JP5585302B2 - Cryptographic recording medium - Google Patents

Description

  The present invention relates to an encryption recording medium that is recorded in an irregular pattern encrypted so that the recorded image cannot be visually recognized in a normal state, and is visualized by superimposing a decryption pattern at the time of restoration. .

  In a normal state, there is a long-standing need to use information recorded in a concealed state when it is needed. For example, concealment seals and crimping postcards are familiar examples. These are one-time use (disposable) and are suitable for temporary use. On the other hand, while maintaining high secrecy when not in use, they can be restored by simple operation when used, and It is very difficult to satisfy the conflicting demands that can be used repeatedly.

  There is a visual decryption type encryption technique called a visual decryption type secret sharing method as one of the techniques for the above requirements. This is to process the original image information into an unrecognizable image by dispersing it into multiple cryptographic patterns (called shared images) composed of irregular patterns, and then superimposing these shared images Thus, the original image information is restored to a visible state.

For example, Patent Document 1 is an invention related to visual decryption encryption technology, and relates to a configuration and production of a recording medium that conceals information without using a concealment layer or the like using a visual decryption secret sharing method. Disclosure.
Various methods have been proposed for the visual decryption secret sharing method, the shared image generation means, and the like, and the principle and generation method are described in detail in Non-Patent Document 1, which is a pioneering paper. .

JP 2001-118122 A

M.Naor and A.Shamir, "Visual Cryptography", Proc. Of Eurocrypt'94 May 1994

  As described above, the visual decryption secret sharing method is advantageous in that it can be restored by visual manual operation. On the other hand, a plurality of shared images are generated from the original image (original image). For this reason, the same number of media as the number of shared images is required for one original image, and in addition, in order to restore the original image, an operation of precisely superimposing the plurality of media is required.

  FIG. 7 is a diagram showing the process of encryption and restoration using the visual decryption secret sharing method. As shown in FIG. 7, in the encryption process, the original image 10 is a share of irregular patterns. It is decomposed into images. In the share image A11 and the share image B12 generated in this way, an irregular pattern is only visually recognized independently, and significant information cannot be read. In the example of FIG. 7, there are two share images, but the number of share images may be two or more.

  Thus, in the normal visual decoding secret sharing method, each pixel constituting the shared image is constituted by a set of white and black cells. Here, the white cell refers to an area where nothing is applied when printing, and is a transparent area in a transparent object such as a film.

  In order to restore the original image from the share image, the share image A11 and the share image B12 may be superimposed at a predetermined position. As a result, a pattern such as the restored image 13 appears. As shown in FIG. 7, the irregular pattern is used as the background portion, and the shape of the original image “T” (referred to as the “image portion” relative to the background portion) is obtained. Can be read. This is because the image line portion appears due to the difference in shading due to the black cell density being different between the background portion and the image line portion.

  However, if the density of the black cells is simply different between the background portion and the image line portion, there is a problem that the outline of the image line portion becomes confused with the background and the shape of the image line portion becomes difficult to read. This is particularly noticeable when the pixel density is low. FIGS. 8A and 8B show the difference in the restored image due to the density of the pixel density, and the restored image of the coarse cell pattern has an unclear outline compared to the restored image composed of the fine cell pattern 21. FIG. The shape of the line becomes difficult to read.

In addition, in such a shared image of black and white cells, a white portion appears with a slight shift in the overlap at the time of restoration, and the difference in density from the background becomes small. There is a problem that becomes difficult. 8 (C) and 8 (D) show the restored image depending on the presence or absence of a deviation. In the restored image 23 without a deviation, the shape of “8” can be read, but a slight deviation is caused in the overlay. In the restored image 24 having a deviation, the image line portion and the background portion cannot be distinguished.
Hereinafter, in the present invention, a cell corresponding to a black cell is referred to as an information cell, and a cell corresponding to a white cell is referred to as a blank cell.

  Therefore, an object of the present invention is to provide an encryption recording medium that can easily read a restored image when restoring an original image from two shared images while using a visual decryption secret sharing method.

The first invention of the present application that solves the above problems is as follows.
A first recording medium consisting of a first base material and an encrypted image, a second base material having visibility and a second recording medium consisting of an encrypted image, and a visual decryption type secret from the original image Of the first and second encrypted images generated by the dispersion method, the first encrypted image is at a predetermined position on the first base material, and the second encrypted image is at a predetermined position on the second base material. The original image is decrypted so as to be visible when the second encrypted image is superimposed on the first encrypted image and observed from the second substrate side. In an encryption recording medium,
The first encrypted image and the second encrypted image are composed of a set of minute cells in which each pixel constituting the encrypted image is divided in a matrix, and the minute cell is either an information cell or a blank cell. The information cell in the first encrypted image is formed as a colored layer exhibiting a first color on the first base material, and the information cell in the second encrypted image is the second information cell. the said the surface on the side of the base material observed first color is a cipher recording medium, characterized in that it is formed as a colored layer exhibiting a different second color.
Furthermore, a light shielding layer is provided between the second base material and the colored layer exhibiting the second color so as to overlap the colored layer.

The second invention of the present application is
A first recording medium consisting of a first base material and an encrypted image, a second base material having visibility and a second recording medium consisting of an encrypted image, and a visual decryption type secret from the original image Of the first and second encrypted images generated by the dispersion method, the first encrypted image is at a predetermined position on the first base material, and the second encrypted image is at a predetermined position on the second base material. The original image is decrypted so as to be visible when the second encrypted image is superimposed on the first encrypted image and observed from the second substrate side. In an encryption recording medium,
The first encrypted image and the second encrypted image are composed of a set of minute cells in which each pixel constituting the encrypted image is divided in a matrix, and the minute cell is either an information cell or a blank cell. The information cell in the first encrypted image is formed as a colored layer exhibiting a first color on the first base material, and the information cell in the second encrypted image is the second information cell. The encryption recording medium is characterized in that the substrate is formed as a colored layer exhibiting a second color different from the first color on the surface of the first recording medium side .
Furthermore, a light-shielding layer that overlaps the colored layer is provided on the colored layer exhibiting the second color.

  According to the encryption recording medium of the present invention, the image to be restored by forming the shared image with the colored layer has a hue difference between the background portion and the image line portion in addition to the difference in lightness (darkness difference). Since the difference occurs, the shape of the image line portion can be clearly read.

The figure which shows the encryption recording medium of this invention The figure which shows the structure of the encryption recording medium of this invention A diagram showing an encryption pattern by a conventional visual decryption secret sharing method The figure which shows the encryption pattern of the encryption recording medium of this invention The figure which shows the mode of the decompression | restoration by the encryption recording medium of this invention The figure which shows the structural example of the encryption recording medium of this invention Conceptual diagram of visual decryption secret sharing method The figure which shows the restoration picture by the conventional visual decoding type secret sharing method

FIG. 1 is a schematic diagram of an encryption recording medium of the present invention.
The encryption recording medium 1 of the present invention includes a medium A5 and a medium B6. FIG. 1 shows a state in which the medium A5 on which the encrypted image a7 is recorded and the medium B6 on which the encrypted image b8 is recorded are superimposed. Represent. The base material of the medium B6 has visible transparency, and the encrypted image a7 and the encrypted image b8 are each composed of minute cells colored with a specific color. When the two media are superposed at a predetermined position, a restored image is obtained. 9 appears.
FIG. 2 is a configuration diagram of the encryption recording medium of the present invention, showing a state in which a medium B6 is overlapped on a medium A5 at a predetermined position and minute cells of both the mediums overlap each other.
The first medium (medium A5) is composed of the first base material (base material A500) and the minute cells formed by the colored layer A501 having the first color, while the second medium (medium B6). Consists of microcells formed by the second substrate (transparent substrate B600) and the colored layer B601 having the second color, and in the example of FIG. A light shielding layer 101 having a size is provided between the colored layer B601 and the transparent substrate B600.

Hereinafter, the features of the present invention will be described in detail with reference to FIGS.
First, a share pattern based on the conventional visual decryption secret sharing method will be described.
As shown in FIG. 3, the share pattern based on the conventional visual decryption encryption technique is a small area that is a small region having an integer ratio (2 × 2 in the example) of pixels constituting the original image (original image pixel 30). It is generated by dividing into cells (hereinafter, a minute cell is simply referred to as a cell) and assigning white or black to each divided cell 35. A set of cells in which white or black is arranged in this way is called a share pattern.

  The share pattern generated in this way is a pixel constituting the share image A and the share image B. That is, the share pattern a32a and the share pattern a33a are the pixels of the share image A, and the share pattern b32b and the share pattern b33b are the pixels of the share image B. Then, when the share image A and the share image B are overlapped and the original image is restored, the overlap of the two patterns such as the share pattern a32a and the share pattern b32b is “white” and “black” like the restoration pixel 32. "Is a pixel representing the crossed" background part ", and the overlapping of the two patterns of the share pattern a33a and the share pattern b33b becomes a pixel representing the" image part "of only" black "like the restored pixel 33.

Next, the encryption pattern of the encryption recording medium of the present invention will be described.
In generating the encryption pattern of the encryption recording medium of the present invention, as shown in FIG. 4, first, it is divided into cells 45 which are 2 × 2 small areas as in FIG. Here, in the encryption pattern of the present invention, the first or second color is arranged in the information cell 46 of the cells 45 in place of the black. That is, if the first color is α color and the second color is β color, α color is arranged in the series of share pattern a and β color is arranged in the series of share pattern b. 42a and 43a, and 42b and 43b share patterns composed of β-colored micro cells are generated. As a result, the pattern of the share pattern a42a and the share pattern a43a becomes a pixel constituting the share image A, and the pattern of the share pattern b42b and the share pattern b43b becomes a pixel constituting the share image B.
In FIG. 4, the α color and the β color are differentiated by applying different shading.

  When the share image A and the share image B are overlapped, the overlap of the two patterns such as the share pattern a42a and the share pattern b42b becomes a pixel representing the “background portion” like the restoration pixel 42, and the share pattern a43a and the share pattern The superposition of the two patterns b43b is a pixel representing the “image portion” like the restored pixel 43.

  When the α color and the β color are different from each other, the α color and the β color overlap each other, and the α color is concealed by the β color. Become. In addition, the image area representing the shape of the original image is visually recognized as an area filled with α and β colors, and a color difference occurs between the background area and the image area, so the shape of the image area is clear. Can be read.

However, when the α color and the β color overlap each other, the α color must not appear through the β color so that the α color is hidden by the β color. That is, it is essential that the light transmittance of the β colored layer is small. On the other hand, since the color rendering properties (color clarity) and light transmittance of the colored layer are generally in a contradictory relationship, the encryption recording medium of the present invention overlaps with the colored layer B601 as shown in FIG. Is provided. In addition, the light shielding layer 101 is provided in the same position on the base material as the colored layer B601, and is provided between the colored layer B601 and the transparent base material B600 in the example of FIG.
As a result, the β color is clearly visible without the α color being transparent, so that the image line portion and the background portion can be clearly identified.

FIG. 5 is a diagram showing a process of encryption and restoration in the encryption recording medium of the present invention.
First, the original image 10 is decomposed into a share image A11 and a share image B12 using a visual decryption type secret sharing method. Subsequently, in the encryption recording medium of the present invention, α color is arranged in the “black” area of the share image A11 and β color is arranged in the “black” area of the share image B12. In the example of FIG. 5, the α color cell 55 is indicated by a solid black color, and the β color cell 56 is indicated by a shaded state to distinguish them.

When the colored image A51 composed of the α-color cells 55 colored in this way and the colored image B52 composed of the β-color cells 56 are superimposed at a predetermined position with the colored image B52 facing upward, a restored image 53 appears. . At this time, since the α color cell 55 is concealed by the β color cell 56 in the “background part”, an irregular pattern of β color appears, and the “image line part” is dull in the α color region 58 and the β color region 59. Appears in a distributed state. As a result, not only mere shade differences but also color differences occur between the background portion and the image line portion, so that the shape of the image line portion (the shape of “T” in the original image) can be more clearly recognized.
Further, even if there is a slight shift as seen in FIGS. 8C and 8D in the superimposed shared image, there is a difference in color between the background portion and the image line portion. The shape is clearly visible.

FIG. 6 is a configuration example of the encryption recording medium of the present invention, and FIG. 6A of a configuration example equivalent to FIG. 2 is also shown for comparison.
In FIG. 6B, the medium B6 is overlaid on the medium A5 so that the surfaces on which the colored layers are formed are in close contact with each other. In such a structure, the colored layer B601 is shielded from the transparent substrate B600. It is placed between the layers 101. Thereby, the colored layer B601 is observed through the transparent base material B600, and the colored layer A501 is concealed by the light shielding layer 101.
In the structure of FIG. 6B, the surface on which the colored layer A501 is formed and the surface on which the colored layer B601 are formed face each other, so that the colored layer A501 and the colored layer B601 are attached to the base material. When viewed from the same plane, they are mirror images of each other.

As the base material of the encryption recording medium of the present invention, various materials can be applied. Examples of the base material suitable for the medium A5 include paper and resin sheets. For example, for card use, a polyvinyl chloride resin, Examples include amorphous polyethylene terephthalate (PET-G) resin, polycarbonate resin, and polylactic acid resin. Further, the base material for the medium A5 may be transparent or opaque.
As the base material for the medium B6, a polymer having transparency is suitable, and examples thereof include polyvinyl chloride resin, amorphous polyethylene terephthalate (PET-G) resin, polycarbonate resin, and polylactic acid resin.

  The encryption image formed on the base material may be formed on the sheet-like base material by printing or ink jet as a simple method. As a color material for forming the colored layer A 501 and the colored layer B 601, for example, a low-priced material such as printing ink can be used, and as a material used for the light shielding layer 101, it is essential to have a light shielding property. Further, it is desirable that the thickness of the layer is thin. Examples of thin and excellent light-shielding properties include metal films such as aluminum vapor deposition. Printing ink can also be applied. For example, white ink mainly composed of titanium oxide has excellent light shielding properties. The thickness of the ink layer of the printing ink is preferably 2 to 5 μm in a dry state and exhibits an effective light shielding property.

1 Cryptographic recording medium 7 Cryptographic image a
8 Encrypted image b
9 Restored image 10 Original image 11 Share image A
12 share image B
13 restored image 30 original image pixel 31 division pattern 32 restored pixel 33 restored pixel 40 original image pixel 41 divided pattern 42 restored pixel 43 restored pixel 51 colored image A
52 Colored Image B
53 Restored image 101 Shading layer 500 Base material A
501 Colored layer A
600 Base material B
601 Colored layer B

Claims (4)

A first recording medium consisting of a first substrate and an encrypted image, and a second recording medium consisting of a second substrate having visible transparency and an encrypted image,
Of the first and second encrypted images generated from the original image by the visual decryption secret sharing method, the first encrypted image is at a predetermined position of the first base material, and the second encrypted image is When the second encrypted image is formed on a predetermined position of the second base material, and the second encrypted image is superimposed on the first encrypted image and observed from the second base material side , the original In the encryption recording medium that decrypts the image to be visible,
The first encrypted image and the second encrypted image are composed of a set of minute cells in which each pixel constituting the encrypted image is divided in a matrix, and the minute cell is either an information cell or a blank cell. The information cell in the first encrypted image is formed as a colored layer exhibiting a first color on the first base material, and the information cell in the second encrypted image is the second information cell. cipher recording medium, characterized in that the said the surface on the side of the base material observed first color is formed as a colored layer exhibiting a different second color. 2. The encryption recording medium according to claim 1, wherein a light-shielding layer that overlaps the colored layer is provided between the second substrate and the colored layer exhibiting the second color. A first recording medium consisting of a first substrate and an encrypted image, and a second recording medium consisting of a second substrate having visible transparency and an encrypted image,
Of the first and second encrypted images generated from the original image by the visual decryption secret sharing method, the first encrypted image is at a predetermined position of the first base material, and the second encrypted image is When the second encrypted image is formed on a predetermined position of the second base material, and the second encrypted image is superimposed on the first encrypted image and observed from the second base material side , the original In the encryption recording medium that decrypts the image to be visible,
The first encrypted image and the second encrypted image are composed of a set of minute cells in which each pixel constituting the encrypted image is divided in a matrix, and the minute cell is either an information cell or a blank cell. The information cell in the first encrypted image is formed as a colored layer exhibiting a first color on the first base material, and the information cell in the second encrypted image is the second information cell. An encryption recording medium, wherein the base material is formed as a colored layer exhibiting a second color different from the first color on the surface of the first recording medium side . 4. The encryption recording medium according to claim 3, wherein a light-shielding layer overlapping with the colored layer is provided on the colored layer exhibiting the second color.

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