DE102005047048A1 - Chip carrier access securing method for use in contactless data transmission system, involves eliminating reading of data as access protection by operating condition and establishing another condition by permanent magnet and foil - Google Patents

Abstract

The method involves reading data of a data carrier by a reading device (7) in an operating condition of the communication over a transmission frequency. The reading of the data is eliminated as an access protection by another operating condition of non-communication. The former operating condition is established by a permanent magnet and a dielectric foil (6), and the latter operating condition is obtained by adjusting the frequency of the reading device or the frequency of an oscillating circuit based on the transmission frequency. An independent claim is also included for a contactless data transmission system.

Description

The The invention relates to a method for securing the access of a chip carrier a resonant circuit and a data carrier, wherein data of the data carrier in a first operating state of the communication over a transmission frequency of one reader be read out. Furthermore, the invention relates to a contactless Data transfer system the at least one chip carrier and at least one reader wherein the chip carrier has a Resonant circuit, the chip carrier has a data carrier, being the data of the volume in a first operating state of communication via a transmission frequency from a reader are readable.

One such contactless data transmission system comes everywhere used there, where a direct connection in the form of electrical contacts makes itself felt in a disadvantageous way. Especially if Persons or property labeled with data, and due to a variety of such Data take a contact-based data transfer or take a long time would be disadvantageous in another form Such a contactless data transmission system can be used.

For example is a contactless data transmission system suitable for the identification of persons who are authorized in one protected Area to enter properly, but must be subjected to an identification check to this To distinguish persons from unauthorized persons. To receives every person a chip carrier, For example, a chip card on which the relevant data for Identification are stored. Furthermore, an application in Connection with products conceivable as z. B. used in production plants becomes. The products also have a chip carrier indicating which one Product or what manufacturing steps the product is has already been subjected, or the like. Farther There are applications in private, public or industrial areas.

contactless Identification systems work on the basis of non-contact transmission technologies. these can are based on electromagnetic means, by means of light, infrared or Ultrasonic. The necessary data are from a read / write device, a non-contact Transmit data transmission link, such as B. over an air interface to a mobile data storage or to a contactless chip carrier and back. The non-contact allows Identification also the collection of data z. B. during a passing movement the contactless chip carrier, without this inserted or pulled through in a read / write device must become.

The most frequently used identification systems are based on an inductively coupled or on a radio-based data transfer by means of microwaves.

Inductive Coupling contactless smart cards can be used indefinitely be due to an integration of chemical energy storage, such as z. B. batteries, can be dispensed with. The necessary electrical Energy is therefore externally, i. H. one from the reader / writer magnetic field, taken without contact.

to Communication of the read / write device with such contactless chip makers are suitable transmission and coding procedures necessary. Thus, i.d.R. only certain frequency bands for data transmission released, z. B. the ISM frequency bands (Industrial, Scientific & Medical) for industrial trielle, scientific and medical applications. Special transmission and coding methods also provide an energetic supply the electronics in the contactless chip carrier safely.

The Contactless chip card as the most common Representative of the chip carrier is z. B. used as an identity card, citizen card or ID card, as driver's license, as a health or health card, as a credit or debit card or as a train, bus or plane ticket.

Next the for Convenient for the consumer or user of a contactless chip carrier Handling is still the virtually unlimited life of Advantage. Because of the contactless data transmission deleted the contact wear through the otherwise necessary electrical contact with the card or the mechanical abrasion i.Vgl. to cards with a magnetic stripe altogether. Out This reason is due to a rapidly increasing displacement of the previous o.g. To calculate cards.

The problem with this is that a reading of the above-mentioned contactless chip carrier can be done without contact and thus unnoticed by the user or owner of the chip carrier. As a result, it is not only possible for third parties to read out certain personal data and process it further in terms of data, but it can also be used in an improper manner, eg by B. in the inlet area of banks or in dense crowds, such. As in pedestrian areas, the data on the contactless chip carrier can be read by means of a mobile reader. The read data can then be transferred to a blank chip carrier and with tels this z. B. an unauthorized access to be procured in companies. It can also - especially in the banking and credit - Kre dit card number and for the data transfer security relevant relevant data, etc. read and decrypted by means available on the Internet decryption programs. Abusive money transfers, purchases at the expense of the cardholder, etc. would be the result.

Of the Invention is based on the object, a user-friendly and reliable Provide access protection to the data of the data storage of a chip carrier.

These Task is solved by a method for access protection, wherein a second operating state of the non-communication as access protection Reading out the data excludes and at least one adjusting means produces the first operating state. The task is continued by a contactless data transmission system of the type mentioned above, which a second operating state of the non-communication as access protection and having an adjustment means for producing the first operating state is provided.

One Oscillation circuit of a chip carrier is operable if it has a frequency that is the transmission frequency a reader equivalent. In this case, the resonant circuit is at the transmission frequency of the reader in resonance, and is energized contactless, and is in capable of data transmission to the reader too enable. Are the resonant circuit and the reader in resonance, so is the State of communication as established. This principle becomes resonant signal transmission called. The adjustment of the frequencies of the reader and the resonant circuit of the chip carrier is a prerequisite for the operational data transmission. According to the invention is still a protection state of the non-communication produced, a read-out excludes the data. The protection state of non-communication is when the Oscillatory circuit of the chip carrier and the reader are not in resonance. The protection state of non-communication is on the one hand produced by a Verstimmungsmittel, or the state of protection of non-communication is from the outset contactless data transmission system implemented. The detuning agent is the user can be used accordingly, so that a readout of the data of the data memory is prevented. The resonance preventing effect of the detuning agent can be due to a frequency shift of the reader or a frequency shift correspond to the resonant circuit. Furthermore, a disturbance effect is possible to prevent contactless coupling.

Farther the state of communication is established by means of an adaptation means or restored. In the case of the restoration was previously a detuning agent applied to the resonant signal transmission to prevent. The adjustment means can enable the data transmission independently whether a detuning agent was used, or the frequencies from the beginning were not identical.

At the contactless data transmission system, the at least one chip carrier and at least one reader has the method described above is used. in this connection is the frequency of the reader and / or the frequency of the resonant circuit can be changed by means of a detuning means, if the resonant circuit and the reader are not in the first place because of missing resonance automatically a protection state of non-communication of the contactless data transmission system have produced. In both cases has the contactless data transmission system at least one adaptation means, which is used to establish the condition the communication is bar. The fitting agent is hereby to suppress interference or to equalize the frequencies of the reader and the resonant circuit used. The detuning is for resonance suppression or to the frequency change of the reader or the resonant circuit provided. The detuned and the Adjusters are used to enhance the effect of each other to compensate.

at an advantageous embodiment the adjustment means and / or the detuning means a dielectric, and / or ferromagnetic material. The effect of using such or similar Materials leads with an appropriate attachment of these materials to a change the frequency of the resonant circuit or the reading device. By a favorable Choice of mounting location and a favorable choice of material sizing a frequency-shifting effect is controllably used. In this way it is possible one for a very specific resonance shift that is necessary to to establish a state of communication, a material or a Indicate the means for exactly the difference in frequency to be compensated for an adjustment manufactures. The present frequency difference can be pre-installed in the reader or chroma carrier be, or at least partially caused by a detuned have been.

In particular, the dielectric material contains a titanate or zirconate, in particular a barium titanate or a barium zirconate with a dielectric The latter materials cause a particularly large detuning of the LC circuit of the reading coil of an RFID reading device so that chip carrier data can no longer be utilized by narrow-band filters in the reading device.

Especially the invention is advantageously applicable for ID cards or smart cards with dimensions according to the DIN / ISO 7810 standard, i.e. with nominal dimensions of 85.46 mm × 53.92 mm × 0.76 mm. This card type puts with great Distance the most common Card format dar.

at a further advantageous embodiment, the fitting means and / or the detuning means a permanent magnetic, permeable and / or a magnetically nonlinear material. In this case takes over the detuning means a fault function and the fitting means a suppression function. Since a magnetically non-linear material has a hysteresis, is the state of communication in the existence of such Material on the chip carrier or not on the reader possible. By the suppression By means of a permanent magnetic material, the state of Communication to be restored. This is possible because by a so-called bias the magnetically non-linear Material saturated is and in a linear range of its magnetization characteristic is operable. Thus, the disturbance effect is canceled and the state of communication is established.

Preferably the permeable material is soft magnetic. The material also shows a relative permeability of at least 10,000, in particular of at least 50,000 to to achieve a sufficient magnetic shielding effect. In contrast, show conventional Metals for a storage means only a relative permeability of approx. 1 with aluminum and max. 2000 for steel alloys on.

Especially suitable are special for Magnetic applications developed nickel-iron alloys, which e.g. under the trade names MUMETALL, PERMALLOY, HYPERM, VACOPERM or also VITROVAC available are. These materials have a relative permeability in the range from about 20000 to 200000 with a low magnetic coercive force of less than 10 A / m. The magnetic material is all the more soft magnetic, the lower the coercive force is.

at a further advantageous embodiment, the contactless Data transfer system at least one chip carrier and at least one reader on, with the chip carrier at least one adjusting agent and / or at least one detuning agent having. Consequently, here are various applications given. Are on the chip carrier both detuning and adjusting means, so is the owner of the chip carrier in able to release it for reading by a reader when needed. Farther is the use of an adjuvant and a detuning agent on the reader conceivable, which makes it possible the reader if necessary in a non-communicative state, or the reader in a state of communication with a particular class of chip carriers to enable the selectively from other chip carriers to be differentiated. This is advantageous if very specific People or groups of people through a specific checkpoint to be smuggled. The classic application is present when the reader an adjustment means and the chip carrier has a detuning means or has a tuned from the outset resonant circuit. On this way is the chip carrier, for example, a passport or other document, only from this special reader readable, which by a special fitting means in the situation has been added. A data transfer on other readers is thus excluded. An example of this is the company ID, the only company-owned readers Grant data access and prevents access by other readers. Furthermore are other combinations and distribution options of fitting and / or Abstimmungsmittel on the chip carrier or readers conceivable.

at In a further advantageous embodiment, the protective state achieved by means of an interruption of the current path of the resonant circuit and the fitting means bypasses electrically conducting this interruption. This embodiment comes at the core of a capacitive change the frequency of the resonant circuit is the same. The bridgeable interruption is for example as an electrical switch executable. A switch means one for the User comfortable adjusting or disturbing or shifting the resonance and thus a very simple switching from the protection state of non-communication in the state of communication. For the user is very easy to control, whether his data is readable are or not. Furthermore, the permission to read the data not permanently to a reader but the user is able to give the reader his personal if needed Data available to deliver.

In a further advantageous embodiment, the chip carrier is designed as a chip card, whereby an easy handling and storage for the user is guaranteed. In this connection, it is further advantageous to use the fitting means and the detuning means as or in Shape a foil. Due to the dimensions of a film, the format of a chip card is advantageously supported. Also in the reader, such executed fitting or detuning effect space-saving.

Further advantageous embodiments and preferred developments of the invention are the figure description and / or the dependent claims remove.

in the Below, the invention with reference to the figures shown in the figures Embodiments described in more detail and explained.

It demonstrate:

1 a schematic representation of a frequency range,

2 a schematic diagram of a resonant circuit of a first embodiment,

3 a chip carrier of a second embodiment,

4 a chip carrier of a third embodiment,

5 a reader of the third embodiment,

6 a chip carrier of a fourth embodiment, and

7 a reader of the fourth embodiment.

1 shows a schematic representation of a frequency range, wherein two frequency spectra are shown. A frequency spectrum is centered around the frequency FL of the reader and the other spectrum is centered around the frequency of the RFID resonant circuit of the chip carrier F0. The figure illustrates that a resonance is necessary to a state of communication between the chip carrier 4 and a reader 7 manufacture. The state of the communication corresponds to a resonance case of the two involved frequencies of the reading device 7 or the chip carrier 4 , A resonance would occur if the two spectra overlap. In the figure above, the frequency spectrum does not overlap, which means that either the frequency F0 or the frequency FL are detuned to the point that there is no common transmission frequency or resonance. An adjustment means is capable of, for example, the frequency F0 of the chip carrier 4 To modify it so that an overlap of the spectra and thus the necessary resonance is possible. A possible shift of the frequency F0 of the chip carrier is illustrated by the arrow shown.

A Frequency detuning can also be given by the amplitude one of the two spectra or frequencies is detuned. In this In the case, the detuning means may also be a disturbance means, which is several Frequency components with low amplitude generated. Such a mood can not by a mere Resonance shift of the reader be compensated, this is a corresponding compensation the signal sturgeon ratio necessary.

2 shows a schematic diagram of a resonant circuit of a first embodiment. The resonant circuit contains an integrated circuit 1 , a switch 2 and a coupling coil 3 , The natural frequency of the resonant circuit generally depends on its inductance and capacitance. Will, as in this case, a switch 2 inserted, the effective capacity of the resonant circuit is manipulated. In particular, the fact that the component used the switch 2 is, by the use of the switch 2 If required, different capacities can be produced. This leads to different natural frequencies of the resonant circuit. One of the two frequencies is chosen as the transmission frequency, and is also from a reader 7 used. The state of communication is achieved by simply flipping or pressing the switch 2 guaranteed. The protection state or state of the non-communication is brought about by establishing the other switching state.

In the first embodiment, detuning means and adjusting means are in the switch 2 integrated. In this sense, for example, the interruption of the current path represents the detuning, or the bridging of the current path through the switch 2 the adjustment agent.

3 shows a chip carrier 4 a second embodiment. The chip carrier 4 may in this context constitute an identification document, such as a passport. The electronic label (RFID) ( 5 ) works on a similar principle as shown in the first embodiment. The one in the electronic label 5 integrated resonant circuit contains a membrane switch 8th or a micromechanical switch, which is also provided as a fitting and Verstimmungsmittel. This chip carrier 4 is thus usable with a conventional reader. It is at the discretion of the user, whether this access to the data memory of the electronic label 5 wants to allow. He can make the identification document readable by pressing a key, ie establish the state of communication. When not in use the identification document, the frequency of the resonant circuit is shifted so that no resonance with the reader 7 is possible. The identification document is hereby reliably secured and can only be read electronically when the switch is intentionally actuated.

In this context, the use of the membrane switch 8th particularly advantageous because these buttons are inexpensive and easy to integrate because of their flatness. Thus, the use of a chip card as a chip carrier 4 supported.

4 shows a chip carrier 4 A third embodiment of a contactless data transmission system. The chip carrier 4 has an electronic label 5 on. The resonant circuit of the electronic label 5 is designed so that resonates with the associated reader 7 is not possible without further ado. It is therefore necessary to use an adapter.

5 shows a reader 7 of the third embodiment. The figure shows a reader 7 with a dielectric foil 6 , which takes over the function of the fitting means. Instead of the dielectric film 6 is also a ferromagnetic film conceivable. The reader 7 is for use with a chip carrier 4 as he is in 4 , is shown provided. The dielectric film 6 causes a frequency shift of the reader 7 to the transmission frequency. The chip carrier 4 has a frequency corresponding to the transmission frequency. Thus, by means of the frequency shift, a resonance or a communication is possible. One possible application of this contactless data transmission system is that the reader 7 can only read out a very specific class of identification documents. The physical properties of the dielectric film 6 are designed so that only the operator of the reader 7 an access to the data of the electronic label 5 has.

The third embodiment could be modified such that the fitting means in the form of the dielectric film 6 just like the electronic label 5 on the chip carrier 4 is appropriate. In this case, the owner of the chip carrier 4 able to decide if the reader 7 should be entitled to read out the data.

Likewise, a combination of the above-mentioned embodiments is conceivable by a dielectric film on the reader 7 as well as on the chip carrier 4 is appropriate. In this case, a readout of the data takes place only if both owners of the reader 7 or the chip carrier 4 want to allow readout of the data.

6 shows a chip carrier 4 a fourth embodiment. The electronic label 5 of the chip carrier 4 is on a sturgeon foil 9 formed. The disturbing foil 9 is located between the electronic 5 and the chip carrier 4 to a disturbance or detuning of the frequency of the resonant circuit of the electronic label 5 bring about. The disturbing foil 9 can be performed for example as a magnetically non-linear film. The functional relationship of magnetic field strength and magnetization is nonlinear in such a film, ie, the two mentioned sizes are linked by a hysteresis-like function. When reading the electronic label 5 A strong magnetic field is applied to supply power. The proximity of the magnetically non-linear film creates a strong background noise due to non-linear mixing, which successfully prevents data transmission. The signal amplitude of the backscattered signal of the electronic label 5 is small in comparison to the background noise and can not be detected by the reader.

7 shows a reader 7 of the fourth embodiment. With a conventional reader 7 is the volume of an electronic label 5 as it is in 6 shown is not readable. The reader 7 must therefore have an adjustment means for adaptation. An adjustment can be made by pre-magnetizing the magnetically non-linear foil so as to reach a range in which the ratio of magnetic field strength and magnetization is linear. Such a bias can, for example, by a permanent magnet 10 be achieved.

It is also conceivable that the permanent magnet 10 on the electronic label 5 or the magnetically non-linear film 9 on the reader 7 is appropriate. That in the 6 and 7 However, the contactless data transmission system shown has the advantage that the chip carrier 4 Resistant to any vibration that is detrimental to a permanent magnet 10 could affect.

In summary The invention relates to a contactless data transmission system and a method to secure the access of a chip carrier with a resonant circuit and a disk, being data of the volume in a state of communication via a transmission frequency read by a reader become. The invention is intended to be a user-friendly and reliable Secure access for specify the data of the data memory of a chip carrier.

To becomes a contactless data processing system and method taught to secure access, with a protection state of non-communication excludes reading of the data and at least one fitting means establishes the state of the communication.

Claims (16)

Method for securing the access of a chip carrier ( 4 ) with a resonant circuit and a data carrier, wherein data of the data carrier in a first operating state of the communication via a transmission frequency from a reading device ( 7 ), characterized in that a second operating state of the non-communication as access protection excludes a read-out of the data and at least one matching means ( 6 . 10 ) produces the first operating state. Method according to claim 1, wherein the second operating state is determined by an adjustment of a frequency of the reading device ( 7 ) and / or a frequency of the resonant circuit with respect to the transmission frequency is achieved. Method according to one of claims 1 or 2, wherein the second operating state by at least one detuning ( 9 ), which determines the frequency of the reading device ( 7 ) and / or the frequency of the resonant circuit changes with respect to the transmission frequency is produced. Method according to one of the preceding claims, wherein the adjusting means ( 6 . 10 ) the frequency of the reader ( 7 ) and / or the frequency of the resonant circuit adapts to the transmission frequency. Method according to one of the preceding claims, wherein the adjusting means ( 6 . 10 ) consists of permeable, dielectric, ferromagnetic, permanent magnetic and / or magnetically non-linear material. Method according to one of the preceding claims, wherein the detuning agent of permeable, dielectric, ferromagnetic, permanent magnetic and / or magnetically non-linear material consists. Method according to one of the preceding claims, wherein the second operating state is achieved by means of an interruption of the current path of the resonant circuit and the adjusting means ( 6 . 10 ) bridges the interruption electrically conductive. Contactless data transmission system comprising at least one chip carrier ( 4 ) and at least one reader ( 7 ), wherein - the chip carrier ( 4 ) has a resonant circuit, - the chip carrier ( 4 ) has a data carrier, wherein the data of the data carrier in a first operating state of the communication via a transmission frequency of a reading device ( 7 ), characterized in that the contactless data transmission system has a second operating state of non-communication as access protection and an adaptation means ( 6 . 10 ), which is provided for the production of the first operating state. Contactless data transmission system according to claim 8, wherein the second operating state by an adjustment of the frequency of the reading device ( 7 ) and / or the frequency of the resonant circuit with respect to the transmission frequency can be produced. Contactless data transmission system according to one of claims 8 or 9, wherein the contactless data transmission system comprises at least one detuning means ( 9 ) to detune the frequency of the reader ( 7 ) and / or the frequency of the resonant circuit with respect to the transmission frequency. Contactless data transmission system according to one of claims 8 to 10, wherein the matching means ( 6 . 10 ) for adapting the frequency of the reading device ( 7 ) and / or the frequency of the resonant circuit with respect to the transmission frequency is provided. Contactless data transmission system according to one of claims 8 to 11, wherein the matching means ( 6 . 10 ) has permeable, dielectric, ferromagnetic, permanent magnetic and / or magnetically non-linear material. Contactless data transmission system according to one of claims 8 to 12, wherein the detuning means ( 9 ) has permeable, dielectric, ferromagnetic, permanent magnetic and / or magnetically non-linear material. Contactless data transmission system according to one of claims 8 to 13, wherein the chip carrier ( 4 ) at least one detuning agent ( 9 ) and / or at least one matching agent ( 6 . 10 ) having. Contactless data transmission system according to one of claims 8 to 14, wherein the reading device ( 7 ) at least one adjuvant ( 6 . 10 ) and / or at least one detuning agent ( 9 ) having. The contactless communication system of any of claims 8 to 15, wherein the second Operating state by means of an interruption of the current path of the resonant circuit can be produced and the adjustment means ( 6 . 10 ) is provided for electrically conductive bridging the interruption.