JP3362260B2 - Hologram sheet and its authentication method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transfer sheet and a seal hologram sheet which are attached to cash cards, credit cards, prepaid cards, securities, passbooks, passports and the like to authenticate their authenticity. And its authentication method.

[0002]

2. Description of the Related Art Conventionally, relief holograms and the like have been attached to cash cards, credit cards, prepaid cards, securities, passbooks, passports, etc. to guarantee their authenticity and to give design qualities to cards and the like. Guarantee of the authenticity utilizes the difficulty of forgery of the hologram, and the authenticity of the card or the like to which the hologram is attached is confirmed by visual authentication.

[0003]

As described above, the function of the hologram used in the conventional cash card and the like is mainly to provide visual authentication and to add designability, and a skilled person Otherwise, strict verification is difficult, and it has no function at all regarding fraud prevention and authentication in an unmanned processing device such as a card. Furthermore, although the relief holograms and the like that have been used conventionally have the characteristic that they are difficult to forge, basically, only the same picture and information can be given, and variable information for individual identification (for example, serial number) is It is necessary to record in a magnetic recording section or a print recording section in an area different from the hologram, and there is a large restriction on the space above the card and the design.

Further, there has been a concept of recording information that can be authenticated by an optical sensor on a hologram of a card or the like,
There is a problem that some information is recorded by visual inspection, and there is a risk of inducing forgery and alteration, and a design of a card or the like is impaired.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a hologram sheet which can be authenticated by a processing device such as an unmanned card and which is difficult to forge or alter, and an authentication method thereof. That is.

[0006]

A hologram sheet of the present invention which achieves the above-mentioned object is at least a printing portion including an infrared light absorbing portion and a reflecting portion, which substantially transmits infrared light and does not transmit visible light. The concealing layer and the Lippmann hologram layer that can be reproduced at a wavelength in the visible wavelength range are sequentially laminated.

In this case, the printing section consisting of the infrared light absorbing section and the reflecting section can be constituted by the infrared reflecting layer and the infrared ray absorbing ink printing located on the concealing layer side thereof, or the infrared absorbing layer. And an infrared light reflective ink print located on the concealing layer side.

Further, this hologram sheet can be formed into a transfer sheet by providing a peelable support on the side of the Lippmann hologram layer, or the peelable support is provided on the side of the printing section via an adhesive layer. It is also possible to form a seal.

Further, the hologram sheet authentication method of the present invention includes at least a printing portion including an infrared light absorbing portion and a reflecting portion, a concealing layer that substantially transmits infrared light and does not transmit visible light, and a visible wavelength range. In a method of authenticating a hologram sheet in which Lippmann-type hologram layers reproducible at the wavelength are sequentially laminated, infrared light is illuminated through the hologram layer and a masking layer, reflected by the printing unit, and again the masking layer. And detecting the light transmitted through the hologram layer by an infrared light detection device, and reading the pattern of symbols, characters, codes, etc. recorded in the printing section to identify the hologram sheet. Is the way to do it.

In this case, the hologram layer is illuminated with visible light of a predetermined wavelength, the pattern reproduced from the hologram layer is detected by a visible light detector, and the detection signal detected by the infrared light detector and the visible light detector are detected. It is also possible to identify the hologram sheet based on the detection signal detected by.

[0011]

According to the present invention, at least a printing portion including an infrared light absorbing portion and a reflecting portion, a concealing layer that substantially transmits infrared light and does not transmit visible light, and can be reproduced at a wavelength in the visible wavelength range. Since the Lippmann hologram layers are sequentially laminated,
From the appearance in the visible wavelength region, only the recorded information of the hologram layer can be seen, and the printed information below it cannot be seen. When irradiating infrared light to detect and identify the print information under the hologram layer by the infrared light detection device, the infrared light is not diffracted in the hologram layer and passes through the concealing layer to reach the printing unit. On the contrary, the light scattered therein surely passes through the concealing layer and the hologram layer, so that the hologram sheet can be surely identified by an unmanned processing device such as a card. Further, since the hologram layer and the printing section are laminated, the restriction of the design space on the adherend is greatly reduced, and the adherend having a high design property can be obtained. Also, if one tries to alter or falsify information on either of the laminated hologram layers or the printing section, the other information will be damaged and the history will be revealed.

[0012]

Embodiments of the hologram sheet and the authentication method thereof according to the present invention will be described below with reference to the drawings.
The Lippmann hologram is a transmittance distribution or a refractive index distribution with an interval d in the thickness direction of the optical recording material when object light is incident from one side of an optical recording material such as a silver halide photographic film and reference light is incident from the other side. The interference fringes of were recorded,
The interval d of the interference fringes is d = λ / (2n · sin θ / 2) ... (where λ is the wavelength, n is the refractive index of the optical recording material, and θ is the angle between the object light and the reference light). There is a relationship of 1). The thus-recorded Lippmann hologram has high wavelength selectivity, and when white light containing infrared rays is incident, only the light of wavelength λ is diffracted and the recorded information is reproduced. Light of other wavelengths is transmitted without being diffracted.

In the present invention, the Lippmann hologram as described above is used, and print information readable by infrared light is arranged below the hologram by a concealing layer which is transparent to infrared light. Only the information recorded on the highly reliable Lippmann hologram can be seen, and the authentication of the hologram is performed by reading the print information under the concealment layer with infrared light. Hereinafter, the present invention will be described based on examples.

FIG. 1 is a sectional view of an embodiment of a transfer sheet-shaped hologram sheet according to the present invention, in which a peelable support 1 is provided with a Lippmann hologram layer 2 reproducible at a visible wavelength λ ₁ , An infrared light transmitting visible light absorbing black masking layer 3 is provided thereon. Then, printing 4 with infrared light absorbing ink is performed on the side of the black masking layer 3 opposite to the hologram layer 2, the upper side thereof is covered with the infrared reflecting layer 5, and the adhesive layer 6 is provided thereon. As shown in FIG. 2, the hologram transfer sheet having such a structure is adhered to an adherend 7 such as a card with an adhesive layer 6 so that the peelable support 1 on the side opposite to the adhesive layer 6 is attached. When peeled off, only the information recorded on the Lippmann hologram layer 4 can be visually observed, and the information on the print 4 below the black concealing layer 3 cannot be seen.

Therefore, when infrared light of wavelength λ ₂ is irradiated from the hologram layer 2 side, it passes through the hologram layer 2 and the black masking layer 3 and reaches the print 4. The infrared light absorbed according to the information of the print 4 and reflected by the infrared reflective layer 5 passes through the black masking layer 3 and the hologram layer 2 and comes out. An optical sensor 8 that detects only light of wavelength λ ₂ is arranged, and variable information such as machine-readable barcodes, symbols, and characters is used as the print 4 information to print with an unmanned card or other processing device. By reading the information, it becomes possible to identify the adherend 7 such as a card.

In the case of FIG. 1, the printing 4 is performed with an infrared light absorbing ink, but it may be performed with an infrared light reflecting ink. In that case, an infrared absorption layer is used instead of the infrared reflection layer 5. Further, the hiding layer 3 does not necessarily have to be black, and may have other colors including white. However, when the reflectance of the visible wavelength λ ₁ reproduced from the Lippmann hologram layer 2 is high, the information reproduced from the hologram layer 2 becomes difficult to see, and when the information is used as authentication information as described later, It becomes difficult to read, and is not desirable. Furthermore, in the Lippmann hologram layer 2,
Not only one piece of information but a plurality of pieces of information may be recorded by wavelength division multiplexing.

In the above, only the print 4 information under the black concealing layer 3 is used for the authentication by the mechanical reading of the hologram, and the information of the hologram layer 2 is the visual authentication information, the other design,
Although it was supposed to be used as other information, the machine-readable authentication information is recorded in the hologram layer 2, and this information is read by another optical sensor 9 that detects only light of wavelength λ ₁ , By performing synchronization and collation with the information of the print 4 read in 9, it is possible to perform higher-level authentication. An example of the signal processing is shown in FIG. In this case, the same bar code pattern is used as the print pattern 4'of the print 4 and the hologram recording pattern 2'of the hologram layer 2. In this case, read signals obtained from both the optical sensors 8 and 9 are used. It is put in the AND circuit 10 so that the authentication signal is output only when the both match. Therefore, if either the hologram layer 2 or the print 4 is altered or tampered with, the authentication information can no longer be read and high-level authentication becomes possible.
Of course, in the above, the information recorded on the hologram layer 2 and the print 4 need not be the same, and the processing of the signals of both is not limited to the collation by the AND circuit as described above, and various known methods are available. Can be adopted.

By the way, in the Lippmann hologram, information can be additionally written by operating the interval of the interference fringes later. For details, refer to Japanese Patent Application No. Hei 4-
See 199481 (Invention title: "Holographic film and its manufacturing method"). As the additional record information, different information can be used for each card. Therefore, if this is used as the authentication information, the authenticity is further improved.

The above is the case where the hologram sheet of the present invention is formed in the form of a transfer sheet. However, as shown in FIG. 4, the peelable support 1 is provided on the side of the adhesive layer 6 opposite to the hologram layer 2. It may be provided to form a seal. In this case, the releasable support 1 is peeled off and attached to the adherend 7 with the adhesive layer 6 on the release side (FIG. 2).

The hologram sheet of the present invention and the authentication method thereof have been described above based on the embodiments, but the present invention is not limited to these embodiments and various modifications can be made.

[0021]

As is apparent from the above description, according to the hologram sheet and the authentication method thereof of the present invention, at least the printing portion including the infrared light absorbing portion and the reflecting portion, which substantially transmits infrared light. Since a concealing layer that does not transmit visible light and a Lippmann hologram layer that can be reproduced at wavelengths in the visible wavelength range are sequentially stacked, only the recorded information on the hologram layer is visible under the visible wavelength range, and it is below that. Print information is not visible. When irradiating infrared light and detecting and identifying the print information under the hologram layer by the infrared light detection device, the infrared light is not diffracted in the hologram layer and passes through the concealing layer to reach the printing unit. On the contrary, the light scattered therein surely passes through the concealing layer and the hologram layer, so that the hologram sheet can be surely identified by an unmanned processing device such as a card. Further, since the hologram layer and the printing section are laminated, the restriction on the design space on the adherend is greatly reduced, and the adherend having a high design property can be obtained. Also, if one tries to alter or falsify information on either of the laminated hologram layers or the printing section, the other information will be damaged and the history will be revealed.

It is also possible to detect information recorded on the hologram layer and print information at the same time, and perform higher-level authentication by performing signal processing such as synchronization of both detection signals and collation.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of an embodiment of a transfer sheet hologram sheet according to the present invention.

FIG. 2 is a diagram showing a state in which the hologram transfer sheet of FIG. 1 is attached to an adherend.

FIG. 3 is a diagram for explaining an example of signal processing for hologram sheet authentication according to the present invention.

FIG. 4 is a cross-sectional view of the hologram sheet of the present invention in a seal-like configuration.

[Explanation of symbols]

1 ... Peelable support 2 ... Lippmann hologram layer 3 ... Black hiding layer 4 ... Print 5 ... Infrared reflective layer 6 ... Adhesive layer 7 ... Adherend 8, 9 ... Optical sensor 2 '... Hologram recording pattern 4 '... printing pattern 10 ... AND circuit

Front page continuation (58) Fields surveyed (Int.Cl. ⁷ , DB name) G09F 3/00 G03H 1/02 B42D 15/02 B42D 15/10

Claims (7)

(57) [Claims] 1. A printing section comprising at least an infrared light absorbing section and a reflecting section, a concealing layer that substantially transmits infrared light and does not transmit visible light, and a Lippmann hologram layer that can be reproduced at a wavelength in the visible wavelength range. A hologram sheet formed by sequentially stacking. 2. The hologram according to claim 1, wherein the printing portion including the infrared light absorbing portion and the reflecting portion is formed by infrared light absorbing ink printing located on the infrared reflecting layer and the concealing layer side thereof. Sheet. 3. The hologram according to claim 1, wherein the printing portion including the infrared light absorbing portion and the reflecting portion is formed by infrared light reflecting ink printing located on the infrared absorbing layer and the concealing layer side thereof. Sheet. 4. The hologram sheet according to claim 1, wherein a peelable support is provided on the Lippmann hologram layer side to form a transfer sheet. 5. The hologram sheet according to any one of claims 1 to 3, wherein a peelable support is provided on the printing portion side via an adhesive layer to form a seal. 6. A printing section comprising at least an infrared light absorbing section and a reflecting section, a concealing layer that substantially transmits infrared light and does not transmit visible light, and a Lippmann hologram layer that can be reproduced at a wavelength in the visible wavelength range. In the method for authenticating a hologram sheet in which the layers are sequentially laminated, infrared light is illuminated through the hologram layer and the masking layer, reflected by the printing unit, and again transmitted through the masking layer and the hologram layer. A hologram sheet authentication method, characterized in that a hologram sheet is identified by detecting light with an infrared light detection device and reading a pattern of symbols, characters, codes, etc. recorded in the printing section. 7. The hologram layer is illuminated with visible light of a predetermined wavelength, a pattern reproduced from the hologram layer is detected by a visible light detection device, and the detection signal and the visible light detected by the infrared light detection device are detected. The hologram sheet authentication method according to claim 6, wherein the hologram sheet is identified based on a detection signal detected by the photodetector.