KR20220049439A - An encryption system using array-type holograms - Google Patents

Abstract

The present invention relates to an encryption system using an array type hologram, capable of providing improved security by forming a hologram structure including a combination of various colors, into an array form. To achieve the purpose, the encryption system includes: a code data generation part generating at least one piece of code data including encryption colors; a pattern data generation part generating pattern data including dithering patterns matched with the encryption colors respectively, based on the code data; and a pattern formation part forming a mask pattern on a dithering mask based on the pattern data, and arranging the dithering mask in an array form.

Description

An encryption system using array-type holograms

The present invention relates to an encryption system in which security is improved by manufacturing a hologram structure expressing various combinations of structural colors in an array type.

A hologram refers to a three-dimensional three-dimensional photograph created using the principle of holography, and refers to a medium in which optical interference fringes that reproduce a three-dimensional image are recorded.

However, with the recent development of technology, not only the conventional hologram using the principle of holography, but also various holograms such as a hologram using a diffraction grating structure, a floating hologram using a transparent film, and a hologram synthesized with digital images have been developed and used.

On the other hand, the scope of use of holograms is becoming very diverse, and in particular, it has been widely developed and used as a mark for distinguishing counterfeit goods. For example, a hologram sticker that guarantees authenticity is attached to a product that has been authenticated, and when a hologram image attached to a specific product is different from a hologram attached to a genuine product, it can be distinguished as a counterfeit product.

However, in the existing manufacturing method of hologram products, a hologram-only fabric, a film engraved with a hologram image, and an adhesive sticker must be separately manufactured and attached. There are problems in that it is limited, takes a long time to manufacture, and the cost is also high. Therefore, there is a problem in that it is practically impossible to mass-produce a variety of security hologram products with high security.

Moreover, since holograms manufactured in this way generally use material-based technology, if counterfeiters imitate the material, they can easily be counterfeited, making them vulnerable to security, and counterfeit manufacturers copy or counterfeit the hologram and distribute it. In this case, there is a problem that the response speed is slow and the response method is limited.

Therefore, it is possible to reduce the time and cost required for production by using a hologram having a combination of various colors, the possibility of forgery and duplication is low, and the development of an encryption method using a hologram with improved security is urgently required. the current situation.

The present invention has been devised to solve the above problems, and in detail, it is an object of the present invention to provide an encryption system using an array-type hologram that can improve security and reduce production time and cost.

However, these problems are exemplary, and the scope of the present invention is not limited thereby.

An encryption system using an array-type hologram according to the present invention,

An encryption data generation unit for generating at least one or more encryption data including an encryption color, a pattern data generation unit for generating pattern data including a dithering pattern corresponding to each encryption color based on the encryption data, and based on the pattern data to form a mask pattern on the dithering mask, and may include a pattern forming unit for arranging the dithering mask in an array type.

In addition, the encrypted data may be partitioned into at least one area, and one encryption color may be assigned to each area.

In addition, the encryption data may be partitioned into a grid-type area of MXN (M and N are natural numbers).

In addition, the encryption data generation unit may sequentially generate the at least one or more encryption data.

In addition, the sequentially generated encryption data may include a combination of at least one or more different encryption colors.

Also, the pattern data generating unit may convert the encrypted color into a dithering pattern corresponding thereto on a one-to-one basis.

In addition, the pattern forming unit may arrange a dithering mask to have a predetermined interval.

In addition, based on the hologram color information expressed in the dithering pattern, it may further include a result output unit for outputting a predicted array-type hologram encryption.

In addition, the result output unit may output a predicted array-type hologram encryption by further including information on changes in the hologram color according to the irradiation angle of the light source.

In addition, the result output unit may output a predicted array-type hologram encryption, further including information on changes in the hologram color according to the viewing angle of the observer.

In addition, it may further include a hologram manufacturing unit for manufacturing the hologram structure based on the dithering mask arranged in the array type.

In addition, the hologram structure may further include a decryption unit for confirming the structure color expressed by irradiating light.

An encryption system using an array-type hologram according to the present invention provides an encryption system with improved security by forming a hologram structure in which various colors are combined in an array type and easily changing the combination of colors included in the hologram as needed. can provide

1 is a diagram schematically illustrating an encryption system using an array-type hologram according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating an embodiment of the encryption data generating unit of FIG. 1 .
FIG. 3 is a diagram illustrating an embodiment of encrypted data generated by the encryption data generating unit of FIG. 1 .
FIG. 4 is a diagram illustrating an embodiment of the pattern data generator of FIG. 1 .
FIG. 5 is a diagram illustrating correlation information between an encrypted color and a dithering pattern stored in the second memory M2 of FIG. 4 .
6 is a diagram illustrating an embodiment in which the pattern data generating unit of FIG. 1 generates pattern data based on an encrypted color.
7 is a view illustrating an embodiment in which the pattern forming unit of FIG. 1 forms a mask pattern.
FIG. 8 is a view illustrating an embodiment of the pattern forming unit of FIG. 1 .
FIG. 9 is a diagram illustrating an embodiment in which the pattern forming unit of FIG. 1 arranges dithering masks in an array type.
10 is a diagram schematically illustrating an encryption system using an array type hologram according to another embodiment of the present invention.
11 is a diagram illustrating an embodiment of the result output unit of FIG. 10 .
12 is a diagram illustrating correlation information between a dithering pattern and a hologram color stored in the fourth memory M4 of FIG. 11 .
13 is a diagram illustrating an embodiment in which the result output unit of FIG. 10 outputs the predicted hologram encryption.
14 is a diagram illustrating color change information according to an irradiation angle of a light source and color change information according to an observer's viewing angle.
15 is a diagram illustrating correlation information between an encryption color, a dithering pattern, and a hologram color.
16 is a diagram illustrating an embodiment in which an encryption color, a dithering pattern, and a hologram color are matched.
17 is a diagram illustrating an embodiment of correlation information of FIG. 14 .
18 is a view showing an embodiment of forming a hologram encryption according to the present invention.
19 is a view schematically expressing the hologram encryption of FIG. 18 when the angle of irradiation of the light source and the viewing angle of the observer are different.
20 is a diagram illustrating an embodiment of a dithering mask array using the present invention.
FIG. 21 is a view showing observation of an encrypted hologram array while changing an irradiation angle of a light source and a viewing angle of an observer.
22 is a diagram illustrating the principle of expression of a structural color in a hologram structure.

The inventor can select or define appropriate terms or words to describe the invention, and in this case, the terms or words used are not limited to the meanings commonly used, but rather the intention of the inventor is taken into account. It should be interpreted so as to conform to the technical idea embodied in the invention.

Accordingly, the terms or words used in the present specification and claims cannot be regarded as being limited to the meanings commonly used. The content to be described below is merely a preferred embodiment of the present invention, and will not represent or limit all of the present technical idea, so there may exist examples corresponding to easily replaceable elements and equivalent ranges from the standpoint of those skilled in the art.

Hereinafter, an encryption system 100 using an array-type hologram according to the present invention based on the above-described principle will be described with reference to the drawings.

The encryption system 100 using an array type hologram according to the present invention may be performed using a photomask used for photolithography. Specifically, an encrypted array-type hologram can be provided by forming a specific pattern for manufacturing a hologram structure on a photomask and manufacturing an array-type hologram using the photomask.

The hologram structure referred to in this specification means a structure that implements a hologram by forming a diffraction grating pattern structure. Specifically, it refers to a structure in which a diffraction grating pattern structure is formed to express a structural color.

The structural color means a color implemented by the structure of an object without depending on the color itself, as shown in FIG. 22 . That is, it means a color implemented by light reflection, diffraction, interference, and the like.

The photomask on which the pattern is formed according to the present invention is for expressing a structural color by forming a diffraction grating pattern on a hologram structure, and preferably may be a dithering mask having a dithering pattern formed thereon. That is, when a specific diffraction grating pattern is formed in the hologram structure, a specific hologram color can be implemented.

Meanwhile, the color of the structure implemented by the hologram may vary depending on the diffraction grating pattern to be formed. That is, the diffraction grating pattern formed on the hologram structure may vary depending on which pattern is formed on the photomask, and accordingly, the color emitted by the hologram structure changes. Accordingly, the present invention can provide an encrypted hologram by forming a specific pattern on a photomask.

Therefore, in the present specification, in order to form a specific diffraction grating pattern on the hologram structure HS, a pattern formed on a photomask to correspond to the pattern is defined as a dithering pattern DP. Also, a photomask on which the dithering pattern DP is formed is defined as a dithering mask DM. Also, a pattern formed on the dithering mask DM is defined as a mask pattern. In addition, a color expressed by the hologram structure HS is defined as a hologram color HC.

1 is a diagram schematically illustrating an encryption system 100 using an array-type hologram according to an embodiment of the present invention.

Referring to Figure 1, the encryption system 100 using an array-type hologram according to the present invention, an encryption data generation unit 110 for generating at least one or more encryption data (ED) including an encryption color (EC), Based on the pattern data generating unit 120 and the pattern data (PD) for generating the pattern data (PD) including a dithering pattern (DP) corresponding to each of the encrypted colors (EC) based on the encrypted data (ED) to form a mask pattern on the dithering mask DM, and may include a pattern forming unit 130 for arranging the dithering mask DM in an array type.

The encryption data generation unit 110 may be a means for generating at least one or more encryption data (ED) including the encryption color (EC). Preferably, it may be a means for generating at least one or more of the encrypted data (ED) in which at least one or more encryption colors (EC) are combined.

At this time, a specific encrypted color given through the encryption data generating unit 110 is defined as an encryption color EC, and a set of data including a combination of the encryption colors EC is defined as the encryption data ED.

FIG. 2 is a diagram showing an embodiment of the encryption data generating unit 110 of FIG. 1 , and FIG. 3 shows an embodiment of the encryption data ED generated by the encryption data generating unit 110 of FIG. 1 . it is one drawing

Referring to FIG. 2 , as an embodiment, the encryption data generating unit 110 may include a first memory M1 that stores a first program P1. In this case, the first program P1 may be for generating the encryption data ED.

According to an embodiment, the encryption data generation unit 110 may generate the encryption data ED by combining at least one or more preset encryption colors EC. For this purpose, it is preferable that a plurality of encryption colors EC are set.

For example, the encrypted data generating unit 110 may use the red, green, and blue encrypted colors (EC) by using the RGB system.

As another example, the encrypted data generating unit 110 may use the encrypted colors (EC) of red, green, blue, and white by using the RGBW system.

However, the present invention is not limited thereto, and the encrypted data generating unit 110 may generate more various combinations of encrypted colors EC by using a number of encrypted colors EC greater than 4, of course.

Encrypted data may be a single encryption composed of a combination of encryption colors (EC). That is, it may be encrypted data in which at least one encryption color (EC) is combined.

The encryption data ED may include an area partitioned into at least one or more. In this case, one encryption color EC may be assigned to each partitioned area.

Preferably, the encryption data ED may include a region partitioned in a grid type of MXN (M and N are natural numbers).

In this case, since the number of cases in which L types of encryption colors (ECs) are arranged in a region partitioned in a grid of MXN (M and N are natural numbers) is L ^MXN , it is possible to have an encryption capability of L ^MXN .

An embodiment of the encrypted data ED will be described with reference to FIG. 3 . The encrypted data (ED) of FIG. 3 is the encrypted data (ED) in which the area is partitioned in a 3X3 grid type, and at this time, the encryption color (EC) is set to four types. In this case, the encryption data ED may be arranged so that the four encryption colors EC1, EC2, EC3, EC4 correspond to each of the nine areas one by one. In this case, since the encrypted data ED corresponds to one of the four encryption colors EC1, EC2, EC3, and EC4 in each of the nine areas, it may have an encryption capability of 4 ^3X3 .

The encrypted data generation unit 110 according to the present invention may generate at least one or more of the above-described encrypted data ED. In this case, the encrypted data generating unit 110 may generate at least one or more of the encrypted data ED while changing the combination of the encrypted colors EC included in the encrypted data ED.

As an embodiment, the encrypted data generating unit 110 may sequentially generate at least one or more of the encrypted data ED. In this case, the sequentially generated encrypted data ED may include a combination of at least one or more different encryption colors EC.

For example, although not shown in the drawing, the encrypted data generating unit 110 may generate the first encrypted data and then generate the second encrypted data. Next, after generating the first and second encryption data, the third encryption data may be generated. In this case, the first to third encryption data may be different from each other, or at least two of them may be the same.

In addition, of course, three or more encryption data (ED) may be generated. In addition, all the encryption data (ED) generated accordingly may be different, and it is also possible that at least two or more of the same encryption data (ED) are generated.

As a plurality of encryption data ED are formed in this way, as will be described later, when each dithering mask DM is arranged in an array type, the encryption effect may be further improved according to the arrangement.

For example, when a plurality of encryption data ED is generated and an array-type hologram HA is manufactured based on this, the color of each hologram subject to a counterfeit check is different from the original, as well as each Even if the arrangement order of the holograms is different, it can be detected as a counterfeit product.

On the other hand, when a plurality of encryption data ED are formed in this way, it goes without saying that a plurality of pattern data PD may be formed to correspond thereto one-to-one as will be described later.

FIG. 4 is a diagram illustrating an embodiment of the pattern data generator 120 of FIG. 1 , and FIG. 5 is a correlation between the encrypted color EC and the dithering pattern DP stored in the second memory M2 of FIG. 4 . It is a diagram illustrating relationship information, and FIG. 6 is a diagram illustrating an embodiment in which the pattern data generating unit 120 of FIG. 1 generates pattern data PD based on the encrypted color EC.

4 to 6 , the pattern data generating unit 120 is a means for generating pattern data PD including a dithering pattern DP corresponding to each of the encrypted colors EC based on the encrypted color EC. can be That is, it may be a means for converting the encrypted color EC into a dithering pattern DP corresponding thereto on a one-to-one basis.

The pattern data generator 120 may include a second memory M2 that stores the second program P2 as an embodiment. In this case, the second program P2 may be for converting the encrypted color EC into the dithering pattern DP.

According to a preferred embodiment, the second program P2 may be for converting the encrypted color EC into a preset dithering pattern DP to correspond thereto on a one-to-one basis.

To this end, referring to FIG. 5 , correlation information corresponding to the encrypted color EC and the dithering pattern DP may be encoded in the second program P2 . In this case, of course, the encryption color EC and the dithering pattern DP may be arbitrarily matched. That is, the specific encryption color EC and the specific dithering pattern DP do not necessarily have to match, and the matching relationship may be changed in some cases.

As such, the one-to-one matching between the encryption color EC and the dithering pattern DP may mean that the encryption color EC is encrypted.

An embodiment in which the pattern data generating unit 120 converts the encrypted color EC into a dithering pattern DP to generate the pattern data PD will be described with reference to FIGS. 5 and 6 .

According to this embodiment, the first encrypted color EC1 corresponds to the first dithering pattern DP1, the second encrypted color EC2 corresponds to the second dithering pattern DP2, and the third encrypted color EC3 corresponds to the third dithering pattern DP3, and the fourth encryption color EC4 corresponds to the fourth dithering pattern DP4.

Accordingly, according to the corresponding information, the first encrypted color EC1 included in the encrypted data ED is converted into the first dithering pattern DP1, and the second encrypted color EC2 is converted to the second dithering pattern DP2. is converted, the third encrypted color EC3 may be converted into a third dithering pattern DP3 , and the fourth encrypted color EC4 may be converted into a fourth dithering pattern DP4 .

As such, when each encryption color (EC1, EC2, EC3, EC4) is converted into a corresponding dithering pattern (DP1, DP2, DP3, DP4), the pattern data (PD) in which the dithering pattern (DP) is combined is formed. can That is, the pattern data PD including the dithering pattern DP corresponding to each of the partitioned regions one-to-one based on the encrypted color EC may be generated.

As a result, the encrypted data composed of the combination of the first encrypted color EC1 to the fourth encrypted color EC4 is pattern data composed of the combination of the first dithering pattern DP1 to the fourth dithering pattern DP4 (PD). can be converted to

7 is a diagram illustrating an embodiment in which the pattern forming unit 130 of FIG. 1 forms a mask pattern.

Referring to FIG. 7 , the generated pattern data PD may be implemented in the dithering mask DM through the pattern forming unit 130 . The pattern forming unit 130 may be a means for forming a mask pattern on the dithering mask DM based on the pattern data PD. In detail, the pattern forming unit 130 may form a mask pattern on the dithering mask DM to correspond to the pattern data PD. Accordingly, the same mask pattern as the pattern data PD may be formed on the dithering mask DM, and accordingly, the pattern data PD and the diffraction grating pattern corresponding to the mask pattern may be formed on the hologram structure HS. do.

Meanwhile, the pattern forming unit 130 suffices as long as a means capable of implementing a mask pattern on the dithering mask DM. For example, the pattern forming unit 130 may be a means for printing a mask pattern on the dithering mask DM, but is not limited thereto.

FIG. 8 is a view showing an embodiment of the pattern forming unit 130 of FIG. 1 , and FIG. 9 is a view showing an embodiment in which the pattern forming unit 130 of FIG. 1 arranges the dithering mask DM in an array type. It is the drawing shown.

8 and 9 , the pattern forming unit 130 may arrange the dithering masks DM on which the mask patterns are formed in an array type. That is, the dithering mask array DMA in which the dithering masks DM are arranged may be formed.

For example, it may be a means for arranging each of the dithering masks DM on which the mask pattern is formed as described above on an upper surface of a separate substrate or the like. As another example, it may be a means for printing a mask pattern by changing a position on the upper surface of the raw material or substrate of the dithering mask DM based on at least one or more pattern data PD. However, the present invention is not limited thereto, and any configuration capable of arranging the dithering masks DM having the mask pattern formed thereon in an array type may be employed.

Meanwhile, referring to FIG. 8 , the pattern forming unit 130 may include a third memory M3 as an embodiment. In this case, the third memory M3 may include a third program for arranging the dithering masks DM in an array type. For example, the third program P3 may be a positioning automation program.

As an embodiment, the pattern forming unit 130 may arrange the dithering mask DM to have a predetermined interval using a positioning automation program. Preferably, the arranged dithering masks DM may be spaced apart to have a constant interval. That is, a dithering mask array (DMA) constituting a set may be formed by moving the stages of the array through the positioning automation program.

Looking in detail through one embodiment, the encryption data generation unit 110 may sequentially generate at least one or more different series of encryption data (ED). In this case, the pattern data generating unit 120 may generate the corresponding pattern data PD when each encryption data ED is generated. When each pattern data PD is generated, the pattern forming unit 130 may arrange each of the dithering masks DM1 to DM9 while changing positions to have a predetermined interval corresponding thereto. Through this, as shown in FIG. 9 , a dithering mask array DMA forming a set may be formed.

When such a dithering mask array DMA is used, an array-type hologram HA may be manufactured. At this time, each hologram structure HS made of a combination of holographic colors HC is gathered to form an array-type hologram HA. In addition, each of these hologram structures HS individually functions as a hologram encryption. In addition, the array-type hologram HA functions as an array-type hologram encryption.

10 is a diagram schematically illustrating an encryption system 100 using an array-type hologram according to another embodiment of the present invention.

Referring to FIG. 10 , the system 100 according to the present invention outputs a result output unit 140 that outputs a predicted array-type hologram encryption based on hologram color (HC) information expressed as a dithering pattern (DP). may include more.

For example, the result output unit 140 may be a means for outputting prediction result data on which hologram encryption will be produced through the pattern data PD. This result data may be monitored on a separate display device, stored as a separate file if necessary, and may be printed if necessary.

Through this, it is possible to determine whether the hologram is forged by comparing whether the actually manufactured hologram structure HS, ie, the hologram encryption, is the same as the result output through the result output unit 140 .

11 is a diagram illustrating an embodiment of the result output unit 140 of FIG. 10 , and FIG. 12 is a correlation between the dithering pattern DP and the hologram color HC stored in the fourth memory M4 of FIG. 11 . It is a view showing information, and Fig. 13 is a view showing an embodiment in which the result output unit 140 of Fig. 10 outputs the predicted hologram encryption, Fig. 14 is a view showing color change information according to the irradiation angle of the light source and the It is a diagram showing color change information according to a viewing angle.

When the hologram structure HS is manufactured using the dithering mask DM on which the mask pattern is formed, a diffraction grating pattern corresponding to the mask pattern may be formed on the hologram structure HS. In this case, the diffraction grating pattern formed on the hologram structure HS may implement a specific hologram color HC when the light source is irradiated.

In detail, a specific diffraction grating pattern exhibits a specific hologram color (HC) according to an irradiation angle of a light source or an observer's viewing angle. In this case, since the hologram color (HC) expressed according to a specific diffraction grating pattern is determined according to the principle of expression of the structural color, it cannot be arbitrarily matched. In addition, even if the color looks similar to the naked eye, the diffraction grating pattern for expressing the color may be different.

Therefore, the holographic color HC to be implemented and the dithering pattern DP for expressing the holographic color HC must be matched and encoded in advance. That is, the dithering pattern (DP) information expressing a specific holographic color (HC) must be matched and input in advance.

To this end, the result output unit 140 may include a fourth memory M4 that stores the fourth program P4 as an embodiment. The fourth program P4 may be for outputting an array-type hologram encryption predicted from the pattern data PD.

According to a preferred embodiment, as shown in FIG. 12 , the fourth program P4 may include correlation information between the dithering pattern DP and the hologram color HC expressed in the hologram structure HS. .

An embodiment in which the result output unit 140 outputs an array-type hologram encryption predicted from the pattern data PD will be described with reference to FIGS. 12 and 13 .

According to the present embodiment, in the fourth program P4, the first dithering pattern DP1 corresponds to the first hologram color HC1, the second dithering pattern DP2 corresponds to the second hologram color HC2, and , the third dithering pattern DP3 may include information corresponding to the third hologram color HC3 , and the fourth dithering pattern DP4 may include information corresponding to the fourth holographic color HC4 . Accordingly, the array-type hologram encryption in which the first hologram color HC1 to the fourth hologram color HC4 is combined through the pattern data PD in which the first dithering pattern DP1 to the fourth dithering pattern DP4 are combined. can be printed out.

Meanwhile, in the hologram structure HS in which the diffraction grating pattern is formed, the hologram color HC may change according to the irradiation angle of the light source. In addition, in the hologram structure HS in which the diffraction grating pattern is formed, the hologram color HC may change according to a viewing angle of an observer.

Accordingly, the fourth program P4 includes not only the dithering pattern DP and the corresponding hologram color HC, but also information on changes in the hologram color HC according to the irradiation angle of the light source and the hologram color HC according to the viewing angle of the observer. ) may further include change information.

14, in the hologram structure in which the diffraction grating pattern corresponding to the first dithering pattern DP1 is formed, the hologram color HC expressed according to the irradiation angle of the light source may change, and the fourth program P4 may further include such change information. For example, the hologram colors (HC11, HC12, HC13, HC14, HC15) that are displayed when the irradiation angle of the light source is 0° are different hologram colors (HC11', HC12', HC13) when the irradiation angle of the light source is changed to 90°. ', HC14', HC15'), and this change information may be included in the fourth program P4.

In addition, in the hologram structure in which the diffraction grating pattern corresponding to the first dithering pattern DP is formed, the hologram color HC expressed according to the viewing angle of the observer may change, and the fourth program P4 further includes such change information. can do. For example, as the viewing angle of the observer increases, the holographic color HC11 may sequentially change to HC12, HC13, HC14, and HC15, and the holographic color HC11' may sequentially change to HC12', HC13', HC14', and HC15'.

As such, the change in the hologram color (HC) according to the change in the irradiation angle of the light source and the viewing angle of the observer can greatly improve the security of the array-type hologram encryption manufactured through the present system 100 .

That is, even if the colors are similar to each other visually, the dithering pattern (DP) for expressing the color may be different, and as the dithering pattern (DP) is different, the hologram color ( HC) can take on a completely different pattern. Accordingly, the security of the hologram structure HS may be greatly improved.

17 is a diagram illustrating an embodiment of correlation information of FIG. 14 . Referring to FIG. 17 , it can be seen that the hologram color HC expressed for each dithering pattern DP is different, and the hologram color HC expressed according to the irradiation angle of the light source and the viewing angle of the observer changes.

For example, the hologram structure HS in which the horizontal dithering pattern DP of FIG. 17 is implemented shows the holographic colors HC of blue, sky blue, jade, yellow, and red when the irradiation angle of the light source is 0°. , when the irradiation angle of the light source is 90°, all black holograms are displayed and the colors are inverted. In addition, in the hologram structure HS in which the horizontal dithering pattern DP of FIG. 17 is implemented, the hologram color HC changes to blue, sky blue, turquoise, yellow, and red as the viewing angle of an observer increases.

15 is a diagram illustrating correlation information between an encryption color (EC), a dithering pattern (DP), and a hologram color (HC).

According to an embodiment, the encryption color EC, the dithering pattern DP, and the hologram color HC may be entirely matched. In this case, when a specific encrypted color EC is given, the hologram color HC to be implemented may be predicted through such matching information.

For example, the result output unit 140 may output prediction result data on which hologram encryption will be produced through the encryption color EC. In addition, it is also possible to predict what kind of dithering pattern (DP) combination is formed through the encryption color (EC).

The encryption system 100 according to the present invention may further include a hologram manufacturing unit for manufacturing the hologram structure HS based on the dithering masks DM arranged in an array type. Preferably, the hologram manufacturing unit may be a means for manufacturing the hologram structure HS through a photolithography process.

Through this, a diffraction grating pattern can be formed on the hologram structure HS, and when light is incident thereon, the structure color can be expressed.

The encryption system 100 according to the present invention may further include a decryption unit for confirming a structure color expressed by irradiating light to the hologram structure HS, if necessary. That is, by comparing the array-type hologram encryption pattern output through the result output unit 140 with the structure color actually expressed by irradiating light to the hologram structure HS, it is possible to determine whether the hologram encryption is forged.

16 is a diagram illustrating an embodiment in which an encryption color (EC), a dithering pattern (DP), and a hologram color (HC) are matched, and FIG. 17 is a diagram illustrating an embodiment of the correlation information of FIG. 14 , FIG. 18 is a view showing an embodiment of forming a hologram encryption according to the present invention, FIG. 19 is a diagram schematically expressing the hologram encryption of FIG. is a diagram showing an embodiment of a dithering mask array (DMA) using the present invention.

Hereinafter, an embodiment using the encryption system 100 using the above-described array-type hologram will be described with reference to FIGS. 16 to 20 . However, since this embodiment is only an embodiment for implementing the present invention, the technical idea of the present invention is not fully represented only by the contents of the embodiment.

[Example]

Referring to FIG. 16 , this embodiment uses red (EEC1), green (EEC2), blue (EEC3), and black (EEC4) as encryption colors (EEC).

16, in this embodiment,

1) The encoding color of red (EEC1), the dithering pattern of 60° upward diagonal (EDP1), and the holographic color of tan (EHC1) are encoded to correspond. 2) The green encryption color (EEC2), the 30° upward diagonal dithering pattern (EDP2), and the sky blue holographic color (EHC2) are encoded to correspond. 3) The blue encryption color (EEC3), the horizontal dithering pattern (EDP3), and the blue holographic color (EHC3) are encoded to correspond. 4) The black encryption color (EEC4), the vertical dithering pattern (EDP4), and the black holographic color (EHP4) are encoded to correspond.

The change information of the hologram color EHC according to the irradiation angle of the light source and the viewing angle of the observer for each dithering pattern EDP is shown in FIG. 17 .

Referring to FIG. 18 , the encrypted data generating unit 110 generates a plurality of encrypted data (EED). The encryption data (EED) is arranged so that four encryption colors (EEC1, EEC2, EEC3, EEC4) correspond to the area partitioned in a 4X4 grid.

The pattern data generation unit 120 selects an encryption color EEC and a dithering pattern EDP respectively corresponding to the encryption data EED based on the encryption data EED, and generates a plurality of pattern data EPD including a combination of such patterns. do.

For example, a pixel to which the encrypted color EEC1 is assigned is converted to a dithering pattern EDP1, a pixel to which an encrypted color EEC2 has been assigned is converted to a dithering pattern EDP2, a color to which an encrypted color EEC3 has been assigned is converted to a dithering pattern EDP3, and encrypted Pixels given color EEC4 are converted to dithering pattern EDP4.

The pattern forming unit 130 forms mask patterns respectively corresponding to the plurality of dithering masks EDM based on the plurality of generated pattern data EPDs. Also, referring to FIG. 20 , the pattern forming unit 130 manufactures a dithering mask array EDMA by arranging the generated dithering masks EDM in an array type.

The hologram manufacturing unit manufactures the hologram structure EHS through a photolithography process using the dithering mask array EDMA arranged in an array type.

The result output unit 140 outputs an array-type hologram encryption predicted based on hologram color (EHC) information expressed as a dithering pattern (EDP).

For example, the holographic color EHC1 may be expressed in the region corresponding to the dithering pattern EDP1, the holographic color EHC2 may be expressed in the region corresponding to the dithering pattern EDP2, and the holographic color EHC3 may be expressed in the region corresponding to the dithering pattern EDP3. may be expressed, and the hologram color EHC4 may be expressed in a region corresponding to the dithering pattern EDP4.

In addition, referring to FIG. 19 , the result output unit 140 is an array type in which the manufactured hologram structure (EHS) is predicted by reflecting change information of the hologram color (HC) expressed according to the irradiation angle of the light source and the viewing angle of the observer. Outputs a hologram password.

Looking through the present embodiment, it is possible to check whether the hologram is forged by comparing the manufactured hologram structure (EHS) with the array-type hologram encryption output to the result output unit 140 with each other.

That is, when the irradiation angle of the light source is 0°, the hologram structure must indicate the hologram codes of EHS1, EHS2, EHS3, EHS4, and EHS5. EHS3', EHS4', EHS5' hologram encryption must be displayed. If it is different from this, it can be determined as a forged hologram.

In addition, as the viewing angle of the observer is increased, the hologram structure changes in the order of EHS1, EHS2, EHS3, EHS4, EHS5, or the hologram encryption in the order of EHS1', EHS2', EHS3', EHS4', EHS5' should be changed If it is different from this, it can be determined as a forged hologram.

In this case, unless all of the encryption data (EED) generated by the encryption data generation unit 110 and the conversion algorithm used in the pattern data generation unit 120 are the same, the same hologram cannot be manufactured. In addition, since the hologram color EHC changes as the irradiation angle of the light source or the viewing angle of the observer changes, it becomes more difficult to easily manufacture the same hologram structure EHS. Accordingly, the encryption system 100 using an array-type hologram according to the present invention can significantly improve security.

FIG. 21 is a diagram expressing an actual embodiment of an encrypted array-type hologram (HA) observed while changing an irradiation angle of a light source and a viewing angle of an observer. This embodiment is an array-type hologram (HA) in which 12 square hologram ciphers divided into a 4X4 area are arranged.

Referring to FIG. 21, the first row is the observation of the array-type hologram (HA) with the light source irradiating angle of 0°, and the second row is the array-type hologram (HA) viewed with the light source irradiating angle of 90°. ) was observed. Looking closely at this, it can be seen that the colors of the light source are inverted when the irradiation angle of the light source is 0° and 90°.

In addition, FIG. 21 shows the observation of the array type hologram (HA) by decreasing the observer's viewing angle as it proceeds from left to right based on the drawing. If you look closely at this, it can be seen that the color is constantly changed as the viewing angle of the observer changes.

In light of this, the encryption system 100 using an array-type hologram according to the present invention includes all of the combination of hologram colors included in the hologram encryption of the manufactured hologram structure (HS), the color change pattern, and the arrangement of the hologram encryption. In summary, since it is possible to check whether the hologram encryption is forged or not, its security can be greatly improved.

For example, each hologram encryption has an encryption capability of 4 ^4X4 because four hologram colors are arranged in a region divided in a 4X4 grid. In addition, since 12 of these hologram encryptions are arranged in an array, and the color of the hologram encryption changes according to the change of the irradiation angle of the light source and the viewing angle of the observer, the encryption ability can be dramatically increased.

On the other hand, the encryption system 100 using an array-type hologram according to the present invention includes an encryption data generation unit 110 , a pattern data generation unit 120 , a pattern formation unit 130 , a result output unit 140 , and a hologram. A manufacturing unit and a decryption unit may be included in one device.

As another optional embodiment, the encryption system 100 using an array-type hologram according to the present invention includes an encryption data generation unit 110 , a pattern data generation unit 120 , a pattern formation unit 130 , and a result output unit ( 140), a hologram manufacturing unit and a decryption unit may be included in at least two or more devices.

Above, the present invention has been described in detail with preferred embodiments with reference to the drawings, but the scope of the technical idea of the present invention is not limited to these drawings and examples. Accordingly, various modifications or equivalent ranges of embodiments may exist within the scope of the technical spirit of the present invention. Therefore, the scope of the technical idea according to the present invention should be interpreted by the claims, and the technical idea within the equivalent or equivalent scope should be interpreted as belonging to the scope of the present invention.

100: encryption system DM: dithering mask
110: encryption data generation unit DMA: dithering mask array
120: pattern data generating unit DP: dithering pattern
130: pattern forming part EC: encryption color
140: result output unit ED: password data
M1: First memory HA: Array type hologram
M2: Second memory HC: Hologram color
M3: third memory HS: hologram structure
M4: 4th memory PD: pattern data

Claims (12)

an encryption data generation unit for generating at least one or more pieces of encryption data including an encryption color;
a pattern data generator for generating pattern data including a dithering pattern corresponding to each of the encrypted colors based on the encrypted data; and
and a pattern forming unit for forming a mask pattern on a dithering mask based on the pattern data and arranging the dithering mask in an array type.
According to claim 1,
The password data is
An encryption system using an array type hologram, which is partitioned into at least one area, and one encryption color is given to each area.
3. The method of claim 2,
The password data is
An encryption system using an array-type hologram, which is divided into grid-type regions of MXN (M and N are natural numbers).
According to claim 1,
The encryption data generation unit,
An encryption system using an array type hologram for sequentially generating the at least one or more encryption data.
5. The method of claim 4,
The sequentially generated encryption data is,
An encryption system using an array-type hologram, comprising a combination of at least one or more different encryption colors.
According to claim 1,
The pattern data generation unit,
An encryption system using an array-type hologram that converts the encryption color into a dithering pattern corresponding thereto on a one-to-one basis.
According to claim 1,
The pattern forming unit,
An encryption system using an array-type hologram in which dithering masks are arranged to have a predetermined interval.
According to claim 1,
The encryption system using an array-type hologram, further comprising a result output unit for outputting a predicted array-type hologram encryption based on the hologram color information expressed by the dithering pattern.
9. The method of claim 8,
The result output unit,
An encryption system using an array-type hologram that further includes information on changes in the color of the hologram according to the irradiation angle of a light source to output a predicted array-type hologram encryption.
9. The method of claim 8,
The result output unit,
An encryption system using an array-type hologram to output a predicted array-type hologram encryption by further including information on changes in the color of the hologram according to an observer's viewing angle.
According to claim 1,
An encryption system using an array type hologram, further comprising a hologram manufacturing unit for manufacturing a hologram structure based on the dithering mask arranged in the array type.
12. The method of claim 11,
An encryption system using an array-type hologram, further comprising a decryption unit for confirming a structural color expressed by irradiating light to the hologram structure.

Images