JP2007253569A - Information-carrying card - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an information-carrying card with such advantages that a pattern etc. printed using a fluorescent material for an anti-forgery purpose can hardly be read by a third party, the diversion of a material to a forged card from a genuine card is difficult and it is possible to read the printed pattern from either one side or the opposite side of, the card, where the fluorescent material is irradiated with an exciting light. <P>SOLUTION: This information-carrying card is structured as follows: a fluorescent part 3 formed of the fluorescent material excited by the exciting light of an infrared range to emit a fluorescence of an infrared region is installed inside a card base 2 formed of the exciting light and fluorescence-permeable material. In addition, the fluorescent part 3 is covered with concealing layers 21 and 22 which permit permeation of the exciting light and the fluorescence but permits no permeation of a visible light or permits permeation of the exciting light and the fluorescence but to the very limited level. Consequently, the fluorescent part 3 inside the card base 2 can be read by a dedicated reader, although the fluorescent part 3 cannot be visually recognized. Besides, it is difficult to collect the fluorescent material making up the fluorescent part 3. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a technique for preventing forgery of various cards such as a credit card, a cash card, a prepaid card, an ID card, for example, an information carrying card into which data such as personal information is written.

  Conventionally, various techniques have been proposed to prevent forgery and alteration of this type of card. For example, Patent Document 1 proposes a card in which at least one surface of a card body is coated with a pattern for identifying the card with a phosphor that emits and visualizes light when irradiated with light of a specific wavelength. According to this, even if the magnetically or electrically recorded data is copied to the card, it is not determined to be an effective card unless the phosphor emission pattern is confirmed. Compared to information carrying cards, it is difficult to forge the cards.

  Further, in Patent Document 2, a substrate and a predetermined infrared phosphor (a so-called infrared excitation / infrared light emission type that outputs a second infrared ray by being excited by an incident first infrared ray on the surface of the substrate). A laminated structure comprising an information layer formed using a phosphor, a protective sheet (upper protective body) laminated on the front surface side, and a protective sheet (lower protective body) laminated on the back surface side of the substrate A card has been proposed. According to this, since the board | substrate with which the information layer was formed is concealed by the upper and lower protectors which pinch | interpose this, the third party cannot see the information layer of this card | curd. In addition, for example, in a card in which an encryption code is recorded using a special paint having the property of absorbing infrared rays, the black code is written in the same manner as when the special paint is used by writing a portion of the encryption code with black ink instead of the special paint. As a result of the absorption of infrared rays by the ink portion, the card is read as a legitimate card. However, according to the card described in Patent Document 2, even if the information layer is formed using black ink, the first infrared ray is irradiated. In this case, since the second infrared ray is not output from the black ink, it is determined that the card using such black ink is not a genuine card. Therefore, it is possible to prevent forgery of the card by printing and recording the encryption code portion using black ink instead of the original special paint.

JP 2002-19345 A JP 2003-191670 A

  However, in the card described in Patent Document 1, since the fluorescent material to be used emits light and is visualized by irradiation with light of a specific wavelength, it is easy to know in which part and in what pattern the fluorescent material exists. Further, since the fluorescent material is applied to at least one surface of the card body, the fluorescent material is collected from the true card, and a forged card may be manufactured using the collected fluorescent material.

  In this regard, in the card described in Patent Document 2, the information layer formed using a predetermined fluorescent material on the surface of the substrate is laminated with a protective layer so that the appearance is not visible. You cannot know the existence of. However, since the protective layer in this card has a structure bonded with an adhesive, only the protective layer on the surface layer can be separated by using various solvents. Therefore, in this case, as long as the protective layer on the surface layer is separated, it is relatively easy to produce a counterfeit card by collecting a fluorescent material, reading its printed pattern, and the like. In addition, in the card described in Patent Document 2, depending on whether the card surface on which the excitation light for the fluorescent material is irradiated and the card surface from which the light is read are the same surface or the opposite surface, the card substrate is infrared transmission type or infrared. It is necessary to change to the reflective type, which is inconvenient.

  The present invention has been made in view of such circumstances, and it is difficult for a third party to read a printing pattern or the like of a fluorescent material imparted to prevent counterfeiting, and material transfer from a true card to a counterfeit card is possible. An object of the present invention is to provide an information-carrying card that is difficult and can be read from both the same surface and the opposite surface of the card surface irradiated with excitation light to the fluorescent material.

  In order to achieve the above object, the information carrying card of the present invention comprises a fluorescent part formed by using a fluorescent material that emits fluorescence in the infrared region when excited by the excitation light in the infrared region. The fluorescent portion is provided with a concealing layer made of a material that is provided inside a card base made of a material that transmits light and transmits the excitation light and fluorescence but does not transmit visible light or transmits light even though it transmits light. By covering, the fluorescent part is made invisible or difficult to see on the appearance.

  In the present invention, in order to provide the fluorescent portion inside the card substrate, the card substrate is formed by, for example, laminating and bonding at least two base layers for forming the card substrate, and at least one of them is formed. It is possible to adopt means such as forming the fluorescent part in advance on the bonding surfaces of the two base material layers by printing or the like.

  The concealing layer that conceals the fluorescent part can be formed of the card substrate itself. In this case, the card base material is formed of a material that transmits the excitation light and fluorescence of the fluorescent material to be used but does not transmit visible light or transmits the visible light even if it is transmitted. If a fluorescent part is provided inside such a card base, the card base does not transmit visible light or the amount of transmission is very small even if it is transmitted, so that the fluorescent part inside the card base is concealed. In terms of appearance, the fluorescent part can be made invisible or difficult to see.

  The concealing layer can be composed of at least two layers: a first concealing layer that conceals the front side of the fluorescent part and a second concealing layer that conceals the back side of the fluorescent part. And among these, the 1st concealment layer is a base material layer (base material layer constituting the surface side of the card base material) in the card base material, printing formed by printing or coating on the surface side of the card base material It can be set as the structure which consists of at least one layer of the thin film sheet-like laminate layer laminated | stacked on the surface side of the layer or the coating layer and the card | curd base material. Moreover, also about a 2nd concealment layer, the printing layer formed by printing or application | coating to the base material layer (base material layer which comprises the back surface side of a card base material) in a card base material, or the back surface side of a card base material, or It can be set as the structure which consists of an application layer and at least one layer of the thin film sheet-like laminate layers laminated | stacked on the back surface side of the card | curd base material. When the concealing layer is composed of the printed layer (coating layer) or laminate layer instead of the card base material, the card base material transmits the excitation light and fluorescence of the fluorescent material used in the fluorescent part. What is necessary is not limited as long as it is transparent to visible light. That is, the card substrate in this case may be formed of a transparent or translucent material that transmits visible light, or an opaque material that does not transmit visible light or a visible light transmission to improve concealability. It may be formed of a material that is very opaque and has a very small amount.

  The fluorescent part may be formed of one type of fluorescent material in consideration of material cost, etc., but in order to further increase the difficulty of counterfeiting, the wavelength of at least one of the excitation light and the fluorescent light is different from each other It can also be formed by printing or the like so as to form a relatively complicated pattern using two or more kinds of fluorescent materials.

  In the information carrying card of the present invention, as a material for forming the fluorescent portion, a fluorescent material that emits fluorescence in the infrared region when excited by excitation light in the infrared region (so-called infrared excitation / infrared emission type fluorescent material) ) Is generally used because infrared rays have good light transmission properties for the materials used in this type of card, so that when the excitation light is irradiated, the light easily reaches the fluorescent material, and the fluorescence is excited by the excitation. This is because the fluorescence emitted from the material is easy to detect.

  In the information-carrying card of the present invention, since the fluorescent part formed using a predetermined fluorescent material is provided inside the card base material, it is impossible or extremely difficult to collect or take out the fluorescent material. . Therefore, it is possible to prevent illegal acts such as illegally collecting the fluorescent material used for this from a genuine card and diverting the collected fluorescent material to another card to produce a counterfeit card. it can.

  Further, according to the information carrying card of the present invention, the fluorescent portion provided inside the card base material itself does not transmit visible light or the card base material itself as a concealing layer made of a material having a very small amount of transmission, Or since it is concealed by the concealing layer formed by the method of printing, application | coating, etc. on the surface and back surface of a card | curd base material, the presence and print pattern are not known from the outside visually. Moreover, since the fluorescent material used in the fluorescent part has wavelengths of excitation light and fluorescent light (emission) in the infrared region, it is impossible to confirm the light emission unless a special special reading device is used.

  Thus, according to the present invention, it is difficult for a third party to read a pattern due to printing of a fluorescent material imparted to prevent counterfeiting, and it is difficult to divert material from a true card to a counterfeit card. An information carrying card can be realized.

  In addition, in the information-carrying card of the present invention, the card substrate is made of a material that transmits excitation light to the fluorescent part provided inside the fluorescent part and fluorescence emitted from the fluorescent part at the time of excitation. The fluorescence (light emission) from the fluorescent portion can be read from both the same surface and the opposite surface of the card surface irradiated with the excitation light for the fluorescent portion.

  In the information-carrying card of the present invention, when the fluorescent part is printed and formed in a predetermined pattern using two or more fluorescent materials having different excitation light and / or fluorescence wavelengths, not only the presence or absence of the fluorescent material. Since it is possible to use the presence / absence of the predetermined pattern and the coincidence / non-coincidence of the pattern with a pattern registered in a reading device or the like for authenticity determination, an information carrying card with higher anti-counterfeiting is realized. it can. In that case, forgery prevention can be further enhanced by distinguishing the fluorescence having different wavelengths emitted from the respective fluorescent materials by the irradiation of the excitation light and making the authenticity determination.

  FIG. 1 is a cross-sectional view schematically showing one configuration example of the information carrying card of the present invention. As shown in the figure, this information carrying card 1 includes a card base 2, a fluorescent portion 3 provided inside the card base 2, and a printed layer 4 formed on the surface of the card base 2. The laminate layer 5 laminated on the printed layer 4 and the laminate layer 6 laminated on the back surface of the card base 2 are included. A magnetic layer 7 on which data is magnetically recorded is provided at a predetermined position on the laminate layer 5 on the front surface side. Further, an IC chip 8 on which data is electrically recorded is embedded on the surface side of the information carrying card 1.

  The fluorescent part 3 is formed using a fluorescent material that emits fluorescence in the infrared region when excited by excitation light in the infrared region. The card substrate 2 transmits the excitation light and the fluorescence of the fluorescent material but does not transmit the visible light or transmits the visible light. It is composed of material layers (sheets) 21 and 22 and is bonded (joined) to form a single card substrate 2. And when setting it as this one card | curd base material 2, as shown in FIG. 2, the said fluorescent material is put on the surface (joining surface) of the side used as the adhesion surface of one 1st base material layer 21. As shown in FIG. As shown in FIG. 1, the fluorescent part 3 is preliminarily printed and formed in a predetermined pattern, the other second base material layer 22 is overlaid and the base material layers 21 and 22 are adhered to each other. The card base 2 is provided with a fluorescent part 3. In this case, the method of bonding the base materials 21 and 22 is not particularly limited. However, when a plastic sheet as described later is used as a constituent material of the base materials 21 and 22, for example, 110 ° C. to 160 ° C. It is preferable to perform thermocompression bonding at a temperature of

  Here, as the fluorescent material used for the fluorescent part 3, for example, metal oxide, metal sulfide, phosphoric acid compound, aluminate compound, titanic acid compound, tungstic acid compound, molybdate compound and the like are used as a base material, and praseodymium is used. (Pr), neodymium (Nd), samarium (Sm), europium (Eu), terbium (Tb), dysprosium (Dy), holmium (Ho), erbium (Er), thulium (Tm), ytterbium (Yb), etc. Examples thereof include fluorescent materials doped with at least one rare earth element. At the time of printing, such a fluorescent material is dispersed in a resin or a binder made of a resin and a solvent to form a fluorescent paint or fluorescent ink, which is used to form the base material layer 21 described above by a technique such as offset printing or screen printing. A fluorescent portion having an arbitrary pattern can be formed on the surface.

  As described above, the first and second base layers 21 and 22, that is, the card base 2 transmit the excitation light and fluorescence of the fluorescent material but do not transmit visible light or transmit it. Although it is formed of a material having a very small amount of permeation, examples of such a material include a white amorphous copolyester sheet, a white polyvinyl chloride sheet, and a white polyethylene terephthalate sheet. Among them, it is preferable to use a white amorphous copolyester sheet. The thickness of each of the first and second base material layers 21 and 22 (the thickness of the sheet) is, for example, in the range of 0.2 to 0.6 mm in consideration of the rigidity and strength as a card, the concealing property described below, and the like. Is preferred. Since both base material layers 21 and 22 made of a white plastic sheet having such a thickness do not transmit visible light or transmit only a small amount of visible light, they are provided inside the card base 2. It serves as a concealing layer that conceals the fluorescent part 3 so that it cannot be seen from the outside.

  In the above example, since the card base 2 itself becomes a concealing layer for the fluorescent part 3, the concealing layer is formed on the front side and the back side of the card base 2 (that is, the first concealing layer on the front side and the back side). Even if the second concealing layer is not separately provided, the internal fluorescent part can be made invisible or difficult to see. For this reason, in the information carrier card 1 described above, the laminate layers 5 and 6 on the front side and the back side are formed of a transparent polyethylene terephthalate (PET) film having a thickness of about 0.05 mm. However, this type of laminate layer can be formed of a material that does not transmit visible light or has a very small amount of transmission, and can be used as a concealing layer for the fluorescent part 3, or a printed layer as the concealing layer can be used as a card. It is also possible to provide on both front and back sides of the substrate. In this case, it is not always necessary to form the card base material 2 with a material having a concealing property as described above, but if the card base material 1 is made of a material having a concealing property with respect to visible light, It goes without saying that the concealing effect on the fluorescent part 3 is further enhanced in combination with the concealing layers (first concealing layer and second concealing layer) on both the front and back sides.

  Various patterns of the fluorescent part 3 can be considered. It may be a pattern consisting only of simple figures, or may be a pattern in which a plurality of relatively simple figures are combined as shown in FIG. In the case of the pattern shape as shown in the figure, it is also possible to identify each portion (one figure) constituting the pattern. As an identification method, for example, using a sensor constituted by an excitation light source such as a laser diode or LED, or a detector such as a photodiode, the detection waveform is read by card conveyance, or the infrared wavelength region has detection sensitivity. Examples include, but are not limited to, image recognition using a camera.

  Further, as shown in FIG. 3, the parts constituting the pattern of the fluorescent part 3 are divided into groups, and the excitation wavelength, emission wavelength, etc., for each of the pattern parts 31 and 32 (or each part constituting the pattern) of each group. By using fluorescent materials having different characteristics, each pattern portion is printed simultaneously or sequentially on the surface of one base material layer 21 constituting the card base material 2, and a predetermined pattern as shown in FIG. Alternatively, the fluorescent part 3 may be formed and the second base material layer 22 may be adhered thereon. In this case, a light source capable of irradiating light corresponding to the excitation wavelength of each fluorescent material and a detection means capable of detecting light of the emission wavelength of each fluorescent material are required. The more complicated the card becomes, the harder it is to forge the card. In addition, about the fluorescent material from which characteristics, such as an excitation wavelength and a light emission wavelength, differ, it can select from the fluorescent materials as mentioned above suitably, and can be used.

<Production of fluorescent material (first fluorescent material)>
Composition (a)
· La ₂ O ₃ 100 parts by weight · Nd ₂ O ₃ 44 parts · NaH ₂ PO ₄ 237 parts by weight

After the above composition (a) was sufficiently mixed in a mortar, it was transferred to an alumina crucible and heated and baked in the atmosphere at 800 ° C. for 3 hours. After this calcination, it was washed with water to remove excess components. Thereafter, drying, fluorescent material having an average particle size of about 2μm (LaPO _4: Nd) was obtained.

<Ink from fluorescent materials>
The fluorescent material (LaPO ₄ : Nd) obtained above, vinyl resin (“VAGF” manufactured by Dow Chemical Co., Ltd.) and cyclohexanone were mixed at the following ratio, and then dispersed by a bead mill to obtain a fluorescent material ink. .

Fluorescent material (LaPO ₄ : Nd) 100 parts by weight Vinyl resin (“VAGF” manufactured by Dow Chemical Co.) 16 parts by weight Cyclohexanone 77 parts by weight

<Carding>
A white non-crystalline copolyester sheet ("Diafix" manufactured by Mitsubishi Plastics, Inc.) having a thickness of 0.35 mm is used as the first base layer constituting the card base. Using the fluorescent material ink, a pattern composed of a single simple figure such as a rectangle located at the central portion of the fluorescent portion 3 shown in FIG. 2 was formed by screen printing. FIG. 4 is a spectrum showing the light transmission characteristics of the white amorphous copolyester sheet used. As can be seen from the figure, the amorphous copolyester sheet used as the card base material hardly transmits light in the visible region (approximately 400 to 700 wavelengths).

  On the printing surface of the printed sheet, a white non-crystalline copolyester sheet having a thickness of 0.35 mm similar to the above is superimposed as the second base material layer 22 constituting the card base 1 and thermocompression bonded at 145 ° C. did. Further, the thermocompression-bonded sheet was punched into a card shape to obtain an information carrying card.

  When the obtained information carrying card was visually observed, the fluorescent part inside the card could not be visually recognized. Further, an LED that emits light having a wavelength that matches the excitation wavelength of the fluorescent material forming the fluorescent part of the card is used as a light source, and light from this light source is irradiated from the front side of the card to obtain a spectroscope (Japan). When the state of light emission from the fluorescent part inside the card was observed via “CT-50C” manufactured by Spectroscopic Co., Ltd., light emission by Nd was confirmed. FIG. 5 shows a spectrum of light emission (fluorescence) from the fluorescent part measured using the spectroscope.

  The information-carrying card produced in this example has a predetermined pattern of fluorescence between two white amorphous copolyester sheets (the first and second base material layers 21 and 22 constituting the card base material 2). Although it is a thing of the simple structure which only formed the part 3 by printing, in providing as a card product actually used, it showed in FIG. 1 on the surface and back surface of the said card | curd according to the use. Needless to say, the print layer 4, the laminate layers 5 and 6, the magnetic layer 7, the IC chip 8, and the like are provided as necessary. This also applies to the following embodiments.

  In <Carding> of Example 1, as the second base material layer 22 constituting the card base material 1, a transparent amorphous copolyester sheet having a thickness of 0.2 mm ("Diafix" manufactured by Mitsubishi Plastics, Inc.) These were stacked and thermocompression bonded at 145 ° C. Further, after a white UV curable resin is printed on the entire surface of the base material layer 22 to form a first printing layer, an image is further offset printed on the first printing layer to perform the second printing. A layer was formed, and the surface side of the fluorescent part was concealed by these first and second printed layers. Note that the back side of the fluorescent part is concealed by the first base material layer (white amorphous copolyester sheet) 21 as in the case of Example 1. This sheet was punched into a card shape to obtain an information carrying card.

  When the obtained information carrying card was visually observed, the fluorescent part inside the card could not be visually recognized. Further, an LED that emits light having a wavelength that matches the excitation wavelength of the fluorescent material forming the fluorescent part of the card is used as a light source, and light from this light source is irradiated from the front side of the card to obtain a spectroscope (Japan). When the state of light emission from the fluorescent part inside the card was observed through “CT-50C” manufactured by Spectroscopic Co., Ltd., light emission by Nd as in Example 1 was confirmed.

  With the printed pattern shown in FIG. 2, the information carrying card was produced in the same manner as in Example 1 for the other production methods. When the obtained information carrying card was visually observed, the fluorescent part inside the card could not be visually recognized. In addition, the fluorescent material is excited by irradiating light of a wavelength that matches the excitation wavelength of the fluorescent material forming the fluorescent part from the surface of the card (the light source is an LED), and the excitation wavelength of the fluorescent material is transmitted. When the light was detected by a CCD through a cut filter that selectively transmits only light having a specific wavelength including the excitation wavelength, light emission of the pattern shape shown in FIG. 2 was confirmed.

<Fabrication of fluorescent material (second fluorescent material)>
Composition (b)
· La ₂ O ₃ 100 parts by weight · Nd ₂ O ₃ 49 parts · Yb ₂ O ₃ 13 parts · NaH ₂ PO ₄ 260 parts by weight

The composition (b) was thoroughly mixed in a mortar, transferred to an alumina crucible, and then heated and fired at 800 ° C. for 3 hours in the air. After this calcination, it was washed with water to remove excess components. Thereafter, drying, fluorescent material having an average particle size of about 2 [mu] m: yield (LaPO ₄ Nd, Yb) to.

Using the second fluorescent material (LaPO ₄ : Nd, Yb) obtained in this way and the first fluorescent material (LaPO ₄ : Nd) prepared in Example 1 above, as shown in FIG. A fluorescent portion 3 having a simple pattern was printed. In this case, as shown in the figure, the first fluorescent material was used for the specific pattern portion 31 constituting the fluorescent portion 3, and the second fluorescent material was used for the other specific pattern portion 32. Except for this point, an information carrying card was produced in the same manner as in Example 1.

  When the produced information carrying card was observed visually, the fluorescent part 3 inside the card could not be visually recognized. In addition, the surface of the card is irradiated with light having a wavelength that matches the excitation wavelength of the first fluorescent material and the second fluorescent material (the light source is an LED), and the excitation wavelength of the first fluorescent material and the excitation wavelength of the second fluorescent material are FIGS. 2 and 3 show detection by a CCD through a cut filter that selectively transmits only light having a specific wavelength corresponding to the emission wavelength of the first fluorescent material without transmitting any light. The light emission of the pattern shape was confirmed. Further, light having a wavelength matching the excitation wavelength of the second fluorescent material (light source is LED) is irradiated from the card surface, and the pattern portion 32 using the second fluorescent material among the pattern portions 31 and 32 constituting the fluorescent portion 3. As a result, the light emission by Yb was confirmed. In FIG. 6, the spectrum of the light emission by said Yb measured using the spectrometer ("CT-50C" by JASCO Corporation) is shown.

It is sectional drawing which shows typically the example of 1 structure of the information holding card | curd of this invention. It is a disassembled perspective view of the card | curd base material which shows the pattern shape of the fluorescence part which decomposed | disassembled the card | curd base material which comprises the said information carrying card and was provided in the inside. It is a disassembled perspective view of the card | curd base material in the other structural example of the information holding card | curd of this invention. It is a spectrum which shows the light transmission characteristic of the white amorphous copolyester sheet | seat used as a card | curd base material in Examples 1-4. It is a figure which shows the spectrum of the fluorescence (light emission by Nd) emitted from the fluorescent material of the said fluorescence part when predetermined | prescribed excitation light is irradiated to the fluorescence part of the information carrying card | curd which concerns on Example 1. FIG. It is a figure which shows the spectrum of the fluorescence (emission by Yb) emitted from the structural part which concerns on the 2nd fluorescence material of the said fluorescence part, when predetermined | prescribed excitation light is irradiated to the fluorescence part of the information carrier card which concerns on Example 4. FIG. .

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Information carrying card 2 Card base material 21 1st base material layer (hiding layer)
22 Second substrate layer (hiding layer)
3 Fluorescent part 31 The pattern part which comprises a fluorescent part (part using the 1st fluorescent material)
32 Pattern part constituting fluorescent part (part using second fluorescent material)

Claims (7)

  A fluorescent portion formed using a fluorescent material that emits fluorescence in the infrared region when excited by excitation light in the infrared region is provided inside a card substrate made of a material that transmits the excitation light and fluorescence. In addition, the excitation light and the fluorescence are transmitted, but the visible light is not transmitted, or the transmitted light is covered with a concealing layer made of a material having a very small amount of transmission, and is not visible or difficult to view. Information-bearing card.   The card substrate is formed by laminating and bonding at least two substrate layers, and the fluorescent portion is formed by printing on a bonding surface of at least one of the substrate layers. The information-carrying card described.   The card base material is formed of a material that transmits the excitation light and fluorescence but does not transmit visible light or transmits the visible light. The card base material itself constitutes a concealing layer. The information carrying card according to claim 1 or 2.   The concealing layer is composed of at least two layers: a first concealing layer for concealing the front side of the fluorescent part and a second concealing layer for concealing the back side of the fluorescent part. Information carrying card.   The first concealing layer is a base material layer in the card base material, a printed layer or application layer formed by printing or coating on the surface side of the card base material, and a thin film sheet-like laminate layer laminated on the surface side of the card base material. The information carrying card according to claim 4, comprising at least one layer.   The second concealing layer is a base layer in the card base, a printed layer or coating layer formed by printing or coating on the back side of the card base, and a thin film sheet-like laminate layer laminated on the back side of the card base The information carrying card according to claim 4 or 5, comprising at least one of the above.   The information carrier according to any one of claims 1 to 6, wherein the fluorescent part is printed and formed to have a predetermined pattern using two or more fluorescent materials having different excitation light and / or fluorescent wavelengths. card.

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