JP2012208149A - Image display body and information medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image display body and information medium that have a visual effect different from a conventional diffraction lattice pattern and achieve higher forgery prevention effect.SOLUTION: An image display body 10 is configured in such a manner that light scattering areas 12a are arranged in matrix in X-axis directions and Y-axis directions on one side of a light permeable substrate 11 and light non-scattering areas 12b are arranged around them. A plurality of linear light scattering patterns all of which are oriented in the Y-axis direction are arranged on each light scattering area 12a. At least part of each light scattering area 12a is covered with a light reflection layer, and diffraction light by Fraunhofer diffraction is generated from light incident to each light scattering area 12a. Thus, a portion corresponding to the matrix arrangement of light scattering areas 12a is displayed in white.

Description

  The present invention relates to an image display body and an information medium having a highly secure anti-counterfeit function that is easy to determine with the naked eye.

  It is desirable that securities such as passports, credit cards, ID cards, gift certificates and checks are difficult to counterfeit. For this reason, such an article is difficult to forge or imitate itself, and a label that can be easily distinguished from a forgery or counterfeit is attached to suppress forgery.

  Further, in recent years, there is a problem in that counterfeit products such as brand products are distributed in addition to the above-mentioned products, so that the demand for the above-described anti-counterfeit technology is increasing.

  A diffraction grating pattern is known as a forgery prevention technique. The diffraction grating pattern can change the pattern according to the angle to be observed or display a stereoscopic image by controlling the direction, angle, brightness, and the like of diffracting light (for example, Patent Document 1). And 2).

As a method for producing a master plate of a diffraction grating pattern, an electron beam exposure apparatus is used, and by computer control, an XY stage on which a planar substrate coated with an electron beam resist is placed is moved, There is a method of forming a diffraction grating pattern on the surface of a substrate (see, for example, Patent Document 3).
Here, as a parameter of the diffraction grating,
(1) Spatial frequency of diffraction grating (pitch of grating line)
(2) Direction of diffraction grating (direction of grating line)
(3) Diffraction grating drawing area (arrangement of diffraction grating pattern)
There are three.
And
In accordance with (1), the color at which the diffraction grating pattern appears shining with respect to a fixed point changes,
In accordance with (2), the direction in which the diffraction grating pattern appears shining changes,
In accordance with (3), a display pattern (picture, character, etc.) is determined.
Therefore, by dividing the surface of the substrate into small areas of about several tens to several hundreds of micrometers and forming diffraction gratings in which these parameters are changed in various areas, it is possible to express pictures, characters, and the like. .

A metal stamper is produced by a method such as electroforming from an original plate having a concavo-convex shape produced by the above method, and a thermoplastic resin or A photo-curing resin is applied, a metal stamper is brought into close contact, and heat or light is applied to soften or harden the resin to replicate the pattern.
Since the replicated pattern is usually transparent, after providing a light reflecting layer by a method such as vapor deposition of a metal or dielectric thin film layer such as aluminum, an adhesive layer is formed on a substrate such as paper or plastic film. A sticker or a transfer foil is attached, and if necessary, a protective layer is provided to prevent the printed layer and pattern layer from being stained and scratched, whereby securities and cards are produced.

Japanese Patent No. 2508387 Japanese Patent No. 2745902 JP 2000-39508 A

In recent years, along with the widespread use of diffraction grating patterns as a forgery prevention technique, forgery and imitation of the conventional diffraction grating patterns are increasing.
An object of the present invention is to provide an image display body and an information medium that have a visual effect different from that of a conventional diffraction grating pattern and realize a higher anti-counterfeit effect.

In order to solve the above-mentioned problems, the present invention takes the following measures.
That is, according to the first invention, a light scattering region in which a plurality of linear light scattering patterns configured of at least one of a concave portion and a convex portion are arranged in the same direction on at least one surface of a light-transmitting substrate. A light reflecting layer covering at least a part of the light scattering region on the one surface of the base material, and the light scattering region on the one surface of the base material. In the image display body that displays an image by arranging a plurality of light scattering patterns in a matrix along the extending direction of the light scattering patterns and the interval direction of the light scattering patterns, the light on the one surface In the image display body, the length of the light scattering region in the interval direction of the scattering pattern is 69 μm or more.

  According to a second aspect of the present invention, in the image display body, the length of the light scattering region in the interval direction is 87 μm or more.

  A third aspect of the present invention is the image display body, wherein each of the light scattering regions has the light scattering pattern in the same arrangement pattern.

  According to a fourth aspect of the present invention, in the extension direction and the interval direction, the light scattering patterns of the two adjacent light scattering regions are continuous, and the intensity distribution of the emitted light is determined by an arbitrary portion of the continuous light scattering patterns. Is an image display body characterized in that the same arrangement pattern can be obtained.

  5th invention is an image display body characterized by the length of the said light-scattering area | region in the said space | interval direction being 145 micrometers or less.

  A sixth invention is an information medium comprising the image display body according to any one of the first to fifth inventions, and an article supporting the image display body.

  According to the present invention, since it has a visual effect different from that of a conventional diffraction grating, it is possible to provide an image display body and an information medium that make it difficult to forge or imitate and realize a higher anti-counterfeit effect.

It is a top view which shows roughly the image display body which concerns on embodiment of this invention. It is sectional drawing along the AA line of the image display body shown in FIG. (A), (c) is a structural pattern employable in the light scattering region of the present invention, and (b), (d) are explanatory diagrams respectively showing image patterns obtained by Fourier transforming them. It is a top view which shows roughly the image display body which concerns on embodiment of this invention. It is the schematic for demonstrating the image display body which concerns on embodiment of this invention. It is the schematic for demonstrating the intensity distribution of the emitted light when incident light injects into the several light-scattering area | region arrange | positioned at matrix form. It is a graph which shows the state which carried out the Fourier transformation of the intensity distribution of the diffracted light from a single light-scattering area | region. (A), (b) is a graph which shows the intensity distribution of the diffracted light from the light-scattering area | region before and after a Fourier-transform by having arranged the light-scattering area | region in matrix form. FIG. 9 is a graph showing the intensity distribution of diffracted light from the light scattering region obtained by combining the intensity distribution S (θ) of FIG. 7 and the intensity distribution G (θ) of FIG. 8B at the position of the screen of FIG. 6. (A), (b) is explanatory drawing which shows the case where the light-scattering pattern of two adjacent light-scattering areas is not continuous. (A), (b) is explanatory drawing which shows the case where the light-scattering pattern of two adjacent light-scattering area | regions continues. (A), (b) is explanatory drawing which shows a light-scattering pattern and the frequency spectrum obtained by the Fourier transform. (A), (b) is explanatory drawing which shows the light-scattering pattern extracted and expanded from the light-scattering pattern of Fig.12 (a), and the frequency spectrum obtained by the Fourier transform. (A), (b) is explanatory drawing which shows the light-scattering pattern extracted and expanded from the light-scattering pattern of Fig.12 (a), and the frequency spectrum obtained by the Fourier transform. 1 is a plan view schematically showing an information medium according to an embodiment of the present invention.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. In addition, the same referential mark is attached | subjected to the component which exhibits the same or similar function through all the drawings, and the overlapping description is abbreviate | omitted.

  FIG. 1 is a plan view schematically showing an image display body according to an embodiment of the present invention. FIG. 2 is a cross-sectional view taken along line AA of the image display body shown in FIG.

The image display body 10 of this embodiment shown in FIG. 1 has a light-transmitting substrate 11 and a light reflection layer 13 as shown in FIG. In the example shown in FIGS. 1 and 2, the base material 11 has, on one surface thereof, two uneven light scattering regions 12 a and a planar non-light scattering region disposed around each light scattering region 12 a. 12b.
Furthermore, the light reflection layer 13 is formed on the surface including the light scattering region 12a so as to cover at least a part of the light scattering region 12a. As shown in FIG. 2, the light scattering region 12a of the present embodiment has a plurality of light scattering patterns 12c. The light scattering pattern 12c in FIG. 2 is composed of only a concave portion on one surface of the substrate 11, but may actually be composed of a convex portion, or may be composed of both a convex portion and a concave portion.

  In the example shown in FIG. 1 and FIG. 2, the light scattering region 12a includes a plurality of linear light scattering patterns 12c having the same direction. As shown in FIG. 1, the two light scattering regions 12 a and 12 a are arranged with an interval in the X-axis direction (corresponding to the interval direction in the claims). The light scattering pattern 12c of each light scattering region 12a extends in the Y-axis direction (corresponding to the extending direction in the claims) orthogonal to the X-axis direction on one surface of the substrate 11. The depth direction of the concave portions constituting the light scattering pattern 12c extends in the Z-axis direction orthogonal to both the X-axis direction and the Y-axis direction. The linear light scattering pattern 12c (concave portion or convex portion or both) provided in the light scattering region 12a does not necessarily have to be completely parallel.

  As the light-transmitting substrate 11, a film or sheet made of a light-transmitting resin such as polyethylene terephthalate (PET), polycarbonate (PC), or triacetyl cellulose (TAC) can be used. The substrate 11 may have a single layer structure or a multilayer structure. The surface of the substrate 11 may be subjected to treatments such as antireflection treatment, low antireflection treatment, hard coat treatment, antistatic treatment and antifouling treatment.

  As the light reflection layer 13, for example, a metal layer made of a metal material such as aluminum, silver, or an alloy thereof can be used. Alternatively, as the light reflecting layer 13, a dielectric layer having a refractive index different from that of the light scattering region 12a may be used. Alternatively, a laminated body of dielectric layers having different refractive indexes, that is, a dielectric multilayer film may be used as the light reflecting layer 13. However, the refractive index of the dielectric layer included in the dielectric multilayer film that is in contact with the light scattering region 12a is preferably different from the refractive index of the light scattering region 12a.

  FIG. 3 is an explanatory diagram showing a structure pattern that can be used in the light scattering region of the present invention and an image pattern obtained by Fourier transforming the structure pattern.

  In the light scattering region 12a shown in FIG. 3A, a plurality of linear light scattering patterns 12c (concave portions) extending in the Y direction are arranged in parallel.

FIG. 3B is an explanatory diagram showing an image pattern obtained by Fourier transforming the arrangement pattern of the plurality of light scattering patterns 12c provided in the light scattering region 12a of FIG.
The pattern of the image 20 in FIG. 3B obtained by Fourier transform shows the diffracted light distribution by Fraunhofer diffraction from the arrangement pattern of the light scattering pattern 12c before the conversion. Therefore, it can be seen from the pattern in FIG. 3B that the light scattering region 12a in FIG. 3A emits diffracted light having directivity in the X-axis direction. Further, since the pattern of FIG. 3B extends over the entire X-axis direction, the diffracted light from the light scattering region 12a of FIG. 3A has a wide spatial frequency distribution. Recognize.
Therefore, when incident light is incident on the light scattering region 12a shown in FIG. 3A from a direction parallel to the X axis, scattered light having directivity in a wide range in a plane perpendicular to the Y axis and including the X axis, That is, white can be observed.

  In the light scattering region 12a shown in FIG. 3C, the orientation of each light scattering pattern 12c is lower than the light scattering region 12a shown in FIG. 3A (the light scattering pattern 12c extends in the Y-axis direction). Although the length is short), the structure can be regarded as a structure in which a plurality of linear light scattering patterns 12c substantially parallel to the Y axis are arranged.

FIG. 3D is an explanatory diagram showing an image pattern obtained by Fourier transforming the arrangement pattern of the plurality of light scattering patterns 12 c provided in the light scattering region 12 a of FIG.
When the pattern of the image 20 in FIG. 3D is interpreted in the same manner as in FIG. 3B, the diffracted light emitted from the light scattering region 12a in FIG. 3C has directivity in the X-axis direction. In addition, it can be seen that the spatial frequency is distributed with a certain range.
Therefore, when incident light is incident on the light scattering region 12a shown in FIG. 3C from a direction parallel to the X axis, scattered light having directivity in a wide range in a plane perpendicular to the Y axis and including the X axis, That is, white can be observed.

  FIG. 4 is a plan view schematically showing the image display body according to the embodiment of the present invention.

The image display body 10 shown in FIG. 4 includes a light scattering region 12a and a non-light scattering region 12b. A plurality of light scattering regions 12a are arranged in a matrix on the XY plane (on one surface of the substrate 11), and a non-light scattering region 12b is arranged around the light scattering regions 12a. In the image display body 10 shown in FIG. 4, the light scattering regions 12a are arranged in a matrix in a direction parallel to the X axis and the Y axis. However, the arrangement direction is not limited to this, and other than the X axis and the Y axis. May be aligned in the direction (the combined direction of the X-axis direction and the Y-axis direction). Each light scattering region 12a has a light scattering pattern 12c having the same arrangement pattern.
When the observer observes the image display body 10, the light scattering region 12a is observed in white at an angle at which the directional scattered light emitted from the light scattering region 12a can be observed. On the other hand, the non-light scattering region 12b can observe the color of the light reflection layer 13 or the 0th-order diffracted light of the incident light when the light reflection layer 13 (see FIG. 2) is present, and is incident when the light reflection layer 13 is not present. Since light is transmitted through the light transmission layer 13, nothing is observed on the surface of the image display body 10, or optical characteristics of the light transmission layer 13 itself (color, refractive index, fine scratches on the surface, etc. of the substrate 11). Diffusivity, etc.) are observed. Regardless of whether the non-light scattering region 12b includes the light reflection layer 13, the observer can observe the light scattering region 12a and the non-light scattering region 12b as having different colors, textures, and the like.
That is, the light scattering region 12a is arranged in a matrix, and the light scattering region 12a and the non-light scattering region 12b are juxtaposed on the same plane, so that the image display body 10 can display an image. Various images can be displayed. That is, it can be said that the light scattering region 12a corresponds to an image pixel.
For example, in the case of the image display body 10 shown in FIG. 4, the observer can observe as “P” of the alphabet. In the case of this image display body 10, since the light scattering region 12 a is large, it is possible to observe the pixel that is the constituent unit of the displayed image “P”. A resolution image can be displayed, and if the size is smaller than the resolution of the human eye, a smoother and more natural image can be displayed.

  FIG. 5 is a schematic diagram for explaining the image display body according to the embodiment of the present invention.

FIG. 5 illustrates a scene in which the incident light 31 is incident on the light scattering region 12a and the observer 14 observes the emitted light 32 from the light scattering region 12a.
FIG. 5A and FIG. 5B are the same scenes, and are illustrated from different directions in the XYZ space.

  FIG. 6 is a schematic diagram for explaining the intensity distribution of emitted light when incident light is incident on a plurality of light scattering regions arranged in a matrix.

In FIG. 6, incident light 31 is incident on a range where the light scattering regions 12a having a length in the X direction of Dx are arranged in a matrix, and the emitted light 32 is projected onto the screen 22 at a distance R from the range. is doing. It is assumed that the distance R between the light scattering region 12a and the screen 22 is sufficiently larger than the length Dx in the X direction of the light scattering region 12a, and the emitted light 32 projected on the screen 22 is Fraunhofer diffraction. Further, it is assumed that the incident light 31 is coherent parallel light incident perpendicularly to the surface of the light scattering region 12a. The angle formed by the incident light 31 and the emitted light 32 transmitted through the light scattering region 12a in the XZ plane is defined as θ.
In this figure, the transmitted light is projected onto the screen 22 as the emitted light 32, but in this figure, the incident light 31 is incident on the image display body 10 and the diffracted light (emitted light 32) emitted from the image display body 10 is observed. The diffracted light projected on the screen 22 corresponds to the diffracted light observed by the observer 14. Further, in this figure, four light scattering regions 12a are arranged, but this figure is a schematic diagram and the present invention is not limited to this.
As described above, since the size of the light scattering region 12a is less than the resolution of the human eye, a smooth image can be displayed. Therefore, when the observer 14 observes the image display body 10, the size of the light scattering region 12a is sufficiently small with respect to the distance between the image display body 10 and the observer 14, and the diffracted light observed by the observer 14 is Fraunhofer. It becomes diffraction.

FIG. 7 is a graph schematically showing the intensity distribution of the emitted light 32 from the single light scattering region 12a.
The emission angle θ shown in the figure indicates the emission angle of the emitted light 32 obtained when the incident light 31 perpendicular to one surface of the substrate 11 provided with the light scattering region 12a is incident. Is defined as θ. The intensity of the diffracted light is shown as a relative value, and the intensity of the 0th-order diffracted light is 1. In addition, the graph shown in figure is a schematic thing used for description, and the intensity distribution of the diffracted light inject | emitted from the light-scattering area | region of the image display body of this invention is not restricted to this.

  The intensity of the emitted light 32 shows a peak in the direction of the 0th-order diffracted light, but as described above, the light scattering region 12a emits scattered light having directivity, so that in a wide range of the value of the emission angle θ, The intensity distribution of the emitted light 32 (diffracted light) emitted from the light scattering region 12a spreads gently.

  However, the diffracted light actually observed by the observer 14 is not only due to the structure provided in the light scattering region 12a. In the present embodiment, the light scattering regions 12a are arranged in a matrix, and diffraction caused by the light scattering regions 12a also contributes.

The contribution of the single light scattering region 12a to the intensity distribution of the diffracted light is expressed as s (θ) at the Z-axis coordinate value z = 0 in FIG. θ). At this time, the intensity distribution shown in FIG. 7 can be expressed as S (θ).
Further, the contribution to the intensity distribution of the diffracted light due to the plurality of light scattering regions 12a being arranged in a matrix is expressed as g (θ) at the Z-axis coordinate value z = 0 in FIG. Let the Fourier transform be G (θ). Note that g (θ) and G (θ) are schematically shown in FIGS. 8 (a) and 8 (b).

  When the light scattering regions 12a are arranged in a matrix, the contribution to the intensity distribution at z = 0 can be expressed as s (θ) * g (θ) using the above formula. Since the intensity distribution of the emitted light 32 (diffracted light) at z = R (position of the screen 22) is a Fourier transform of the intensity distribution, it becomes S (θ) · G (θ).

  FIG. 8A and FIG. 8B are graphs showing g (θ) and G (θ), respectively. Since g (θ) is a comb function, G (θ) obtained by Fourier transform of the function also becomes a comb function. 8 (a) and 8 (b), the period of G (θ) is larger than that of g (θ). However, in practice, the magnitude relationship changes depending on how each unit is taken. The magnitude relationship between the periods of g (θ) and G (θ) is not limited to that shown in FIG.

  FIG. 9 is a graph schematically showing S (θ) · G (θ).

The broken line shown in FIG. 9 represents S (θ) shown in FIG. 7, and the solid line represents S (θ) · G (θ).
From the figure, it can be seen that S (θ) · G (θ) has an intensity for each fixed period. That is, when the observer 14 observes the emitted light 32 emitted from the plurality of light scattering regions 12a arranged in a matrix, it is possible to observe how light and darkness and color changes appear periodically.

  However, the light and darkness and the color change that appear periodically are similar to the visual effect of a conventional diffraction grating pattern, and become a factor that makes it difficult for the observer 14 to observe the white color due to the light scattering region 12a.

By the way, the period of G (θ) can be calculated from the value of D in the following equation (1).
D = λ / sin θ (1)

  In the above equation (1), D is the length of the light scattering region 12a in the first direction (X-axis direction), λ is the wavelength of the incident light 31, and sin θ is the sine of the emission angle θ shown in FIG.

As described above, the periodic intensity distribution shown in the graph of FIG. 9 causes changes in brightness and color when observed by an observer. However, although there is a periodic intensity distribution, no change in brightness or color is observed unless the eyes of the observer 14 can perceive it.
Therefore, if the period of G (θ) is equal to or smaller than the human pupil diameter, it is possible to stably observe white due to directional scattering without observing light and darkness and color change.

By the way, the pupil diameter of the human eye is generally 2 to 8 mm, and the wavelength range of visible light is 400 to 700 nm. Further, it is assumed that the distance between the display surface (one surface) of the image display body 10 and the eyes of the observer 14 is 500 mm.
At this time, the prospective angles of the left and right eyes are 0.23 to 0.92 °.

When the observer 14 observes the image display body 10 according to the present embodiment and an information medium 200 to be described later using the image display body 10, the observer rarely observes in an extremely bright place or an extremely dark place. There are often. Therefore, although the pupil diameter of the human eye is 2 to 8 mm as described above, the pupil diameter of the human eye when observing the image display body 10 to the information medium 200 of the present embodiment is approximately 4 to 5 mm. Become. At this time, each prospect of each of the left and right eyes is 0.46 to 0.57 °.
Further, the wavelength range of visible light is 400 to 700 nm, but here, 555 nm, which has the highest spectral sensitivity, is considered as a representative value.

  Substituting = λ = 555 nm and θ = 0.46 ° in equation (1) yields D = 69 μm. Therefore, when the length of the light scattering region 12a in the first direction is 69 μm or more, it is possible to provide the image display body 10 and the information medium 200 that stably display white without observing light and darkness or color change. Is possible.

From the equation (1), it is understood that the value of the length D in the first direction (X-axis direction) of the light scattering region 12a increases as the value of the wavelength λ of the incident light 31 increases. Therefore, for example, in the case of λ = 700 nm, even if the length of the light scattering region 12a in the first direction is 69 μm or more, light and darkness and color change are observed.
However, the observer 14 observes the image display body 10 and the information medium 200 according to the present embodiment generally under room illumination as described above, and receives coherent light having a wavelength length of 700 nm. There is no observation. In addition, indoor lighting is usually white light, and is rarely a single point light source, and generally consists of a plurality of point light sources, line light sources, and surface light sources.
Therefore, in view of the indoor lighting environment as described above, an image display body that stably displays a white color under a normal indoor lighting environment can be obtained if it is 69 μm or more obtained with 555 nm having the highest spectral sensitivity as a representative value. It becomes possible to provide.

  Substituting λ = 700 nm and θ = 0.46 ° in equation (1) yields D = 87 μm. Therefore, if the length of the light scattering region 12a in the first direction is 87 μm or more, an image that stably displays white without being observed in light and darkness or color change even in an illumination environment composed of a single point light source. The display body 10 and the information medium 200 can be provided.

By the way, if a stable white color due to directional scattering is displayed, a complete random pattern as produced by photographing or the like may be used, and there is no need to arrange a plurality of light scattering regions 12a. However, in order to produce a high-definition and high-resolution image, a method using the above-described electron beam exposure apparatus is more common than photographing.
In order to produce a complete random pattern with an electron beam exposure apparatus, it is necessary to create data of the structure pattern. However, in order to create an image using it, it is necessary to create data of a structure pattern corresponding to the size of the image, and the amount of data becomes enormous, which is very difficult to handle.
Therefore, a method of arranging a plurality of light scattering regions 12a in a matrix as in this embodiment is effective. In the case of this method, the amount of data required is far less than creating a complete random pattern, and it becomes possible to create a high-definition, high-resolution image by repeatedly arranging it. .

  Furthermore, when all the structural patterns of the light scattering region 12a are the same, the required data is only the area of the light scattering region 12a, and the data creation effort can be greatly reduced. In this case, by arranging the same structure pattern, the data of the entire image can be compressed at a high compression rate, and adverse operational effects due to the enormous amount of data can be reduced.

When the arrangement pattern of the light scattering pattern 12c is continuously connected between the adjacent light scattering regions 12a, the contribution to the intensity distribution due to the plurality of the light scattering regions 12a arranged in a matrix can be reduced. Therefore, since the structural patterns are continuously connected between the adjacent light scattering regions 12a, a more stable white color can be displayed.
Here, the arrangement pattern of the light scattering pattern 12c is continuously connected between the adjacent light scattering regions 12a is a boundary portion between two light scattering regions 12a and 12a adjacent in the X-axis direction and the Y-axis direction in FIG. The light scattering pattern 12c of each light scattering region 12a is connected so that the seam is not conspicuous.
When the light scattering pattern 12c of the light scattering region 12a is, for example, as shown in FIG. 10A, when two light scattering regions 12a are arranged in the X-axis direction of FIG. 1, it is shown in FIG. As described above, the light scattering pattern 12c is not continuous at the boundary portion between the two light scattering regions 12a and 12a, and the joint is conspicuous. In such a joint portion, the distribution of the emitted light is different from the distribution of the emitted light in each light scattering region 12a.
Therefore, in the light scattering region 12a having the light scattering pattern 12c of FIG. 10A, the intensity distribution of the emitted light in the entire matrix is uniform when arranged in a matrix in the X-axis direction and the Y-axis direction of FIG. Can not be converted.
On the other hand, when the light scattering pattern 12c of the light scattering region 12a is as shown in FIG. 11A, for example, when two light scattering regions 12a are arranged in the X-axis direction of FIG. 1, FIG. As shown in FIG. 4, the light scattering pattern 12c is continuous at the boundary portion between the two light scattering regions 12a and 12a, and the joint becomes inconspicuous.
Thus, if the light scattering pattern 12c of both the regions 12a and 12a continues at the boundary portion between the adjacent light scattering regions 12a and 12a, a plurality of light scattering regions 12a are formed in the X-axis direction and the Y-axis direction of FIG. By arranging in a matrix, one large light scattering region can be configured.
By the way, the light scattering pattern shown in FIG. 12A has an intensity distribution of emitted light that shows the frequency spectrum of FIG. Then, different partial regions are extracted from the light scattering pattern of FIG. 12A and enlarged to obtain the light scattering patterns shown in FIGS. 13A and 14A, respectively. When each of these light scattering patterns is Fourier transformed, the same frequency spectrum as shown in FIG. 12B is obtained as shown in FIGS. 13B and 14B. That is, the light scattering patterns in FIGS. 13A and 14A have the same intensity distribution of emitted light as the light scattering pattern in FIG.
For this reason, when it has the arrangement pattern which the light-scattering pattern 12c connects continuously in the X-axis direction of FIG. 1, or the Y-axis direction like the light-scattering area | region 12a of FIG. By arranging the regions 12a in a matrix, a light scattering pattern having the same intensity distribution of the emitted light can be formed regardless of which region is partially cut out as shown in FIG.
That is, if the light scattering region 12a has the light scattering pattern 12c in FIG. 11A, the content of the light scattering pattern 12c is changed to the light scattering pattern in FIG. 13A or FIG. When arranged in a matrix in the X-axis direction and the Y-axis direction of FIG. 1, the intensity distribution of the emitted light can be made uniform throughout the matrix.
Thereby, the contribution to the intensity distribution of the diffracted light due to the light scattering regions 12a being arranged in the X-axis direction and the Y-axis direction can be reduced.

By the way, when the observer 14 observes the image display body 10 at a position 500 mm away from the eye, generally, the resolution of a human eye having a visual acuity of 1.0 is 1 minute (1 / 1.0 = 60 seconds). Therefore, a structure of 145 μm or less cannot be decomposed due to the limit of eye resolution. Therefore, if the length of one side of the light scattering region 12a is 145 μm or less, the light scattering regions 12a cannot be decomposed. Therefore, by setting the length of one side of the light scattering region 12a to 145 μm or less, it is possible to provide the image display body 10 that displays a higher quality image.
As described above, the image display body 10 according to the present embodiment has a visual effect of white display different from the conventional diffraction grating pattern, so it is difficult to forge or imitate, thereby realizing a higher anti-counterfeit effect. can do.

FIG. 15 is a plan view schematically showing an information medium according to an embodiment of the present invention.
An information medium 200 of this embodiment shown in FIG. 15 is a magnetic card and includes a base material 51. A printed layer 52 and a strip-shaped magnetic recording layer 53 are formed on the substrate 51. Furthermore, the image display body 10 is affixed on the base material 51 as an anti-counterfeit or personal identification label.

  The information medium 200 includes the image display body 10. Therefore, forgery or imitation of this information medium 200 is difficult.

  Note that the material of the substrate 51 may not be paper such as natural paper and synthetic paper. For example, polyethylene terephthalate resin (thermoplastic PET), polyvinyl chloride resin, thermosetting polyester resin, polycarbonate resin, synthetic resin such as polymethacrylic resin and polystyrene resin, ceramics such as glass, ceramic and porcelain, or single metal and It may be a metal material such as an alloy.

DESCRIPTION OF SYMBOLS 10 ... Image display body 11 ... Light transmission layer 12a ... Light scattering area | region 12b ... Non-light scattering area | region 12c ... Light scattering pattern 13 ... Light reflection layer 14 ... Observer 20 ... Fourier-transform image 22 ... Screen 31 ... Incident light 32 ... Ejection Light 32a ... 0th order diffracted light 32b ... Diffraction light 51 ... Base material 52 ... Printed layer 53 ... Magnetic recording layer 200 ... Information medium

Claims (6)

On at least one surface of the light-transmitting substrate, a light scattering region in which a plurality of linear light scattering patterns constituted by at least one of the concave portion and the convex portion are arranged in the same direction is provided.
A light reflection layer covering at least a part of the light scattering region on the one surface of the substrate;
An image is displayed by arranging a plurality of the light scattering regions on the one surface of the base material in a matrix along the extending direction of the light scattering patterns and the interval direction of the light scattering patterns. In the image display body to
The length of the said light-scattering area | region in the space | interval direction of the said light-scattering pattern on said one surface is 69 micrometers or more, The image display body characterized by the above-mentioned.   The image display body according to claim 1, wherein a length of the light scattering region in the interval direction is 87 μm or more.   The image display body according to claim 1, wherein each of the light scattering regions has the light scattering pattern in the same arrangement pattern.   In the extending direction and the interval direction, the light scattering patterns of two adjacent light scattering regions are continuous, and an arrangement pattern in which the intensity distribution of the emitted light is the same is obtained by an arbitrary portion of the continuous light scattering patterns. The image display body according to claim 1, 2, or 3.   The image display body according to claim 1, wherein a length of the light scattering region in the interval direction is 145 μm or less.   An information medium comprising the image display body according to any one of claims 1 to 5 and an article supporting the image display body.

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