FR2693014A1 - Fraudulent smart card usage detection appts. e.g. in public telephone - detects cards connected to external electronic circuits by measurement of coupling capacitance - Google Patents

Abstract

The appts. comprises an electronic circuit connected to the terminals of the smart card (20) when it is placed in the slot (10). The circuit comprises a source of high frequency alternating current (24) connected to the terminals (K) during the test phase. One wall of the slot (10), made of conducting material, is connected to one line of the a.c. generator. A leakage current detection circuit (26,28,30) measures the capacitance between the card and the slot wall, detecting whether external wires (22) are connected to the card. ADVANTAGE - Automatic detection of use of external connections to smart cards in attempts at fraudulent use.

Description

DETECTOR FOR USE OF A CHIP CARD
FRAUDULENT
The present invention relates to devices operating with smart cards, and in particular a device for detecting the use of a fraudulent card.

 The devices operating with smart cards generally include a slot provided with connectors coming to connect the circuits of the device to the contacts of the chip of a card inserted in the slot.

 One possibility of fraud is to simulate the functions of a chip. For this, a fraudster inserts into the slot a dummy card comprising only contacts corresponding to those of a chip or else including an invalidated chip. The contacts are connected by wires to remote electronic circuits making it possible to simulate an advantageous chip operation for the fraudster.

 Such fraud was previously particularly difficult since the card devices included motorized card receiving devices which retracted the cards. These devices are being abandoned because they are complex and may not return a card in the event of a breakdown. Current card receiving devices, with which the aforementioned type of fraud is possible, are reduced to a slot where the card is always accessible.

 An object of the present invention is to detect the use of a smart card, the contacts of which are connected by wires to remote electronic circuits.

 To achieve this object, the present invention provides for detecting the presence of a capacitive coupling between the card insertion slot and one or more wires connecting the contacts of the card to remote circuits.

 The present invention relates more particularly to a fraud detection device for an apparatus operating with a smart card intended to be inserted into a slot provided with connectors, comprising an alternating signal generator whose output is coupled, at least during a phase of detection, at least one of said connectors; a slit with walls of an electrically conductive material connected to at least one of the generator supply lines; and a longitudinal current detector in said supply lines, arranged between the connectors and the point of connection of said walls to said at least one supply line.

 According to an embodiment of the present invention, the walls of the slot are connected to the earth, at least one of the supply lines being connected to the earth by a capacitor.

 According to an embodiment of the present invention, the longitudinal current detector comprises two coils arranged respectively in series with said supply lines, these coils being connected so that the fields which they generate are opposed, and a third coil magnetically coupled to said two coils and the terminals of which are connected to a circuit for detecting that a threshold has been exceeded.

 According to an embodiment of the present invention, said generator supply lines also supply, via a filter comprising said capacity, two supply connectors for the chip card and a chip control circuit. .

 According to an embodiment of the present invention, the device comprises switches which, connect the connectors, either to the control circuit and to the supply lines, or to the output of the generator during a detection phase.

 These objects, characteristics and advantages as well as others of the present invention will be described in more detail in connection with the attached figure which represents in very schematic form elements of a card payphone as well as an embodiment of detector of use of fraudulent card according to the present invention.

 The present invention will be described in the context of a card payphone, but those skilled in the art will note that it applies to any other device operating with a smart card.

 A card payphone conventionally comprises a slot 10 intended to receive a smart card. A side wall of the slot 10 comprises, at the bottom of the slot, connectors K intended to connect the contacts of the chip of an inserted card, to an electronic circuit 11 for controlling the chip. Two of the connectors K are connected to two DC voltage supply lines VCC and VSS coming from the outputs of a diode rectifier bridge 12. The lines VCC and VSS also supply the circuit 11.

 The supply voltage for the public phone circuits is supplied by the telephone line. Two terminals A and B are connected, outside the payphone, to two wires not shown of the telephone line and, inside, to the inputs of the rectifier bridge 12 by means of a low-pass filter 14 of electro-magnetic compatibility (EMC), intended to attenuate parasites emitted by the payphone on the telephone line.

The filter 14 includes two coupled inductors
L1 and L2 connected respectively between terminal A and a first input of bridge 12 and between terminal B and a second input of bridge 12. Hereinafter, the input lines of the bridge will also be referred to as "supply lines" 12. The connection point between inductance L1 and the first input of bridge 12, on the one hand, and the connection point between inductance L2 and second input of bridge 12, on the other hand, are connected between them by two capacities C1 and C2 arranged in series. The connection point between capacitors C1 and C2 is connected to earth.

 There is also shown a fraudulent card 20 in place in the slot 10, comprising contacts 21 connected to the connectors K. This card 20 is provided with a wire 22 extending along the rear face of the card (on the opposite side to contacts 21 of the card) from outside the slot to a contact 21 connected to one of the connectors K.

 A fraud detector according to the invention comprises a slot 10 whose walls are made of a conductive material connected to the ground, and a high frequency generator 24 supplied by the lines VCC and VSS. The output of the generator 24 can be connected to each of the connectors K (or to at least one of the connectors which is essential for the operation of the card) by means of switches S controlled by a suitable circuit 11.

 In normal operation, as shown, the switches S connect the circuit 11 and the supply lines to the corresponding connectors K.

When a card is inserted into the slot 10, the circuit detects the presence of the card in a conventional manner, and switches the switches S so that the connectors K are connected to the output of the generator 24. This switching is carried out during a phase of sufficient duration to allow the detection of a fraudulent card.

With this configuration, if a metal part is introduced into the slot 10, such as the wire 22, a capacitive coupling is formed between this metal part and the earth. This coupling is represented by a stray parasitic capacitance Cp. While the connectors K are connected to the generator 24 during a detection phase, if a wire 22 connected to a connector K is present, the generator causes a leakage current i towards the earth, passing through the stray capacitance Cp linked to the presence of wire 22. This current i is reintroduced into the supply circuit of the public phone upstream on the telephone line, for example by virtue of the capacities C1 and
C2 of filter 14, connected to earth.

 In normal operation, that is to say in the absence of the leakage current i, the current I entering through one of the supply lines is equal to the current leaving through the other of the supply lines. When a leakage current i appears, passing according to the figure through the earth, a longitudinal current arises between the supply lines, that is to say that the leakage current i is distributed over the lines of supply of respective currents il and i2 in the same direction (both inbound or outbound).

 It is therefore sufficient to detect the presence of this longitudinal current in the supply lines to indicate the presence of a questionable phenomenon in the slot 10, such as the presence of a fraudulent card with wires.

For this, a longitudinal current detector 26 is provided, which must be arranged on the supply lines.
VCC and VSS, or, as shown, on the input lines of the bridge 12, downstream of the filter 14, that is to say downstream of the place where the leakage current i is reintroduced into the lines.

 The current detector 26 comprises, for example, two coils B1 and B2 respectively arranged in series on the input lines of the bridge 12. The coils B1 and B2 are magnetically coupled so that the fields which they generate are opposed. Thus, in normal operation, that is to say when the coils are each traversed by the same current I, the fields which they generate cancel each other out. A third coil B3, magnetically coupled to the coils B1 and B2, detects the field generated by these coils B1 and B2. This field is zero in normal operation and there is no induced voltage across the coil B3.

 When a longitudinal current occurs (leakage currents il and i2 flow respectively in the coils B1 and B2, in the same direction), a field appears which results in the birth of an induced voltage across the terminals of the coil B3. This voltage, which is alternative since the high frequency generator 24 is the origin thereof, is rectified by a rectifier circuit 28 and compared to a reference voltage Vref by a comparator 30. When the voltage across the terminals of the coil B3 exceeds the voltage Vref in absolute value, comparator 30 switches and provides an alarm signal AL. This AL alarm signal can be used in different ways to, for example, sound a ringtone, cut the power to the public phone ...

 The fact of using switches S which, during a detection phase, disconnect the supply lines from the connectors K, has the advantage that the wires of a fraudulent card cannot be shielded by a connected screen, by via a connector K, to one of the supply lines. Indeed, such a shielding would cause the leakage current i to flow from the generator to the screen (by capacitive coupling) and not to earth, which would not cause any longitudinal current in the supply lines.

 A person skilled in the art will be able to choose the voltage Vref appropriately so that a “normal” leakage current of low value, such as that generated by the permanent capacitive coupling between the connectors K and the slot 10, is not detected. It will also be able to modify the control circuit 11 to switch the switches S during a detection phase.

 In the example described of the card payphone, the presence of the EMC filter 14 and of the earth was exploited to reintroduce the leakage current i on the supply lines. If in another device there is no connection to earth or a filter 14, we can provide the device with capacities C1 and C2 arranged as shown in the figure and connect their connection point directly to the walls of the slot 10, which are then no longer connected to the ground.

 Many variants and modifications of the present invention will appear to those skilled in the art. For example, the rectifier 28 can be omitted and a flip-flop at the output of the comparator 30 can be provided to memorize the fact that the amplitude of an alternation supplied by the coil B3 exceeds the value Vref. One can also provide a high pass filter between the coil B3 and the rectifier 28 to consider only the current imbalances caused by a leakage current i of high frequency. Any other coupling means, such as capacitors, may be used to connect the connectors K to the output of the generator 24.

Claims (5)

 1. Fraud detection device for an apparatus operating with a smart card (20) intended to be inserted into a slot (10) provided with connectors (K), characterized in that it comprises  - an alternating signal generator (24) whose output is coupled, at least during a detection phase, to at least one of said connectors  - a slot (10) with walls of an electrically conductive material connected to at least one of the generator supply lines; and  - a detector (26, 28, 30) of longitudinal current in said supply lines, disposed between the connectors and the point of connection of said walls to said at least one supply line.  2. Device according to claim 1, characterized in that the walls of the slot (10) are connected to the earth, at least one of the supply lines being connected to the earth by a capacity (C1, C2).  3. Device according to claim 1, characterized in that the longitudinal current detector (26) comprises two coils (B1, B2) respectively arranged in series with said supply lines, these coils being connected so that the fields that they generate oppose, and a third coil (B3) magnetically coupled to said two coils and the terminals of which are connected to a circuit (28, 30) for detecting when a threshold is exceeded (Vref).  4. Device according to claim 2, characterized in that said generator supply lines (24) also supply, via a filter (14) comprising said capacity (C1, C2), two connectors (K) chip card supply and a chip control circuit (11).  5. Device according to claim 4, characterized in that it comprises switches (S) which, connect the connectors (K), either to the control circuit and to the supply lines, or to the output of the generator (24) during a detection phase.