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    • 专利摘要:
    The invention provides a system (SY) comprising a smart card (DV1) and a peripheral device (DV2) configured to cooperate together to allow the acquisition of a biometric fingerprint, the smart card (DV1) comprising: a sensor biometric fingerprints (10) and a control module for transmitting control signals (SG) to the peripheral device (DV2), each control signal (SG) being defined by a single level of an electrical characteristic; and in which, apart from a possible internal power source, the peripheral device (DV2) comprises only passive components, among which a user interface (20) configured to enter into a predetermined state in response to each control signal (SG) received, so as to guide a user in the acquisition of the biometric fingerprint by the biometric fingerprint sensor (10).
    公开号:FR3084942A1
    申请号:FR1857353
    申请日:2018-08-07
    公开日:2020-02-14
    发明作者:Nicolas Prawitz;Olivier LATRILLE;David Lucas;Sebastien Douche
    申请人:Idemia Identity and Security France SAS;
    IPC主号:
    专利说明:

    Invention background
    The present invention lies in the general field of electronic devices and relates more particularly to the acquisition of a biometric fingerprint using a smart card. The invention aims in particular to allow authentication of a user from a biometric fingerprint captured by a biometric fingerprint reader which is equipped with a smart card.
    The use of smart cards (or microcircuit cards) is widely used in everyday life today. Such cards are for example used as bank cards, loyalty cards, access cards etc., and can take various formats according to their respective uses. Smart cards can be designed to perform various types of functions, in particular for carrying out transactions, such as banking transactions (payment transaction, transfer transaction, etc.), authentication transactions, etc.
    In known manner, a smart card generally comprises a card body which is equipped with an electronic chip configured to process signals and perform various functions according to the desired use of the card. A smart card is also provided with communication means allowing the electronic chip to interact with the outside, for example with an external terminal or reader.
    Traditionally, a smart card is designed to cooperate with an external terminal through contact areas accessible on the surface of the card. An external terminal can thus position appropriate contact pins on the contact areas of the card in order to establish contact communication.
    More recently, contactless smart cards have experienced a growing boom due to the gain in speed and simplicity associated with contactless transactions. To do this, contactless cards have a radio frequency (RF) antenna for transmitting and receiving RF signals with an external terminal.
    A constant effort is made in the smart card industry to secure the transactions carried out by their users. EMV is for example the standardized protocol used today mainly in the world to secure in particular the payment transactions carried out by smart cards.
    A current trend is to secure transactions using biometric fingerprints of users, and in particular by means of their fingerprints.
    It is already known to equip a smart card with a fingerprint sensor in order to allow its user to authenticate. Acquiring fingerprints on such a reader embedded in the smart card however presents technical difficulties which it is necessary to overcome in order to allow the development of this new technology.
    Acquiring fingerprints on a smart card can seem complex or tedious for some users, especially for those who are not familiar with this type of technology. It is therefore necessary to guide the user through the process of acquiring the fingerprint.
    However, current smart cards generally do not have internal means to communicate directly with users and are therefore not able to guide them in the process of capturing the fingerprint.
    In addition, the integration of increasingly numerous and complex components in smart cards is problematic, in particular it makes smart cards more fragile and more prone to failures. Chip cards, such as bank cards or access badges for example, must generally have certain minimum characteristics in terms in particular of mechanical strength and robustness.
    An additional problem may arise from the need to power an on-board fingerprint sensor electrically on a chip card, the latter being generally devoid of an internal power source.
    There is therefore today a need for a simple and easy-to-use solution allowing the acquisition of biometric fingerprints (such as fingerprints for example) using a smart card and this, without compromising in particularly the robustness and mechanical characteristics of the smart card.
    It is particularly desirable to guide users so that they can easily take a biometric fingerprint capture using a smart card without this requiring complex modifications of current smart cards or in-depth knowledge of from users.
    Subject and summary of the invention
    To this end, the present invention relates to a system comprising a smart card and a peripheral device configured to cooperate together to allow the acquisition of a biometric fingerprint, the smart card and the peripheral device being separated one from the other, the smart card comprising:
    - a biometric fingerprint sensor configured to acquire a biometric fingerprint; and
    - a control module configured to transmit at least one control signal to the peripheral device, each control signal being defined by a single level of an electrical characteristic;
    in which the peripheral device comprises, apart from at least one possible internal power source, only passive components, among which:
    a user interface configured to enter a predetermined state in response to each control signal received, so as to guide a user in the acquisition of the biometric fingerprint by the biometric fingerprint sensor.
    The invention is advantageous in that it offers a simple and easy-to-use solution for the acquisition of biometric fingerprints from a smart card, without compromising in particular the robustness and the mechanical characteristics of the Smartcard. In fact, the user interface is embedded in a peripheral device which can advantageously be selectively coupled with the smart card. The smart card can be decoupled from the peripheral device when the latter is not useful, thus preserving the user interface from possible failures in the event of mechanical stresses (twists, shocks, falls, etc.) applied to the smart card. .
    The invention allows users to be guided so that they can easily take a biometric fingerprint capture from their smart card without requiring complex modifications of current smart cards or in-depth knowledge on the part of users. .
    According to a particular embodiment, the user interface is configured to present, in each predetermined state, respective information guiding a user in the acquisition of said biometric fingerprint by the biometric fingerprint sensor.
    According to a particular embodiment, the electrical characteristic is one of: a voltage, a current and a frequency.
    According to a particular embodiment, the peripheral device does not include any active processing means capable of interpreting any command coming from the smart card.
    According to a particular embodiment, the smart card comprises:
    a memory for storing said biometric fingerprint as a reference biometric fingerprint, once it has been acquired by the biometric fingerprint sensor; and
    - An authentication module configured to authenticate said user from a comparison of the reference biometric fingerprint and another biometric fingerprint acquired subsequently.
    According to a particular embodiment, the smart card comprises:
    - a memory for storing said biometric fingerprint, once it has been acquired by the biometric fingerprint sensor; and
    an authentication module configured to authenticate said user on the basis of a comparison of the acquired biometric fingerprint and of pre-recorded fingerprint data as a reference biometric fingerprint.
    The invention advantageously makes it possible to authenticate a user by comparing a biometric fingerprint acquired with other fingerprint data, and this without it being necessary to remove these data from the smart card. The data representative of the biometric fingerprints captured using the biometric fingerprint sensor can advantageously be stored securely in a memory of the smart card.
    According to a particular embodiment, the peripheral device comprises a battery for electrically supplying the user interface.
    According to a particular embodiment, the user interface is configured to:
    - go into a first predetermined state in response to a first control signal received from the smart card, so as to indicate the start of a phase of acquisition of a biometric fingerprint by the biometric fingerprint sensor ;
    - go into a second predetermined state in response to a second control signal received from the smart card, so as to indicate that a biometric fingerprint is being acquired; and
    - enter a third predetermined state in response to a third control signal received from the smart card, so as to indicate that the phase of acquisition of the biometric fingerprint is completed, in which the first, second and third control signals are distinct from each other.
    According to a particular embodiment, the user interface is configured to:
    - switch between two predetermined states at a first frequency in response to a series of first control signals received from the smart card, so as to indicate the start of a phase of acquisition of a biometric fingerprint by the sensor biometric fingerprints;
    - switching between two predetermined states at a second frequency in response to a series of second control signals received from the chip card, so as to indicate that a biometric fingerprint is being acquired; and
    - go into a third predetermined state in response to a third control signal received from the smart card, so as to indicate that the phase of acquisition of the biometric fingerprint is completed, in which the first and second frequencies are distinct from each other, and the third signal is distinct from the first and second signals.
    According to a particular example, the first and second control signals are identical (same single level of an electrical characteristic) and are emitted at separate emission frequencies (in other words, the first frequency and the second frequency are different one the other).
    According to a particular embodiment, the user interface comprises a first LED and a second LED distinct from each other, the control module being configured to transmit to the peripheral device, as control signal:
    - a ground voltage to light only the first LED among the two LEDs; and
    - a voltage at a predetermined high level, greater than ground, to light only the second LED among the two LEDs.
    According to a particular embodiment, the smart card is a card comprising external contacts, conforming to the ISO 7816 standard, for transmitting by contact each control signal to the peripheral device.
    According to a particular embodiment, the smart card is configured to transmit each control signal via the external contact C4, C6 or C8 within the meaning of the ISO 7816 standard.
    According to a particular embodiment, the smart card is configured to transmit each control signal via a contact among the external contacts C2, C3 and C7 within the meaning of standard ISO 7816, in which the smart card is configured to switch between :
    - A first operating mode in which the smart card uses said contact among the external contacts C2, C3 and C7 within the meaning of the ISO 7816 standard to carry out ISO 7816 type communication with an external terminal; and
    - a second operating mode in which the smart card uses said contact among the external contacts C2, C3 and C7 within the meaning of standard ISO 7816 to transmit each control signal to the peripheral device;
    the smart card including:
    a verification module configured to verify, at the start of the smart card, at least one signal level among the RST signal detected on the external contact C2 within the meaning of the ISO 7816 standard, the CLK signal detected on the external contact C3 within the meaning of ISO 7816 and the supply signal VCC detected on the external contact Cl within the meaning of ISO 7816; and
    a configuration module configured to switch the smart card, either in the first operating mode or in the second operating mode, as a function of said at least one signal level detected among the RST signal, the CLK signal and the VCC signal .
    According to a particular embodiment, the smart card is a payment card.
    According to a particular embodiment, the peripheral device is a case in which the smart card is inserted to allow the transmission of said at least one control signal from the control module to the peripheral device.
    According to one embodiment, the invention is implemented by means of software and / or hardware components. In this context, the term "module" can correspond in this document to a software component, a hardware component or a set of hardware and software components.
    A software component corresponds to one or more computer programs, one or more subroutines of a program, or more generally to any element of a program or of software capable of implementing a function or a set of functions, as described in this document for the module concerned.
    In the same way, a hardware component corresponds to any element of a hardware assembly (or hardware) capable of implementing a function or a set of functions, according to what is described in this document for the module concerned. It may be a programmable hardware component or with an integrated processor for executing software, for example an integrated circuit.
    The invention also relates to the smart card as defined above, configured to cooperate with a peripheral device within the meaning of the invention.
    The invention also relates to a corresponding control method implemented by a system as defined above.
    More particularly, the invention relates to a control method implemented by a system comprising a smart card and a peripheral device cooperating together to allow the acquisition of a biometric fingerprint, the smart card and the peripheral device being separated. one from the other, the smart card comprising a biometric fingerprint sensor and the peripheral device comprising, apart from at least one possible internal power source, only passive components among which a user interface, in which the process includes:
    acquisition of a biometric fingerprint by the biometric fingerprint sensor;
    transmission, from the smart card to the peripheral device, of at least one control signal, each control signal being defined by a single level of an electrical characteristic; and configuring the user interface in a predetermined state in response to each control signal received, so as to guide a user in the acquisition of the biometric fingerprint by the biometric fingerprint sensor.
    Note that the various embodiments defined above in relation to the system of the invention as well as the associated advantages apply analogously to the control method of the invention. For each step of the control process, the system of the invention may include a corresponding module configured to carry out said step.
    The invention also relates to the control method implemented more specifically by a smart card as defined above, within the framework of the control method implemented by the system of the invention.
    In a particular embodiment, the different steps of the control method implemented by the smart card are determined by instructions from computer programs.
    Consequently, the invention also relates to a computer program on an information medium (or recording medium), this program being capable of being implemented in a smart card, this program comprising instructions adapted to the implementation of the steps of a control process as defined above.
    This program can use any programming language, and be in the form of source code, object code, or intermediate code between source code and object code, such as in a partially compiled form, or in any other desirable form.
    The invention also relates to an information medium (or recording medium) readable by a computer, and comprising instructions of a computer program as mentioned above.
    The information medium can be any entity or device capable of storing the program. For example, the support may include a storage means, such as a ROM, for example a CD ROM or a microelectronic circuit ROM, or else a magnetic recording means, for example a floppy disc or a disc. hard.
    On the other hand, the information medium can be a transmissible medium such as an electrical or optical signal, which can be routed via an electrical or optical cable, by radio or by other means. The program according to the invention can in particular be downloaded from a network of the Internet type.
    Alternatively, the information medium can be an integrated circuit in which the program is incorporated, the circuit being adapted to execute or to be used in the execution of the process in question.
    Brief description of the drawings
    Other characteristics and advantages of the present invention will emerge from the description given below, with reference to the accompanying drawings which illustrate exemplary embodiments thereof without any limiting character. In the figures:
    - Figure 1 schematically shows a system comprising a smart card and a peripheral device, in accordance with an embodiment of the invention;
    - Figure 2 is a general perspective view showing a system as illustrated in Figure 1, in accordance with an embodiment of the invention;
    - Figure 3 shows schematically the functional modules implemented by a smart card belonging to a system of the invention, according to a particular embodiment;
    - Figure 4 shows, in the form of a diagram, the steps of a control method implemented by a system of the invention, in accordance with a particular embodiment;
    - Figure 5 shows a contact communication interface of a smart card belonging to a system of the invention, in accordance with a particular embodiment;
    - Figure 6 shows schematically, in the form of a diagram, the steps of a control method implemented by a smart card belonging to a system of the invention, in accordance with a particular embodiment;
    - Figure 7 is an electrical diagram schematically representing a circuit implemented in the system of the invention, according to a particular embodiment; and
    - Figure 8 schematically shows a configuration of the control signals according to a particular embodiment.
    Detailed description of several embodiments
    The invention applies generally to the acquisition of biometric fingerprints from a chip card (or microcircuit card) in which a biometric fingerprint sensor is on board. This acquisition phase, which can be carried out at different stages as explained below, can in particular allow a user to authenticate on the basis of his biometric fingerprint.
    In this document, examples of implementation of the invention are described in the context of chip cards conforming to ISO 7816 standard, other implementations being however possible for chip cards not conforming to ISO 7816.
    In addition, the examples of implementation described below apply more particularly to the case of the acquisition of fingerprints. As indicated below, the invention can be applied to other types of biometric fingerprints.
    The invention relates in particular to the acquisition of biometric fingerprints from an EMV chip card (for "Europay Mastercard Visa"), that is to say configured to process transactions according to the EMV protocol. Other implementations of the invention are however possible without adopting the EMV protocol.
    The invention applies in particular to smart cards such as bank cards or payment cards, but also to all other suitable types such as access cards, authentication cards or loyalty cards, for example.
    The invention proposes to guide the user in a simple and effective manner during an acquisition phase (or capture phase) of one or more biometric fingerprints using a biometric fingerprint sensor embedded in a smart card. . To do this, the invention, according to different embodiments, implements a system comprising a smart card and a peripheral device, these two elements being separated from each other and being configured to couple one with the other to allow the acquisition of one or more biometric fingerprints while effectively guiding the user during the fingerprint capture process.
    To this end, the smart card has a biometric fingerprint sensor while the peripheral device has a user interface configured to be controlled remotely by the smart card. When these two elements are coupled, the smart card is configured to transmit control signals to the peripheral device so that the user interface of the latter presents the user with useful information relating to the capture of one or more biometric fingerprints. on the smart card.
    The peripheral device comprises, apart from at least one possible internal power source, only passive components, including the user interface, so that the control signals emitted from the smart card directly control the state in which is the user interface at a given time.
    The removable nature of the smart card vis-à-vis the peripheral device has the advantage that the coupling between these two elements can only be achieved during an acquisition phase of one or more biometric fingerprints. The peripheral device can be decoupled from the smart card, so that the latter can be used in other applications, such as for example for carrying out a transaction or communication (of ISO 7816 type for example) with an external terminal.
    By thus deporting the user interface to a removable peripheral device, it is possible to ensure that the smart card retains good mechanical properties in terms in particular of robustness and resistance to mechanical stresses (twists, falls, etc.).
    The invention also relates to the smart card itself, to the peripheral device itself, and to a control method implemented by each of these elements taken in isolation, and by the system taken as a whole.
    As described below, the biometric fingerprint or fingerprints acquired in the context of the invention can have several possible uses. During an initial acquisition phase (called the “enrollment phase”), it may be necessary to capture at least one biometric fingerprint to acquire a reference biometric fingerprint to which a user fingerprint is subsequently compared. acquired later to authenticate the latter, for example as part of a transaction being processed. In general, this enrollment phase is carried out only once during an initial configuration (personalization) of the smart card.
    Furthermore, during an acquisition phase subsequent to the initial enrollment phase, the invention makes it possible to acquire a biometric fingerprint which can be compared to a biometric fingerprint prerecorded in the smart card as a fingerprint. reference, in order to authenticate a user.
    Other aspects and advantages of the present invention will emerge from the exemplary embodiments described below with reference to the drawings mentioned above.
    Unless otherwise indicated, the elements common or analogous to several figures bear the same reference signs and have identical or analogous characteristics, so that these common elements are generally not described again for the sake of simplicity.
    Figures 1 and 2 schematically represent the structure of a system SY comprising: a smart card DV1 and a peripheral device DV2, these two elements being distinct (separate) from each other and configured to cooperate together, that is to say to couple with each other, in order to allow the acquisition of a biometric fingerprint (in this example a fingerprint).
    The coupling and decoupling of the smart card DV1 with the peripheral device DV2 can be carried out selectively, that is to say on demand. The peripheral device DV2 can be removably coupled to the smart card DV1 when a user wishes to capture a fingerprint.
    The coupling between the smart card DV1 and the peripheral device DV2 can be achieved in various ways, and in particular by contact or without contact as the case may be. In the present case, this coupling results in the establishment of a communication link L1 between the chip card DV1 and the peripheral device DV2, this link being a contact link in the examples shown in FIGS. 1 and 2.
    The peripheral device DV2 can take various forms. FIG. 2 represents a nonlimiting exemplary embodiment in which the peripheral device DV2 takes the form of a case in which the smart card DV1 is inserted to achieve coupling by contact. To do this, the case has a cavity configured to accommodate the smart card so that, once inserted, the smart card can control the user interface of the case (as described below).
    Other forms of coupling, by contact or without contact, are however possible.
    As shown in Figures 1 and 2, the smart card DV1 comprises in the example envisaged here external contacts 2, a processor 4, a non-volatile memory 6, a volatile memory (RAM) 8 and a sensor (or reader) 10 fingerprints.
    In this example, the DV1 chip card complies with ISO 7816 standard, although other examples are possible. The DV1 chip card is for example a payment card (or bank card), of the EMV type or other.
    The external contacts (or contact pads) 2, conforming in this example to the ISO 7816 standard, constitute a communication interface allowing the smart card DV1, and more particularly to the processor 4, to transmit by control control signals SG to the peripheral device DV2, in order to remotely control the user interface 20 of the latter.
    As described below, at least one external contact (Cl to C8) within the meaning of ISO 7816-2 can be used by the smart card DV1 to transmit the control signal (s) SG to the peripheral device DV2. In this way, the DV1 chip card can advantageously drive the DV2 peripheral device without this requiring structural modifications to the DV1 chip card.
    As already indicated, the smart card DV1 can alternatively cooperate without contact with the peripheral device DV2, for example via an NFC link. To do this, the DV1 smart card can include a radio frequency (RF) antenna, not shown in the figures.
    The memory 6 is a rewritable non-volatile memory (of the Flash type for example), this memory constituting a recording medium (or information medium) conforming to a particular embodiment, readable by the smart card DV1, and on which is recorded a computer program PG1 according to a particular embodiment. This computer program PG1 includes instructions for the execution of the steps of a control method, these steps being executed by the processor 4 of the smart card DV1.
    The non-volatile memory 6 is further able to store a fingerprint PR1 acquired or detected by the fingerprint sensor 10 and also to store fingerprint data DTI which represents a reference fingerprint to which the fingerprint PR1 is compared. to authenticate a UR user (Figure 2).
    As already indicated, the sensor 10 is configured to acquire (capture) a fingerprint. To do this, this sensor 10 is accessible from the surface of the smart card DV1 so that a user can affix his finger to it and thus carry out a capture of a fingerprint.
    In this document is meant by capture (or acquisition) of a fingerprint, the acquisition of biometric data representative of a fingerprint. More generally, the term capture (or acquisition) of a biometric fingerprint is understood to mean the acquisition of biometric data representative of this fingerprint.
    In the example shown in FIG. 2, the DV1 chip card comprises an electronic module 30 which includes the external contacts 2 accessible on the surface of the DV1 chip card and which also comprises an electronic chip (not shown) in which finds processor 4 (Figure 1). The processor 4 controls the fingerprint sensor 10 through an appropriate communication link (bus).
    It will be noted that the smart card DV1 has no user interface so that it does not have means capable of guiding a user UR during a phase of acquiring a fingerprint.
    Furthermore, as shown in FIGS. 1 and 2, the peripheral device DV2 comprises in this example a user interface 20, a communication interface 22 and, optionally, an internal power source (or battery) 24.
    The peripheral device DV2 comprises, apart from at least one possible internal power source (a battery for example), only passive components, among which the aforementioned user interface 20. As well known to those skilled in the art, a component is said to be “passive” when it does not make it possible to increase the power of a signal. A passive component can be, for example, a resistor, a capacitor, a coil, a diode (for example a light-emitting diode also known by the abbreviation Anglo-Saxon LED), etc., as well as any assembly of these passive components.
    In other words, in a particular example, the peripheral device DV2 does not include an internal power source and therefore comprises only passive components, among which the user interface 20.
    According to another example, the peripheral device DV2 comprises at least one internal power source (a battery for example). In this case, apart from this or these internal power sources, the peripheral device DV2 only comprises passive components, including the user interface 20.
    It follows that the peripheral device DV2 does not include a component called "active" (that is to say capable of increasing the power of a signal) other than one or possible internal power sources. In particular, the peripheral device DV2 does not include any active processing means capable of interpreting (in the software sense) any command originating from the smart card.
    In the examples considered here, the peripheral device DV2 does not include a processor or memory.
    As indicated below, it is thus possible to provide a remote user interface vis-à-vis the DV1 smart card, and this with a minimum of complexity as to the resources necessary to implement the peripheral device, and more generally the system according to the principle of the invention.
    The user interface 20 makes it possible to guide a user UR during the acquisition (or capture) phase of a fingerprint by the sensor 10 of the smart card DV1. To do this, the user interface is configured to present, in any suitable form, useful information relating to the capture of a fingerprint by the sensor 10. The user can thus find his way in the acquisition phase of one or more fingerprints and easily determine what to do.
    In the context of the invention, the term “user interface” means any means or component capable of presenting to a UR user information relating to the capture of one or more biometric fingerprints from the sensor 10. The information thus provided can be visual, auditory, vibratory or any other suitable form.
    The user interface 20 can for example comprise at least one indicator light, namely two indicator lights 20a and 20b in the case shown in FIGS. 1 and 2. In this example, these indicator lights are LEDs. The indicators 20a and 20b, of respective red and green colors for example, make it possible to display information relevant to the user UR.
    According to a particular example, the user interface 20 may comprise a display screen capable of displaying information making it possible to guide the user UR in taking his fingerprint on the sensor 10.
    The peripheral device DV2 can possibly also include at least one control means (button, switch, detector, etc.) allowing the UR user to send an instruction to the peripheral device DV2 and / or to the smart card DV1 through of the peripheral device DV2.
    The communication interface 22 allows the peripheral device DV2 to receive at least one control signal SG transmitted by the smart card DV1.
    As described below, each control signal SG emitted by the smart card DV1 is defined by a single level of an electrical characteristic. In this example, “electrical characteristic” means one of the following parameters: a voltage, a current, and a frequency. In other words, each control signal SG has a single voltage level, a single current level, or a single frequency level. This single signal level is fixed by the processor 4 of the smart card DV1 so as to trigger the presentation (by display in this example) of predetermined information on the user interface 20 of the peripheral component DV2.
    As already indicated, the peripheral device 22 does not include a processor capable of interpreting any command coded in a computer language, which could come from the chip card DV1. As described later in specific examples, the control signals SG emitted by the smart card DV1 can each be in the form of an analog pulse (in voltage, current, or frequency) to force the user interface 20 in a predetermined state.
    In a particular example, the processor 4 transmits control signals SG in the form of a voltage, current or frequency modulation.
    The user interface 20 is configured to go into a predetermined state in response to each control signal SG received, so as to guide a user UR in the acquisition of a fingerprint by the sensor 10 of fingerprints. In the example considered here, each predetermined state of the user interface 20 corresponds to a global state [indicator state 20a, indicator state 20b] representative of the combined states of the indicator lights 20a and 20b (each being on or off at a given instant ).
    For example, in a particular state of the user interface 20, the indicator light 20a is on while the indicator light 20b is off. According to another example of state of the user interface 20, the indicator light 20a is off while the indicator light 20b is on. According to yet another example of state of the user interface 20, the indicator lights 20a and 20b are lit simultaneously.
    The user interface 20 is configured to present, in each predetermined state, respective information guiding a user UR in the acquisition of a fingerprint by the fingerprint sensor 10. The user interface 20 can be configured to switch between different states, for example so as to alternate between a first state and a second state at a given frequency, in order to present particular information to the user. Examples of implementation are described later.
    The user interface 20 allows for example to indicate to a user UR that a phase for acquiring a fingerprint is initiated (thus inviting the user to place his finger on the sensor 10), makes it possible to indicate that 'a fingerprint is being read, or can indicate that a fingerprint has been acquired (thus ending the fingerprint acquisition phase).
    In the example represented in FIGS. 1 and 2, each control signal SG has a direct effect on the state (on / off) of each indicator light 20a, 20b of the user interface 20, insofar as the peripheral device DV2 only includes passive components (apart from a possible internal power source as already indicated). No software interpretation of the control signals is carried out by the peripheral device DV2 which, as already indicated, does not have a processor.
    As shown in Figures 1 and 2, the peripheral device DV2 can also include a battery 24 (or any other suitable internal power source) configured to electrically supply the user interface 20 and possibly the smart card DV1, although the presence of such a battery in the peripheral device DV2 is not compulsory. According to another embodiment, it is for example the DV1 smart card which includes an internal power source (a battery) configured to electrically power its internal components (processor 4, sensor 10, etc.) as well as the user interface 20 embedded in the peripheral device DV2. According to another variant, the smart card DV1 and the peripheral device DV2 each comprise an internal battery.
    Note that the SY system shown in Figures 1 and 2 is only an exemplary embodiment, other implementations being possible within the framework of the invention. A person skilled in the art understands in particular that certain elements of the smart card DV1 and of the peripheral device DV2 are only described in this document to facilitate understanding of the invention, these elements not being compulsory for implementing the invention. 'invention.
    FIG. 3 schematically represents, according to a particular embodiment, the functional modules implemented by the processor 4 controlled by the computer program PG1, namely: an acquisition module ML2, a control module ML4, and possibly an ML6 authentication module, an ML8 verification module and / or an ML10 configuration module.
    The acquisition module ML2 is configured to acquire (or read) a fingerprint PR1 using the sensor 10 for fingerprints. This PR1 fingerprint takes the form of biometric data representative of a fingerprint. To do this, the acquisition module can recover data measured by the sensor 10 and generate, from these measured data, a fingerprint PR1 by any appropriate processing.
    The memory 6 is able to store the fingerprint PR1 thus acquired.
    The control module ML4 is configured to transmit at least one control signal SG to the peripheral device DV2, in order to remotely control the user interface 20. As already indicated, each control signal SG emitted by the control module ML4 is defined by a single level of an electrical characteristic (voltage, current or frequency). In the example shown in FIGS. 1 and 2, the control signals SG are transmitted via the external contacts 2.
    The authentication module ML6 is configured to authenticate a user from a comparison between the fingerprint PR1 acquired through the sensor 10 and the data of another fingerprint DTI. In the event of a match detected between the biometric data PR1 and DTI, the authentication is positive.
    As indicated below, this other fingerprint DTI can be acquired subsequently to the fingerprint PR1, so that the authentication module ML6 checks the validity of this other fingerprint DTI by comparing it with the fingerprint PR1 serving as reference fingerprint.
    According to another example, this other fingerprint DTI can be prerecorded in the memory 6 as a reference fingerprint, before acquisition of the fingerprint PR1. The authentication module ML6 then checks the validity of the fingerprint PR1 by comparing it to the fingerprint DTI serving as a reference.
    The verification module ML8 is configured to check, at the start of the smart card DV1, a level of a signal (RST or CLK for example) detected on a predetermined external contact 2 (C2 within the meaning of standard ISO 7816, by example).
    As described later in a particular embodiment, the configuration module ML10 is configured to switch the smart card DV1, either in a first operating mode or in a second operating mode, depending on said signal level detected by the module ML8 verification. Switching between these two operating modes allows the DV1 smart card to use the same external contact 2 for two different uses, namely: either for conventional use, for example for carrying out ISO 7816 communication (for example as standardized in the IOS7616-3 and / or ISO7816-4 standards) with an external terminal, either to transmit at least one control signal SG to the peripheral device DV2 according to the principle of the invention, so as to control the user interface 20 and thus allowing a user to be guided during a fingerprint capture process.
    The operation and configuration of the modules ML2-ML10 of the smart card DV1 will appear more precisely in the exemplary embodiments described below.
    It will be understood that the modules ML2-ML10 as shown in FIG. 3 only represent an example of non-limiting implementation of the invention.
    A control method, implemented by the SY system described above with reference to Figures 1-3, is now described with reference to Figure 4, in accordance with a particular embodiment of the invention. More particularly, the smart card implements a control method by executing the computer program PG1.
    It is assumed that a user UR (FIG. 2) wishes to acquire a fingerprint using the sensor 10 on board the smart card DV1. Such a capture may in particular be necessary to authenticate the user, for example during a transaction such as a payment transaction (of EMV type or other) for example, or even to obtain access to a service or to a secure place.
    During a preliminary step CPI, it is assumed that the smart card DV1 and the peripheral device DV2 are coupled together so that they can cooperate to carry out the control method of the invention. This CPI coupling results in the establishment of a communication link L1, by contact in this example, between the smart card DV1 and the peripheral device DV2 (FIG. 1).
    As shown in FIG. 2, it is assumed for example that this coupling is carried out by inserting the smart card DV1 into the peripheral device DV2 here taking the form of a case. This coupling makes it possible to bring the external contacts 2 of the smart card DV1 into contact with the communication interface 22 of the peripheral device DV2. As already indicated, other types of coupling (in particular contactless) are however possible.
    During a detection step A2 (FIG. 4), the smart card DV1 detects the initiation of a phase for acquiring a fingerprint. This detection can result from the CPI coupling carried out or possibly in response to another predefined event.
    The smart card DV1 then sends (A4) to the peripheral device DV2 at least a first control signal SGI. In this example, the smart card DV1 sends (A4) a series of first control signals SGI which can be in the form of pulses in voltage, at a first transmission frequency denoted f1. Each pulse (represented in the form of a slot in FIG. 4) has the same peak voltage corresponding to a high level denoted H (greater than the mass). The first SGI control signals therefore each have a single voltage level denoted H, making it possible to force the user interface 20 into a first state E1, described below.
    The peripheral device DV2 receives the first control signals SGI during a reception step B4. Each of the first control signals SGI forces the user interface 20 into the aforementioned first state El. In this example, in state E1, the user interface 20 is such that the first indicator light 20a is on while the second indicator light 20b remains off. In the periods of inactivity between each first SGI control signal received, the user interface 20 is in an idle state E0 in which the indicator lights 20a and 20b are off.
    The user interface 20 reacts (B6) thus by the flashing of the first indicator light 20a synchronously with the series of first control signals SGI received here in the form of electrical pulses at the frequency f1, while the second indicator lights 20b remains off.
    In response to the first SGI control signals, the user interface therefore switches between the states E0 and El at the first frequency f1 so as to indicate the start of a phase for acquiring a fingerprint by the sensor 10 fingerprints. This alternation between the states E0 and El at the frequency fl thus invites the user UR to place his finger on the sensor 10 in order to acquire a fingerprint.
    During a determination step A8, the smart card DV1 determines whether it detects the presence of a finger on the sensor 10. If so, the method proceeds to the sending step A10 during which the smart card DV1 transmits at least one second signal SG2 to the peripheral device DV2. In this example, the smart card DV1 sends (A10) a series of second control signals SG2 which may be in the form of voltage pulses, at a second transmission frequency denoted f2.
    In this example, the second control signals SG2 are identical to the first control signals SGI in the sense that these control signals all have the same single voltage level but are transmitted at different transmission frequencies (fl Ψ f2). Other implementations are however possible where the first and second signals SGI and SG2 are different from the fact that they have different voltage levels.
    Still in this example, the second frequency f2 is greater than the first frequency f1 although the reverse is possible. Each pulse (represented in the form of a slot in FIG. 4) has the same peak voltage corresponding to the aforementioned high level H. The second control signals SG2 therefore each have a single voltage level denoted H, making it possible to force the user interface 20 into the first predetermined state El already described above.
    The peripheral device DV2 receives the second control signals SG2 during a reception step B10. Each of the second control signals SG2 forces the user interface 20 into the aforementioned first state El (indicator light 20a on and indicator light 20b off). In the periods of inactivity between each second control signal SG2 received, the user interface 20 is in a state E0 of rest in which the indicator lights 20a and 20b are off.
    The user interface 20 reacts thus (B12) by the flashing of the first indicator light 20a synchronously with the series of second control signals SG2 received here in the form of electrical pulses at the frequency f2, while the second indicator light 20b remains off. Also, the flashing light 20a takes place at a frequency higher than the flashing frequency of step B6 (f2> fl).
    In response to the second control signals SG2, the user interface 20 therefore switches between the states E0 and El at the second frequency f2 so as to indicate that a fingerprint PR1 is being acquired. This alternation between the states
    E0 and El at the frequency f2 therefore invites the user UR to hold his finger on the sensor 10 until the fingerprint capture is completed.
    During a determination step A14, the smart card DV1 determines whether the fingerprint PR1 of the user UR has been acquired. More precisely, during this acquisition, the smart card DV1 acquires biometric data representative of the fingerprint PR1. If the fingerprint PR1 is acquired (A14), the method proceeds to the sending step A16 during which the smart card DV1 transmits at least a third signal SG3 to the peripheral device DV2. In this example, the smart card DV1 sends (A16) a third control signal SG3 which is maintained for a predetermined period of time denoted t1. This third control signal SG3 is here a signal to ground, and therefore has a single low voltage level denoted L, making it possible to force the user interface 20 into a second predetermined state E2, described below.
    The peripheral device DV2 receives the third control signal SG3 during a reception step B16. This third control signal SG3 forces the user interface 20 into the aforementioned second state E2. In this example, in state E2, the user interface 20 is such that the first indicator light 20a is off while the second indicator light 20b is on. Since the third control signal SG3 is here emitted continuously for a period of time tl, the indicator light 20b is kept lit continuously during this period of time tl.
    In response to the third control signal SG3, the user interface 20 is put (is configured) in the second predetermined state E2 so as to indicate that the phase of acquisition of the fingerprint PR1 is finished. This second state E2 therefore invites the user UR to withdraw his finger from the sensor 10, and possibly, to decouple the smart card DV1 from the peripheral device DV2.
    In the example described here, the signal or signals SG transmitted to trigger each respective state of the user interface are different (since the states E1 and E2 are different from each other).
    At the end of the sending step A16, the fingerprint acquisition phase is completed.
    The chip card DV1 can then record (A20) the fingerprint PR1 thus acquired in its non-volatile memory 6. This fingerprint PR1 can thus be consulted later by the chip card DV1 for a use which may vary according to the case.
    The smart card DV1 can thus authenticate (A22) the user UR from a comparison of the fingerprint PR1 acquired with another fingerprint. If the smart card DV1 detects that there is a correspondence between the fingerprint PR1 and the data of another fingerprint DTI, it determines that the authentication of the user UR has passed successfully.
    More particularly, in a first particular example, the fingerprint PR1 is recorded as a reference fingerprint in the memory 6 (step A20). In this case, the capture of the reference fingerprint PR1 is carried out during an enrollment phase, for example during an initial configuration (personalization) of the smart card DV1. During the authentication step A22, the smart card DV2 authenticates the user UR (FIG. 2) from a comparison of the reference fingerprint PR1 and another fingerprint DTI acquired subsequently in using the sensor 10. The smart card DV1 checks the validity of the subsequent fingerprint DTI by comparing it with the reference fingerprint PR1. The fingerprint PR1 can thus be used as a reference fingerprint to authenticate the user UR during subsequent uses of the smart card DV1, for example during transactions, such as bank transactions (payment transaction , transfer ...) or authentication transactions.
    In a second particular example, the fingerprint PR1 is recorded in step A20 in the memory 6. Then, the smart card DV1 authenticates the user UR on the basis of a comparison of the acquired fingerprint PR1 and DTI fingerprint data prerecorded in memory 6 as a reference fingerprint. In this case, the DTI reference fingerprint can be acquired and recorded by the DV1 smart card, during an enrollment phase prior to the acquisition of the PR1 fingerprint.
    The user could also use the invention to acquire several fingerprints and / or several acquisitions of the same fingerprint. The implementation of steps A2 to A22, and B4 to B18 can therefore be repeated with the presentation by the user UR of a finger at each iteration. Thus, in a particular implementation mode, the smart card DV1 can also send a fourth control signal SG to the peripheral device DV2 to put the interface 20 in a third predetermined state, for example so as to indicate the number d 'fingerprints registered.
    The invention is advantageous in that it offers a simple and easy-to-use solution for the acquisition of biometric fingerprints from a smart card, without compromising in particular the robustness and the mechanical characteristics of the Smartcard. In fact, the user interface is embedded in a peripheral device which can advantageously be selectively coupled with the smart card, for example only when it is necessary to proceed to enrollment by capturing a biometric fingerprint. The smart card can be decoupled from the peripheral device when the latter is not useful, thus preserving the user interface from possible failures in the event of mechanical stresses (twists, shocks, falls, etc.) applied to the smart card. .
    The invention allows users to be guided so that they can easily take a biometric fingerprint capture from their smart card without requiring complex modifications of current smart cards or in-depth knowledge on the part of users. .
    An enrollment phase intended to acquire a reference biometric fingerprint, for example during an initial configuration phase (personalization), can in particular be complex or confusing, in particular if it requires the acquisition of several fingerprints according to a particular sequence . The invention makes it possible to avoid the user being disturbed when such an enrollment phase is carried out using a smart card comprising a biometric sensor.
    In a particular example, the peripheral device also has a battery which makes it possible to supply the user interface electrically, and possibly also the DV1 smart card when the latter is coupled (by contact or without contact) with the peripheral device.
    The invention advantageously makes it possible to authenticate a user by comparing an acquired fingerprint with other fingerprint data, without having to remove this data from the smart card. The PR1 and DTI data can advantageously be stored securely in a memory of the smart card.
    It will of course be understood that the control signals SGI, SG2 and SG3 as described above with reference to FIG. 4 constitute only nonlimiting examples of the invention, other configurations being possible (for SG, and therefore for the state of the user interface obtained in response) within the framework of the invention.
    In the embodiments described above with reference to FIGS. 1-4, the communication link L1, through which each control signal is transmitted
    SG, is established by contact through at least one external contact 2 of the smart card DV1.
    By using, for example, an external contact as defined by the ISO 7816 standard, it is possible to advantageously use the current structure of a majority of smart cards on the market, thus avoiding structural modifications which would pose difficulties in practice (costs, deadlines ...).
    As shown for example in FIG. 5, the smart card DV1 can be configured to use an external contact 2 conforming to the ISO 7816-2 standard to transmit each control signal SG to the peripheral device DV2.
    According to a first particular example, the smart card DV1 is configured to transmit each control signal SG via the external contact C6 within the meaning of the ISO 7816 standard, that is to say a contact whose use is left to the manufacturer's discretion. One of the contacts C4 and C8 within the meaning of ISO 7816 can also be used for this purpose.
    According to a second particular example, the smart card DV1 is configured to transmit each control signal SG via the external contact C7 within the meaning of the ISO 7816 standard. In this case, the contact C7 can therefore have different uses, namely: either a conventional use of input / output contact, ie a use according to the principle of the invention for transmitting SG control signals. It is then necessary that the smart card DV1 can determine what use should be made of the contact C7 at a given time. To do this, the DV1 smart card can be configured to switch between:
    - A first operating mode MD1 - called transaction mode - in which the smart card DV1 uses the external contact C7 within the meaning of the ISO 7816 standard to carry out ISO 7816 type communication with an external terminal (not shown); and
    - A second operating mode MD2 - called fingerprint acquisition mode - in which the smart card DV1 uses the external contact C7 within the meaning of the ISO 7816 standard to transmit each control signal SG to the peripheral device DV2.
    Note that different configurations can be envisaged to allow the DV1 smart card to detect if an enrollment phase (acquisition of fingerprint) is in progress, and therefore to allow the DV1 smart card to configure itself in the appropriate mode of operation.
    FIG. 6 represents, according to a particular embodiment, a control method implemented by the chip card DV1, and more generally by the system SY, in the case of the second particular example below where the chip card DV1 is configured to use contact C7 to transmit control signals SG to peripheral device DV2.
    More specifically, during a detection step A30, the smart card DV1 detects that it is started (or activated), that is to say that its processor 4 is switched on.
    In response to start-up, the DV1 chip card checks (A32) the level of the RST signal (for "Reset") detected on the external contact C2 within the meaning of ISO 7816. More precisely, the DV1 chip card determines (A32 ) in this example if the RST signal detected on the external contact C2 within the meaning of the ISO 7816 standard reaches a predetermined value denoted L.
    According to the ISO 7816-3 standard, when activating the DV1 chip card, the RST signal should theoretically be kept low for a predetermined period (at least 400 clock cycles) when the chip card is power up on the external contact Cl (Vcc) within the meaning of standard ISO 7816.
    Also, if the signal RST detected in A32 is at a predetermined value L (low state in this example), then the smart card DV1 is configured (A34) in the transaction mode MD1 allowing a conventional use of the external contact C7. Otherwise (RST Ψ L), then the smart card DV1 is configured (A36) in the fingerprint acquisition mode MD2 allowing the acquisition of a fingerprint in accordance with the principle of the invention. Once the MD2 fingerprint acquisition mode is activated, the DV1 smart card can carry out the control process as shown in FIG. 4 (A2, ...).
    The smart card DV1 thus switches either to the transaction mode MD1 or to the fingerprint acquisition mode MD2, as a function of the detected level of the signal RST on the external contact C2 within the meaning of the ISO 7816 standard.
    The invention thus allows the smart card DV1 to effectively detect the use which must be made of the external contact C7 in the case where it is used in particular in the context of the invention.
    According to another example, the selection of the operating mode (MD1 or MD2) can be carried out in an analogous manner by the smart card from this time the signal level, or the frequency of said signal, detected on the external contact C3 at sense of ISO 7816, corresponding to the clock (CLK).
    According to another example, the selection of the operating mode (MD1 or MD2) can be carried out by the smart card from the signal level on the external contact Cl within the meaning of the ISO 7816 standard, corresponding to the power supply (VCC ).
    According to another example, the transmission of each control signal SG can be done in an analogous manner via the external contact C2 and / or C3 within the meaning of the ISO7816 standard. In this case, the contacts C2 and C3 can therefore have different uses, namely: either a conventional use of input contact, or a use according to the principle of the invention for transmitting control signals SG.
    FIG. 7 schematically represents, according to a particular embodiment, a circuit CT making it possible to impose on the user interface 20 predetermined states E1 and E2 as already described previously with reference to FIG. 4.
    In the example envisaged here, the circuit CT is included in the peripheral device DV2. In a variant, at least part of this circuit CT can be arranged in the smart card DV1.
    As shown in Figure 7, the CT circuit includes two LEDs 20a and 20b and a resistor RI. When the smart card DV1 is coupled with the peripheral device DV2, the external contact C7 is connected to a terminal of the resistor RI. The two LEDs 20a, 20b are connected in series so that the LED 20a is connected on a terminal to ground and that the LED 20b is connected on a terminal to a power supply imposing a high level noted H (H = 3V for example ). The second terminal of the resistor RI is connected to the common terminals of the two LEDs 20a, 20b.
    In this way, the smart card DV1 is configured to transmit via the external contact C7 to the peripheral device DV1, as a control signal SG:
    a voltage at the predetermined high level H, greater than the ground, for lighting only the first LED 20a among the two LEDs (state El already described previously with reference to FIG. 4); and
    a voltage to ground, to light only the second LED 20b among the two LEDs (state E2 already described previously with reference to FIG. 4).
    When no control signal SG is sent (the LEDs 20a and 20b remain off, which corresponds to the rest state E0 already described previously with reference to FIG. 4), the smart card DV1 can for example impose on the through the external contact C7 a floating signal, the latter being inherent in the SY system. This floating signal (the voltage of which is included in 0 and the level H) neither allows the first LED 20a nor the second LED 20b to light up.
    As already indicated, a series of control signals SG at a given transmission frequency can be transmitted by the smart card DV1 to the peripheral device DV2 in order to force the user interface 20 to alternate synchronously between two states (between E0 and El for example, or between E0 and E2).
    Furthermore, as already indicated, each control signal SG according to the invention is defined by a single level of an electrical characteristic. In the implementations of the invention described above, the control signals are defined by a single voltage level. In other words, it is the voltage level of the control signal which imposes a predefined state corresponding to the user interface. It is however possible to transmit control signals defined by a single current level or by a single frequency level.
    FIG. 8 schematically represents an example in which the control signals SG transmitted by the smart card DV1 to the peripheral device for controlling the state of the user interface 20 are defined by their unique level in frequency. As illustrated, a first control signal SG at the transmission frequency f5 can be transmitted by the smart card DV1 to force the user interface 20 into the first state El in which the first indicator light 20a is on and the second indicator light is off. Similarly, a second control signal SG at the transmission frequency f6 can be transmitted by the smart card DV1 to force the user interface 20 into the second state E2 in which the first indicator light 20a is off and the second indicator light is on. Other implementations are however possible.
    In the examples of implementations described in this document, the invention makes it possible to capture a fingerprint of a user using a sensor embedded in a smart card. It is understood that the principle of the invention more generally applies to the capture of any biometric fingerprint using a biometric sensor embedded in a smart card. Thus, it is for example possible to acquire an electrocardiogram in accordance with the principle of the invention, from a sensor on board the smart card.
    A person skilled in the art will understand that the embodiments and variants described above only constitute nonlimiting examples of implementation of the invention. In particular, a person skilled in the art can envisage any adaptation or combination of the embodiments and variants described above in order to meet a very specific need.
    权利要求:
    Claims (15)
    [1" id="c-fr-0001]
    1. System (SY) comprising a smart card (DV1) and a peripheral device (DV2) configured to cooperate together to allow the acquisition of a biometric fingerprint, the smart card and the peripheral device being separated one of the other, the smart card comprising:
    - a biometric fingerprint sensor configured to acquire a biometric fingerprint; and
    - a control module configured to transmit at least one control signal to the peripheral device, each control signal being defined by a single level of an electrical characteristic;
    in which the peripheral device comprises, apart from at least one possible internal power source, only passive components, among which:
    - A user interface configured to enter a predetermined state in response to each control signal received, so as to guide a user in the acquisition of the biometric fingerprint by the biometric fingerprint sensor.
    [2" id="c-fr-0002]
    2. The system as claimed in claim 1, in which the user interface is configured to present, in each predetermined state, respective information guiding a user in the acquisition of said biometric fingerprint by the biometric fingerprint sensor.
    [3" id="c-fr-0003]
    3. System according to claim 1 or 2, in which the electrical characteristic is one of:
    - a tension ;
    - current ; and
    - a frequency.
    [4" id="c-fr-0004]
    4. System according to any one of claims 1 to 3, in which the peripheral device does not include any active processing means capable of interpreting any command coming from the smart card.
    [5" id="c-fr-0005]
    5. System according to any one of claims 1 to 4, in which the smart card comprises:
    a memory for storing said biometric fingerprint as a reference biometric fingerprint, once it has been acquired by the biometric fingerprint sensor; and
    - An authentication module configured to authenticate said user from a comparison of the reference biometric fingerprint and another biometric fingerprint acquired subsequently.
    [6" id="c-fr-0006]
    6. System according to any one of claims 1 to 4, in which the smart card comprises:
    - a memory for storing said biometric fingerprint, once it has been acquired by the biometric fingerprint sensor; and an authentication module configured to authenticate said user from a comparison of the acquired biometric fingerprint and pre-recorded fingerprint data as a reference biometric fingerprint.
    [7" id="c-fr-0007]
    7. System according to any one of claims 1 to 6, wherein the peripheral device comprises a battery for electrically supplying the user interface.
    [8" id="c-fr-0008]
    8. System according to any one of claims 1 to 7, in which the user interface is configured for:
    - switch between two predetermined states (E0, El) at a first frequency (fl) in response to a series of first control signals (SGI) received from the smart card, so as to indicate the start of a phase acquisition of a biometric fingerprint by the biometric fingerprint sensor;
    - switch between two predetermined states (E0, El) at a second frequency (f2) in response to a series of second control signals (SG2) received from the smart card, so as to indicate that a biometric fingerprint is being acquired; and
    - go into a third predetermined state (E2) in response to a third control signal (SG3) received from the smart card, so as to indicate that the phase of acquisition of the biometric fingerprint is completed, in which the first and second frequencies are distinct from each other, and the third signal (SG3) is distinct from the first and second control signals (SGI, SG2).
    [9" id="c-fr-0009]
    9. System according to any one of claims 1 to 8, in which the user interface comprises a first LED and a second LED distinct from each other, the control module being configured to transmit to the peripheral device, in as a control signal:
    - a ground voltage to light only the first LED among the two LEDs; and
    - a voltage at a predetermined high level, greater than ground, to light only the second LED among the two LEDs.
    [10" id="c-fr-0010]
    10. System according to any one of claims 1 to 9, in which the smart card is a card comprising external contacts, in accordance with standard ISO 7816, for transmitting by contact each control signal to the peripheral device.
    [11" id="c-fr-0011]
    11. The system as claimed in claim 10, in which the smart card is configured to transmit each control signal via the external contact C4, C6 or C8 within the meaning of the ISO 7816 standard.
    [12" id="c-fr-0012]
    12. The system as claimed in claim 10, in which the smart card is configured to transmit each control signal via a contact among the external contacts C2, C3 and C7 within the meaning of the ISO 7816 standard, in which the smart card is configured to switch between:
    - A first operating mode in which the smart card uses said contact among the external contacts C2, C3 and C7 within the meaning of the ISO 7816 standard to carry out ISO 7816 type communication with an external terminal; and
    - a second operating mode in which the smart card uses said contact among the external contacts C2, C3 and C7 within the meaning of standard ISO 7816 to transmit each control signal to the peripheral device;
    the smart card including:
    a verification module configured to verify, at the start of the smart card, at least one signal level among the RST signal detected on the external contact C2 within the meaning of the ISO 7816 standard, the CLK signal detected on the external contact C3 within the meaning of ISO 7816 and the supply signal VCC detected on the external contact Cl within the meaning of ISO 7816; and
    a configuration module configured to switch the smart card, either in the first operating mode or in the second operating mode, as a function of said at least one signal level detected among the RST signal, the CLK signal and the VCC signal .
    [13" id="c-fr-0013]
    13. System according to any one of claims 1 to 12, in which the smart card is a payment card.
    [14" id="c-fr-0014]
    14. System according to any one of claims 1 to 13, in which the peripheral device is a case in which the smart card is inserted to allow the transmission of said at least one control signal from the control module to the device. peripheral.
    [15" id="c-fr-0015]
    15. Control method implemented by a system comprising a smart card and a peripheral device cooperating together to allow the acquisition of a biometric fingerprint, the smart card and the peripheral device being separated from each other , the smart card comprising a biometric fingerprint sensor and the peripheral device comprising, apart from at least one possible internal power source, only passive components among which a user interface, in which the method comprises:
    acquisition of a biometric fingerprint by the biometric fingerprint sensor; transmission, from the smart card to the peripheral device, of at least one control signal, each control signal being defined by a single level of an electrical characteristic; and configuring the user interface in a predetermined state in response to each control signal received, so as to guide a user in the acquisition of the biometric fingerprint by the biometric fingerprint sensor.
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    法律状态:
    2019-07-22| PLFP| Fee payment|Year of fee payment: 2 |
    2020-02-14| PLSC| Publication of the preliminary search report|Effective date: 20200214 |
    2020-07-21| PLFP| Fee payment|Year of fee payment: 3 |
    2021-07-22| PLFP| Fee payment|Year of fee payment: 4 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1857353A|FR3084942B1|2018-08-07|2018-08-07|ACQUISITION OF A BIOMETRIC FOOTPRINT FROM A CHIP CARD|FR1857353A| FR3084942B1|2018-08-07|2018-08-07|ACQUISITION OF A BIOMETRIC FOOTPRINT FROM A CHIP CARD|
    EP19188933.6A| EP3608833A1|2018-08-07|2019-07-29|Acquisition of a biometric fingerprint from a smart card|
    AU2019213296A| AU2019213296A1|2018-08-07|2019-08-05|Acquiring a biometric print by means of a smartcard|
    US16/533,476| US11216712B2|2018-08-07|2019-08-06|Acquiring a biometric print by means of a smartcard|
    CN201910724523.3A| CN110826674A|2018-08-07|2019-08-07|Obtaining a biometric print via a smart card|
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