1. Field of the Invention
The present invention relates to a forgery prevention technique.
2. Description of the Related Art
Authentication articles such as cash cards, credit cards and passports and securities such as gift certificates and stock certificates are desired to be difficult of forgery. For this reason, a label which is difficult of forgery or imitation and which makes it easy to distinguish a genuine article from a forged article or an imitated article has conventionally been attached to such an article in order to suppress the forgery.
Further, in recent years, circulation of forged articles is regarded as a problem also for articles other than the authentication articles and securities. For this reason, opportunities have been increasing to apply the forgery prevention technique mentioned for the authentication articles and the securities to such articles.
Patent document 1 describes a display in which multiple pixels are arranged. In this display, each pixel includes a relief-type diffraction grating in which grooves are arranged.
This display displays an image by utilizing diffracted light, and hence it is impossible to forge the display using the printing technique or electrophotographic technique. Accordingly, if this display is attached to an article as a label for authentication, seeing the image displayed on the label makes it possible to confirm that the article is genuine. Therefore, an article to which this label is attached is hardly forged as compared with an article to which this label is not attached.
The above-mentioned relief-type diffraction grating, however, can be formed with comparative ease if a device such as a laser is available. Further, in the above display, although a change in the display image is caused by changing an incident angle of the illumination light, an observation angle or an orientation of the display, the change is not so rich in variety. Therefore, with the development of the technology, the forgery prevention effect of this display is becoming lower. Incidentally, difficulty of forgery or imitation, or ease in distinction of a genuine article from a forged or imitated article is called here a forgery prevention effect.
Patent document 1: Jpn. Pat. Appln. KOKAI Publication No. 2-72320
An object of the present invention is to realize a higher forgery prevention effect.
According to a first aspect of the present invention, there is provided a display characterized by comprising a relief-structured region as an image-constituting element including recessed portions, protruding portions or both of them arranged two-dimensionally on one of main surfaces of a light-transmitting layer, and a reflection layer supported by said one of the main surfaces and covering at least a part of the relief-structured region, wherein a center-to-center distance of the recessed portions, protruding portions or both of them falls within a range of 200 nm to 500 nm.
According to a second aspect of the present invention, there is provided a labeled article characterized by comprising the display according to the first aspect, and an article supporting it.
According to the present invention a higher forgery prevention effect can be realized.
Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. Incidentally, in the drawings, constituent elements exhibiting the identical or similar function are denoted by the identical reference symbols, and a duplicate description will be omitted.
This display 10 is constituted by a light-transmitting layer 11 and a reflection layer 13. In the example shown in
Further, on the main surface of the light-transmitting layer 11 that includes the relief-structured region 12a, the reflection layer 13 is formed such that it covers at least a part of the relief-structured region 12a.
As a material for the light-transmitting layer 11, for example, a resin with optical transparency can be used. For example, when a thermoplastic resin or a photo-setting resin is used, it is possible to easily form a light-transmitting layer 11 provided with recessed portions, protruding portions or both of them on one main surface thereof by transfer using a master.
In the case where the display 10 according to the present invention includes both of the light-transmitting layer 11 and the reflection layer 13, damage of surface of the relief-structured region 12a is less prone to occur and an image with a higher viewabillity can be displayed on the display as compared with the case where it includes only one of them.
As the reflection layer 13, for example, a metallic layer made of a metallic material such as aluminum, silver, and alloys thereof can be used. Alternatively, a dielectric material layer with a refractive index different from that of the light-transmitting layer may be used as the reflection layer 13. Further, as the reflection layer 13, a laminated body of dielectric layers in which adjacent layers have different refractive indices, i.e. a multilayered dielectric film, may be used. However, one of the dielectric layers of the dielectric multilayer film that is in contact with the light-transmitting layer 11 needs to have a refractive index different from the refractive index of the light-transmitting layer.
The relief-structured region 12a shown in
Note that the non-relief-structured region 12b is a flat surface.
Next, the special visual effect of the display 10 originated from the relief-structured region 12a will be described.
In the case where center-to-center distances of the recessed portions, protruding portions or both of them have a constant periodicity, when the relief-structured region is illuminated, the relief-structured region emits diffracted light in a specific direction that depends on a traveling direction of the illumination light as the incident light.
1st-order diffracted light is the most representative diffracted light. An angle of emergence β of 1st-order diffracted light can be calculated using the following equation (1).
d=mλ/(sin α−sin β) (1)
In this formula (1), d represents a center-to-center distance of the recessed portions or protruding portions, and λ represents a wavelength of the incident light and the diffracted light. Further, α represents the angle of emergence of the 0-order diffracted light, i.e., the transmitted light or the regular reflected light. In other words, α is equal in absolute value to the incident angle of the illumination light, and is symmetrical to the incident angle with respect to the Z axis (in the case of the reflection-type diffraction grating). Incidentally, as for α and β, the clockwise direction from the Z axis is the positive direction.
As is evident from the formula (1), the angle of emergence β of the 1st-order diffracted light changes according to the wavelength λ. That is, the relief-structured region has a function as a spectroscope. Accordingly, in the case where the illumination light is white light, when the observation angle is changed, the color perceived by the observer will be changed.
Further, the color perceived by the observer under a certain observation condition changes according to the grating constant d. As an example, it is assumed that the relief-structured region emits 1st-order diffracted light in the normal direction thereof. That is, it is assumed that the angle of emergence p of the 1st-order diffracted light is 0°. Further, it is assumed that the observer perceives this 1st-order diffracted light. When it is assumed that the angle of emergence of the 0-order diffracted light at this time is αN, the formula (1) can be simplified to the following formula (2).
d=λ/sin αN (2)
As is evident from the formula (2), in order to allow the observer to perceive a specific color, it suffices that a wavelength λ corresponding to the color, an incident angle |αN| of the illumination light, and a center-to-center distance d are set to satisfy the relationship shown by the formula (2).
As described above, the center-to-center distance of the recessed portions, protruding portions or both of them provided in the relief-structured region 12a falls within a range of 200 nm to 500 nm. Therefore, the reflectance for the regular reflected light 32 with respect to the illumination light 31 can be decreased significantly, and the periodicity of the structure may allow visible light to be emitted as the 1st-order diffracted light 33 in a specific direction depending on the incident angle of the illumination light 31.
Thus, when the display 10 according to the present invention is observed in the normal direction, the relief-structured region 12a is seen black. Here, “black” means that the reflectance for any of the light components within a wavelength range of 400 nm to 700 nm is 25% or less when the display 10 is irradiated with light from the normal direction and the intensity of the regular reflected light is measured. Thus, the relief-structured region 12a is seen as if it is a black printed layer.
In the case where the angle of emergence of the 1st-order diffracted light from the relief-structured region 12a falls within a range of −90° to 90°, if the angle formed by the normal to the display 10 and the observation direction is set appropriately, the observer can perceive the 1st-order diffracted light 33 from the relief-structured region 12a. Thus, in this case, it is possible to check with eyes that the relief-structured region 12a is different from a black printed layer.
That is, the relief-structured region 12a can greatly decrease the reflectance for regular reflected light with respect to incident light and can allow visible light to be emitted as reflection-diffracted light by the periodicity of the structure in a specific direction depending on the incident angle of the incident light. Therefore, under most observation conditions, the relief-structured region 12a is seen black while the regular reflected light 32 from the non-relief-structured region 12b can be observed, and a high-contrast image can thus be displayed.
On the other hand, since diffracted light can be observed under the aforementioned condition where the 1st-order diffracted light 33 can be observed, it is possible to impart an unique visual effect that an image seen black under a normal condition is suddenly seen lucently when changing the observation angle.
Therefore, when the display 10 is used as a label for forgery prevention, a high forgery prevention effect can be achieved.
The master can be formed using a method in which interference fringes are recorded in a photoresist by a laser beam or a method in which micromachining is performed at a constant pitch. Further, when embossing is performed on a thermoplastic resin or a photo-setting resin using the master, the same displays can be manufactured in quantity with a high degree of precision. On the other hand, it is very difficult to analyze the microstructure and the arrangement pattern from the appearance of the display according to the present invention and to manufacture the same display. Thus, its forgery prevention effect is high.
In the display 10 shown in
In the display shown in
In the display 10 shown in
In the display 10 shown in
The relief-structured region 12a shown in
Further, the intermediate portions can be omitted.
It should be noted in the case where embossing is utilized for volume production, it is preferable in terms of ease of molding that whole the relief-structured region 12a including the recessed portions 14a and the protruding portions 14b is lower than the main surface.
The recessed line 16a in the present invention is constituted by recessed portions arranged in a line. The recessed line 16a may be a straight line as shown in
Further, it suffices that the longitudinal directions of the recessed lines 16a and the protruding lines 16b are almost the same. This means that the recessed line 16a and the protruding line 16b adjacent to each other do not intersect each other.
Since the relief-structured region 12a includes the recessed portions 14a and the protruding portions 14b, a lower reflectance can be achieved even when the depth of the recessed portions 14a is made shallower or the height of the protruding portions is made lower as compared with the case where the relief-structured region includes only the recessed portions 14a or the protruding portions 14b. In other words, a deeper black can be displayed without making the depth of the recessed portions 14a deeper or the height of the protruding portions 14b higher.
In addition, since the relief shape is more complicated as compared with the relief-structured region including only the recessed portions 14a or the protruding portions 14b, analysis of the relief shape is more difficult. Thus, the forgery prevention effect is enhanced.
In
In the master for the relief-structured region 12a formed by the method shown in
However, the relief-structured region 12a is not limited to this. In the relief-structured region 12a including the recessed portions 14a and the protruding portions 14b, the reference level may be positioned at the same level as that of the surface of the resist material or may be positioned higher than it. Further, as described above, the intermediate portions 14c may be omitted.
Note that as for the relief-structured region 12a including the recessed portions 14a and the protruding portions 14b, the depth of the recessed portions 14a and the height of the protruding portions 14b means depth and height from the reference level, respectively.
In
Further, in the structure shown in
Although the center-to-center distance of the recessed portions, protruding portions or both of them in the X direction and that in the Y direction are made equal to each other in
When the center-to-center distances of the recessed portions, protruding portions or both of them are set comparatively long in both of the X direction and the Y direction, it is possible to allow the relief-structured region 12a to emit diffracted light in both the case where the display 10 is illuminated from a direction perpendicular to the Y direction and the case where the display 10 is illuminated from a direction perpendicular to the X direction, and is possible to make the wavelength of the diffracted light in the former case and that in the latter case different from each other. When the center-to-center distances of the recessed portions, protruding portions or both of them are set comparatively short in both the X direction and the Y direction, it is possible to prevent the relief-structured region 12a from emitting diffracted light regardless of the illumination direction. When the center-to-center distances of the recessed portions, protruding portions or both of them are set comparatively long in one of the X direction and the Y direction, and are set comparatively short in the other of the directions, it is possible to allow the relief-structured region 12a to emit diffracted light when the display 10 is illuminated from a direction perpendicular to one of the Y direction and the X direction, and prevent the relief-structured region 12a from emitting diffracted light when the display 10 is illuminated from a direction perpendicular to the other of the Y direction and the X direction.
In
Further, when the structure shown in
In
In
As exemplified in
Each structure shown in
In the structure shown in
In the structure shown in
In the structure shown in
Note that the structure shown in
In the structure shown in
In the case where the structure shown in
As described above, the shape of the recessed portions, protruding portions or both of them influences the reflectance of the relief-structured region. Accordingly, when the relief-structured region is constituted by pixels different in the shape of the recessed portions, protruding portions or both of them, a gray-scale image can be displayed on the relief-structured region.
In the present invention, when the center-to-center distance of the recessed portions, protruding portions or both of them is 400 nm or less, it is possible to prevent diffracted light components within a wavelength range of 400 to 700 nm from being emitted by the recessed portions, protruding portions or both of them in the normal direction. According to the equation (2), the light of 400 nm is barely able to travel in the normal direction when illuminated at 89°. Thus, under any illumination condition, the recessed portions, protruding portions or both of them cannot emit diffracted light in the normal direction at sufficient intensity within substantially the whole visible range of wavelength. Therefore, it is possible to make the relief-structured region seen black at a higher degree of reliability when observed in the normal direction. This makes the discrimination between a genuine article and a non-genuine article easier, and the forgery prevention effect is thus enhanced.
When the center-to-center distance of the recessed portions, protruding portions or both of them is 200 nm or more and 350 nm or less, as for the visible wavelength range of 400 to 700 nm, diffracted light corresponding to at least the red component cannot be observed on the relief-structured region. According to the equation (1), light of 700 nm is diffracted in a direction of 89° in the case of the center-to-center distance of 350 nm and the illumination light at 89°. Thus, as for substantially red light, the recessed portions, protruding portions or both of them cannot emit diffracted light in the normal direction at sufficient intensity under any illumination condition. On the other hand, light of 400 nm is diffracted in a direction of 89° in the case of the center-to-center distance of 200 nm and the illumination light at 89°. Thus, it will be understood that blue light is the lower limit for diffraction. Accordingly, in the case where the pitch of the arrangement of the recessed portions, protruding portions or both of them is 200 nm or more and 350 nm or less, when illuminated at a wide angle, diffracted light other than red can be observed at a similar wide angle. Further, under the other conditions, no diffracted light is emitted, and no diffracted light is thus be perceived under ordinary observation conditions. Therefore, it is possible to make the relief-structured region seen black at a higher degree of reliability when observed in the normal direction, and thus make blue or green diffracted light observed under a specific condition. This makes the discrimination between a genuine article and a non-genuine article easier and more reliable, and the forgery prevention effect is thus enhanced.
When the depth of the recessed portions or the height of the protruding portions is made larger, the relief-structured region becomes seen darker. For example, when the depth of the recessed portions or the height of the protruding portions is made equal to or larger than half their center-to-center distance, the relief-structured region becomes seen very dark. Therefore, when the relief-structured region is constituted by pixels different from each other in the depth of the recessed portions or the height of the protruding portions, a gray-scale image can be displayed on the relief-structured region.
When the ratio of a size of the recessed portions or protruding portions in a direction parallel with the relief-structured region to a center-to-center distance of the recessed portions or protruding portions in the same direction as the above direction is made nearer to 1:1, the relief-structured region becomes seen darker. Further, when the size of the recessed portions or protruding portions in the direction parallel with the relief-structured region is made equal to the center-to-center distance of the recessed portions or protruding portions in the same direction as the above direction, the relief-structured region becomes seen darkest. Accordingly, when the relief-structured region is constituted by pixels different from each other in the above ratio, a gray-scale image can be displayed on the relief-structured region.
In the display according to the present invention, it is possible that on one of main surfaces of the light-transmitting layer having the relief-structured region, the reflection layer is to cover at least a part of the relief-structured region, and a resin layer is further formed to cover at least the relief-structured region.
For the resin layer, a resin such as acrylics, urethanes and epoxides can be used. Note that in the case where a part of the relief-structured region is not covered with the reflection layer, it is preferable that its refractive index is the same as the refractive index of the light-transmitting layer, because the effect of the relief structure is cancelled, and the presence and absence of the reflection layer is thus accentuated.
When this is done, it becomes possible to prevent the function of the present invention from being greatly damaged due to inclusion of foreign matter on the surface of the relief-structured region. Thus, using the display according to the present invention, the discrimination between a genuine article and a non-genuine article can be performed with reliability and stability. The reflectance of the reflection layer is less than 100%. Covering the reflection layer's side of the light-transmitting layer with the resin layer increases the refractive index from the refractive index of the air (1.0) to the refractive index of a resin (about 1.4 to 1.6) and thus decreases the reflectance of the interface between the reflection layer and the resin layer. This makes black seen deeper, and the visual effect becomes thus clear.
This printed matter 100 is a magnetic card, and includes a substrate 51. The substrate 51 is made of, for example, plastic. A printing layer 52 and a band-shaped magnetic recording layer 53 are formed on the substrate 51. Further, a display 10 is adhered to the substrate 51 as a label for forgery prevention or identification. Incidentally, the display 10 has the same structure as that described previously with reference to
This printed matter 100 includes the display 10. Accordingly, as described above, this printed matter 100 is difficult of forgery or imitation. Further, because this printed matter 100 includes the display 10, an article whose genuineness is uncertain can be easily descriminated between a genuine article and a non-genuine article. Moreover, this printed matter 100 further includes the printing layer 52 in addition to the display 10, and hence it is easy to constrast the vision of the printing layer 52 with the vision of the display. Therefore, an article whose genuineness is uncertain can be descriminated between a genuine article and an non-genuine article easier as compared with the case where the printed matter 100 does not include the printing layer 52.
Although in
Although in the printed matter 100 shown in
Further, it is not necessary for a labeled article to be a printed matter. That is, the display 10 may be supported by an article including no printing layer.
10 . . . display, 11 . . . light-transmitting layer, 12a . . . relief-structured region, 12b . . . non-relief-structured region, 13 . . . reflection layer, 14a . . . recessed portion, 14b . . . protruding portion, 14c . . . intermediate portion, 16a . . . recessed line, 16b . . . protruding line, 31 . . . illumination light, 32 . . . regular reflected light or O-order diffracted light, 33 . . . 1st-order diffracted light, 51 . . . substrate, 52 . . . printed layer, 53 . . . magnetic recording layer, 100 . . . printed matter.
Number | Date | Country | Kind |
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2007-254689 | Sep 2007 | JP | national |
This is a Continuation Application of PCT Application No. PCT/JP2007/072133, filed Nov. 14, 2007, which was published under PCT Article 21(2) in Japanese. This application is based upon and claims the benefit of priority from prior Japanese Patent Application No. 2007-254689, filed Sep. 28, 2007, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/JP2007/072133 | Nov 2007 | US |
Child | 12592527 | US |