SK406492A3 - Device for establishing forgery attempts on a chips card reader/writer - Google Patents

Abstract

A device for detecting forgery attempts by connecting an electrical feedline (13) to a chip card (3) reader/writer essentially consists of a resonant unit (6) coupled to a contacting element (2) of the device, and a measuring device (7). In the resonant unit (6), a generator (4) coupled to a resonator (1) via an impedance converter (5) generates a standing wave. The feedline (13) interferes with the characteristics of the resonator (1) which is detected and evaluated by the measuring device (7). <IMAGE>

Description

Apparatus for providing a trial attempt, device chip card fraud on reading and description of the technique

BACKGROUND OF THE INVENTION The present invention relates to a device for detecting fraud attempts on a smart card reader and writer, by connecting an electrical lead to a smart card terminal, and with a measuring device.

BACKGROUND OF THE INVENTION The device is preferably used! in service power systems, e.g. automatically collecting telephone stations that work with electronic chip cards.

In a fraud attempt, a varied smart card is used: or a very similar card with a randomly arranged connection point, at least one of the connection points being connected to the electrical supply of the apparatus, located outside the writing and reading device, it does matter, the piece of fraud can be ascertained by examining whether such an impermissible supply exists.

There is known a device of the above-mentioned type (± u ·· 0 <k> be Al ') ^, which is assisted by an inductive sensor detectable signal in the existing water supply of the card stack, whereby it is The reading and manipulation process is known to my standardized frequency.

It is also known to arrange a transmitter at one end of a smart card at the end and a receiver at the other end and to use any incoming connection such as a carrier medium, the transmitter side being galvanic and the receiver side inductive. 0 347

AL »FR 2 55 * + tbľ, FR 2 b4b? BU> or capacitance (FR 2 b ^ b? Bu) or in this case the coupling on the transmitter side inactive and on the receiver side inactive (Kr 0 * + 47 bbb'i or galvanic (Ri ú 454 570) ·

In addition, an oscillator (FR 2 b4b cbl) device is known which has a frequency determining element that moves over a chip card, so that any incoming leads cause interference at the output of the oscillator.

With known devices, mechanical devices, such as a device, must be arranged in the card tray in the chip card area. antennas, or movable sensors so that they are perfectly protected from damage by them.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION The object of the invention is to propose reliable and well-protected devices for reliable detection of fraud attempts on a smart card reader and writer.

This object is achieved according to the invention in that the device has a resonant unit 3 with a resonator connected to a connection point, the electrical properties of which are changeable by the conductor and can be impregnated with the measuring device. device.

Preferred embodiments of the invention are set out in the dependent claims.

BRIEF DESCRIPTION OF THE DRAWINGS FIG

The following examples illustrate the invention with reference to the drawings.

In FIG. 1 shows the principle of the experiment detection device. fraud on smart card readers and writers.

In FIG. 2 shows a variant of a device with a conductor as a resonator.

In FIG. 3 shows a variant of a device with a parallel oscillating circuit as a resonator.

In FIG. * ♦ shows a variant of ae oscillating circuit as a resonator.

In FIG. 5> and a variant of the device in front view is shown.

In FIG. 5b shows a side view of parts of the apparatus of FIG. 5a.

In FIG. 6 shows a variant of a conductor-resonator device with at least two taps.

FIG. 6 shows an embodiment of the resonator of FIG. b.

DETAILED DESCRIPTION OF THE INVENTION

In FIG. 1, a resonator 1 is shown which is a galvanic contact 2 forming a contact with the known reader; Chipcurd Keader / V is also known as a chip card 6, which together with the generator 4 and the impedance transducer 6 forms a resonance unit 6, the output of the generator 4 being connected to the resonator 1 via the impedance converter 7 with the resonator 1. the alarm output b for the alarm signal has at least one input connected to the resonance unit 6 and an output which is brought back to the resonance unit via the actuator 2.

In addition to the contact generating element 2, the chip card reader and writer further has the same but not shown dome forming elements processing unit 10, as well as a card holder with a chip card insertion slot 11 not shown. Each of the touch generating contacts is only via the line 11 with the processing unit 1G.

The chip card X is a valuable card having at least one electronic component, e.g. a microcomputer or a memory, which can be retrofitted via a plurality of attachment points 12 for a reading and writing device and which has a contact generating element 2 for each attachment point 12. connection points. 12 and theirs. the arrangement on the smart card J is standardized, with various standards existing.

In the fraud attempt, it is known to use a double chip bore X or a maximum similar card with the same arranged connection points 12, at least one of the connection points 12 being connected to the electrical supply ΐχ of the apparatus ln outside the device. When the chip wick is sold to the device, the randomly occurring lead is connected with the control element 1 forming the contact. . ŕístro j

1¼ Serving a fraudulent experiment is, for example, a measuring device or a simulator.

Device for determining or resp. detecting a fraud attempt by connecting the lead 11 to the contact forming element 2 consists of a resonant unit 6, a metering device 7, an actuator 2 ^{and a} shielding means 18 arranged between the resonant unit 6 and the line 111 of the device details and functions described in the following text.

The generator {♦, whose output impedance is tuned to the impedance converter na per resonator 1, generates electromagnetic oscillations in the resonator 1 at a frequency of e.g.

GHz.

Advantageously, the resonant unit 6 is so tuned that at least then a wave is formed in the resonator 1 if the lead 10 to the connection point 12 connected through the resonator 1 contact element 1 is missing. and the vibrations become measurable.

Preferably, the resonator 1 according to FIG. 2 electric conductor respl waveguide, which is formed in ?. in the form of a wire, strand, conductive track or hollow body and having at least one branch and which is galvanically connected to the input of the measuring device 2. The branch A lies advantageously close to the standing wave node.

In the first variant of the device, the metering device 2 measures the electrical voltage at the branch A and compares the measured value with a predetermined voltage setpoint, since the lead 1g is not connected to the contact generating element 2. Based on the magnitude of the difference than the set value and the setpoint value, the fraud attempt is detected and an alarm signal is generated, for example, at the output of the threshold switch associated with a heavy load.

It is advantageous if the measuring device 2 has preparatory elements such as e.g. or filters to reliably identify the measured value.

The alarm signal is preferably evaluated in a known manner by the processing unit 10.

The actuator 10 allows feedback of the measured value on the generator 4 and / or the impedance converter, so that the frequency of the generator 4 and the output impedance of the impedance converter can be varied by measuring load m 2 if necessary.

The shielding means 15 protects the processing unit 10 from disturbances caused by the resonant unit 6 and protects the device from the disturbances of the lines 11.

In a second variant, the voltage or impedance at the input of the resonator 1 is preferably measured and compared to a predetermined value of the impedance, e.g. voltage. The reference value is the impedance of resonator 1 resp. voltage on the resonator 1 without lead 1 to the contact forming element 2.

The first and second variant are successfully combinable ·

In a third variant of the device, the frequency of the oscillation or the oscillation frequency is changed on the generator 4. oscillation in the resonator until the voltage at tap A reaches a certain target value. The target value is equal to the voltage value which, at a predetermined setpoint value, oscillates at the branch A, unless the lead 10 is connected to the contact forming element 2, and the actuating device Z mediates the measured oscillating frequency value.

e.g. by means of an additional input connected to the generator output and compares the measured value with the frequency setpoint. The fraud attempt is recognized based on the magnitude of the difference between the measured value and the reference value.

The second and third variants are successfully combinable.

In a fourth variant of the apparatus, the resonator 1 is formed according to FIG. 3 by a parallel oscillating circuit consisting of a coil Lp and a capacitor C _p or according to FIG. to a series oscillating circuit consisting of a coil L and -3 of a capacitor Cg, the properties of which can be varied by an inlet 16 (FIG. 1). In this variant, the voltage or impedance at the input of the resonator 1 is preferably measured and compared with a predetermined setpoint of impedance resp. the voltage that the resonator 1 has without the lead 16 on the contact forming element 2.

In the device, the electrical properties of the resonant unit 6 measurable are influenced by the inlet 13, the resonant unit 6 operating in the giga hertz range and being galvanic connected to the contact generating element 2, the guide 13 being reliably detectable irrespective of its size, position and shielding. .

The device can be completely arranged outside the card holder, since it is bound only to the rod-forming element 2. There is no need to take any action in the space between the electronic component (microcomputer or memory) of the smart card 3 ^{and the} insertion opening of the cartridge.

The resonator 1 is preferably connected to the contact generating element 2 which is in contact with the reference potential point (signal-grip) of the chip card 3.

In FIG. 5 has a resonator 1 instead of a galvanic coupling βί and a contact forming element g (i.e. 1) a coupling member 16 for non-parallel coupling of the resonator 1 to the connection points 12 and hence to the supply 10. The coupling is carried out in the manner of the coupling member 16 capacitively or inductively.

Because of the capacitive coupling of the resonator 1, the coupling member 16 is designed such that the voltage at the output of the resonate 1 is influenced from the supply 1j by the electric field.

The capacitive coupling coupler 16 preferably has the largest plane surfaces of the smart card 1 having a parallel 1% metal layer which is aligned with the band adjacent to the attachment points 12 of the smart card 6 ^and approximately covers the area of the band.

For the inductive coupling of the resonator 1, the coupler 16 is formed such that the current in the resonator 1 is influenced by the magnetic field from the lead 11.

By means of a coupler 16 connected to the resonator 1, an electrical connection to one of the connection points 18 changes the properties of the resonator 1 sensed by the measuring device.

With a further embodiment of the device, the fraud attempt is detectable without the attachment points 12 of the chip card 3 being galvanic connected to the contact generating element. Thus, the fraud attempt can advantageously be detected before the contacting element 2 is deposited on the contact points L 'or also when the smart card J is inserted into the reader and writer Sp. card, wherein the properties of the resonator 1 are preferably far-reaching

independent of the contact forming elements 2 on the guides 11.

Y have given them the properties of the resonator 1 maximum, independent of the embedded electronic components on the chip card J; The device is therefore preferably usable unchanged for hazardous chip card embodiments

J ·

Fig. 6 shows a part of a fifth variation from the load in which the resonator 1 is an electric conductor or an electric conductor. water, wherein the resonator 1 has a branch Λ connected to the inlet of the metering device 7 and is connected to the coupler 16. The resonator 1 has a second branch B which is connected to the other inlet 18 of the metering device

7. The second branch B lies preferably near the standing wave node. The measuring device is a measurable electrical voltage at branch A - as already described - and also at branch B.

Fig. 7 shows a resonator 1 coupled to a coupler 16, with an inlet to both taps A and B, a generator 4, an impedance changer 2, a metering device 2 and an actuator 2. a second input member 20 connected by the inlet side to the second branch B, the first switch 21, respectively. a threshold switch 21 and a second threshold switch 22, wherein both the threshold switches 21 and 22 are an input side connected to the actuator 2;

Generator 4 has preferably a phase control circuit (PLL) 20, a voltage-controlled oscillator (VCO 24 connected by an output with an impedance converter 2), and a low-pass filter 22 ' 2 is connected to the input to the resonator 1 connected to the output of the impedance converter 2, and the multi-pole control input 27 of the phase-to-phase switching circuit is connected to the actuator 2 via a bus 28.

The phase control circuit gj is realized, for example, by a construction element of the type IClCl2.

The reference input 22 of the first threshold switch 21 is coupled to the reference input JO of the second threshold switch gg and is connected to the input E of the resonator 1 via the compensating member J1. The compensating member J1 compensates the voltage variations at the input E of the resonator 1. The reference signal at the output of the compensating element 11 and at both the reference inputs 22 and 12 is maximum temperature independent.

The first threshold switch g1 has a signal input Jg which is connected to the output of the first input P1. The signal input 11 of the second threshold switch g '1 is only associated with the output of the second input member 20.

The resonator 1, which is designed as an electric conductor, respectively. As a waveguide, it has, if necessary, a plurality of conductor pieces connected by couplers, at least one of the conductor pieces _being sliding, if at least one. That it requires the design or function of the reader and writer of the smart card memory J.

In FIG. 0 shows the first conductor part 14 and the second ventilator part 16 of a resonator 1 formed as a waveguide, at one end of which is an inlet E and the other end of which is connected to a coupler 16. The shape of the first conductor part 14 is adaptable to a structure and space which is The first conductor part JU has two branches A and B and the first coupler, respectively. coupling element J6.

One end of the second conductor part 11 is closed by a coupling 16 and the other end c is closed by a second coupling element.

Preferably, the first conductor portion is a flexible cable and the printed connections have a coupler 16 and a second conductor portion 35 with a 32¼ coupler.

The first coupling element 3 ' ^{in the} plane from which the part with the mythical frame 36 is exchanged, which also includes the first coupling element 36.

The second coupling element 3? it lies in a further plane, which is preferably parallel to the first plane and defines therefrom a portion with a further imaginary frame 32 which also comprises a second coupling element 37 and the imagined frames 18 and 39 enclose the same surfaces.

The second conductor part 35 is less so perceptible in the direction of the lace 40 that both conductor portions 34 &apos; by both bonding elements 36 ^and are optimally adjustable for the wave in resonator 1. The advantageous bonding of both conductor portions 34 and 35 is achieved. if the frame 38 and 32 ⁱⁿ FIG. 8 overlap <

By moving the second conductor portion 32 in the direction of the lace 40, the fraud detection device is connectable to the chip card 3, while moving in the upstream direction of the lace 40 is detachable from the chip card.

Movement in the direction of the Lace 40 is effected by inserting the Chip Card 3 of the chip card reader and writer.

In a preferred embodiment of the resonator 1, the two inlet members 18 and 20 are arranged directly on the respective branches A and B respectively. B and are implemented as Siih (surface aouted device).

If necessary, both the A and B branches are connected. B on the resonator 1 are arranged directly next to each other, or they are physically designed as one branch to which the measuring device 2 * can be connected

A preferred embodiment of the weighing members. 36 and 62, which are attainable in each case by a single thread on the first conductor part 14 and 22 respectively. on the second conductor portion 6.

To set the actuator 2 2 ^S0U at least two different values for the frequency of the generator 4, for example the first value is 5θθ MHz and the second value 455 MHz.

Preferably, the length of the second conductor portion 45 is tuned to a quarter of the wavelength of the resonant 1 at the first frequency, while the length of the first conductor portion 45 is preferably multiple of that half-wavelength.

In the following, a method is described in which, as shown in FIG. 7 detectable fraud attempt.

In a first step, the frequency of the generator 4 is set to a first value, sensing the voltage at the tap A via the first input member 19 8β and comparing in the threshold switch 21 with a reference signal that is on the reference input 2g. If the sensed voltage is not within the expected first range, the fraud attempt is recognized, interrupted, and the smart card 1 is rejected.

If the voltage at the tap A is removed within the expected range, the frequency of the generator 4 is set to a second value in the second step, the voltage at the second tap B is sensed by the second input member 20 and compared to the reference signal in the second threshold switch. If the detected voltage is not within the expected range, the fraud attempt is recognized and the chip card 1 is rejected.

Chip card 1 is only accepted if, when oscillating with the first frequency value, there is voltage, sowing the mutome on tap A in the first range and drinking the oscillation with the second frequency value is the voltage tapped on second tap B in the second range.

In the case of resonator 1, when n δ has two different frequency values, one voltage is recorded and equals one setpoint at a time, the fraud test can be even if the effective supply distance 1 ^ / is multiple of half the wavelength frequency at least from two frequency values ·

The device according to FIG. ? without supply 1J (Fig. 1), the first value of the tap frequency and the first node and the second value of the tap frequency B the second node.

In one preferred method for determining the optimal first value of the oscillation frequency in the resonator 1, the frequency actuator fades in a certain direction and then the beer threshold frequency f is taken if the output signal on the first threshold switch g1 from the first extreme value - e.g. the second extreme value - for example the minimum - occurring in the second frequency range of the first node. The frequency continues to flicker in the same direction, and a second threshold frequency f is sensed if the output signal from the second extreme value is thrown back to the first extreme value.

The optimum first frequency value is the mean of both threshold frequencies and f ~; preferred is the first value of the geometric center (^P of both threshold frequencies and _? F).

1¼

The optimum second frequency value is ensured by applying the described method to the second node, wherein the output signal is used on the second threshold switch.

The method b of the two optimum oscillation frequency values in the reactonator 1 is preferably feasible automatically. In use, each embodiment of the device is tuned according to the method individually.

Claims (16)

1 · Experimental detection facility ú. Chip card readers and inscriptions Chip cards · by connecting the power supply to the chip card connection point and with a sweep device, characterized in that the device has a resonance unit (6) with a reeonator (Ό connected to the connection point. (12) Whether the electrical properties are readily operable by the supply (1J) and the measuring device (7). Device according to claim 1, characterized in that the resonator (10) is a galvanic connection n to a contact-forming element (2) with a connection point (12) of the reader and writer device (5). Apparatus according to claim 1, characterized in that the reaonator (1) is connected via a weighing member (16) capacitive or inductive to the connection boa (12). * ♦. Device according to one of Claims 1 to 3, characterized in that the resonant unit (6) is formed in such a way that there is at least then a standing wave in the resonator (1), where there is no electrical supply (1J). Device according to one of Claims 1 to 3, characterized in that the reaonator (1) is an electric conductor. 6 «Equipment according to bar 5» indicating! characterized in that the electric conductor has a first conductor part (JU) with a first coupling element (36) and a second conductor part (35) and a second coupling element (37), wherein both conductor parts (3, 13) are both coupling elements (36). J6j37) capacitively or inductively connectable. Device according to claim 5 or 6, characterized in that the electric conductor has at least one branch (s) which is connected to a metering device (7) by which the voltage on the branch (s) is measurable. Device according to any one of claims 1 to 3, characterized in that the resonator (1) is an oscillating circuit having a capacitor (Gg) and a coil (¾) connected in series with the condensate or e m (C-1). ABOUT ' Device according to claims 1 to 3, characterized in that the resonator (1) is an oscillating circuit having a capacitor (Gp) and a coil (ip) connected in parallel to the capacitor (Cp). 10. A device according to claim 7, characterized in that: The device according to claim 1, characterized in that the electric conductor has a second tap (B) which is connected to a metering device (7) which is a measurable voltage on the second tap (B). 11. Apparatus according to one of Claims 1 and 10, characterized in that the resonator (1) contains variable frequencies whose frequency is measurable, the frequency being selectable from the first value and at least one second hoonot. Device according to any one of claims 1 to 11, characterized in that the resonator (1 ') is connected to an impedance converter 3 (3) by a generator (4) having a voltage-controlled oscillator (24) and a phase-to-phase converter. solution (23) · 13. A method of detecting fraud by means of a load according to any one of items 1 to 12, characterized in that the impedance at the resonator input (1) is measured and compared to the impedance setpoint, which shows the resonator (1) without supply (13) to point (12). 14. A method for detecting fraud by means of a device according to any one of Claims 1 to 12, characterized in that oscillations are generated in the resonator (1) and the voltage is measured on the resonator and compared with the desired value on the resonator (1). ) is set without connection / 13) at the connection point (12). A method of detecting fraud by means of a device according to any one of Claims 1 to 12, characterized in that oscillations are generated in the resonator (1), the frequency of which has a first value and that the resonator (1) can be energized and , which on the resonator (1) is measurable without a lead (13) at the connection point (12), that the frequency is set to a second value different from the first value and the voltage is measured again and compared with the next setpoint The resonator (1) can be measured without the lead (13) at the connection point (12) and that the chip card (') is now accepted if the voltage on the resonator lies at the first or second frequency value always within a predetermined range. 16. Detection of fraud attempts Using a device according to any one of Claims 7 or 10 and 1, characterized in that it can voltage at tap (A) and compare to the voltage setpoint at tap (a). if the lead (1J) is not connected to the connection point (1?). · 17. The detection method attempted fraud using a device according to any one of claims 7 or 10 to 12, characterized in that the impedance at the resonator input (1) can be compared with the impedance setpoint that the resonator (1> without supply) can 10 at the junction point (1?> and that the voltage at the junction (A) can be compared with the voltage setpoint at junction (a) when the supply (1J $ is not connected or at the junction point (1?)) . 18. The method of identifying aid fraud attempts is one of the claims. 7 or 10 a212, characterized in that the frequency of the input signal on the resonator (1) is changed until the cap on tap (a) reaches a certain value, whereupon the frequency of the input signal is measured and compared with a predetermined frequency setpoint. wherein the voltage at tap (a) shows a certain target value if the resistor (1) oscillates with a predetermined frequency setpoint and the supply (1J) is not connected to the connection point (1?).