DE10165105B3 - smart card - Google Patents

Abstract

A method for producing a chip card with a chip card body (1), in which a conductor track (2) is integrated, wherein the conductor track (2) within the chip card body (1) at least partially a position coding (3), wherein the position coding (3) encrypted or unencrypted in an information carrier (4) of the chip card (5) is stored, wherein the arrangement of the conductor (2) in the chip card body (1) takes place in the manner of a bar code, wherein the position coding (3) of the conductor (2) during manufacture of the Chip card detected and stored in the information carrier (4) of the smart card (5).

Description

The invention relates to a chip card in whose chip card body ( 1 ) a conductor track ( 2 ) is integrated.

This formed as a coil or antenna trace ( 2 ) points within the chip card body ( 1 ) at least in sections a location coding ( 3 ) on. A layer coding according to the invention of the strip conductor is to be understood as a universal, card-specific laying of the strip as a whole or at least in a locally limited section which can be detected and makes the chip card a chip card with improved protection against counterfeiting.

The invention relates to a chip card according to the preamble of claim 1.

Smart cards, commonly referred to as data cards or often smart cards, are used for a wide variety of applications. In this case, passive chip cards, that is to say chip cards with a read memory (ROM, EPROM or similar memory), and also active chip cards in the form of a processor card which, for example, processes card-internal data, are known. The information transfer takes place in the previously known smart cards by touching contact corresponding contact surfaces on the smart card with associated readers or by contactless data transmission. Frequently, combinations of non-contact and contact-based systems are also used within a chip card.

EP 0 384 274 A2 describes a method of making a multi-layered ID card. In this case, several optical fibers are embedded in the identity card in order to customize optically scannable structures with information content card-specific.

From the DE 196 01 391 A1 already a chip card is known which has a chip card body, in which at least one conductor track is integrated. The trace represents a substantially planar-like structure and forms a coil or antenna. In the known smart cards, the conductor runs mostly within a plane. By a multiple circulation of the conductor track coil windings can be generated within this plane, so that a total spiral-shaped coil pattern is created. In this case, the track laying within the chip card body or on the chip card body can be made in any arrangement. The installation options are largely determined by the memory chip to be provided on the chip card or connections, switching elements or data carriers.

As chip cards begin to assert themselves more and more in cashless payment transactions, the loss of a chip card represents a particular risk.

To counter this, it is known to provide a PIN code that must be entered by the user of the chip card to a corresponding chip card reader. Although this PIN code brings a significant increase in security, but has the disadvantage that it is often forgotten. In addition, previously known smart cards are not absolutely forgery-proof.

The invention is based on the object of increasing the security against counterfeiting of a chip card.

The invention solves this problem with the features of claim 1. Further embodiments of the invention are the subject of the dependent claims.

A chip card according to the invention, which consists of a chip card body in which a conductor track is integrated, becomes a tamper-proof unique chip card, in which the conductor tracks within the chip card body at least in sections have a position coding. During the production of the chip card, the position coding of the conductor track is detected and stored in a smart card own information carrier. As information carrier, the microchip, a magnetic stripe, a barcode, optical storage, such as holographic storage or similar storage media can be used. Of course, a combination of these memories is possible.

In addition, it is advantageous if the position coding realized by the conductor track is determined by means of a suitable measuring transducer. This could be part of a chip card reader.

Furthermore, the arrangement of the printed conductors in the chip body can be carried out in the manner of a barcode. This is easy to read and requires only a slight change in the wall thickness of the conductors in a plane, which can also be done locally limited.

A position coding of the conductor track is to be understood as a universal, card-specific laying of the conductor track as a whole or at least in a locally limited section.

This feature of the invention makes it difficult or completely impossible to falsify such a chip card. This ensures an increase in chip card security.

A measured value acquisition and storage in the information carrier takes place according to the invention during the production of the chip card. Thus, the recorded and stored encrypted or unencrypted information can for example be stored as additional information on the smart card itself and read later in a corresponding smart card reader.

A distinction is made between absolute and relative measured values. An absolute measured value is a value that is measured and saved once. This can be, for example, the position or impedance of the coil. The stored value is measured by the user when using the chip card and compared with the stored measured value.

On the other hand, the detection of a relative measured value relates to the determination of two different values of one or two safety features, which may be, for example, the position of the antenna within the chip card, but at different locations and / or for example in the position detection of the coil or a hologram , These different values do not change or to the same extent, so that their measurement and the storage of the ratio of these measured values as a relative value on the chip card is possible. When the chip card is used by the user, the measured values are measured again, with a comparison of the stored relative values with the relative values determined from the measured values. The advantage here is that this process is independent of aging processes and also there is an increased security against counterfeiting. This alone or as a redundant safety precaution to other systems (eg PIN code) deployable solution of the invention is simple and inexpensive to produce and requires a significant increase in counterfeit security of such security devices equipped smart cards only a minor change in manufacturing.

The position coding of a chip card according to the invention can be determined by the course of the conductor track in the chip card body. This course accordingly has a pattern which is detected by means of a reading device. Thus, the position coding of a chip card according to the invention can be used as an additional security system, for example in cashless payment where, in addition to the usual coding via a PIN code, the reader detects the special location encoding, ie the course, the trace in the smart card body and, for example, a corresponding comparison with predefined Performs parameters.

According to a further proposal of the present invention, it is possible to arrange the conductor track of the chip card not only within a plane of the chip card. Rather, a spatial, so over several levels of the smart card, running arrangement is provided. This makes it possible to significantly increase the variety of variants for the position coding of the chip card according to the invention. Each change in the course of the track in the chip card body acts individualizing for the corresponding chip card. In this case, even small changes or deviations from chip card to chip card by the reader in a simple manner, so also from a technical point of view unproblematic to detect and implement. However, they have a decisive effect on the security options that have been achieved.

An inductive transducer can be used as the transducer for detecting the position coding of the printed conductor or it is likewise possible to detect the sought-after values by means of a light source in the transmitted light method.

An advantageous development of the invention is further to be seen in that the chip card is divided into grid squares. These grid squares each have a divergence in the position and in the arrangement of the conductor tracks.

Even by such an implementation of the solution according to the invention, it is possible to form a universal position coding of the chip card so that each chip card is unique.

The trace of a chip card according to the invention can be made of various electrically conductive materials, eg. As polymers, of metallic materials, eg. As copper, aluminum, electrically conductive pastes or a combination of different materials.

For laying the conductor track and thus for producing the coil or antenna screen printing method, windings, hot stamping, etching or other methods can be used. The conductor or web forming a coil or antenna is preferably applied to an electrically insulating layer plane, which may be, for example, a plastic film. Also known are insulating layers which can be applied as pastes or can be imprinted.

By a method according to the invention for the production of a chip card, a counterfeit-proof solution is provided which can be used individually or as a redundant system for further security measures of chip cards or smart cards and which, moreover, can be implemented inexpensively and simply.

A preferred embodiment of a chip card according to the invention will be explained in more detail with reference to the accompanying drawings.

Show it:

1 a top view of a first embodiment of a smart card,

2 a section through another chip card according to the invention and

3 a plan view of a third embodiment of a smart card.

The illustrated in the figures, with a total of 5 designated chip cards have an information carrier 4 on, which in the present case is a chip module with an integrated microchip. In electrically conductive connection with the information carrier 4 is a track 2 in the 1 in one level of the chip card 5 completely circumferential and designed as a conductor loop. The conductor track 2 in the 1 has been simplified four lanes shown. It is in one plane in the chip card body 1 integrated.

The integration of the conductor track 2 in the chip card body 1 takes place in a conventional manner by lamination or gluing the carrier plastic in the chip card body 1 or by introducing the antenna / coil into an injection card body. In the upper picture area the 1 has the trace 2 a location encoding 3 on. This consists in the present case of a pattern, which by the course of the conductor track 2 is formed. In the embodiment according to 1 These are formations of the track in the form of a digital sine curve, which are characterized by several successive, straight lobes. The interconnects are arranged at the same distance from each other.

The in the 2 shown sectional view of another chip card according to the invention 5 consists of a total of three superimposed individual layers 1.1 . 1.2 and 1.3 , which are permanently connected to each other, which can be done for example by a corresponding lamination of the individual layers. The topmost location 1.1 the in 2 shown chip card has a cavity 6 into which a chip module 4 is used as an information carrier.

The information carrier 4 has an electrically conductive connection to the conductor track 2 on. The conductor track 2 is in the illustrated chip card 5 over several levels 1.1 . 1.2 and 1.3 running arranged. It traverses these levels in a special, characteristic only for the illustrated chip card arrangement. In addition, a location encoding 3 at the lowest level 1.3 intended. This location encoding 3 consists in the embodiment shown in a wavy contour of the conductor track 2 , The in the individual levels 1.1 - 1.3 Laminated conductors can be made visible at one point or at several points by means of a strong light source in the transmitted light method (eg white spot light). This circumstance is useful to a value for the arrangement of the conductor within the chip card body 1 to determine or generate, after its identification permanently encrypted or unencrypted in the information carrier 4 the chip card is stored and thus can be checked by any suitable smart card reader. The chip card is thus universal and forgery-proof.

Applicable solutions of the invention for all types of smart cards with antennas / coils, such as contactless smart cards in the ID area, for dual-interface smart cards, for labels of any kind or for combination and hybrid cards, etc.

LIST OF REFERENCE NUMBERS

1

Smart card body

2

layer plane

3

layer plane

4

layer plane

5

conductor path

6

location coding

7

information carrier

8th

smart card

9

cavity

Claims (12)

Method for producing a chip card with a chip card body ( 1 ) into which a track ( 2 ) is integrated, wherein the conductor track ( 2 ) within the chip card body ( 1 ) at least in sections a location coding ( 3 ), wherein the position coding ( 3 ) encrypted or unencrypted in an information carrier ( 4 ) of the chip card ( 5 ), the arrangement of the track ( 2 ) in the chip card body ( 1 ) is carried out in the manner of a barcode, the position coding ( 3 ) the conductor track ( 2 ) recorded during the production of the chip card and in the information carrier ( 4 ) of the chip card ( 5 ) is stored. Method according to claim 1, characterized in that the position coding ( 3 ) through the course of the conductor track ( 2 ) in the chip card body ( 1 ) itself having a pattern detected by a reader. Method according to one of the preceding claims, characterized in that the conductor track ( 2 ) within the chip card body ( 1 ) is arranged running in one or more planes. Method according to one of the preceding claims, characterized in that the information carrier ( 4 ) is a chip, a magnetic stripe in or on the smart card, a bar code or optical memory, such as a holographic memory. Method according to one of the preceding claims, characterized in that the position coding ( 3 ) the conductor track ( 2 ) is determined by means of a transducer. Method according to one of the preceding claims, characterized in that the position coding ( 3 ) the conductor track ( 2 ) is determined by means of an inductive transducer. Method according to one of claims 1 to 5, characterized in that the position coding ( 3 ) the conductor track ( 2 ) is determined by means of a light source in the transmitted light method. Method according to one of the preceding claims, characterized in that the chip card is divided into grid squares, in which the position and arrangement of the conductor track ( 2 ) diverges and thus a universal position coding ( 3 ) of the chip card is formed. Method according to one of the preceding claims, characterized in that the conductor track made of copper, aluminum, conductive plastics, such as polymers, or consists of an electrically conductive paste. Method according to one of the preceding claims, characterized in that by means of a screen printing process, by winding, in the hot embossing process or by means of an etching process produced conductor track ( 2 ) a coil or antenna is formed. Method according to one of the preceding claims, characterized in that the conductor track forming a coil or antenna ( 2 ) on an electrically insulating layer plane ( 13 ) is applied. Method according to claim 11, characterized in that the layer plane ( 13 ) is a plastic film.

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