JP2000141960A - Card having security function - Google Patents

Abstract

PROBLEM TO BE SOLVED: To upgrade a cost performance and to prevent a forgery by constituting a solar cell of an electrode layer, a semiconductor layer and a transparent conductive layer, applying an electromotive force from the cell to a pattern, and enabling identification of a card by utilizing an infrared ray generated from the pattern. SOLUTION: When an incident light shines from a light incident window, a potential difference is generated between a transparent conductive film 5 and an electrode layer 3, a closed circuit is constituted of a conductor coating 1 for connecting the film 5 to the pattern 1 and a conductor coating 2 for connecting the layer 3 to the pattern 10, a current flows to the pattern 10 to generate a heat, thereby radiating an infrared ray. An identifying device for reading this heating pattern and identifying the heating pattern collates identification information registered with a data base with the heating pattern of the pattern 10, to identify the card and to unnecessitate a power supply function for conducting the pattern. Thus, its cost performance can be upgraded and a forgery can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a card requiring a security function, such as an ID card, a credit card, a cash card, a prepaid card, and the like.

[0002]

2. Description of the Related Art Currently, generally used ID cards and credit cards are provided with various security functions in order to prevent unauthorized use due to forgery or falsification. Elementary technologies for such security functions include watermarks, holograms, punches, ultrafine printing of characters and designs, magnetic recording, data writing to IC chips, etc. Security techniques such as forming a special pattern using fluorescent ink are used. Information used when collating an ID card, a credit card, or the like in a security system includes a password, a face photograph, a fingerprint, a palm, a handwriting, a stamp, a voice, an ear, an iris, a retina, and a DN.
A and the like, and fitting (like a lock and a key) are used.

[0003]

In particular, in a security system that uses some figure or shape for collation, the surface of the object to be subjected to the security function is coated with ultraviolet / infrared fluorescent ink or ITO (indium oxide (In ₂ O _4)). )
Is an oxide doped with tin oxide (SnO ₂ ), ATO
When a pattern is formed with a transparent conductive material such as (an oxide obtained by doping tin oxide (SnO ₂ ) with antimony (Sb)) or ZnO (zinc oxide), the pattern may be visible with visible light. In order to eliminate this, it is necessary to form a multilayer film in order to adjust the refractive index. Also, even when a security function is provided inside the card, if the pattern is made of copper, nickel chrome, aluminum, tin, or the like, such as a normal wiring, the internal pattern may be seen through when exposed to light (by applying transmitted light). Yes, poor security.

[0004] This is because, when a figure or shape to be used for collation is visible, the technology has been advanced enough to make a copy from the figure or shape, and it is difficult to prevent forgery. It is. Even a method using an ultraviolet / infrared fluorescent ink cannot make it completely invisible and can be forged. Therefore, when a coating or the like is applied to make it invisible, for example, if the method of irradiating infrared rays from the outside and utilizing its reflection or absorption, the infrared rays are absorbed or reflected before reaching the pattern, It becomes difficult to read the pattern with an infrared camera or the like. In order to improve this, there is a method of energizing the pattern and emitting infrared rays from the pattern. In this case, a power supply device for supplying power to the card is required on the card collation device side, and there is a problem that the card and the power supply terminal provided in the card collation device are worn due to repeated use. In any case, there is a problem in that providing such security requires a considerable cost.

[0005] The present invention has been made in view of the above points, and provides a card having a security function that makes it difficult to forge with high cost performance.

[0006]

According to the present invention, there is provided a card having a security function, comprising a plate-like or film-like electrode layer, a semiconductor layer formed on the upper surface of the electrode layer, and a semiconductor layer formed on the upper surface of the semiconductor layer. A transparent conductive layer using a transparent conductive material,
A card formed of one or more layers having a unique wiring shape formed in a position outside the three layers and in parallel with each layer using a transparent conductive material, wherein the electrode layer and A solar cell is constituted by the semiconductor layer and the transparent conductive layer, and the card can be identified using infrared rays emitted from the pattern by applying an electromotive force from the solar cell to the pattern. Features.

The card having a security function of the present invention uses a plate-like or film-like electrode layer, a semiconductor layer formed on the upper surface of the electrode layer, and a transparent conductive material formed on the upper surface of the semiconductor layer. A card comprising a transparent conductive layer and a pattern formed of a plurality of layers having a unique wiring shape formed at positions outside the three layers using a transparent conductive material and in parallel with each layer, Each layer of the pattern is made of a transparent conductive material having a different component, and the electrode layer, the semiconductor layer, and the transparent conductive layer constitute a solar cell, and the pattern is formed by applying an electromotive force from the solar cell to the pattern. The card is identifiable using infrared rays emitted from.

A card having a security function according to the present invention uses a plate-like or film-like electrode layer, a semiconductor layer formed on the upper surface of the electrode layer, and a transparent conductive material formed on the upper surface of the semiconductor layer. A transparent conductive layer, and a pattern formed of one or more layers having a unique wiring shape formed outside the three layers using a transparent conductive material and in parallel with each layer. A solar cell is constituted by the electrode layer, the semiconductor layer, and the transparent conductive layer, and the card is formed using infrared rays emitted from the pattern by applying an electromotive force from the solar cell to the pattern. Identifiable and IC
A chip is provided inside the card or on the surface of the card, and the solar cell is used as a power supply for the IC chip.

[0009]

Embodiments of the present invention will be described below with reference to the drawings. 1 to 5 are diagrams showing a configuration of a card having a security function according to an embodiment of the present invention.

A card having a security function according to the present embodiment (hereinafter referred to as a card) shown in FIG. 1 includes a substrate 1 (glass, plastic, paper, etc.), an insulating film 2 formed on the upper surface of the substrate 1, An electrode layer 3 formed on the upper surface of the insulating film 2, a semiconductor layer 4 formed on the upper surface of the electrode layer 3, a transparent conductive film 5 as a transparent conductive layer formed on the upper surface of the semiconductor layer 4, Light incident layer 6 formed on the upper surface of film 5
(Glass, plastic, alumina, etc.) and the light incident layer 6
4, a pattern 10 formed between the substrate 1 and the insulating film 2 (an example is shown in FIG. 4), conductor coatings 1.8 connecting the transparent conductive film 5 and the pattern 10, and an electrode layer. Conductor coating 2 connecting pattern 5 to pattern 10
9 Part of the light incident layer 6 is used as a light incident window through which light enters. As shown in FIG. 3, the outer surface of the light incident layer 6 excluding the light incident window is coated as an upper plate 7 with an opaque insulator from above. Note that the pattern 10 in FIG. 4 is simplified for explanation, and may form characters or designs (for example, the fingerprint shape in FIG. 5). The semiconductor layer 4 includes a P-type semiconductor layer and an N-type semiconductor layer,
It consists of amorphous silicon, single crystal silicon, and others. In addition, the conductor coatings 1, 8, 2 and 9 may be formed by printing or the like. In addition, IT as a transparent conductive material
Using O, ATO, ZnO, or the like, the pattern 10 is formed in a unique wiring shape (pattern) by sputtering, etching, printing, thermal transfer, coating, or the like.

In the card of the present embodiment, light from an external light source is made incident on a light entrance window, and light irregularly reflected inside is transmitted through a transparent conductive film 5.
The principle of a solar cell that generates a potential difference by being incident on the semiconductor layer 4 between the electrode layer 3 and the semiconductor layer 4 is used. The unique wiring shape (pattern) and other physical properties of the pattern 10 can be used to identify the pattern 10 or a card including the pattern 10. In this embodiment,
Infrared rays radiated from the pattern 10 depending on the wiring shape of the pattern 10 are used as identification targets. In the drawings referred to for the description, common portions are denoted by common reference numerals.

Next, a method of acquiring security information included in the card having the security function of the embodiment configured as described above will be described with reference to FIG.

Light is incident from a light entrance window, and a transparent conductive film 5 is formed.
When a potential difference occurs between the electrode and the electrode layer 3, the conductor coatings 1.8 connecting the transparent conductive film 5 of the card and the pattern 10 are formed.
And the conductor coatings 2 and 9 connecting the electrode layer 3 and the pattern 10 form a closed circuit, and a current flows through the pattern 10. Then, the pattern 10 generates heat and emits infrared rays. Therefore, the heat generation pattern can be read by an external CCD camera (having sensitivity in the infrared region). An identification device (not shown) separately provided outside for identifying the heat generation pattern of the pattern 10 includes identification information registered in a database (not shown) and the pattern 1
The card can be identified by collating with the heat generation pattern of 0. The identification information registered in the database includes a code for identifying each card,
The information includes at least information on the pattern shape set in each card (for example, image data on the pattern shape).

In the above embodiment, the pattern 10 may be formed so as to form a plurality of layers. By doing so, a more complicated pattern shape for identification can be formed, and forgery becomes difficult.

In addition, the pattern 10 may be formed in a plurality of layers, and the composition of the material may be different for each layer. For example, ITO, A
For example, the tin content of a transparent conductive material made of TO, ZnO, or the like may be changed for each layer. In this case, since the resistance value differs for each layer, the heat generation pattern of the pattern 10 becomes complicated, and furthermore, the forgery becomes difficult.

In another embodiment, when a card is required to have multiple functions, a predetermined IC chip (not shown) is arranged on the card shown in FIG. 1 inside or on the surface of the card. Further, the transparent conductive film 5 is set so that the polarities are matched to the power supply terminal and the GND terminal of the IC chip.
And an electrode layer 3 and a terminal (not shown) connected to an input / output signal line of the IC chip for inputting / outputting a signal to / from an external device (not shown). In the present embodiment, power can be supplied to the IC chip by entering light from the light incident window. The built-in IC chip can input and output various data, and the card can be used for multiple functions.

[0017]

As described in detail above, claim 1 is as follows.
According to the invention of the present invention, infrared rays emitted by energizing the pattern using solar cells structurally incorporated in the card can be captured and identified by an infrared sensor such as an infrared camera from the outside, so that the card can be collated. A power supply function for supplying power to the pattern is not required on the identification device side for identification, so that cost performance is good. Further, by forming the pattern provided on the card so as to form a plurality of layers, forgery becomes more difficult.

According to the second aspect of the present invention, the pattern provided on the card is formed so as to form a plurality of layers.
Since the components of the transparent conductive material are different for each layer,
Furthermore, forgery becomes difficult.

According to the third aspect of the present invention, since the IC chip is incorporated in the card, the card can be used for multiple functions and the IC chip can be driven by using the solar cell incorporated in the card as a power supply. So no external power supply is needed.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a configuration of a card according to an embodiment.

FIG. 2 is a diagram showing a structure of a card viewed from an A direction.

FIG. 3 is a diagram showing a structure of a light incident portion.

FIG. 4 is a diagram showing an example of a pattern shape.

FIG. 5 is a diagram showing another example (fingerprint pattern) of a pattern shape.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... substrate, 2 ... insulating film, 3 ... electrode layer, 4 ... semiconductor layer (amorphous silicon), 5 ... transparent conductive film, 6 ... light incident layer, 7 ... upper plate, 8 ... conductor coating 1, 9 ... conductive Body coating 2, 10 ... pattern

Claims (3)

[Claims] 1. A plate-like or film-like electrode layer, a semiconductor layer formed on an upper surface of the electrode layer, a transparent conductive layer using a transparent conductive material formed on an upper surface of the semiconductor layer, and a transparent conductive layer. A card formed of a material and having a pattern formed of one or more layers having a unique wiring shape formed at positions outside of the three layers and parallel to each layer, wherein the electrode layer and the semiconductor A solar cell is constituted by a layer and the transparent conductive layer, and by using an infrared ray emitted from the pattern by applying an electromotive force from the solar cell to the pattern,
A card having a security function, wherein the card is identifiable. 2. A plate-like or film-like electrode layer, a semiconductor layer formed on an upper surface of the electrode layer, a transparent conductive layer using a transparent conductive material formed on an upper surface of the semiconductor layer, and a transparent conductive layer. And a pattern formed of a plurality of layers having a unique wiring shape formed at positions outside the three layers using materials and in parallel with the respective layers, wherein each layer of the pattern has a different component. The electrode layer, the semiconductor layer, and the transparent conductive layer constitute a solar cell, and use an infrared ray emitted from the pattern by applying an electromotive force from the solar cell to the pattern. ,
A card having a security function, wherein the card is identifiable. 3. A plate-shaped or film-shaped electrode layer, a semiconductor layer formed on an upper surface of the electrode layer, a transparent conductive layer using a transparent conductive material formed on an upper surface of the semiconductor layer, and a transparent conductive layer. A card formed of a material and having a pattern formed of one or more layers having a unique wiring shape formed at positions outside of the three layers and parallel to each layer, wherein the electrode layer and the semiconductor A solar cell is constituted by a layer and the transparent conductive layer, and by using an infrared ray emitted from the pattern by applying an electromotive force from the solar cell to the pattern,
A card having a security function, wherein the card is identifiable, and an IC chip is provided inside or on the surface of the card, and the solar cell is used as a power source of the IC chip.