JP7462603B2 - Performance output system - Google Patents

Description

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

Conventionally, there is known an information storage medium that holds multiple pieces of identification information that can be used in a game as corresponding concave and convex parts, and when the medium is attached to a mounting part of a game device, reads the combination of concave and convex parts based on whether a switch provided on the mounting part is pressed by the concave and convex parts, and allows the game device to read the corresponding identification information (for example, Patent Document 1).

The uneven portion of the information-holding medium described in Patent Document 1 has a data signal portion and a synchronization signal portion arranged in parallel, each of which is made up of a combination of a concave portion and a convex portion, and when the information-holding medium is inserted into the game device, each convex portion of the uneven portion presses a switch.

JP 2010-221004 A

The synchronization signal portion in the concave-convex portion of the information storage medium described in Patent Document 1 merely indicates the timing for determining whether the convex portion in the data signal portion has pressed the switch, and does not itself represent any information. Therefore, if the synchronization signal portion could be eliminated and a second data signal portion could be provided instead, the amount of information that the concave-convex portion can represent could be increased. However, when convex portions are continuous, the boundary between the previous convex portion and the next convex portion can only be determined by the switch being turned off, so if the speed at which the concave-convex portion is moved relative to the switch is increased, there is a risk that the previous convex portion and the next convex portion will be mistakenly recognized as a single convex portion.

One of the objectives of the present invention is to provide an information storage medium and an information processing system that can relatively reduce the chance of the stored information being misrecognized.

The information-retaining medium according to the present invention has a medium substrate and a plurality of unit data sections arranged on the medium substrate in a first direction and a second direction intersecting the first direction, and is characterized in that marks for forming digital codes in the arrangement of the unit data sections are provided in some of the unit data sections, and in the arrangement in the second direction of the unit data section strings extending in the first direction, the mark patterns of the first direction permutation of two adjacent unit data section strings are different from each other.

In addition, in the information-retaining medium according to the present invention, the unit data section string may include at least one of the marks.

The information-bearing medium according to the present invention has a medium substrate and a plurality of unit data sections arranged in a first direction and a second direction intersecting the first direction and provided on the medium substrate, and is characterized in that a mark for forming a digital code in the arrangement of the unit data sections is provided in some of the unit data sections, and the mark pattern of the first direction permutation of the start end unit data section string in the second direction arrangement of the unit data section strings extending in the first direction is different from the mark pattern of the first direction permutation of the end end unit data section string and the mark pattern of the permutation in the direction opposite to the first direction.

In addition, in the information-holding medium according to the present invention, the mark pattern of the first direction permutation of the unit data section strings excluding the start end unit data section string and the end end unit data section string may be different from the mark pattern of the first direction permutation of the end end unit data section string.

The information-bearing medium according to the present invention may further include a guided portion provided on the medium substrate and extending in the second direction.

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

In addition, the information processing system of the present invention comprises the information bearing medium and an information reading device that reads a digital code formed in the arrangement of the unit data sections of the information bearing medium, and the information reading device is characterized in that it has a mounting section in which the information bearing medium is mounted with relative movement of the information bearing medium in the second direction, a plurality of detection sections arranged in the mounting section in a direction parallel to the first direction of the information bearing medium mounted in the mounting section, detect the marks provided in the unit data sections of the information bearing medium and output a signal corresponding to the detection result, and a processing section that generates a data string based on a unit signal that takes a plurality of signals output synchronously from the plurality of detection sections as one unit, and recognizes the digital code based on a group of the data strings obtained sequentially from the arrangement of the unit data sections of the information bearing medium. Further, an information processing system according to the present invention comprises: a medium substrate; an information bearing medium having a unit data section string composed of a plurality of unit data sections arranged on the medium substrate in a first direction, the unit data section string being arranged in a plurality of rows in a second direction intersecting the first direction, and a mark for forming a digital code in the array of the unit data sections being provided in some of the unit data sections; and an information reading device for reading the digital code formed in the array of the unit data sections of the information bearing medium, the information reading device comprising: a mounting section in which the information bearing medium is mounted with relative movement of the information bearing medium in the second direction; and an information reading device for reading the digital code formed in the array of the unit data sections of the information bearing medium, the information reading device comprising: a mounting section in which the information bearing medium is mounted with relative movement of the information bearing medium in the second direction; The information reading device has a plurality of detection units which detect the mark provided on the unit data section of the holding medium and output a signal corresponding to the detection result, and a processing unit which generates a data string based on a unit signal which takes as one unit a plurality of signals output synchronously from the plurality of detection units when one unit data section string passes over the plurality of detection units, and recognizes the digital code based on a group of the data strings obtained sequentially for each unit data section string of the information holding medium, and the information reading device further has an operation unit and a memory unit which stores operation data for operating the operation unit in association with the digital code, and the processing unit of the information reading device reads out operation data corresponding to the recognized digital code from the memory unit, and operates the operation unit based on the read operation data. Further, an information processing system according to the present invention includes: a medium substrate; and an information bearing medium having a unit data section string consisting of a plurality of unit data sections arranged on the medium substrate in a first direction, the unit data section strings being arranged in a plurality of rows in a second direction intersecting the first direction, marks for forming a digital code in the array of the unit data sections being provided in some of the unit data sections, and in the second direction arrangement of the unit data section strings extending in the first direction, mark patterns in the first direction permutation of two adjacent unit data section strings are different from each other; and an information reading device that reads the digital code formed in the array of the unit data sections of the information bearing medium, and the information reading device reads the digital code formed in the array of the unit data sections of the information bearing medium. a processing unit that generates a data string based on a unit signal that takes as one unit data section string a plurality of signals output synchronously from the plurality of detection units when one unit data section string passes over the plurality of detection units, and recognizes the digital code based on a group of the data strings obtained sequentially for each unit data section string of the information holding medium; and a mounting unit into which the information holding medium is mounted with relative movement of the holding medium in the second direction; a plurality of detection units that are arranged in a direction parallel to the first direction of the information holding medium mounted in the mounting unit and are provided in the same number as the number of unit data sections that constitute one unit data section string in the mounting unit, the detection units detecting the marks provided in the unit data sections of the information holding medium and outputting a signal corresponding to the detection result; and a processing unit that generates a data string based on a unit signal that takes as one unit a plurality of signals output synchronously from the plurality of detection units when one unit data section string passes over the plurality of detection units, and recognizes the digital code based on a group of the data strings obtained sequentially for each unit data section string of the information holding medium.The information reading device further has an operation unit and a memory unit that stores operation data for operating the operation unit in association with the digital code, and the processing unit of the information reading device reads out operation data corresponding to the recognized digital code from the memory unit, and operates the operation unit based on the read operation data. The performance output system according to the present invention further comprises: a medium substrate; an information retention medium having a unit data section string consisting of a plurality of unit data sections arranged on the medium substrate in a first direction, the unit data section strings being arranged in a second direction intersecting the first direction, and a mark for forming a digital code in the array of the unit data sections being provided in some of the unit data sections, and in the second direction arrangement of the unit data section strings extending in the first direction, two adjacent unit data section strings have different mark patterns consisting of the permutations of the marks arranged in the first direction; and an information reading device that reads the digital code formed in the array of the unit data sections of the information retention medium, the information reading device comprising: a mounting section in which the information retention medium is mounted with the information retention medium moving relatively in the second direction; the information reading device further comprises an operation unit and a memory unit storing operation data for operating the operation unit in association with the digital code, the processing unit reading out operation data corresponding to the recognized digital code from the memory unit, and causing the operation unit to operate based on the operation data read out from the memory unit, the information reading device further comprising: a plurality of detection units arranged in a direction parallel to the first direction of the information bearing medium attached to the attachment unit, the detection units being provided in the same number as the number of unit data units constituting one unit data unit string on the attachment unit, the detection units detecting the marks provided in the unit data units of the information bearing medium and outputting a signal corresponding to the detection result; and a processing unit generating a data string based on a unit signal taking as one unit a plurality of signals output synchronously from the plurality of detection units when one unit data unit string passes over the plurality of detection units, and recognizing the digital code based on a group of the data strings obtained sequentially for each unit data unit string of the information bearing medium, the information reading device further comprising: an operation unit; The performance output system according to the present invention includes a medium substrate, a unit data section string consisting of a plurality of unit data sections arranged on the medium substrate in a first direction, the unit data section strings being arranged in a second direction intersecting the first direction, and a mark for forming a digital code in the array of the unit data sections being provided in some of the unit data sections, and in the second direction of the unit data section strings extending in the first direction, mark patterns consisting of permutations of the marks arranged in the first direction of two adjacent unit data section strings of the unit data section strings are different from each other, and an information reading device that reads the digital code formed in the array of the unit data sections of the information holding medium, the information reading device including: an attachment section in which the information holding medium is attached with a relative movement of the information holding medium in the second direction; and an information reading device that detects the marks provided in the unit data sections of the information holding medium, the information reading device being arranged in a direction parallel to the first direction of the information holding medium attached to the attachment section, and the marks being provided in the same number as the number of unit data sections constituting one unit data section string in the attachment section, The information reading device has a plurality of detection units which output a signal corresponding to the detection result, and a processing unit which generates a data string as a unit at the timing when the signal output from at least one of the detection units switches from a plurality of signals output from the plurality of detection units when a unit data section string passes over the plurality of detection units, and recognizes the digital code based on the group of the data strings obtained sequentially for each unit data section string of the information holding medium, and the information reading device further has an operation unit and a memory unit which stores operation data for operating the operation unit in association with the digital code, and when the processing unit of the information reading device recognizes the digital code, it reads out operation data corresponding to the recognized digital code from the memory unit, and operates the operation unit to output an effect including at least one of sound or light emission based on the read operation data, and the mark of the information holding medium is a convex portion formed on the surface of the medium substrate, and the detection unit of the information reading device is a switch pressed by the convex portion.

The information processing system according to the present invention includes the information storage medium and an information reading device that reads the digital code formed in the arrangement of the unit data sections of the information storage medium, and the information reading device includes a mounting section in which the information storage medium is mounted with the relative movement of the information storage medium in the second direction, a plurality of detection sections arranged in a direction parallel to the first direction of the information storage medium mounted in the mounting section and provided in the mounting section, which detect the marks provided in the unit data sections of the information storage medium and output a signal corresponding to the detection result, and a processing section that generates a data string based on a unit signal that takes a plurality of signals output synchronously from the plurality of detection sections as one unit, and recognizes the digital code based on a group of the data strings obtained sequentially from the arrangement of the unit data sections of the information storage medium, and the mark pattern of the first direction permutation of the unit data sections on the terminal side of the information storage medium is a specific mark pattern, and the processing section performs a process of recognizing the digital code when it detects a specific data string obtained from the specific mark pattern, and performs error processing when it detects an inverted specific data string obtained from an inverted specific mark pattern obtained by inverting the specific mark pattern in the opposite direction to the first direction.

In addition, in the information processing system according to the present invention, the information-holding medium may further have a guided portion provided on the medium substrate and extending in the second direction, and the mounting portion of the information reading device may be provided with a guide portion that engages with the guided portion of the information-holding medium to guide the relative movement of the information-holding medium in the second direction.

In addition, in the information processing system according to the present invention, the guided portion of the information-holding medium may be a groove, and the guide portion of the information reading device may be a protrusion extending in a direction parallel to the second direction of the information-holding medium attached to the attachment portion.

In addition, in the information processing system according to the present invention, the mark of the information-bearing medium may be a convex portion formed on the surface of the medium substrate, and the detection unit of the information reading device may be a switch that is pressed by the convex portion.

In addition, in the information processing system according to the present invention, the information reading device further includes an operating unit and a storage unit that stores operation data for operating the operating unit in association with the digital code, and the processing unit of the information reading device may read out the operation data corresponding to the recognized digital code from the storage unit and operate the operating unit based on the read out operation data.

In addition, in the information processing system according to the present invention, the operation unit may be capable of outputting effects including at least one of sound and light emission.

The present invention can reduce the likelihood of the information held being misrecognized.

1 is a diagram showing a configuration of an example of an information processing system for explaining an embodiment of the present invention. FIG. 2 is a diagram showing a configuration of an information bearing medium shown in FIG. 1; 3 is a diagram showing an example of a mark pattern formed in an array of unit data sections of the information bearing medium of FIG. 2; FIG. 2 is a diagram showing a configuration of the information reading device shown in FIG. 1; FIG. 2 is a diagram showing functional blocks of the information reading device shown in FIG. 1 . FIG. 6 is a diagram showing a flow of processing executed by the information reading device of FIG. 5 .

Figure 1 shows an example of the configuration of an information processing system to explain an embodiment of the present invention.

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

The information reading device 3 is provided with a mounting section 4 into which the information holding medium 2 is attached, and the mounting section 4 has an insertion port 4a that opens on the side of the information reading device 3. The information holding medium 2 is inserted into the mounting section 4 through the insertion port 4a and attached to the mounting section 4. The information reading device 3 then reads the digital code of the information holding medium 2 attached to the mounting section 4.

Figure 2 shows the configuration of the information-holding medium 2.

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

A groove 12 is formed on the back surface 10a of the medium substrate 10. The groove 12 extends along an arbitrary diameter of the medium substrate 10, and both ends reach the side edges of the medium substrate 10. The groove 12 determines the insertion direction of the information holding medium 2 into the mounting portion 4 when the information holding medium 2 is mounted on the information reading device 3.

The array of unit data sections 11 is provided on the bottom surface of the groove 12, and is arranged two-dimensionally in a first direction and a second direction that is approximately perpendicular to the first direction. The second direction in the array of unit data sections 11 is the same as the extension direction of the groove 12. In the illustrated example, the unit data sections 11 are arranged in a 4x4 array, but the number of unit data sections 11 arranged in each of the first and second directions is not particularly limited.

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

Some of the unit data sections 11 have marks 13 formed therein for forming a digital code. In the illustrated example, the marks 13 are configured as convex parts having a predetermined height, and binary data of "1" or "0" is assigned to each unit data section 11 depending on the presence or absence of the marks 13, thereby forming a digital code in the arrangement of the unit data sections 11.

Figure 3 shows an example of a mark pattern formed in an array of unit data sections 11. Note that Figure 3(A) shows the mark pattern by the physical arrangement of marks 13, while Figure 3(B) shows the mark pattern by a digital code in which the presence or absence of marks 13 is replaced with binary data of "1" or "0."

Each of the unit data section rows 14a, 14b, 14c, and 14d formed by four unit data sections 11 aligned in the X direction includes at least one mark 13.

The mark patterns of the X-direction permutation of two adjacent unit data section strings in the Y-direction arrangement of unit data section strings 14a, 14b, 14c, and 14d are different from each other. For example, the mark pattern of the X-direction permutation of unit data section string 14a is "present, absent, present, present" and the corresponding data string is "1, 0, 1, 1", while the mark pattern of the X-direction permutation of unit data section string 14b is "absent, present, present, absent" and the corresponding data string is "0, 1, 1, 0", which are different from each other.

The mark pattern of the X-direction permutation of unit data section string 14d at one end of the Y-direction arrangement of unit data section strings 14a, 14b, 14c, and 14d is a specific mark pattern common to multiple types of digital codes. This specific mark pattern and the corresponding data string represent the end of the digital code formed in the array of unit data sections 11. In the illustrated example, the mark pattern of the X-direction permutation of unit data section string 14d is "present, absent, present, absent," and the corresponding data string is "1, 0, 1, 0."

Hereinafter, unit data section 14d will be referred to as the terminal unit data section string, and unit data section string 14a on the other end will be referred to as the start unit data section string.

The mark pattern of the X-direction permutation of the start-side unit data section 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 section sequence 14d.

Furthermore, the mark patterns of the X-direction permutation of unit data section strings 14b and 14c are also different from the mark patterns of the X-direction permutation and the -X-direction permutation of the terminal unit data section string 14d.

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

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

Two convex strips 20 are formed on the mounting section 4 of the information reading device 3. These two convex strips 20 extend in a direction parallel to the Y direction in the arrangement of the unit data sections 11 when the information holding medium 2 is mounted in the mounting section 4, and engage with both side surfaces of a groove 12 formed in the medium substrate 10. This defines the insertion direction of the information holding medium 2 into the mounting section 4 as the Y direction.

The mounting section 4 is provided with a detection section 21 that detects the marks 13 formed in the array of unit data sections 11 of the information bearing medium 2 and outputs a signal according to the detection result of the marks 13. The detection sections 21 are provided in the same number as the number of unit data sections 11 that make up one unit data section string, and are arranged between the two convex strips 20 in a direction parallel to the X direction in the array of unit data sections 11 when the information bearing medium 2 is mounted in the mounting section 4.

In the illustrated example, the detection unit 21 is configured as a switch that is pressed by the mark 13. When the mark 13 passes over the detection unit 21 as the information holding medium 2 is inserted into or removed from the mounting unit 4, the detection unit 21 is pressed by the mark 13 and automatically floats up after the mark 13 has passed. The detection unit 21 outputs a high-level signal when pressed, and outputs a low-level signal when in the floated state.

When the information-holding medium 2 is inserted into or removed from the mounting section 4, the unit data section strings 14a, 14b, 14c, and 14d pass sequentially over the row of detection sections 21. Each time a unit data section string passes through the row of detection sections 21, a signal is output in synchronization from the group of detection sections 21.

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

The information reading device 3 has a processing unit that acquires signals output from the group of detection units 21 to recognize the digital code of the information holding medium 2 and executes various processes, and a power supply unit 22 that supplies power to each unit of the information reading device 3. The processing unit is composed of an operating unit 23, a memory unit 24, and a control unit 25.

The operating unit 23 is configured to be capable of outputting effects that include at least one of sound and light emission, and in the illustrated example, includes a speaker 26 and is configured to be capable of outputting sound effects.

The storage unit 24 includes a storage medium such as a ROM (Read Only Memory) or a RAM (Random Access Memory), and stores programs executed by the control unit 25, a table that associates various digital codes assigned to the information holding medium 2 with various types of audio data to be output by the operation unit 23, and the like.

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

This control unit 25 regards the group of signals output synchronously from the group of detection units 21 as one unit, assigns digital data corresponding to each signal constituting the unit signal group, and generates a data string by arranging the assigned data according to the X-direction permutation of the detection units 21.

In this example, the detection unit 21 is configured to output a high level signal when pressed by the mark 13 and to output a low level signal when it is in a raised state, and the control unit 25 is configured to determine the signal level of the signal output from the detection unit 21 and assign data "1" when the signal level is high level and data "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, absent, present, present" of the X-direction sequence of the start end unit data section string 14a (see Figure 3).

As described above, each of unit data section strings 14a, 14b, 14c, and 14d is configured to include at least one mark 13, and the mark patterns of the X-direction permutation of two adjacent unit data section strings are different from each other. Therefore, when the mark patterns of two adjacent unit data section strings are detected by the group of detection units 21, at least one signal output from the detection unit 21 will change between the two adjacent unit data section strings.

The control unit 25 detects a change in the signal output from at least one detection unit 21, acquires the signal output synchronously from the group of detection units 21 at the timing of the signal change, and generates a data string. This allows the control unit 25 to accurately recognize the boundaries of the unit data section strings 14a, 14b, 14c, and 14d without being separately instructed on the timing of acquiring the signal output from the group of detection units 21, and to generate a data string for each unit data section string.

A memory area with a capacity for three data columns is reserved in the storage unit 24, and the control unit 25 stores the data columns obtained sequentially for each unit data section column as the information-holding medium 2 is inserted into the mounting unit 4 in the memory area reserved in the storage unit 24. For example, when the information-holding medium 2 is inserted into the mounting unit 4 with the starting unit data section column 14a at the top, three data columns obtained sequentially from the unit data section columns 14a, 14b, and 14c are stored in the memory area of the storage unit 24.

When the control unit 25 detects the data sequence "1, 0, 1, 0" corresponding to the specific mark pattern "present, absent, present, absent" in the X-direction sequence of the terminal side unit data section sequence 14d, it recognizes the digital code based on the data sequence stored in the memory unit 24 at that time, and executes processing according to the recognized digital code.

Hereinafter, the data sequence "1, 0, 1, 0" pattern corresponding to the above specific mark pattern "present, absent, present, absent" will be referred to as the end data sequence pattern, the mark pattern "absent, present, absent, present" obtained by inverting the permutation of the specific mark pattern will be referred to as the inverted specific mark pattern, and the data sequence "0, 1, 0, 1" pattern corresponding to the inverted specific mark pattern will be referred to as the inverted end data sequence pattern.

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

When the information reading device 3 is powered on, the control unit 25 secures a memory area in the storage unit 24 with a capacity for three data rows and erases the data in this memory area (step S1).

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

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

For example, when the information bearing medium 2 is inserted into the mounting section 4 with the starting end unit data section sequence 14a at the top, the mark pattern of the X-direction sequence of the starting end unit data section sequence 14a is detected first by the group of detection sections 21, but this mark pattern is different from the above-mentioned inverted specific mark pattern, and the data sequence is different from the above-mentioned inverted end data sequence pattern.

In contrast, when the information bearing medium 2 is inserted into the mounting section 4 with the end side unit data section sequence 14d at the beginning, the mark pattern of the -X direction permutation of the end side unit data section sequence 14d is detected first by the group of detection sections 21, and this mark pattern matches the above-mentioned inverted specific mark pattern, and the data sequence matches the above-mentioned inverted end data sequence pattern.

Therefore, when the data string matches the above-mentioned inverted end data string pattern, the control unit 25 executes error processing assuming that the information-holding medium 2 has been inserted in the insertion unit 4 in the reverse direction (step S4), and erases the data in the memory area of the storage unit 24 (step S5). An example of the error processing is a process of operating the operation unit 23 based on audio data such as an error message stored in the storage unit 24.

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

If the data string does not match the end data string pattern, the control unit 25 stores the data string in a memory area reserved in the storage unit 24 (step S7).

For example, when the information-bearing medium 2 is inserted into the mounting section 4 with the starting unit data section sequence 14a at the top, the mark patterns of the X-direction sequence of each of the unit data section sequences 14a, 14b, and 14c are detected in sequence by the group of detection sections 21, but the mark patterns of the X-direction sequence of each of the unit data section sequences 14a, 14b, and 14c are all different from the specific mark pattern described above, and the data sequences obtained from each of the unit data section sequences 14a, 14b, and 14c are all different from the end data sequence pattern described above. Therefore, the data sequences obtained in sequence from the unit data section sequences 14a, 14b, and 14c are stored in the memory area of the storage section 24.

On the other hand, if the data string matches the end data string pattern, the control unit 25 determines whether the memory area of the storage unit 24 is empty (step S8). If the memory area is not empty, i.e., if a data string is stored in the memory area, the control unit 25 then recognizes a digital code based on the data string stored in the memory area (step S9), and determines whether the digital code is appropriate based on whether the digital code is included in the table stored in the storage unit 24 (step S10).

For example, when the information-bearing medium 2 is inserted into the mounting section 4 with the leading unit data section sequence 14a at the top, and the data sequences obtained sequentially from the unit data section sequences 14a, 14b, and 14c are stored in the memory area of the storage section 24, the end data sequence pattern is detected in the data sequence obtained from the trailing unit data section sequence 14d as the information-bearing medium 2 is completely mounted in the mounting section 4. At that point, the data sequences obtained from the unit data section sequences 14a, 14b, and 14c are stored in the memory area of the storage section 24, and a digital code is recognized based on these data sequences. This digital code is included in the table of the storage section 24 as one of the digital codes to be assigned to the information-bearing medium 2, and is determined to be appropriate.

If the digital code is valid, the control unit 25 reads the audio data stored in association with the digital code from the memory unit 24 as an on-insertion performance process when the information holding medium 2 is inserted into the mounting unit 4, executes a performance process to operate the operation unit 23 based on the read audio data (step S11), and erases the data in the memory area of the memory unit 24 (step S12).

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

An example of a case in which the digital code is not correct is when the information-carrying medium 2 is moved back and forth during insertion into the mounting portion 4, the unit data section sequence 14a and the unit data section sequence 14b are detected multiple times by the group of detection units 21, and the data sequences obtained from the unit data section sequence 14a and the unit data section sequence 14b are stored in duplicate in the memory area of the storage unit 24.

When the information-holding medium 2 is attached to the attachment unit 4 and the above-mentioned attachment performance process (step S11) or error process (step S13) is executed, and then the information-holding medium 2 is removed from the attachment unit 4, the group of detection units 21 first detects the mark pattern of the X-direction sequence of the terminal side unit data section string 14d. The above-mentioned end data string pattern is detected in the data string obtained from the terminal side unit data section string 14d, but at this time, the memory area of the storage unit 24 has been erased and is empty (steps S12, S14).

In this way, when the data string matches the above-mentioned end data string pattern and the memory area is empty, the control unit 25 executes a performance process when the information holding medium 2 is removed from the mounting unit 4 (step S15), and erases the data in the memory area of the storage unit 24 (step S16). An example of the performance process when the information holding medium 2 is removed is a process of operating the operation unit 23 based on audio data such as sound effects stored in the storage unit 24.

The above-mentioned removal performance process is also executed when the information-holding medium 2 is removed from the mounting section 4 after the information-reading device 3 is powered on while the information-holding medium 2 is mounted in the mounting section 4.

In the above-described information processing system 1, the mark 13 is configured as a convex portion having a predetermined height, and binary data is assigned to the unit data section 11 of the information holding medium 2 depending on the presence or absence of the mark 13, but the data assigned to the unit data section 11 is not limited to binary data. For example, it is possible to use marks of different heights and assign ternary or more valued data to the unit data section 11 depending on the presence or absence of the mark and the mark height. Also, the mark 13 may be any mark that can take multiple discrete values for a specific physical quantity, and for example, the mark 13 can be configured by coloring the unit data section 11 with colors that have different reflectances.

1 Information processing system 2 Information carrying medium 3 Information reading device 4 Mounting section 10 Medium substrate 11 Unit data section 12 Groove (guided section)
13 Mark 14a Starting end side unit data section row 14b Unit data section row 14c Unit data section row 14d End end side unit data section row 20 Convex stripe (guide section)
21 Detector 23 Operation unit (processor)
24 Memory unit (processing unit)
25 Control section (processing section)

Claims (3)

an information storage medium having a medium substrate, and a unit data section string consisting of a plurality of unit data sections arranged on the medium substrate in a first direction, the unit data section strings being arranged in a second direction intersecting the first direction, marks for forming digital codes in the arrangement of the unit data sections being provided in some of the unit data sections, and in the arrangement in the second direction of the unit data section strings extending in the first direction, mark patterns consisting of permutations of the marks arranged in the first direction of two adjacent unit data section strings are different from each other;
an information reading device for reading a digital code formed in the array of the unit data portions of the information storage medium;
Equipped with
The information reading device is
a mounting portion to which the information bearing medium is mounted with the information bearing medium being moved relative to the second direction;
a plurality of detection units arranged in a direction parallel to the first direction of the information bearing medium mounted in the mounting unit, the detection units being provided in the same number as the number of unit data sections constituting one unit data section string in the mounting unit, the detection units detecting the marks provided in the unit data sections of the information bearing medium and outputting a signal corresponding to the detection result;
a processing unit which generates a data string by treating a plurality of signals output from the plurality of detection units when one unit data section string passes above the plurality of detection units as a unit at a timing when a signal output from at least one of the detection units is switched , and recognizes the digital code based on a group of the data strings obtained sequentially for each unit data section string of the information bearing medium;
having
The information reading device further includes an operating unit and a storage unit that stores operation data for operating the operating unit in association with the digital code,
the processing unit of the information reading device, when recognizing the digital code, reads out from the storage unit motion data corresponding to the recognized digital code, and causes the motion unit to output a performance including at least one of sound and light emission based on the read motion data;
the mark of the information bearing medium is a protrusion formed on a surface of the medium substrate,
A performance output system , wherein the detection unit of the information reading device is a switch that is pressed by the convex portion . The performance output system according to claim 1,
the information bearing medium further includes a guided portion provided on the medium substrate and extending in the second direction,
A performance output system in which the mounting portion of the information reading device is provided with a guide portion that engages with the guided portion of the information holding medium to guide relative movement of the information holding medium in the second direction. The performance output system according to claim 2,
the guided portion of the information bearing medium is a groove,
A performance output system in which the guide portion of the information reading device is a convex rib extending in a direction parallel to the second direction of the information bearing medium attached to the attachment portion.

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