WO2001082212A1 - Connection interface between two smart card readers and connection system between readers comprising same - Google Patents

Abstract

The invention concerns a connection interface (I) between at least two contact smart card readers, characterised in that it comprises means for connection (CxCP) to a smart card (CP) micromodule, connection means (CxA, CxB) to said readers and a switch (C) capable of alternately setting up a connection between said smart card (CP) micromodule and one of the readers, then between said card (CP) micromodule and another reader.

Description

CONNECTION INTERFACE BETWEEN SMART CARD READERS AND CONNECTION SYSTEM BETWEEN READERS INCLUDING A

SUCH AN INTERFACE

The invention relates to a connection interface between at least two smart card readers.

It also relates to a connection system comprising such an interface and at least two readers. The field of the invention is that of systems allowing a smart card to be connected to several smart card readers with contact.

The invention applies in particular to reader test systems, that is to say to the testing of terminals communicating with a smart card. We can cite as an example of such terminals, ATMs or payment terminals, in particular those that merchants present to us today when paying by bank card. These tests commonly comprise around 300 steps constituting a battery of tests.

Among these test systems is known a simulator shown in Figure 1 comprising an Sde probe connected to a device D itself connected to a PC computer. Once the Sde probe has been partially inserted into the terminal A to be tested, this simulator makes it possible to execute the battery of tests residing in the PC at once. But this system is expensive, not portable and cannot be used for testing terminals in which the chip card is fully inserted, such as ATMs.

Another solution represented in FIG. 2 consists in using a test card: it is a smart card CP personalized by a reader B connected to a computer PC in which the test battery resides.

It will be recalled that a smart card (s) comprises a microcircuit essentially comprising an input-output interface, a microprocessor, an operating program memory, for example ROM (“Read Only Memory” in English designating a read only memory). ), a memory of application programs (s), for example EEPROM (“Electrically Erasable Programmable Read Only Memory” in English, designating a read-only memory programmable by the user and erasable electrically), a working memory for example RAM (“ Random Access Memory "in English, designating a volatile random access memory).

The input-output interface is in the case of smart cards with contacts produced by an asynchronous reception or transmission unit and a connector generally comprising eight contact pads C1, ..., C8 flush with the card. Each of these contacts is assigned to a specific signal: C1 to the supply voltage signal denoted Vcc, C2 to the reset signal denoted RST, C3 to the clock signal denoted CLK, C5 to the electrical ground denoted GND, C6 at the voltage of programming noted Vpp, C7 at the serial data inputs and outputs, C4 and C8 being reserved for future needs.

In order to be able to transfer a step from the test battery from the reader B to the smart card CP, the CP card is inserted in the reader B. The connection to the reader B is established by the contacts and the data transfer takes place through the input-output contact (C7).

Once personalized, the CP card is manually inserted into terminal A so as to subject terminal A to the test. The connection is established as described for reader B.

However, the CP card does not contain the entire test battery, in particular due to the insufficient size of its memory. It could however contain for example ten tests but in this case, if the terminal rejects the card on the first of these ten tests, it is not known if the following tests are good. This is why in practice, we prefer to separate the tests. It is therefore necessary to carry out numerous manipulations around 300, each manipulation consisting in personalizing the CP card with one of the tests of the test battery and then manually inserting the CP card in the terminal A in order to test it. This solution is economical, allows you to take advantage of the portability of the CP test card but requires many manipulations.

The object of the invention is to propose an economical solution which does not require all these manipulations. The subject of the invention is a connection interface between at least two contact smart card readers, mainly characterized in that it comprises means for connection to a smart card micromodule, means for connection to said readers and a switch capable of alternately establishing a connection between said micromodule of the chip card and one of the readers then between said micromodule of the card and another reader.

According to a characteristic of the invention, the means of connection to the readers each comprise a connector provided with flush contact areas arranged on the interface so as to allow the partial insertion of the interface into the reading slot for smart cards. readers. According to one embodiment of the invention, the functional elements of one of the readers are integrated into the interface.

The smart card micromodule can also be integrated into the interface. It can itself be in a smart card.

The smart card can be fixed in the interface, or the interface comprising a slot for inserting a smart card, inserted in said slot.

According to another characteristic of the invention, one of the readers is able to control the switch.

More particularly, the connection means consisting of contacts each assigned to a signal specific, the switch is controlled by one of these specific signals.

This specific signal can be a supply voltage signal or a reset signal. The invention also relates to a connection system comprising an interface as described above and at least two readers, characterized in that one of the readers comprises an application program comprising subroutines capable of being transferred to the chip card micromodule as they run on the other reader.

According to a characteristic of the invention, the application is a test application for the other reader. According to another characteristic, the switch is controlled by the application.

Other features and advantages of the invention will appear clearly on reading the description given by way of nonlimiting example and with reference to the appended drawings in which:

FIG. 1 represents a simulator for testing smart card readers according to the state of the art,

FIG. 2 describes the use of a test card to carry out tests on readers according to another state of the art,

FIG. 3 shows the principle of the interface according to the invention, FIG. 4 a) represents the connections between the switch and the means of connection to the terminal, to the reader and to the smart card,

- Figure 4 b) highlights the two connection states of the interface,

- Figure 5 shows schematically the switch from one state to another,

- Figures 6 a), 6 b) and 6c) show three embodiments of the invention.

The interface I according to the invention shown in FIG. 3 is connected to a reader B and to a terminal A; it allows on the one hand to connect the smart card CP to which it is also connected, to a reader B used to personalize the CP card into a test card. This reader B is indeed connected to a PC computer in which the test battery resides. Different readers could be successively used to personalize the CP card.

The interface I also makes it possible to connect the test card CP to the terminal A to be tested.

As the CP test card is in relation with the two readers, a device is provided which makes it possible to avoid short-circuits: in fact, the signals usually used by smart cards (the supply voltage signal Vcc, ground GND, reset signal RST, clock signal CLK, programming voltage Vpp and I / O 10 in series of cannot be activated by reader B while terminal A transmits them.

To this end, the interface I comprises a switch C, means of connection CxB to the reader B, CxA to the terminal A and a location E intended to receive the smart card CP, this location E being provided with connection means CxCP to the CP smart card. These connection means CxA, CxB, CxCP can take the form of the connector comprising eight contact pads as described above. These connection means are interconnected via the switch C as described in Figure 4 a).

In operating mode, the interface I is connected to the smart card CP, to the reader B and to the terminal A but only two states are authorized by the switch C.

Initially, the switch C is in the state 1 represented in FIG. 4 b), that is to say the state establishing the connection between the CP card and the reader

B; the CP card and terminal A are no longer connected. Reader B can then personalize the CP card with a test of the test battery.

Once the personalization has been completed, the switch C then switches to state 2, that is to say the state establishing the connection between the card CP and the terminal A; the CP card and reader B are no longer connected. The personalized CP card can then carry out the corresponding test of terminal A. Once this test has been completed, the switch switches to state 1 to personalize the CP card with the next test step and so on until the whole battery of tests has been carried out. Switching the switch from one state to another can be done in several ways.

The switching from one state to another can be activated by one of the signals mentioned above and in particular the signal Vcc: in fact, this signal goes to 5 V at the start of the transaction and goes back down to 0 V at the end of the transaction. By transaction is meant the personalization of the PC card or the test of terminal A. The switch can thus be controlled by this signal according to the diagram shown in FIG. 5. When the level of the signal Vcc of the reader B goes from 5 to 0 V, the toggle switch from state 1 of personalization of the CP card to test state 2 of terminal A. Likewise when the signal level Vcc of terminal A goes from 5 to 0 V, the switch toggles from state 2 test of terminal A to state 1 of personalization of the CP card.

It can also be provided that the switch C systematically switches to state 1 as soon as the signal RST is activated. The switchover can also be activated by other signals than the signals mentioned above. Indeed, since the contacts C4 and C8 are not generally used by smart cards, we can envisage new signals assigned to these contacts C4 and C8 and use one to control the switching of the switch from one state to another.

Failover can also be predicted by the test software. Each personalization step of the CP card will include an end-of-personalization instruction consisting in switching the switch from the personalization state 1 of the CP card to the test state 2 of terminal A. Similarly, each test step will include a end of test instruction consisting in switching the switch from state 2 of test of terminal A to state 1 of personalization of the CP card.

Other methods are possible.

We will now describe three embodiments of the invention.

According to the first embodiment shown in FIG. 6 a), the interface I is independent of the terminal A, the reader B and the chip card CP. Before starting the test battery, the interface I in which the CP card is partially or totally inserted, is partly inserted in the reader B and partly inserted in the terminal A. The test battery can then start and run as previously described.

In a second embodiment, the functional elements of the reader B are integrated into the interface I.

The functional elements of reader B denote all of the hardware and software elements that allow it to operate, that is to say the reader stripped of its case. Before starting the test battery, it suffices to partially insert into the terminal A the interface I into which the CP card is partially or totally inserted. In the case where the terminal A to be tested operates with a total insertion of the chip card CP such as for example cash dispensers, the interface I cannot be used but its configuration allows the chip card CP to be used alone according to the procedure of figure 2 requiring manual manipulations. These first two embodiments have great adaptability to the various situations of terminals to be tested.

According to the third embodiment presented in FIG. 6 c), the smart card CP is integrated into the interface I as well as the reader B. The smart card CP can be replaced by its micromodule or by a card the size of the micromodule , the contact pads of said micromodule being in contact with the CxCP connections of the interface I. Before starting the test battery, it suffices to partially insert the interface I in the terminal A. This solution is the most compact three.

In all cases, the interface I comprises means of connection CxCP to a micromodule, whether the latter is alone or integrated in a support card. The card can be fixed in the interface I as we have seen or removable as in a conventional reader.

Claims

1. Interface (I) for connection between at least two contact smart card readers, characterized in that it comprises connection means (CxCP) to a smart card micromodule (CP), connection means ( CxA, CxB) to said readers and a switch (C) capable of alternately establishing a connection between said chip card micromodule (CP) and one of the readers then between said card micromodule (CP) and another reader.

2. Interface (I) according to the preceding claim, characterized in that the connection means (CxA, CxB) to the readers each comprise a connector provided with flush contact pads arranged on the interface

(I) so as to allow partial insertion of the interface (I) into the reading slot for smart cards of the readers.

3. Interface (I) according to one of the preceding claims, characterized in that the functional elements of one of the readers are integrated into the interface (D •

4. Interface (I) according to one of the preceding claims, characterized in that the chip card micromodule (CP) is integrated into the interface (I).

5. Interface (I) according to one of claims 1 to 3, characterized in that the smart card micromodule (CP) is in a smart card.

6. Interface (I) according to the preceding claim, characterized in that the smart card is fixed in one interface (I).

7. Interface (I) according to claim 5, characterized in that the interface (I) comprises a slot for inserting a smart card and in that the smart card is capable of being inserted in said slot .

8. Interface (I) according to one of the preceding claims, characterized in that one of the readers is capable of controlling the switch (C).

9. Interface (I) according to one of the preceding claims, the connection means consisting of contacts each assigned to a specific signal, characterized in that the control of the switch (C) is carried out by one of these specific signals.

10. Interface (I) according to the preceding claim, characterized in that the specific signal is a supply voltage signal.

11. Interface (I) according to claim 9, characterized in that the specific signal is a reset signal.

12. Connection system comprising an interface (I) according to one of the preceding claims and at least two readers, characterized in that one of the readers comprises an application program comprising subroutines capable of being transferred to the chip card micromodule (CP) as they are executed on the other reader.

13. Connection system according to the preceding claim, characterized in that the application is a test application for the other reader.

14. System according to one of claims 12 or 13, characterized in that the control of the switch (C) is carried out by the application.