate, and the detection portion of the information reader is pressed by the convex portion. It may be a switch.

  Further, in the information processing system according to the present invention, the information reading apparatus further includes an operation unit, and a storage unit storing operation data for operating the operation unit in association with the digital code. The processing unit of the information reading apparatus may read operation data corresponding to the recognized digital code from the storage unit, and operate the operation unit based on the read operation data.

  Further, in the information processing system according to the present invention, the operation unit may output an effect including at least one of sound and light emission.

  According to the present invention, false recognition of held information can be relatively reduced.

It is a figure showing composition of an example of an information processing system for describing an embodiment of the present invention. It is a figure which shows the structure of the information storage medium of FIG. It is a figure which shows an example of the mark pattern formed in the arrangement | sequence of the unit data part of the information storage medium of FIG. It is a figure which shows the structure of the information reader of FIG. It is a figure which shows the functional block of the information reader of FIG. It is a figure which shows the flow of the process performed by the information reader of FIG.

  FIG. 1 shows a configuration of an example of an information processing system for describing an embodiment of the present invention.

  The information processing system 1 includes an information holding medium 2 to which a digital code is assigned, and an information reading device 3 that reads the digital code attached to the information holding medium 2.

  The information reading device 3 is provided with a mounting portion 4 to which the information holding medium 2 is mounted, and the mounting portion 4 has an insertion port 4 a opened on the side surface of the information reading device 3. The information holding medium 2 is inserted into the mounting portion 4 through the insertion port 4 a and mounted to the mounting portion 4. Then, the information reading device 3 reads the digital code of the information holding medium 2 attached to the attachment unit 4.

  FIG. 2 shows the configuration of the information holding medium 2.

  The information holding medium 2 has a medium base 10 and an arrangement of unit data parts 11. The arrangement of the unit data unit 11 holds a digital code. In the illustrated example, the medium substrate 10 is a substantially circular plate-like hard member, but the shape and the material thereof are not particularly limited.

  A groove 12 is formed on the back surface 10 a of the medium substrate 10. The grooves 12 extend along any diameter of the media substrate 10, the ends of which extend to the side edges of the media substrate 10. The groove 12 defines the insertion direction of the information holding medium 2 to the mounting portion 4 when the information holding medium 2 is mounted to the information reading device 3.

  The arrangement of the unit data parts 11 is provided on the bottom of the groove 12 and arranged in a two-dimensional manner in a first direction and a second direction substantially orthogonal to the first direction. The second direction in the arrangement of the unit data portions 11 is the same as the extending direction of the grooves 12. In the illustrated example, the unit data units 11 are arranged in 4 × 4, but the number of unit data units 11 in each of the first direction and the second direction is not particularly limited.

  Hereinafter, the first direction in the arrangement of the unit data portions 11 is referred to as the X direction, and the second direction is referred to as the Y direction.

  In some unit data portions 11, marks 13 for forming digital codes are formed. In the illustrated example, the mark 13 is configured as a convex portion having a predetermined height, and binary data of “1” or “0” is given to the unit data portion 11 according to the presence or absence of the mark 13. As a result, a digital code is formed in the arrangement of the unit data portion 11.

  FIG. 3 shows an example of the mark pattern formed in the array of the unit data part 11. As shown in FIG. Note that FIG. 3A shows a mark pattern according to the physical arrangement of the marks 13, and FIG. 3B replaces the presence or absence of the mark 13 with binary data of “1” or “0”. The mark pattern is indicated by the following digital code.

  Each of the unit data section trains 14a, 14b, 14c, 14d formed by the four unit data sections 11 arranged in the X direction is configured to include at least one mark 13.

  The mark patterns of the X-direction permutations of two unit data divisions adjacent to each other in the Y-direction of the unit data divisions 14a, 14b, 14c and 14d are different from each other. For example, while the mark pattern of the X-direction permutation of the unit data part sequence 14a is "presence, absence, presence, existence" and the corresponding data sequence is "1, 0, 1, 1", the unit data division sequence 14b The mark patterns of the X-direction permutations are “none, with, with, without”, and the corresponding data strings are “0, 1, 1, 0”, which are different from each other.

  In addition, the mark pattern of the X-direction permutation of unit data division row 14d at one end side in the Y-direction alignment of unit data division row 14a, 14b, 14c, 14d is a specific mark pattern common to plural types of digital codes. ing. The specific mark pattern and the corresponding data string represent the end of the digital code formed in the array of the unit data portion 11. In the illustrated example, the mark pattern of the X-direction permutation of the unit data part sequence 14d is "present, absent, present, absent", and the corresponding data string is "1, 0, 1, 0."

  Hereinafter, the unit data portion 14d is referred to as a termination side unit data portion sequence, and the other end side unit data portion sequence 14a is referred to as a start side unit data portion sequence.

  The mark pattern of the X-direction permutation of the start-end-side unit data portion sequence 14a is different from the mark pattern of the X-direction permutation and the mark pattern of the −X-direction permutation of the end side unit data portion sequence 14d.

  Furthermore, the mark patterns of the X-direction permutations of the unit data part sequences 14b and 14c are also different from the mark patterns of the X-direction permutations of the end-side unit data part sequence 14d and the mark patterns of the -X-direction permutations.

  The information holding medium 2 is inserted into the insertion port 4 a of the information reading device 3 with the leading end side unit data section sequence 14 a at the top, and is mounted to the mounting section 4.

  FIG. 4 shows the configuration of the information reading device 3.

  In the mounting portion 4 of the information reading device 3, two convex streaks 20 are formed. The two ridges 20 extend in a direction parallel to the Y direction in the arrangement of the unit data portions 11 when the information holding medium 2 is mounted on the mounting portion 4, and are provided on the medium substrate 10. It engages with both sides of the formed groove 12. Thereby, the insertion direction of the information holding medium 2 to the mounting portion 4 is defined in the Y direction.

  The mounting unit 4 is provided with a detection unit 21 that detects the marks 13 formed in the array of the unit data units 11 of the information holding medium 2 and outputs a signal according to the detection result of the marks 13. The detection units 21 are provided in the same number as the number of unit data units 11 constituting one unit data unit sequence, and when the information holding medium 2 is attached to the attachment unit 4 between the two ridges 20. Are arranged in a direction parallel to the X direction in the arrangement of unit data portions 11.

  In the illustrated example, the detection unit 21 is configured as a switch pressed by the mark 13. When the mark 13 passes above the detection unit 21 as the information holding medium 2 is inserted into the mounting unit 4 or removed from the mounting unit 4, the detection unit 21 is pressed by the mark 13 and automatically passes after the mark 13 passes. To surface. Then, the detection unit 21 outputs a high level signal when pressed, and outputs a low level signal when floating.

  Then, as the information holding medium 2 is inserted into the mounting unit 4 or removed from the mounting unit 4, the unit data portion arrays 14 a, 14 b, 14 c, 14 d sequentially pass over the rows of the detection units 21. Every time one unit data section train passes through the train of detection units 21, a signal is output synchronously from the group of detection units 21.

  FIG. 5 shows functional blocks of the information reading device 3.

  The information reading device 3 acquires signals output from the group of the detecting portion 21 to recognize the digital code of the information holding medium 2 and executes various processings, and power is supplied to each portion of the information reading device 3. And a power supply unit 22 for supplying power. The processing unit is configured to include an operation unit 23, a storage unit 24, and a control unit 25.

  For example, the operation unit 23 is configured to be able to output an effect including at least one of sound and light emission, and in the illustrated example, includes a speaker 26 and is configured to be able to output an effect by sound.

  The storage unit 24 includes a storage medium such as a ROM (Read Only Memory) or a RAM (Random Access Memory), for example, and a program executed by the control unit 25 and various digital codes assigned to the information holding medium 2 and an operation unit. A table etc. which associates various voice data to be output to the H.23 are stored.

  The control unit 25 includes, for example, a processing device such as a microprocessor, operates according to a program stored in the storage unit 24, and controls the operation of each unit of the information reading device 3.

  The control unit 25 assigns the digital data corresponding to the signal to each of the signals forming the unit signal group, with the signal group synchronously output from the group of the detection unit 21 as one unit, and the assigned data A data string is generated by arranging in accordance with the X-direction permutation of the detection unit 21.

  In this example, the detection unit 21 is configured to output a High level signal when pressed by the mark 13 and output a Low level signal in the floating state, and the control unit 25 is a detection unit. 21 is configured to determine the signal level of the signal output from 21 and to allocate data of “1” when the signal level is high level and data of “0” when the signal level is low level. Therefore, for example, a data string of "1, 0, 1, 1" is generated for the mark pattern "present, not present, present, present" of the X direction permutation of the leading end side unit data part sequence 14a (see FIG. 3). ).

  Here, as described above, each of the unit data portion sequences 14a, 14b, 14c, 14d is configured to include at least one mark 13, and the mark pattern of the X direction permutation of two adjacent unit data portion sequences Are different from each other. Therefore, when the mark patterns of two adjacent unit data section trains are respectively detected by the group of the detection unit 21, at least one is output from the detection section 21 between two adjacent unit data section trains. The signal will change.

  The control unit 25 detects the switching of the signal output from at least one detection unit 21 and acquires the signal output in synchronization from the group of the detection unit 21 at the timing when the signal is switched to generate a data string. . As a result, the control unit 25 can accurately recognize the boundaries of the unit data portion sequences 14a, 14b, 14c, and 14d without being separately instructed on the timing of acquiring the signal output from the group of the detection unit 21, It is possible to generate a data string for each data division string.

  In the storage unit 24, a memory area having a capacity of three rows of data strings is secured, and the control unit 25 is sequentially obtained for each unit data section row as the information holding medium 2 is inserted into the mounting portion 4. The data string is stored in the memory area secured in the storage unit 24. For example, when the information holding medium 2 is inserted into the mounting unit 4 with the leading end side unit data division train 14a at the top, the data train for three columns sequentially obtained from the unit data division trains 14a, 14b, 14c is a storage unit It is stored in 24 memory areas.

  Then, when the control unit 25 detects a data string “1, 0, 1, 0” corresponding to the specific mark pattern “Yes, No, Yes, No” of the X-direction permutation of the terminal-side unit data part sequence 14 d. Then, the digital code is recognized based on the data string stored in the storage unit 24 at that time, and processing according to the recognized digital code is executed.

  Hereinafter, the pattern of the data string "1, 0, 1, 0" corresponding to the above specific mark pattern "Yes, No, Yes, No" is referred to as an end data string pattern, and the permutation of the specific mark patterns is reversed. The mark pattern “none, with, without, with” is referred to as a reverse specific mark pattern, and the pattern of the data string “0, 1, 0, 1” corresponding to the reverse specific mark pattern is referred to as a reverse end data string pattern.

  FIG. 6 shows the flow of processing executed by the control unit 25.

  When the information reader 3 is powered on, the control unit 25 secures a memory area having a capacity of three rows of data strings in the storage unit 24 and erases the data in the memory area (step S1).

  As the information holding medium 2 is inserted into the mounting unit 4 or removed from the mounting unit 4, a signal is output from the group of the detection unit 21 that has detected the mark pattern for each unit data section row. The control unit 25 acquires the signals output from the group of the detection unit 21 and generates a data string (step S2).

  Next, the control unit 25 determines whether the data string matches the above-mentioned inverted end data string pattern (step S3).

  For example, when the information holding medium 2 is inserted into the mounting unit 4 with the leading end side unit data division row 14a at the top, the mark pattern of the X direction permutation of the leading end side unit data division row 14a is first by the group of detection portions 21. Although detected, this mark pattern is different from the above-mentioned inverted specific mark pattern, and the data string is different from the above-mentioned inverted end data string pattern.

  On the other hand, when the information holding medium 2 is inserted into the mounting unit 4 with the end-side unit data section sequence 14 d at the top, the mark pattern of the −X-direction permutation of the end-side unit data section sequence 14 d is First detected by the group, this mark pattern matches the above-mentioned inverted specific mark pattern, and the data string matches the above-mentioned inverted end data string pattern.

  Therefore, when the data string matches the above-mentioned inverted end data string pattern, the control unit 25 executes the error processing on the assumption that the information holding medium 2 is mounted on the mounting unit 4 in the reverse direction (step S4). The data in the memory area of the storage unit 24 is erased (step S5). As the error processing, processing for operating the operation unit 23 based on voice data such as an error message stored in the storage unit 24 can be exemplified.

  On the other hand, when the data string does not match the above-described inverted end data string pattern, the control unit 25 determines whether the data string matches the above-described end data string pattern (step S6).

  Then, when the data string does not match the above-described end data string pattern, the control unit 25 stores the data string in the memory area secured in the storage unit 24 (step S7).

  For example, when the information holding medium 2 is inserted into the mounting unit 4 with the leading end side unit data unit sequence 14a at the top, the mark pattern of the X direction permutation of each unit data unit sequence 14a, 14b, 14c is the detection unit 21. The mark patterns of the X-direction permutations of each of the unit data part sequences 14a, 14b, 14c are different from the above specific mark patterns, and the unit data part sequences 14a, 14b, 14c are detected sequentially. The data strings obtained from each of these are different from the end data string pattern described above. Therefore, data strings sequentially obtained from the unit data part strings 14a, 14b and 14c are stored in the memory area of the storage part 24.

  On the other hand, when the data string matches the above-described end data string pattern, the control unit 25 determines whether the memory area of the storage unit 24 is empty (step S8), and when the memory area is not empty, That is, when the data string is stored in the memory area, the control unit 25 subsequently recognizes the digital code based on the data string stored in the memory area (step S9), and the digital code is stored in the storage unit. Whether or not the digital code is appropriate is determined based on whether or not it is included in the table stored in 24 (step S10).

  For example, the information holding medium 2 is inserted into the mounting unit 4 with the leading end side unit data section sequence 14a at the top, and the data sequence sequentially obtained from the unit data section sequences 14a, 14b, 14c is stored in the memory area of the storage unit 24. In this case, with the completion of mounting of the information holding medium 2 to the mounting portion 4, the above end data string pattern is detected in the data string obtained from the termination-side unit data component string 14d. At that time, in the memory area of the storage unit 24, data strings obtained from the unit data part strings 14a, 14b and 14c are stored, and the digital code is recognized based on these data strings. The digital code is included in the table of the storage unit 24 as one of the digital codes given to the information holding medium 2, and is determined as appropriate.

  When the digital code is appropriate, the control unit 25 reads out from the storage unit 24 the audio data stored in association with the digital code, as installation processing at the time of mounting the information holding medium 2 in the mounting unit 4. Based on the read audio data, the effect processing for operating the operation unit 23 is executed (step S11), and the data in the memory area of the storage unit 24 is erased (step S12).

  On the other hand, when the recognized digital code is not appropriate, the control unit 25 executes an error process (step S13) and erases data in the memory area of the storage unit 24 (step S14).

  In the case where the digital code is not appropriate, the information holding medium 2 is reciprocated back and forth in the process of being inserted into the mounting unit 4, and the unit data section sequence 14 a and the unit data section sequence 14 b It is possible to illustrate a case where data strings which are detected and obtained from the unit data unit sequence 14a and the unit data unit sequence 14b are stored redundantly in the memory area of the storage unit 24.

  In the case where the information holding medium 2 is removed from the mounting unit 4 after the information holding medium 2 is mounted on the mounting unit 4 and the mounting process (step S11) or the error process (step S13) is performed. The mark pattern of the X-direction permutation of the end-side unit data part sequence 14 d is first detected by the group of detection units 21. The above end data string pattern is detected in the data string obtained from the end-side unit data part string 14d, but at this time, the memory area of the storage section 24 is empty because the data is erased (step S12, S14).

  As described above, when the data string matches the above-described end data string pattern and the memory area is empty, the control unit 25 executes the rendering process when the information holding medium 2 is removed from the mounting unit 4. Then, the data in the memory area of the storage unit 24 is erased (step S16). As the removal-time effect process, a process of operating the operation unit 23 based on audio data such as a sound effect stored in the storage unit 24 can be exemplified.

  The removal effect process described above is performed when the information holding medium 2 is removed from the mounting unit 4 after the information reading device 3 is powered on with the information holding medium 2 mounted on the mounting unit 4. Is also performed.

  In the information processing system 1 described above, the mark 13 is configured as a convex portion having a predetermined height, and binary data is added to the unit data portion 11 of the information holding medium 2 depending on the presence or absence of the mark 13 The data given to the data unit 11 is not limited to binary data. For example, it is also possible to assign data of three or more values to the unit data portion 11 by using marks having different heights and depending on the presence or absence of the marks and the mark height. Further, the mark 13 may be any as long as it can take a plurality of discrete values with respect to a specific physical quantity. For example, it is possible to form the mark 13 by coloring the unit data portion 11 with colors having different reflectances.

DESCRIPTION OF SYMBOLS 1 information processing system 2 information holding medium 3 information reader 4 mounting part 10 medium base 11 unit data part 12 groove (guided part)
13 mark 14a leading end side unit data division row 14b unit data division row 14c unit data division row 14d end side unit data division row 20 ridge (guide portion)
21 detection unit 23 operation unit (processing unit)
24 storage unit (processing unit)
25 control unit (processing unit)

Claims (7)

Media substrate,
A plurality of unit data portions arranged in the first direction and a second direction intersecting the first direction and provided on the medium substrate;
Have
A mark for forming a digital code in the arrangement of the unit data part is provided in a part of the unit data part,
The mark pattern of the first direction sequence of the start side unit data portion sequence in the second direction alignment of the unit data portion sequence extending in the first direction is the mark pattern of the first direction sequence of the end side unit data portion sequence. Unlike down,
It further has a groove provided in the medium substrate and extending in the second direction,
An information storage medium provided on the bottom of the groove ; The information holding medium according to claim 1 , wherein
The mark pattern of the first direction sequence of the unit data portion sequence excluding the leading end side unit data portion sequence and the end side unit data portion sequence is different from the mark pattern of the first direction sequence of the end side unit data portion sequence. Information holding medium. An information holding medium according to claim 1 or 2.
An information reader for reading a digital code formed in an array of the unit data portion of the information storage medium;
Equipped with
The information reader is
A mounting portion on which the information holding medium is mounted with relative movement of the information holding medium in the second direction;
The recording medium is arranged in a direction parallel to the first direction of the information holding medium mounted on the mounting section and provided on the mounting section, and detects the mark provided on the unit data portion of the information holding medium. A plurality of detection units that output signals corresponding to detection results;
A data string is generated based on a unit signal in which a plurality of signals synchronously output from the plurality of detection units are one unit, and a data string of the data string sequentially obtained from the array of the unit data portion of the information storage medium. A processing unit that recognizes the digital code based on a group;
An information processing system having A claim 3 Symbol placement information processing system,
Wherein the mounting portion, the information processing system guide portion for guiding the relative movement of the second direction of the information storage medium engaged with the groove of the information storage medium is provided before Symbol information reading device. The information processing system according to claim 4 , wherein
The guide portion to an information processing system is a convex extending in a direction parallel to the second direction of the information storage medium attached to the attachment portion of the front SL information reading device. The information processing system according to any one of claims 3 to 5 , wherein
The information reading apparatus further includes an operation unit, and a storage unit storing operation data for operating the operation unit in association with the digital code.
An information processing system, wherein the processing unit of the information reading apparatus reads out operation data corresponding to the recognized digital code from the storage unit, and operates the operation unit based on the read out operation data. The information processing system according to claim 6 , wherein
The information processing system, wherein the operation unit can output an effect including at least one of voice and light emission.

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