JPH08194797A - Data propriety recognition method, and recording body and recognition device for it - Google Patents

Abstract

PURPOSE: To provide a method for recognizing the propriety of data capable of accurately discriminating whether the data is not altered nor forged by proper, and a recording body and a recognition device to be used in the method. CONSTITUTION: Data obtained by combining data in a hologram data recording part 20 on a credit card 10 and data in a magnetic data recording part 16 and weighting it is recorded in a weighted data recording part 18. Laser beam is applied to the hologram data recording part 20 to reproduce a picture on a screen. Magnetic data in the magnetic data recording part 16 and picture data reproduced on the screen are combined to give the same processing as data in the weighed data recording part 18 by a controller 116. A comparator 118 compares data obtained by the controller 116 and data in the weighted data recording part 18.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for recognizing correctness of data, a recording medium used for the method, and a recognition device,
In particular, for example, a method for recognizing the validity of data for confirming whether the magnetic data recorded on a credit card or a magnetic disk or the IC data recorded on an IC card is valid, and a recording medium used therefor And a recognition device.

[0002]

2. Description of the Related Art For example, in a credit card or an IC card, a sheet on which an image is formed by hologram is attached to prevent forgery. Such sheets include
An image is formed by, for example, a rainbow hologram. An image formed by such a rainbow hologram can reproduce a relatively clear three-dimensional image even when white normal light such as sunlight is used as reproduction light. In order to form an image by such a rainbow hologram, a relatively high technology is required and it cannot be easily forged. Therefore, by sticking this sheet to a credit card, an IC card, or the like, it is possible to prove that the card is a legitimate credit card or IC card that is not forged.

A magnetic data recording section is formed on the credit card to record personal identification data such as a personal identification number. Then, the data in the magnetic data recording unit is read, and the user presses the personal identification number with a numeric key or the like to collate the data with the data in the magnetic data recording unit to confirm that the user is who he / she is. In the IC card, such data is recorded in the IC.

Further, in some prepaid cards and the like, an identification code which can be identified by reflected light of infrared rays is printed on the card, and the identification code is read to identify the authenticity of the card. Further, there is a method in which an identification mark is printed using a special ink that can be seen only when irradiated with ultraviolet rays, and the authenticity of the card is identified based on the presence or absence of the identification mark. Further, some magnetic recording units have a two-layer structure, and magnetic recording data is encrypted to prevent data tampering and unauthorized copying.

[0005]

However, in the method using the hologram sheet or the infrared rays and the ultraviolet rays, the authenticity of the card itself can be identified, but the contents recorded in the magnetic data or IC data are valid. I can't identify if. For example, if the validity of the card is confirmed by a hologram sheet or the like, but the data such as the personal identification number is tampered with, the credit card or the I
There is a risk of unauthorized use of C cards and the like.

Further, money data is recorded on the prepaid card, and the money data is rewritten every time it is used. Considering this, the magnetic data recording unit is
It is possible to falsify or illegally copy the magnetic data even if it has a layered structure or the magnetic data is encrypted. As described above, in the conventional method, there is no method for recognizing the authenticity that the magnetic data is not falsified or forged although the authenticity of the card itself can be identified.

Therefore, a main object of the present invention is to provide a method for recognizing the correctness of data, which can accurately determine whether the data is authentic, not falsified or forged. Another object of the present invention is to provide a recording body and a recognition device used in such a method for recognizing the validity of data.

[0008]

According to the present invention, there is provided a hologram data recording section in which image data of a hologram is recorded, a data recording section in which data is recorded, data in the hologram data recording section and data in the data recording section. A step of preparing a recording body having a weighted data recording section in which weighted data is recorded in combination, a step of reading data in the hologram data recording section, a step of reading data in the data recording section, A step of creating weighted data by combining the data of the hologram data recording section and the data of the data recording section by performing the same processing as the data of the data recording section, and the data of the hologram data recording section and the data of the data recording section. And the weighted data and the data in the weighted data recording section are compared. To include a step, a validity recognition method data. In this method of recognizing the validity of data, it is possible to perform arithmetic processing for combining the data of the hologram data recording section and the data of the data recording section for encryption, and weight the arithmetically processed data. The data recorded in the hologram data recording section is preferably formed by a Fourier transform hologram. Further, it is possible to add a step of newly recording the weighted data by combining the data of the hologram data recording section and the data of the data recording section in the weighted data recording section.

Further, according to the present invention, a substrate, a hologram data recording section in which image data of a Fourier transform hologram is recorded on the substrate, a data recording section in which data is recorded on the substrate, and hologram data on the substrate. A recording body including a weighted data recording unit in which data of the recording unit and data of the data recording unit are combined and weighted data is recorded. In this recording medium, the substrate can be a card.

Further, the present invention provides a laser beam emitting device, a screen mounted in the reflection direction of the laser beam for receiving the laser beam emitted by the laser beam emitting device on the hologram forming surface, and An image reading device for reading the image reproduced on the screen, a data reading device for reading the data recorded in the data recording unit, data obtained by the image reading device and data obtained by the data reading device A control device for performing weighting by combining and a comparison device for comparing the data obtained by combining the data of the hologram forming surface and the data of the data recording unit in advance and the data obtained by the control device. It is a recognition device including. In this recognition device, a writing device for writing the data obtained by the control device into the weighted data recording unit may be added. Also, the laser light is applied to the hologram forming surface at a predetermined angle.
Further, the laser light emitting device is equipped with a diffusion adjusting lens for adjusting the diffusivity of the laser light.
Moreover, it is desirable that the screen be white with irregularities on its surface. Further, the image reading device is provided with a reading adjustment lens for clearly reading the image reproduced on the screen.

[0011]

By combining and weighting the data in the hologram data recording section and the data in the data recording section, it is possible to create data that cannot be easily decoded. Then, the weighted data is recorded in the weighted data recording section of the recording medium. If necessary, arithmetic processing for encrypting the combined data is performed, and the arithmetically processed data is weighted. In order to identify whether the data in the data recording unit is valid, the data in the hologram data recording unit and the data in the data recording unit are read. These data are weighted in the same way as the data recorded in the weighted data recording section. The weighted data is compared with the data in the weighted data recorder.

By forming the data of the hologram data recording section by the Fourier transform hologram, the data cannot be reproduced by natural light, but the data is reproduced by reflecting the laser light. An image formed by a Fourier transform hologram is formed by interference fringes of laser light, and its resolution is 1000 to 2000 lines / mm.
Further, when the data in the data recording unit is changed, the changed data and the data in the hologram data recording unit are combined, weighted, and then newly written in the weighted data recording unit.

The legitimacy of the data in the data recording section is confirmed by reading the data in the hologram data recording section, the data recording section and the weighted data recording section of the recording medium and comparing them by the above method. Here, if a card is used as the base, it can be used as, for example, a credit card, an IC card, a prepaid card, or the like, and the validity of data such as a personal identification number or amount data is confirmed.

A laser beam is emitted from the laser beam emitting device of the recognition device to the hologram data recording portion of the recording medium.
The image recorded in the hologram data recording unit is reproduced on the screen by the laser light reflected by the hologram data recording unit. The image reproduced on the screen is read by the image reading device. The data recorded in the data recording unit is read by the data reading device. These data are combined and weighted by the controller. Further, the data pre-weighted and recorded in the weighted data recording unit and the data obtained by the control device are compared by the comparison circuit. The legitimacy of the data in the data recording section is determined depending on whether these data match.

When the data of the recording medium is changed, the changed data and the data of the hologram data recording unit are combined and weighted, and the writing device newly writes the weighted data recording unit. Therefore, in the next correctness recognition, the data component included in the data of the weighted data recording unit matches the data of the changed data recording unit.

The laser light is applied to the hologram forming surface at a predetermined angle so that the laser light is reflected by the hologram forming surface and reaches the screen. This laser light is diffused by the diffusion adjusting lens, and the width of the laser light is adjusted. Thereby, the energy per unit area of the laser light irradiation surface is adjusted. Further, by making the screen white with unevenness, the hologram image can be reproduced clearly and the shade of the image can be made clear. Furthermore, by using a reading lens,
The image reproduced on the screen is clearly read by the image reading device.

[0017]

According to the present invention, by recording the unique data as the hologram data, the weighted data combined with the data recorded in the data recording section cannot be easily decoded. This data is recorded in the weighted data recording section. Therefore, it is possible to confirm whether the data has been tampered with by combining the hologram data and the data in the data recording unit, weighting them, and collating with the data in the weighted data recording unit. Further, if the combined data is weighted after performing the cryptographic function calculation, it becomes more difficult to know what data is recorded, and it is difficult to forge the weighted data. Therefore, even if the data in the data recording unit is falsified, the weighted data cannot be falsified, and the validity of the data can be surely confirmed.

Particularly, if an image is recorded in the hologram data recording section by using a Fourier transform hologram, the image cannot be reproduced by natural light and the resolution can be improved. Therefore, the hologram data must be decoded. Will be difficult. Therefore, it becomes difficult to forge the weighted data, and the correctness of the data can be surely recognized. In the case of a recording body such as a prepaid card in which the amount data changes, by writing new data in the weighted data recording section every time the card is used, the validity of the data can be recognized at the next use.

As a recording medium using such a method, a recording medium having a hologram data recording section, a data recording section and a weighted data recording section is used. If a card is used as the substrate of such a recording medium, it can be used as a credit card, an IC card, a prepaid card, or the like. In such a recording medium, it is possible to confirm whether or not the data in the data recording section is valid by using the above method.

Further, the data of such a recording medium is read by a data reading device and an image reading device. The above method is implemented by combining these data, weighting them by the control device, and comparing them with the data of the weighted data recording section by the comparison circuit. For data such as a prepaid card whose data is changed, weighted data using new data is written in a recording medium by a writing device. Therefore, the correctness of the data in the data recording section can be confirmed even at the next use.

Further, by adjusting the width of the laser light with the diffusion adjusting lens, the energy per unit area on the laser light irradiation surface can be adjusted. Therefore, even if the laser beam accidentally hits the eyes, safety can be ensured. Further, by making the screen white with unevenness, it is possible to clearly reproduce the image of the hologram data. In particular, by making the screen white, the contrast of the image can be made clear and the image can be read easily. In addition, the image read on the screen can be clearly read by the reading lens, and the data can be read without fail.

The above-mentioned objects, other objects, features and advantages of the present invention will become more apparent from the following detailed description of the embodiments with reference to the drawings.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is an illustrative view showing a credit card as an example of a recording body whose legality can be confirmed by using the legality recognition method of the present invention. The credit card 10 includes a card-shaped base 12 made of, for example, paper or synthetic resin. The base 12 has a card name,
A display 14 such as a card number and a user name is formed. Further, on the substrate 12, a magnetic data recording section 16 on which a personal identification number and the like is magnetically recorded is formed as a data recording section. The magnetic data recording unit 16 is formed in a strip shape using, for example, a magnetic material. A weighted data recording unit 18 for recording weighted data, which will be described later, is formed at the end of the magnetic data recording unit.

Further, on one main surface of the substrate 12, a hologram data recording section 20 on which an image by a Fourier transform hologram is formed is formed. The hologram data recording unit 20 is formed, for example, by pasting a sheet on which an image formed by a Fourier transform hologram is formed. The data of the hologram data recording unit 20 and the data of the magnetic data recording unit 16 are combined, and the weighted data is recorded in the weighted data recording unit 18. Further, a hologram image portion 22 on which an image by a conventional image hologram is formed is formed on the base 12. The image of the hologram image portion 22 can be reproduced by natural light, and it can be confirmed that the credit card 10 is not forged.

In order to form an image by the Fourier transform hologram, as shown in FIG. 2, first, a photographing original plate 24 is formed. A pattern such as an image is formed on the original plate 24 for photographing. As the image, as shown in FIG. 3, for example, numbers, alphabets and various figures are used. Images unique to the user of the credit card 10 are used as these images.

These images are formed as a pattern on, for example, a stainless plate to form the original plate 24 for photographing. In this case, the pattern is formed on the stainless steel plate by the laser processing machine, and then the black coating is finished to have a satin finish to form the original plate 24 for photographing. As another method, the photographic original plate 24 may be formed by printing a pattern on a squirrel-type film. Further, a photoresist pattern may be formed on a stainless steel plate by using a squirrel-type film having a pattern printed thereon, etched with a ferric chloride solution, and then subjected to Parker treatment to obtain the photographing original plate 24.

A Fourier transform hologram is produced by using the obtained original plate 24 for photography and the optical system shown in FIG. In this optical system, laser light is emitted from the laser device 30, and this laser light is reflected by the half mirror 32.
Divided into two. The laser light reflected by the half mirror 32 is reflected by the reflection mirror 34 and spreads by passing through the lenses 36 and 38. The expanded laser light is
It becomes object light through the diffusion plate 40 and the original plate 22 for photographing. This object light is converged by the Fourier transform lens 42 and applied to the photographic dry plate 44. At this time, the original plate 2 for photography
2 and the photographic dry plate 44 are installed at the front focus and the rear focus of the Fourier transform lens 42. In this example,
The Fourier transform lens 42 has a short focal length of about 50 mm. It should be noted that by using the diffusion plate 40, the information of the original plate 22 for photographing can be dispersed uniformly.

The laser light transmitted through the half mirror 32 is reflected by the reflection mirror 46 and is expanded by the lenses 48 and 50. The spread laser light is applied to the photographic plate 44 as reference light at a predetermined angle with the object light. Therefore, an interference fringe is formed by the object light and the reference light, and this interference fringe is recorded on the photographic dry plate 44. In this way, the information of the original plate 22 for photography is recorded on the photographic plate 44.
It is formed as an image by a Fourier transform hologram.

To form an image by a Fourier transform hologram, a lensless Fourier transform hologram method may be used as shown in FIG. In this method, the object light is applied to the photographic dry plate 44 without being converged by the Fourier transform lens. Further, the reference light is expanded by one lens 48 and is applied to the photographic dry plate 44. At this time, the distance between the original plate 22 for photography and the photographic dry plate 44 is set to be the same as the distance between the lens 48 and the photographic dry plate 44. In this method, the object light is a Fresnel diffracted wave on the surface of the photographic dry plate 44, but during recording, the secondary phase term is canceled by the secondary phase term of the reference light to form a hologram similar to the Fourier transform hologram. .

Since these holograms record interference fringes on the surface irregularities, a large amount can be inexpensively reproduced by making a mold from the irregularities and hot pressing it on a thermoplastic. A method of manufacturing the embossed hologram thus obtained will be described with reference to FIG.

First, as shown in (A), the obtained hologram is prepared as an original plate 60. This original plate 60
Then, as shown in (B), a metal such as Au or Ag is vapor-deposited to form a conductive metal layer 62. As shown in (C), the nickel plating layer 6 is formed on the metal layer 62.
4 is formed. Then, as shown in (D), the nickel plating layer 64 is peeled off to form a mold 66. By hot pressing a thermoplastic resin using this mold 66, a hologram forming layer 68 which is a copy of the original plate 60 is obtained as shown in (E). Next, as shown in (F), a metal such as Al is vapor-deposited on the hologram surface of the hologram forming layer 68 to form a vapor deposition layer 70, and the adhesive layer 72 is formed on the vapor deposition layer 70. Further, the peeling layer 7 is formed on the surface of the hologram forming layer 68 on which the hologram is not formed.
4 and the base material 76 are formed. In this way, the embossed hologram seal 78 is obtained.

Then, as shown in (G), the obtained embossed hologram seal 78 is adhered to the base 12 and the base 76 is peeled off to form the sheet 20 on which an image by the Fourier transform hologram is formed. . In the sheet 20, even if the hologram forming layer 68, the vapor deposition layer 70, the adhesive layer 72 and the peeling layer 74 are included, it is several μm,
It can be formed so that there is almost no step with the base 12.

The data of the hologram data recording section 20 and the data of the magnetic data recording section 16 are combined and further subjected to arithmetic processing to create arithmetic data. For example, assume that the data in the hologram data recording unit 20 is the character "A". Further, it is assumed that the data in the magnetic data recording unit 16 has a personal identification number of "1111". Then, setting is made in advance so that “A” is replaced with “0010”. In order to combine these hologram data “0010” and magnetic data “1111”, two data are processed by an OR circuit, and “1111” is output. Furthermore, by setting so that "0001" is subtracted, data "1110" is obtained.
This calculation method is an example, and any cryptographic calculation method can be set.

The arithmetically processed data is further weighted. Normally, when recording numbers or the like on a prepaid card or the like, a system of Japanese Industrial Standard is used, and a magnetic field is generated by fixing a current applied to a writing and reading magnetic head. Then, the “H” signal is made to correspond to + 5V, the “L” signal is made to correspond to 0V, and numbers and the like are recorded. For example, when a decimal number "1" is represented by a 4-bit binary number, "0001" is obtained. When recording or reproducing this number, as shown in FIG. 7, "0" is associated with 0V and "1" is associated with + 5V. Therefore, the recorded information can be read by determining the outputs of 0V and + 5V.

On the other hand, in the method of the present invention, for example, as shown in FIG. 8, the "1" portion of "0001" is made to correspond to + 8V. Therefore, the decimal number "1" is read only after "+ 8V" is detected after three "0V". Furthermore, if the format of each number is decided in the case of the decimal number "2" or "3", the recorded information cannot be decrypted unless the format is clarified. Therefore, also in this embodiment, it is possible to make the information difficult to decipher by weighting the data "1110" that is calculated by combining the hologram data and the magnetic data in a unique format.

This data is data in which hologram data and magnetic data are combined, further processed, and then weighted. By setting such a calculation method and further weighting, weighted data obtained by combining the data of the hologram data recording unit 20 and the data of the magnetic data recording unit 16 can be obtained. This weighted data is recorded in the weighted data recording unit 18. Of course, the hologram data and the magnetic data are unique to the user of the credit card 10. Therefore, the weighted data is unique to each individual.

Whether or not the credit card 10 itself is valid is confirmed by looking at the image of the hologram image section 22. However, when the personal identification number of the magnetic data recording unit 16 of the credit card 10 is tampered with, it is difficult to distinguish it. Therefore, in order to confirm whether the data in the magnetic data recording unit 16 is valid, the recognition device 10 as shown in FIG.
0 is used. The recognition device 100 includes a case 102, and the case 102 is formed with a slit 103 through which the credit card 10 is inserted. In case 102,
As shown in FIG. 10, the laser light emitting device 104 is attached. A divergence lens 106 is formed in the laser light emitting device 104, and the width of the laser light can be changed by adjusting the divergence lens 106. Especially by expanding the width of the laser light,
The energy per unit area of the laser light irradiation surface can be reduced, and the safety when hitting the human eye is increased.

Further, in the case 102, a screen 108 is attached adjacent to the laser beam emitting device 104. The screen 108 is attached so that its main surface is parallel to the main surface of the hologram data recording unit 20. Then, the laser light reflected by the hologram data recording unit 20 hits the screen 108, and the image formed on the hologram data recording unit 20 is reproduced.
The screen 108 has a transmission / diffusion property and fine irregularities are formed on the surface thereof. This is to make the reproduction of the image by the laser light clear. Further, the screen 108 is formed in white. By making the screen 108 white, the gradation of the reproduced image can be made clear and the reading of the image can be facilitated.

Further, a hologram data reading device 110 for reading the data of the hologram data recording section 20 is attached to the upper part of the screen 108.
As the image reading device 110, for example, a CCD image sensor or the like is used. Image reading device 110
A reading lens 112 is attached to the display, and the image reproduced on the screen 108 can be clearly read by adjusting the reading lens 112.

A magnetic data reader 114 and a magnetic head 115 for reading data from the magnetic data recording unit 16 and the weighted data recording unit 18 are mounted in the case 102. The magnetic data reading device 114 and the magnetic head 115 are formed near the slit 103, and when the credit card 10 passes through the slit, the data in the magnetic data recording unit 16 and the weighted data recording unit 18 are read. Further, a control device 116 is formed to perform arithmetic processing and weighting on the data read by the image reading device 110 and the data read by the magnetic data reading device 114. In the control device 116, each data is processed so as to be easily processed, and the hologram data and the magnetic data are combined, arithmetically processed, and further weighted. As the calculation method and the weighting method, the same method as that for creating the above-mentioned weighted data is used. Therefore, if the hologram data and the magnetic data have not been tampered with, the control device 116 can obtain the same data as the data of the weighted data recording unit. Further, in the case 102, a comparison device 118 is formed. The comparison device 118 is for comparing the data processed by the control device 116 with the data of the weighted data recording unit 18.

In order to confirm the validity of the data recorded in the magnetic data recording section 16 of the credit card 10 using this device, the credit card 10 is used as the recognition device 10.
It is passed through the 0 slit 103. At this time, the hologram data recording unit 20 is controlled by the laser beam emitting device 104.
The laser light is radiated at a predetermined angle. The laser light reflected by the hologram data recording unit 20 is reflected by the screen 1
The image formed by the Fourier transform hologram is reproduced on 08. Since the screen 108 is formed in a white color having irregularities, the shape and shade of the image can be reproduced clearly. Then, the hologram data recording unit 20
Data is read by the image reading device 110.
At this time, the image can be accurately read by adjusting the reading lens 112.

The data of the read image contains noise and also contains data other than the required image. Therefore, as shown in FIG. 11, the control device 116 performs image processing to remove noise included in the data. Further, the image data is classified into two-value data of a white part and a black part. For example, screen 10
When the inside of the image reproduced on 8 is black, the coordinates inside the image are classified into data corresponding to black, and the coordinates outside the image are classified into data corresponding to white. In order to perform such classification, it is preferable that the screen 108 be white so that the gradation of the reproduced image is clear. Further, the data classified into two values of white and black is converted into data of only the contour of the image. Thereby, the amount of information can be reduced as compared with the data corresponding to all the coordinates. Thus, by reducing the amount of information, the processing speed can be increased and the amount that can be stored can be increased.

Further, the data in the magnetic data recording unit 16 and the weighted data recording unit 18 are read by the magnetic data reading device 114. Magnetic data recording unit 1
The data of 6 is combined with the data of the hologram data recording unit 20, and further processed and weighted.
This calculation process and weighting are performed in the same manner as the data recorded in the weighted data recording unit 18. A program for performing such processing is previously stored in the control device 11
It is set to 6.

The data processed by the control unit 116 is compared with the data in the weighted data recording unit 18 by the comparison unit 118. Then, if the data processed by the control device 116 and the data in the weighted data recording unit 18 are the same, it is determined that the data in the magnetic data recording unit 16 is valid. If the two data are different, it is determined that the data in the magnetic data recording unit 16 has been tampered with or forged.

In this method, hologram data and magnetic data are combined, arithmetically processed, and further weighted. In order to obtain such weighted data, the weighting format set in the controller 116 must be clarified. Therefore, it is difficult to forge the weighted data. Therefore, even if the magnetic data can be falsified, the weighted data cannot be falsified, and the validity of the magnetic data can be confirmed.

In the case of a prepaid card or the like, money data is recorded as the data in the magnetic data recording section 16. And every time I use a prepaid card,
The used amount of money is subtracted and recorded in the magnetic data recording unit 16. In such a case, weighted data may be created from the subtracted amount data and the hologram data, and may be newly recorded in the weighted data recording unit 18. By doing so, the magnetic data component in the weighted data and the data in the magnetic data recording unit will match and the validity can be confirmed at the next use. In such a case, a magnetic reader / writer that doubles as a writing device is used as the magnetic data reading device 114. Then, the weighted data using the changed amount data is recorded in the weighted data recording unit 18.

In the above-described embodiment, the data in the hologram data recording section 20 and the data in the magnetic data recording section 16 are combined, subjected to cryptographic calculation processing and then weighted, but the cryptographic calculation processing is not always necessary. . That is, the data of the hologram data recording unit 20 and the data of the magnetic data recording unit 16 may be combined, and the combined data may be directly weighted. That is, according to the present invention, it is impossible to falsify the weighted data unless the format is elucidated by weighting the combined data. Of course, the protection of the weighted data is further ensured by using the cryptographic calculation process together.

Further, the weighted data recording section 18 does not need to be formed at the end of the magnetic data recording section 16, and is located at a position distant from the magnetic data recording section 16, for example, above the hologram image section 22. You may form. In this way, the position of the weighted data recording unit 18 cannot be known only by appearance, and it becomes more difficult to falsify the data.

A Fourier transform hologram is used as the data of the hologram data recording section 20 using this method. The image by the conventional rainbow hologram is
While its resolution is 100-200 lines / mm,
Fourier transform hologram 1000-2000 lines / m
m, and it is technically difficult to forge an image. Furthermore, if a special diffuser plate 40 is used when photographing a hologram, the same hologram cannot be produced unless the same diffuser plate is used, and forgery is difficult. Further, in order to forge a hologram, the shooting conditions must be the same, and the wavelength of the laser light, the incident angles of the object light and the reference light, the positions and sizes of the original plate for photography and the photographic dry plate, etc. must be matched. is there. It is difficult to find these shooting conditions from the hologram data recording unit 20, and it is difficult to forge them. For these reasons, the justification recognition method of the present invention can ensure the justification of the magnetic data as compared with the conventional card in which only the magnetic data recording portion is formed.

This justification recognition method can be applied not only to credit cards and prepaid cards but also to other cards using magnetic data, floppy disks, etc., and can prevent falsification and forgery of magnetic data.
Furthermore, it can be applied to the recognition of the validity of the IC data recorded on the IC card. In this case, an IC is used as the data recording unit. Then, similarly to the above-mentioned credit card, the data recorded on the IC and the hologram data are combined, and the arithmetic processing and the weighting are performed. By doing so, it is possible to confirm the validity of the data recorded in the IC.

[Brief description of drawings]

FIG. 1 is a plan view showing a credit card for recognizing the validity of magnetic data by the method of the present invention.

FIG. 2 is an illustrative view showing a photographic original plate used for forming a hologram data recording section.

FIG. 3 is a chart showing an example of an image recorded in a hologram data recording unit.

FIG. 4 is an illustrative view showing an optical system for producing a Fourier transform hologram.

FIG. 5 is an illustrative view showing an optical system for producing a lensless Fourier transform hologram.

6A to 6G are schematic views showing a process of producing an embossed hologram using a Fourier transform hologram as an original plate.

FIG. 7 is an explanatory diagram showing a relationship between a binary number and voltage according to Japanese Industrial Standards.

FIG. 8 is an explanatory diagram showing an example of a relationship between a weighted binary number and a voltage according to the present invention.

FIG. 9 is a perspective view showing an example of a recognition device used in the method of the present invention.

10 is an illustrative view showing the inside of the recognition device shown in FIG. 9. FIG.

FIG. 11 is an illustrative view showing a step when recognizing the validity of magnetic data by the method of the present invention.

[Explanation of symbols]

 10 credit card 12 base material 16 magnetic data recording unit 18 weighted data recording unit 20 hologram data recording unit 100 recognition device 102 case 104 laser light emitting device 106 divergence lens 108 screen 110 image reading device 112 reading lens 114 magnetic data reading Device 116 Control device 118 Comparison device

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location G06K 19/08 G09C 1/00 7259-5J H04B 10/105 10/10 10/22 (72) Invention Satoshi Isaka Satoshi Ichikawa 5-10-1 Ichikawa, Chiba Prefecture Soleil Ichikawa 201 (72) Inventor Hironori Sato 2-1 Miyake, Matsubara-shi, Osaka

Claims (12)

[Claims] 1. A hologram data recording section in which image data of a hologram is recorded, a data recording section in which data is recorded, and data in the hologram data recording section and data in the data recording section are combined and weighted. Preparing a recording body having a weighted data recording section recording the data, a step of reading data of the hologram data recording section, a step of reading data of the data recording section, and data of the weighted data recording section A step of creating weighted data by combining the data of the hologram data recording section and the data of the data recording section by performing the same processing, and the data of the hologram data recording section and the data of the data recording section Combined weighted data and the weighted data recording unit A method for recognizing correctness of data, including the step of comparing the data of. 2. The data according to claim 1, wherein the data of the hologram data recording unit and the data of the data recording unit are combined to perform an arithmetic process, and the arithmetically processed data is weighted. How to recognize the correctness of. 3. The method for recognizing the validity of data according to claim 1, wherein the data recorded in the hologram data recording section is formed by a Fourier transform hologram. 4. The method according to claim 1, further comprising a step of newly recording weighted data by combining data of the hologram data recording section and data of the data recording section in the weighted data recording section. Item 4. A method for recognizing the validity of data according to any one of Items 3. 5. A substrate, a hologram data recording unit in which image data of a Fourier transform hologram is recorded on the substrate, a data recording unit in which data is recorded on the substrate,
And a recording body including a weighted data recording unit on which data obtained by combining and weighting the data of the hologram data recording unit and the data of the data recording unit is recorded on the substrate. 6. The recording medium according to claim 5, wherein the substrate is a card. 7. A laser beam emitting device, a screen mounted in the reflection direction of the laser beam to receive the laser beam emitted by the laser beam emitting device on the hologram forming surface, and the screen is attached by the reflected beam on the screen. An image reading device for reading the reproduced image, a data reading device for reading the data recorded in the data recording unit, the data obtained by the image reading device and the data obtained by the data reading device. A controller for combining and weighting, and a comparing device for comparing the data obtained by combining the data of the hologram forming surface and the data of the data recording unit in advance and the data obtained by the controller. Including a recognition device. 8. The recognition device according to claim 7, further comprising a writing device for writing the data obtained by the control device into a weighted data recording unit. 9. The recognition device according to claim 7, wherein the laser light is applied to the hologram forming surface at a predetermined angle. 10. The recognition device according to claim 7, wherein a diffusion adjusting lens for adjusting the diffusivity of the laser light is attached to the laser light emitting device. 11. The recognition device according to claim 7, wherein the screen is white with unevenness on a surface thereof. 12. The recognition device according to claim 7, wherein the image reading device is provided with a reading adjustment lens for clearly reading an image reproduced on the screen. .