JP2016212771A - Information recording medium with non-contact type IC - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an information recording medium mounting an IC chip, capable of preventing fabrication using an antenna and the IC chip having same configuration, in addition to authenticity determination function by a watermark, and a booklet using the same medium.SOLUTION: The information recording medium with a non-contact type IC is formed by laminating sequentially, a first layer which is a paper base material, a second layer which is a plastic base material, and a third layer with common areas on same positions of the respective layers having light permeability. The first layer has a first image which is a permeation pattern on the common area, and the second layer has an IC chip and an antenna on the surrounding of the common area.SELECTED DRAWING: Figure 2

Description

  The present invention provides an information recording medium equipped with a non-contact type IC chip capable of performing non-contact communication with an external processing apparatus, and a passport, a bankbook, a student ID card, an employee ID card using the information recording medium. It is about the booklet to prove.

  2. Description of the Related Art Conventionally, a booklet having an identification function such as a passport is printed with a face photo and personal information for identifying himself / herself on the front cover, and a sheet on which necessary items such as a visa can be written. The paper is provided with a forgery prevention element capable of performing authenticity determination by visual inspection such as squeezing or pearl ink. In the entry / exit screening of travelers, in order to prevent unauthorized entry / exit, humans visually identify the items described above and the anti-counterfeiting elements described above.

  In recent years, the need for mechanical recognition has further increased, and by incorporating a card-like information recording medium having a non-contact type IC chip and an antenna into a booklet, in addition to a visual authenticity discrimination function, Various devices having a true / false discrimination function by machine reading have been proposed.

  For example, in Patent Document 1, an IC sheet having an area for diffusing light and an IC chip and an antenna is provided in the intermediate layer, and the upper layer is a paper having a gap adjacent to the intermediate layer, and the lower layer is a paper. A booklet having an information recording medium is disclosed. When the booklet is viewed from the upper layer side under transmitted light, the clearance formed in the upper layer is visible through the light transmission region of the intermediate layer, but when viewed from the lower layer side, the light diffusion function of the intermediate layer Due to this, it is impossible to visually recognize the clearance.

Japanese Patent No. 5345685

  According to Patent Document 1, by having an information recording medium provided with a transparent pattern and an IC chip, it is possible to have a function of reading information in a booklet in addition to a function of discriminating authenticity using a watermark. However, in the booklet of Patent Document 1, since the intermediate layer has a light diffusing function, the clearance cannot be visually recognized from the front and back. Therefore, when a counterfeit product is produced as a pattern by printing using ordinary printing ink, it becomes difficult to visually distinguish the reflected image from the transmissive pattern at first glance.

  SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems, and in an information recording medium on which an IC chip is mounted, an information recording medium capable of performing authenticity determination by a watermark from both front and back, and the information It is to provide a booklet using a recording medium.

  In the information recording medium with a non-contact type IC of the present invention, the first layer that is a paper base, the second layer that is a plastic base, and the third layer have a light transmitting property at the same position in each layer. The first layer has a first image that is a transmissive pattern in the common area, and the second layer has an IC chip and an antenna around the common area. It is characterized by.

  The non-contact type IC-attached information recording medium of the present invention has a second image that is a transmissive pattern in a common area in the second layer and / or the third layer, and the first image and the first image. A composite pattern (10) based on the second image is formed.

  The information recording medium with a non-contact type IC according to the present invention is characterized in that the periphery of the common area has a predetermined opacity and conceals the IC chip and the antenna.

  Furthermore, the information recording medium with a non-contact type IC according to the present invention is used for a booklet.

  According to the present invention, the information recording medium is formed in a three-layer structure, and the transmission pattern is visible on the front and back surfaces under the transmitted light by having the transmission pattern in the common area formed at the same position of each layer. Therefore, when authenticity determination is performed based on the presence or absence of a transmissive pattern, it is possible to determine instantaneously without depending on the observation surface.

It is a schematic diagram showing an information recording medium with a non-contact type IC of the present invention. It is a schematic diagram which shows the lamination | stacking state of an information recording medium. It is a schematic diagram which shows the other lamination | stacking state of an information recording medium. It is a top view which shows a 1st layer. It is the top view and sectional drawing which show a 2nd layer. It is a top view which shows a 3rd layer. It is a schematic diagram which shows the visual recognition state of an information recording medium (S). It is a top view which shows the information recording medium (S) which has a printing part (7). It is a top view which shows the information recording medium (S) which has a concealing layer (8). It is a schematic diagram which shows the modification of an information recording medium (S). It is a schematic diagram which shows the visual recognition state of an information recording medium (S '). It is the schematic which shows use to the booklet (M) of an information recording medium (S, S '). It is the schematic which shows the binding method to the booklet (M) of an information recording medium (S, S ').

(First embodiment)
EMBODIMENT OF THE INVENTION The form for implementing this invention is demonstrated with reference to drawings. However, the present invention is not limited to the embodiments to be described below, and includes various other embodiments within the scope of the technical idea described in the scope of claims.

  FIG. 1 is a schematic diagram showing an information recording medium with a non-contact type IC (hereinafter referred to as “information recording medium”) (S) of the present invention, and FIG. 1 (a) shows the information recording medium (S). It is a top view. The information recording medium (S) is a card that requires individual identification such as a driver's license and an employee ID card. The information recording medium (S) includes a common area (Z) and a peripheral area (P) formed around the common area (Z).

  The common area (Z) is light transmissive, and a first image (1) having a transmissive pattern is formed. The peripheral area (P) includes an IC chip (2) and an antenna (3).

  In the present invention, having light transparency means that the transmission density is 0.9 or less. The transmission density decreases as the inspection object easily transmits light. When the difference between the transmission densities in two adjacent areas exceeds 0.9, the two adjacent areas cannot be visually recognized by being visually distinguished. Therefore, by setting the transmission density of the common region (Z) to 0.9 or less, the transmission density of the common region (Z) and the peripheral region (P) formed therearound can be visually distinguished. Under the reflected light, the common area (Z) and the peripheral area (P) cannot be distinguished and visually recognized, but under the transmitted light, the common area (Z) and the peripheral area (P) should be distinguished and visually recognized. Is possible. Therefore, in the present invention, since the first image (1) is visible under transmitted light, the transmission density of the common region (Z) is set to 0.9 or less. The transmission density was measured using a portable transmission densitometer 341 manufactured by X-Rite.

  As shown in FIG. 1 (b), when the information recording medium (S) is viewed under reflected light, the first image (1) cannot be viewed, but as shown in FIG. 1 (c), When observed under transmitted light, the first image (1) can be viewed as a transmissive pattern from the common region (Z).

  FIG. 2 is a schematic diagram showing a stacked state of the information recording medium (S), and the first layer (4), the second layer (5), and the third layer (6) are sequentially stacked. . As shown in FIG. 2, the common region (Z1) in the first layer (4), the common region (Z2) in the second layer (5), and the common region (Z3) in the third layer (6) are: Overlapping at the same position.

  In FIG. 2, the common regions (Z1, Z2, Z3) have the same shape. The same shape in the present invention means that the size (area) is also the same, but includes not only the completely same shape but also different shapes within a range that can be regarded as the same by the naked eye. The common region (Z2) of the second layer (5) has the same shape as the common region (Z1) of the first layer (4) and the common region (Z3) of the third layer (6) described later. is there. The common area (Z1, Z2, Z3) of each layer has the same shape and is laminated so as to be in the same position, so that when it becomes an information recording medium (S), it actually has a three-layer structure. However, it can be visually recognized as a single layer configuration.

  If the first image (1) is visible from the front and back surfaces of the information recording medium (S) under transmitted light, the common areas (Z1, Z2, Z3) are not limited to the same shape. As shown in FIG. 3, each layer may have a different shape. When each layer has a different shape, there is a difference in the amount of transmitted light in the information recording medium (S) between a portion formed by one common region and a portion formed by stacking a plurality of common regions. Therefore, it is possible for the naked eye to visually recognize an area having light and shade (gradation) due to a difference in transmitted light amount.

  Hereinafter, the information is formed by stacking the common region (Z1) in the first layer (4), the common region (Z2) in the second layer (5), and the common region (Z3) in the third layer (6). When referring to the common area of the recording medium (S), it is referred to as “common area (Z)”. Further, the peripheral region (P1) in the first layer (4), the peripheral region (P2) in the second layer (5), and the peripheral region (P3) in the third layer (6) are laminated. When referring to the peripheral area of the recording medium (S), it is referred to as “peripheral area (P)”. Next, the information recording medium (S) of the present invention will be described in detail.

  First, the first layer (4) will be described.

  FIG. 4 is a plan view showing the first layer (4), and includes a common region (Z1) and a peripheral region (P1) formed around the common region (Z1). The first layer (4) is a paper base material having light transmission characteristics, so-called light transmission properties, such as high-quality paper and coated paper. With opaque plastic or metal, the effect under transmitted light cannot be obtained.

  Further, by using the paper base material, the printability when the personal information indicating the owner, the background pattern, or the like is provided on the information recording medium (S) is improved.

  The first layer (4) may have different light transmittance between the common region (Z1) and the peripheral region (P1). For example, in a paper base material with low light transmission, white transparency or penetrating ink is applied only to the common area (Z1) to increase the light transmission, and the common area (Z1) has a transparent pattern. It is also possible to have a certain first image (1) configuration.

  The common area (Z1) has a first image (1) that is a transmissive pattern. The first image (1) is not particularly limited in the formation method as long as the first image (1) can be viewed under transmitted light, such as squeezing, laser drilling, and printing using watermark ink. However, it is possible to visually recognize the first image (1) without being distinguished from the peripheral region (P1) under reflected light, and the concealability of the first image (1) is improved. Is preferred.

  When the first image (1) is formed by laser drilling, when the information recording medium (S) is repeatedly used, the first layer (4) may be damaged from the drilled portion, and durability may be reduced. There is sex. Therefore, when it is formed by laser drilling, it is preferable to perform lamination so as to cover the first image (1) as necessary.

  In addition, the watermark ink has a penetrating ink that improves the light transmittance of the paper base material to form a transparent pattern, as in white ink, and the light transmittance of the paper base material, as in black ink. There is a light-blocking ink containing titanium or iron oxide that forms a transmissive pattern, but the first image (1) cannot be distinguished from other regions under reflected light, and under transmitted light There is no particular limitation as long as it is visible. Further, the first image (1) may be formed as a transmission pattern having gradation by combining penetrating ink and light blocking ink.

  The color of the common area (Z1) in the first layer (4) makes the first image (1) invisible under reflected light and makes the first image (1) visible under transmitted light. There is no particular limitation as long as it is a color, but the same color as that of the first image (1) under reflected light is preferable. By using the same color as the first image (1), it is impossible to visually distinguish the first image (1) and the common area (Z1) under reflected light. In addition, the same color in the present invention includes a hue difference that cannot be distinguished or difficult to distinguish when two colors are visually recognized under reflected light.

  As described above, the information recording medium (S) in the present invention is not composed of only the first layer (4), but the first layer (4), the second layer (5), and the third layer. It is a laminated structure consisting of three layers called layer (6). Therefore, the common region (Z1) in the first layer (4), the common region (Z2) in the second layer (5) described later, and the common region (Z3) in the third layer (6) are both Rather than using a light-transmitting material or color so that the first image (1) can be visually recognized by only one layer under transmitted light, each common region (Z1, Z2, Z3) of the three layers Is appropriately set so that the first image (1) can be visually recognized under the transmitted light.

  The common region (Z) and the peripheral region (P) when the three layers are stacked will be described later after the configuration of each layer is described.

  Next, the second layer (5) will be described.

  FIG. 5A is a plan view showing the second layer (5). The second layer (5) consists of a common region (Z2) and a peripheral region (P2). The common region (Z2) of the second layer (5) has the same shape as the common region (Z1) of the first layer (4) and the common region (Z3) of the third layer (6) described later. is there.

  The second layer (5) is a material capable of thermocompression bonding with the first layer (4) described above, such as a resin such as vinyl chloride and polyethylene, highly synthetic paper, and the like, and can form a transmissive pattern. As long as there is no particular limitation, a base material made of a plastic material is preferable.

  A plastic material has a property of gradually softening when heated and melting after the degree of softening has progressed. Therefore, after laminating the first layer (4), the second layer (5), and the third layer (6), a part of the molten plastic material is a paper base material by thermocompression bonding. By solidifying after penetrating into the first layer (4), it becomes possible to make the layers more closely contacted.

  As the plastic material, a known resin such as PET (polyethylene terephthalate) or PET-G (polyethylene tetraphthalate-grained ethylene glycol) can be used.

  In addition, when using the material which is not softened by heating, such as a paper base material and a biaxially stretched PET sheet, the second layer (5) and the other layers (4, 6) are adhered to the second layer (5). Therefore, it is necessary to apply in advance an adhesive that is fused by heat to the entire surface and back surface of the second layer (5).

  The second layer (5) includes an IC chip (2) capable of exchanging information with the outside in a non-contact manner in the peripheral area (P2), and an antenna (3) communicating in a non-contact manner with the IC chip (2). ). The IC chip (2) and the antenna (3) receive the radio wave transmitted from the IC reader provided at the place where the owner of the information recording medium (S) and the authenticity are confirmed, by the antenna (3), By transmitting a response radio wave from the antenna (3), the IC reader receives it and can read information stored in the memory of the IC chip (2) and write information.

  FIGS. 5B and 5C are cross-sectional views taken along line A-A ′ in FIG. If the IC chip (2) and the antenna (3) are in contact with the plastic material constituting the second layer (5), they constitute the second layer (5) as shown in FIG. There are no particular limitations on the structure buried in the plastic material or the structure disposed on the plastic material constituting the second layer (5) as shown in FIG. 5 (c).

  The color of the common region (Z2) in the second layer (5) is not particularly limited as long as it is a color that allows the first image (1) to be visually recognized under transmitted light, but the first image (1) ) To be visible as a transmissive pattern from the front and back surfaces of the information recording medium (S). The permeability of the common region (Z2) in the second layer (5) is equivalent to the permeability of the common region (Z1) in the first layer (4) described above.

  The color of the peripheral region (P2) in the second layer (5) is not particularly limited. Also in the second layer (5), the common region (Z2) and the peripheral region (P2) may be made of different materials as in the first layer (4) described above.

  Next, the third layer (6) will be described.

  FIG. 6 is a plan view showing the third layer (6). The third layer (6) is a layer provided for imparting durability to the information recording medium (S), and includes a common region (Z3) and a peripheral region (P3).

  The third layer (6) is not particularly limited as long as it is a material that can be thermocompression-bonded with the second layer (5) described above, such as a resin such as vinyl chloride and polyethylene, or highly synthetic paper, but plastic. A substrate made of a material is preferred.

  As described above, since the information recording medium (S) of the present invention is a card that requires individual identification such as a driver's license and an employee ID card, it is used and carried over a long period of time. Communication with the processing device needs to be performed in a non-contact manner.

  Therefore, the third layer (6) is not a paper base material but a plastic material that is superior in durability to the paper base material in order to impart durability such as water resistance, bending resistance and chemical resistance. Is preferable.

  In addition, about the plastic material which comprises a 3rd layer (6), since it is the same as that of the 2nd layer (5) mentioned above, description is abbreviate | omitted.

  The common region (Z3) in the third layer (6) is not particularly limited as long as it is a color that allows the first image (1) to be visually recognized under transmitted light, but the first image (1) In order to be visible as a transmissive pattern from the front and back surfaces of the information recording medium (S). The permeability of the common region (Z3) in the third layer (6) is equivalent to the transmittance of the common region (Z1) in the first layer (4) described above.

  The color of the peripheral region (P3) in the third layer (6) is not particularly limited.

  In the third layer (6), as in the first layer (4) and the second layer (5) described above, the common region (Z3) and the peripheral region (P3) are made of different materials. It is good also as a structure.

  As described above, when the information recording medium (S) of the present invention is disassembled by a person who intends to forge the IC chip (2) and the antenna (3) attached to the information recording medium (S). Since the first image (1) formed on the first layer (4) adhered to the second layer (5) is destroyed by peeling, it cannot be restored and a counterfeit product is produced. It becomes difficult to do. Furthermore, it is possible to determine the authenticity of the information recording medium (S) by simple visual determination of whether or not the transmission pattern is destroyed under transmitted light.

  Next, the visual recognition state of the information recording medium (S) will be described.

  FIG. 7A is a schematic diagram when the information recording medium (S) is observed under reflected light. Under the reflected light, the first image (1) is the same color as the common area (Z) and cannot be visually recognized by the naked eye.

  FIG. 7B is a schematic diagram when the information recording medium (S) is observed under transmitted light. Under the transmitted light, the first image (1) which is a transmissive pattern is visible with the naked eye. In addition, since the common region (Z) is transmissive, the first image (1) even when observed from either the first layer (4) side or the third layer (6) side. Can be visually recognized as a transparent pattern.

  As described above, when the information recording medium (S) is observed under reflected light, the first image (1) is not visually recognized by the naked eye. However, when observed under transmitted light, the first image (1) is observed from both the front and back surfaces. The image (1) becomes visible. Therefore, when authenticating the information recording medium (S), it is possible to perform simple identification without using a tool under transmitted light in addition to identification by machine reading using a conventional IC reader. .

  As shown in FIG. 8, the anti-counterfeit medium (S) of the present invention has an anti-counterfeit medium on at least one of the first layer (4) and the third layer (6) as the front and back surfaces. You may further give the printing part (7), such as personal information regarding the holder of (S), a background pattern, a minute character, and a pattern. When the printing unit (7) is provided on the first image (1) in the first layer (4), the first image (1) is concealed by being placed under reflected light.

  Moreover, it is preferable that the peripheral region (P) in the anti-counterfeit medium (S) of the present invention has a color that conceals the IC chip (2) and the antenna (3) under reflected light other than colorless and transparent. Since the IC chip (2) and the antenna (3) become invisible under reflected light, the configuration of the type, model number, etc. of the IC chip (2) and the antenna (3) becomes the information recording medium (S). It cannot be known without disassembling. Therefore, forgery using the IC chip (2) and the antenna (3) having the same configuration can be prevented.

  Note that the peripheral region (P) of each layer (4, 5, 6) is covered with the IC chip (2) and the antenna (3) under reflected light in order to conceal the IC chip (2) and the antenna (3). A material having an opacity of 90% or more, such as titanium white or carbon black, which is not visually recognized, is appropriately selected. For the measurement of opacity in the present invention, an ISO whiteness-compatible high-speed spectrophotometer manufactured by Murakami Color Research Laboratory is used.

  Further, as shown in FIG. 9B, the third layer (6) adjacent to the location where the IC chip (2) and the antenna (3) are arranged in the second layer (5) is made thicker. Thus, the peripheral region (P) having the IC chip (2) and the antenna (3) may be concealed.

  Next, a modification of the information recording medium (S) will be described.

  FIG. 10 is a schematic diagram showing a modification of the information recording medium (S). The information recording medium (S) described above has a configuration in which an image applied to one layer is visible as a transmissive pattern among the layer configurations having a multilayer configuration. It is assumed that the composite pattern (10) composed of a plurality of images assigned to is visible as a transmissive pattern. Hereinafter, modified examples will be described.

  The information recording medium (S ′) shown in FIG. 10A has a synthetic pattern (10) that is visible under transmitted light. The information recording medium (S ′) includes a first layer (4) shown in FIG. 10 (b), a second layer (5) shown in FIG. 10 (c), and a third layer shown in FIG. 10 (d). (6) are sequentially laminated. In addition, about the laminated structure of each layer, since it is the same as that of the laminated structure demonstrated using FIG. 2, description is abbreviate | omitted.

  The common area (Z1) of the first layer (4) shown in FIG. 10 (b) is a transmissive pattern and has a first image (1) showing the shape of three petals, and FIG. The common area (Z2) of the second layer (5) shown in FIG. 10 is a transparent pattern, has a 2a image (9a) showing the shape of a single petal, and is shown in FIG. The common area (Z3) of the third layer (6) is a transmissive pattern and has a 2b image (9b) showing the shape of one petal.

  When the images formed on the second layer (5) and the third layer (6) are described separately, the transmission pattern formed on the second layer (5) is referred to as “2a When the image (9a) ”is described and the transparent pattern formed on the third layer (6) is described as“ the second image (9b) ”and the two images are described together, the“ second image ” Image (9) ".

  In the modified example, in addition to the first layer (4), a transmissive pattern is formed on the common region (Z2) in the second layer (5) and the common region (Z3) in at least one layer in the third layer (6). Has a second image (9). Further, the composite pattern (10) includes a first image (1) and a second image (9). For example, in FIG. 10, the first image (1) and the second image (9) form a composite pattern (10) indicating the shape of five petals.

  As a result, when the layers (4, 5, 6) are laminated to form the information recording medium (S ′), the information recording medium (S) described above is reflected under reflected light as shown in FIG. As in FIG. 11B, the composite pattern (10) of the first image (1) and the second image (9) is a transparent pattern as shown in FIG. Can be visually recognized.

  The synthetic pattern (10) is visually recognized as one flower composed of five petals with the naked eye, but is actually a pattern composed of three images formed in different layers. Therefore, when the information recording medium (S ′) is to be tampered with by peeling, the composite pattern (10) is destroyed more complicated than the case where the synthetic pattern (10) is formed in one layer, and the first layer each layer has. Since it becomes difficult to specify the shapes of the image (1) and the second image (9), the forgery prevention effect is improved.

  The material and method for forming the second image (9) that is a transmissive pattern are the same as those of the first image (1) described above, and thus the description thereof is omitted.

  In the modified example, the second layer (5) and the third layer (6) both have the second image (9), but may be configured to have one of them.

  The information recording media (S, S ′) shown in FIGS. 1 to 11 can be used by being incorporated into a booklet that requires identification, such as a passport or a passbook.

  FIG. 12A is a schematic diagram showing the use of the information recording medium (S, S ′) for the booklet (M). In FIG. 12, a booklet (M) used as a passport will be described below.

  The booklet (M) has a content sheet (11) composed of a plurality of pages that can be written or stamped, and an information recording medium (S, S ') is incorporated into the booklet (M). As an assembling method, for example, the information recording medium (S, S ′) is attached to the inside of the cover (12), or it is bound using a binding thread. Further, as shown in FIG. 12A, a configuration may be adopted in which one page (11T) located at the top of the content sheet (11) is attached to the cover (12).

  Even when used as a booklet (M), as shown in FIG. 12 (a), from the viewpoints (E1, E2) of the first layer (4) side and the third layer (6) side, It is possible to visually recognize the first image (1) under transmitted light.

  When the information recording medium (S, S ′) is bound in the booklet (M), the second layer (5) is composed of the first layer (4) and the third layer as shown in FIG. It is preferable that it is smaller than the layer (6). Since the second layer (5) has the IC chip (2) and the antenna (3), the second layer (5) is thicker than the first layer (4) and the third layer (6), and is in the booklet (M). It is difficult to bind with a binding thread

  Therefore, the second layer (5) is sandwiched between the first layer (4) and the third layer (6), and the long sides of the first layer (4) and the third layer (6). It becomes easy by binding the binding portion (L) into the booklet (M).

  As shown in FIG. 13, the information recording medium (S, S ′) is previously bound with a binding portion (L) of the first layer (4) and the third layer (6) in a booklet (M). After that, the second layer (5) may be sandwiched later to be bound into the booklet (M).

  The information recording medium (S, S ′) may be approximately the same size as the booklet (M) or not the same size as the booklet (M), but the booklet ( When M) is folded and used, the smaller one than the booklet (M) is preferable. When the information recording medium (S, S ′) is made smaller than the booklet (M), the side surface is added to the front and back surfaces of the information recording medium (S, S ′) by the cover (12) when folded in half. Can also be protected.

DESCRIPTION OF SYMBOLS 1 1st image 2 IC chip 3 Antenna 4 1st layer 5 2nd layer 6 3rd layer 7 Printing part 8 Concealment layer 9 2nd image 9a 2a image 9b 2b image
10 Composite pattern 11, 11T Contents sheet 12 Cover Z, Z1, Z2, Z3 Common area P, P1, P2, P3 Peripheral area S, S 'Information recording medium M with non-contact type IC Booklet

Claims (4)

A first layer that is a paper substrate, a second layer that is a plastic substrate, and a third layer are sequentially laminated with a common region having light transmittance at the same position of each layer,
The first layer has a first image that is a transmissive pattern in the common area;
The information recording medium with a non-contact type IC, wherein the second layer has an IC chip and an antenna around the common area. The second pattern and / or the third layer has a second image that is a transmissive pattern in the common area, and a composite pattern is formed by the first image and the second image. The information recording medium with a non-contact IC according to claim 1. 3. The information recording medium with a non-contact type IC according to claim 1, wherein the periphery of the common area has a predetermined opacity to conceal the IC chip and the antenna. Use of the information recording medium with a non-contact IC according to any one of claims 1 to 3 for a booklet.

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