WO2024061933A1

WO2024061933A1 - Contactless chip card provided with a three-dimensional position sensor

Info

Publication number: WO2024061933A1
Application number: PCT/EP2023/075853
Authority: WO
Inventors: Bertrand Bertrand; Haig KAMBOURIAN; Jerome Tonin
Original assignee: Smart Packaging Solutions
Priority date: 2022-09-20
Filing date: 2023-09-19
Publication date: 2024-03-28
Also published as: FR3139928A1

Abstract

The invention relates to a contactless chip card comprising: - an antenna (30) of a concentrator of the module comprising a first connection pole (31) and a second connection pole (32); - a first secure element (10) configured to be able to carry out a first function. The invention is essentially characterised in that it further comprises: - a second secure element (20) configured to be able to carry out a second function; - a three-dimensional position sensor (40), configured to transmit a signal representative of at least one from among: o the position; o the acceleration; and o the movement of the chip card in space, the chip card being configured so as to be able to activate the first or the second function when it is supplied with power by a reader according to the value of the signal from the three-dimensional position sensor (40).

Description

Contactless smart card equipped with a three-dimensional position sensor.

The present invention relates to the field of contactless smart cards.

Contactless smart cards are now well known and used for numerous applications, indiscriminately called functions. For example in the banking sector, a contactless smart card allows cash payment or deferred or staggered payment.

There are also contactless smart cards for other non-banking applications, for example subscription cards, access cards, electronic wallets, etc.

We therefore see the emergence of a multiplication of applications, which implies a multiplication of physical media. Such a multiplication of supports is not eco-responsible since it requires in particular the use of plastic.

Furthermore, from an ergonomic point of view, the proliferation of smart cards increases the volume required to store and transport them, with as much risk of loss or theft as this implies.

For the sake of brevity, the “contactless” character will generally be omitted from this description.

Also for brevity we will take here a single example in which the contactless smart card is a bank card. For the sake of brevity, “bank account” means a bank account or a customer account with a merchant.

In this area, it appears useful for a user to be able to use the same payment method for several functions. If there are mobile applications for smartphones, the present invention aims here to propose a solution making it possible to implement at least two functions with a single smart card.

The examples are illustrative and not limiting.

Thanks to the present invention, it is for example possible to implement:

A first payment function in a first currency, and A second payment function in a second currency.

For example, the first currency is EURO and the second currency is US dollars or a cryptocurrency. By payment function, we mean without distinction a debit (payment) or credit (reimbursement) order from a bank account. It is also possible to implement:

A first immediate payment function in a first currency, and

A second deferred (or installment) payment function in the first currency.

At a merchant, a user can thus choose the first function to pay in cash, or the second function to pay in X installments, with X a natural number which depends on the merchant.

For the purposes of the present invention, we therefore have a first electronic circuit which makes it possible to activate the first function, and a second electronic circuit which makes it possible to activate the second function, as described later.

According to a first of its objects, the invention relates to a contactless smart card comprising:

A first face and a second face, opposite the first face,

At least one module,

A single antenna, capable of communicating without contact with an antenna (30) of a hub of the module, the antenna of the hub (30) comprising a first connection pole (31) and a second connection pole (32), and

A first secure element (10), electrically connected at least to the first connection pole (31) of the antenna of the concentrator (30), and configured to be able to perform a first function.

It is essentially characterized in that it also includes:

A second secure element (20), configured to be able to execute a second function, distinct from the first function,

A three-dimensional position sensor (40), configured to emit a signal representative of at least one of: o the position of the smart card in space, o the acceleration of the smart card in space, and o the movement of the smart card in space,

The smart card being configured so as to be able to selectively activate said first function or said second function when powered by a reader, the first function or the second function being selectively activated depending on the signal value of the three-dimensional position sensor (40).

It can be envisaged that: the first secure element (10) is electrically connected to the second connection pole (32) of the antenna of the concentrator (30), and is configured as a master; the second secure element (20) is electrically connected to the first secure element (10), and is configured as a slave, the three-dimensional position sensor (40) being electrically connected at least to the first secure element (10), activation of the master inhibiting the slave, and activation of the slave by the master inhibiting the master.

It can be provided that the first connection pole (31) of the antenna of the concentrator (30) is further connected to the second secure element (20), and that it further comprises: a microcontroller (70), and a first switch (61) controlled by the microcontroller (70) and capable of selectively adopting: o a first position in which the second connection pole (32) of the antenna of the concentrator (30) is electrically connected to the first secure element (10) and o a second position in which the second connection pole (32) of the antenna of the concentrator (30) is electrically connected to the second secure element (20), the signal from the three-dimensional position sensor (40) being sent to the microcontroller ( 70) to control the position of said first switch (61); the smart card further comprising a power management device (50), electrically powered by the antenna of the concentrator (30), and configured to control the electrical power of at least the microcontroller (70) and the position sensor three-dimensional (40).

We can predict that: the first secure element (10) is not electrically connected directly to the second secure element (20), the first secure element (10) is electrically connected at least to the first connection pole (31) of the antenna of the concentrator (30 ) via a first switch (61), and which it further comprises: a microcontroller (70), said first switch (61), controlled by the microcontroller (70) and capable of selectively adopting: o a first position in which the first connection pole (31) of the concentrator antenna (30) is electrically connected to the first secure element (10), and o a second position in which the first connection pole (31) of the concentrator antenna (30) is electrically connected to the second secure element (20); a second switch (62) controlled by the microcontroller (70) and capable of selectively adopting: o a first position in which the second connection pole (32) of the antenna of the concentrator (30) is electrically connected to the first secure element (10) ), and o a second position in which the second connection pole (32) of the antenna of the concentrator (30) is electrically connected to the second secure element (20), the signal from the three-dimensional position sensor (40) being sent towards the microcontroller (70) for controlling the position of said first switch (61) and said second switch (62), said first switch (61) and said second switch (62) being configured to simultaneously adopt the first position or the second position; the smart card further comprising a power management device (50), electrically powered by the antenna of the concentrator (30), and configured to control the electrical power of the microcontroller (70) and the three-dimensional position sensor (40) .

It can be provided that at least one of said first switch (61) and said second switch (62) is a static relay. It is also possible to provide: a microcontroller (70), electrically connected to the three-dimensional position sensor (40), and which comprises: o a first general-purpose input-output port (GPIO), connected to the power connection pad ( Vcc) of the first secure element (10), and through which a first binary power signal can pass; o a second general-purpose input-output port (GPIO), connected to the power connection pad (Vcc) of the second secure element (20), and through which a second binary power signal can pass; in which: the ground of the first secure element (10) is connected to the ground of the second secure element (20) and to the ground of the microcontroller (70), the smart card further comprises a power management device (50) , electrically powered by the antenna of the concentrator (30), and configured to control the electrical power of the microcontroller (70) and the three-dimensional position sensor (40).

It is also possible to provide: a microcontroller (70), electrically connected to the three-dimensional position sensor (40), and which comprises: o a first general-purpose input-output port (GPIO), connected to the ground connection pad of the first secure element (10), and through which a first binary power signal can pass; o a second general-purpose input-output port (GPIO), connected to the ground connection pad of the second secure element (20), and through which a second binary power signal can pass; a power management device (50), electrically powered by the antenna of the concentrator (30), and configured to control the electrical power of the microcontroller (70), of the three-dimensional position sensor (40), of the first secure element (10 ) and the second secure element (20). It is also possible to provide: a microcontroller (70), electrically connected to the three-dimensional position sensor (40), and which comprises: o a first general-purpose input-output port (GPIO), connected to a signal connection pad d clock or to a reset connection pad of the first secure element (10), and through which a first clock signal or a first reset signal can pass respectively; o a second general purpose input-output port (GPIO), connected to a clock signal connection pad or to a reset connection pad of the second secure element (20), and through which a second signal can pass clock or a first reset signal respectively; a power management device (50), electrically powered by the antenna of the concentrator (30), and configured to control the electrical power of the microcontroller (70), of the three-dimensional position sensor (40), of the first secure element (10 ) and the second secure element (20).

According to another of its objects, the invention also relates to a contactless smart card, comprising:

A first face and a second face, opposite the first face,

At least one module, and

A single antenna, capable of communicating without contact with an antenna (30) of a hub of the module, the antenna of the hub (30) comprising a first connection pole (31) and a second connection pole (32).

It is essentially characterized in that the smart card further comprises:

A first secure element (10), configured to be able to selectively execute a first function or a second function,

The smart card being configured so as to be able to selectively activate said first function or said second function when powered by a reader, the first function or the second function being selectively activated as a function of the value of the signal from the three-dimensional position sensor (40).

Finally, the smart card according to the invention may comprise a microcontroller (70) configured to: detect the accelerations of the smart card in a predetermined direction, using the signal from the three-dimensional position sensor (40), count the number of accelerations of the smart card in a predetermined time window, selectively activate the first function, the second function or another function, according to at least one of: o the number of accelerations of the smart card counted in the window of predetermined time, and o the position of the smart card in space.

Other characteristics and advantages of the present invention will appear more clearly on reading the following description given by way of illustrative and non-limiting example and made with reference to the appended figures.

Figures are not to scale. Some details have been omitted and others amplified, to facilitate understanding.

DESCRIPTION OF THE DRAWINGS

[Fig. 1] illustrates an embodiment of a smart card according to the invention, comprising a switch capable of cutting off the antenna of the concentrator,

[Fig. 2] illustrates an embodiment of a smart card according to the invention, comprising a double switch capable of cutting off the concentrator antenna, [Fig. 3] illustrates an embodiment of a smart card according to the invention, in which the supply of the secure elements is carried out by the microcontroller via the supply voltage (Vcc),

[Fig. 4] illustrates an embodiment of a smart card according to the invention, in which the activation of the first secure element or the second secure element is carried out by the microcontroller via a reset signal (Rst),

[Fig. 5] illustrates an embodiment of a smart card according to the invention, in which the secure elements are powered by the microcontroller via ground (Gnd),

[Fig. 6] illustrates an embodiment of a smart card according to the invention, in which the first secure element and the second secure element are configured as master/slave.

detailed description

In known manner, a contactless smart card is generally planar and comprises a first face and a second face, opposite the first face.

In use, a contactless smart card is intended to be placed substantially horizontally on a magnetic reader.

A standard smart card includes a first electronic circuit. The first electronic circuit includes:

A first secure element 10, which comprises a secure processor, and a set of data; a first antenna (not illustrated), making it possible to communicate with a smart card reader, and a hub equipped with an antenna comprising a first connection pole 31 and a second connection pole 32, and which is configured to receive the energy from the first antenna and distribute it to at least one of the first secure element 10 and a second secure element 20 described later.

Activation of the first electronic circuit makes it possible to implement a first function, indiscriminately "application", for example a payment in a first predetermined currency.

According to the invention, a smart card further comprises a second electronic circuit, distinct from the first electronic circuit and, which according to the embodiments described below, can be in direct electrical connection or without direct electrical connection with the first electronic circuit.

The second electronic circuit comprises a second secure element 20, which comprises a secure processor, and a set of data.

Activation of the second electronic circuit makes it possible to implement a second function, indiscriminately "application", for example a payment in a second predetermined currency.

Other functions can be provided. For example: the first function corresponds to an immediate debit order, and the second function corresponds to a deferred or staggered debit order.

Preferably, a single module is provided comprising the first secure element 10 and the second secure element 20.

Obviously, the activation of the first electronic circuit must not activate the second electronic circuit, and vice versa.

For this purpose, it is provided that only one of the first electronic circuit and the second electronic circuit is closed by default.

To selectively implement one or the other of the functions, a three-dimensional position sensor 40 is provided, the signal value of which makes it possible to selectively activate the first function or the second function.

The three-dimensional position sensor 40 is configured to emit a signal representative of at least one of: the position of the smart card in space, the acceleration of the smart card in space, and the movement of the smart card in space.

In this case, the three-dimensional position sensor 40 is a 3-dimensional accelerometer, which is in the form of a microelectromechanical system (MEMS), which sends a signal representative of its orientation in space; for example a 3-axis gyroscope, or 3-axis magnetometer, or a 3-axis accelerometer.

For this purpose, the following embodiments are provided. In a first embodiment, the first secure element 10 is configured to be able to selectively execute a first function or a second function.

When the smart card is powered by a reader, the first function or the second function is activated selectively depending on the value of the signal from the three-dimensional position sensor 40.

For example, when the first face is adjacent to a reader which powers the smart card, then the three-dimensional position sensor 40 emits a first value, for example whose vertical component of the signal is positive, and the first function of the first secure element 10 is activated.

Conversely, when the second face is adjacent to a reader which powers the smart card, then the three-dimensional position sensor 40 emits a second value, for example whose vertical component of the signal is negative, and the second function of the first secure element 10 is activated.

In this case, it is possible to advantageously configure the three-dimensional position sensor 40, or add a microcontroller 70, so that the function activated by the first secure element 10 only depends on the sign of the vertical component of the signal from the three-dimensional position sensor 40.

In a second embodiment, the smart card comprises the first secure element 10, which is configured to be able to execute a first function, and a second secure element 20 which is configured to be able to execute a second function.

Advantageously, the smart card comprises a single antenna, capable of communicating without contact with the antenna 30 of the concentrator, to supply energy to the first secure element 10 and the second secure element 20.

The first secure element 10 is electrically connected at least to the first connection pole 31 of the antenna 30 of the concentrator.

The smart card is configured such that it can selectively activate the first function or the second function when powered by a reader, the first function or the second function being selectively activated based on the value of the signal from the three-dimensional position sensor 40. In a first variant of the second embodiment, illustrated in Figure 6, the second connection pole 32 of the antenna 30 of the concentrator is also electrically connected to the first secure element 10.

The first secure element 10 is therefore connected to the two connection poles of the antenna 30 of the concentrator.

The first secure element 10 and the second secure element 20 are configured in a master/slave configuration, in which the first secure element 10 is configured as a master and the second secure element 20 is configured as a slave.

The second secure element 20 is electrically connected to the first secure element 10, for example by a general input/output port 10.

In this variant, the three-dimensional position sensor 40 is electrically connected at least to the first secure element 10, from which it receives its electrical supply Vcc_Out, and to which it sends its output signal, for example via an input/port 10. general exit.

Depending on the value of the signal from the three-dimensional position sensor 40, the first secure element 10 is activated as master, or it is inhibited so as to activate the second slave secure element 20.

When the first secure element 10 is activated as master, it inhibits the slave.

Activation of the slave by the master inhibits the master, that is to say inhibits its function but the first secure element 10 (master) remains a power supply gateway for the second secure element 20 (slave). When the slave is activated, the slave accesses the antenna 30 of the concentrator via certain ports of the master, in this case through a general input/output port of the master to port 10 of the slave , illustrated in dotted lines in Figure 6.

In a second variant of the second embodiment, illustrated in Figure 1, the first connection pole 31 of the antenna 30 of the concentrator is further connected to the second secure element 20.

In this case a second connection pad (Lb) of the second secure element 20 is electrically connected to a second connection pad (Lb) of the first secure element 10, and the second connection pad (Lb) of the first secure element 10 is electrically connected to the first connection pole 31 of the antenna 30 of the concentrator via the first secure element 10 with which it is electrically connected. The second connection pole 32 of the antenna 30 of the concentrator is selectively electrically connected to the first secure element 10 or to the second secure element 20, thanks to a first switch 61, for example a static relay.

In this variant, we also provide: a microcontroller 70, and said first switch 61 controlled by the microcontroller 70.

The first switch 61 can selectively adopt:

- a first position in which the second connection pole 32 of the antenna 30 of the concentrator is electrically connected to the first secure element 10 by a first connection pad (La) of the first secure element 10, which cuts off the communication of the second element secure 20, and

- a second position in which the second connection pole 32 of the antenna 30 of the concentrator is electrically connected to the second secure element 20, by a first connection pad (La) of the second secure element 20; which cuts off the communication of the first secure element 10.

The signal from the three-dimensional position sensor 40 is sent to the microcontroller 70 to control the position of said first switch 61.

The smart card further comprises a power management device 50, electrically powered preferably via the antenna 30 of the concentrator, and configured to control the electrical power of at least the microcontroller 70 and the three-dimensional position sensor 40.

In a third variant of the second embodiment, illustrated in Figure 2, the first secure element 10 is not electrically connected directly to the second secure element 20.

In this variant: the first secure element 10 can be electrically connected to the first connection pole 31 of the antenna 30 of the concentrator via a first switch 61, and to the second connection pole 32 of the antenna 30 of the concentrator via a second switch 62; and the second secure element 20 can be electrically connected to the first connection pole 31 of the antenna 30 of the concentrator via the first switch 61, and to the second connection pole 32 of the antenna 30 of the concentrator via the second switch 62.

A microcontroller 70 is also provided.

The first switch 61 is controlled by the microcontroller 70 and can selectively adopt: a first position in which the first connection pole 31 of the antenna 30 of the concentrator is electrically connected to the first secure element 10, and a second position in which the first connection pole 31 of the antenna 30 of the concentrator is electrically connected to the second secure element 20;

Similarly, the second switch 62 is controlled by the microcontroller 70 and can selectively adopt: a first position in which the second connection pole 32 of the antenna 30 of the concentrator is electrically connected to the first secure element 10, and a second position in which the second connection pole 32 of the antenna 30 of the concentrator is electrically connected to the second secure element 20.

The signal from the three-dimensional position sensor 40 is sent to the microcontroller 70 to control the position of the first switch 61 and the second switch 62, said first switch 61 and said second switch 62 being configured to simultaneously adopt the first position or the second position.

The smart card further comprises a power management device 50, preferably electrically powered by the antenna 30 of the concentrator, and configured to control the electrical power of the microcontroller 70 and the three-dimensional position sensor 40.

For example, the first switch 61 and the second switch 62 are in the form of a double static relay.

In a fourth variant of the second embodiment, illustrated in Figure 3, the first secure element 10 is electrically connected directly to the first connection pole 31 of the antenna 30 of the concentrator thanks to a first specific connection pad Lb, and to the second connection pole 32 of the antenna 30 of the concentrator thanks to a second specific connection pad La.

The second secure element 20 is electrically connected to the first secure element 10 via a first specific connection pad Lb and a second specific connection pad La du second secure element 20, which are electrically connected to the first specific connection pad Lb and to the second specific connection pad La of the first secure element 10.

In this way, the second secure element 20 is electrically connected to the first connection pole 31 of the antenna 30 of the concentrator via the first specific connection pad Lb, and to the second connection pole 32 of the antenna 30 of the concentrator via the second specific connection pad La.

A microcontroller 70 is further provided, which is electrically connected to the three-dimensional position sensor 40 and which comprises: a first general-purpose input-output port (GPIO), connected to the power connection pad (Vcc) of the first secure element 10, and through which a first binary power signal can pass; and a second general-purpose input-output port (GPIO), connected to the power connection pad (Vcc) of the second secure element 20, and through which a second binary power signal can pass.

Preferably, a binary signal 0 (Gnd) or 1 (Vcc) is used to power the first secure element 10. By default the signal is 0. Likewise to power the second secure element 20.

The common collector voltage (Vcc) of the first secure element 10, like the common collector voltage (Vcc) of the second secure element 20, is output by the microcontroller 70 on a respective general purpose input-output port (GPIO).

The ground (Gnd) of the first secure element 10 is connected to the ground (Gnd) of the second secure element 20 and to the ground of the microcontroller 70. The ground (Gnd) of the other components is not illustrated, but all grounds are connected between them.

In this variant, we have a common ground (Gnd) and we selectively activate the power supply (Vcc) of the first or second secure element 20 using the microcontroller 70 which acts as a switch. In a fifth variant of the second embodiment, illustrated in Figure 5, as according to the fourth variant, the first secure element 10 is electrically connected directly to the first connection pole 31 of the antenna 30 of the concentrator thanks to a first contact pad. specific connection Lb, and to the second connection pole 32 of the antenna 30 of the concentrator thanks to a second specific connection pad La.

The second secure element 20 is electrically connected to the first secure element 10 via a first specific connection pad Lb and a second specific connection pad La of the second secure element 20, which are electrically connected to the first specific connection pad Lb and to the second pad specific connection La of the first secure element 10.

There is also provided a microcontroller 70, which is electrically connected to the three-dimensional position sensor 40 and which comprises: a first general-purpose input-output port (GPIO), connected to the ground connection pad (Gnd) of the first secure element 10, and through which a first binary power signal can pass; and a second general-purpose input-output port (GPIO), connected to the ground connection pad (Gnd) of the second secure element 20, and through which a second binary power signal can pass.

By default, we can provide that the first binary power supply signal is at 1 (Vcc); in which case the first secure element 10 is inactive. The first binary signal is set to 0 or Vdd to activate the first secure element 10, provided that the voltage Vcc-Vdd is sufficient to power the first secure element 10.

By default, we can predict that the second binary signal is at 1 (Vcc); in which case the second secure element 20 is inactive. The second binary signal is set to 0 or Vdd to activate the second secure element 20, provided that the voltage Vcc-Vdd is sufficient to power the second secure element 20.

A power management device 50 can be provided, preferably electrically powered by the antenna 30 of the concentrator, and configured to control the electrical power of the microcontroller 70, the three-dimensional position sensor 40, the first secure element 10 and the second element secure 20.

Unlike the fourth variant, here we have a common power supply (Vcc) and we selectively activate the ground (Gnd) using the microcontroller 70 which acts like a switch. In a sixth variant of the second embodiment, illustrated in Figure 4, as according to the fourth variant, the first secure element 10 is electrically connected directly to the first connection pole 31 of the antenna 30 of the concentrator thanks to a first contact pad. specific connection Lb, and to the second connection pole 32 of the antenna 30 of the concentrator thanks to a second specific connection pad La.

There is further provided a microcontroller 70, which is electrically connected to the three-dimensional position sensor 40 and which comprises: a first general purpose input-output port (GPIO), connected to a reset connection pad (Rst) or to a pad clock connection (Clk) of the first secure element 10, and through which a first reset signal or a clock signal can pass respectively; and a second general purpose input-output port (GPIO), connected to a reset connection pad (Rst) or to a clock connection pad (Clk) of the second secure element 20, and through which a second reset signal or a clock signal respectively.

In Figure 4, only the Reset (Rst) connection pads are shown. A person skilled in the art will easily transpose it to the connection pads of the Clk clock.

On the clock connection pad (Clk): if the first secure element 10 receives a 0 signal then it is inactive; if the first secure element 10 receives a periodic clock signal then it is activated; the periodic clock signal being generated by the microcontroller 70 as a function of the value of the signal from the three-dimensional position sensor 40.

On the reset connection pad (Rst): if the first secure element 10 receives a 0 signal then it is inactive; if the first secure element 10 receives a signal at 1 then it is activated; the reset signal being generated by the microcontroller 70 as a function of the value of the signal from the three-dimensional position sensor 40.

The microcontroller 70 acts like a switch.

The power supply of the first secure element 10 and the second secure element 20 is not done by the reset connection pad Rst or the clock connection pad Clk, but on another connection pad, in this case the La and Lb connection pads. It is also possible to provide power to the first secure element 10 and the second secure element 20 by the power management device 50.

According to another embodiment, the microcontroller 70 is configured to detect accelerations of the smart card in a predetermined direction, using the signal from the three-dimensional position sensor 40.

In particular, we plan to detect accelerations along a vertical axis.

We can then plan to count the number of accelerations that the smart card undergoes in a predetermined time window.

Thanks to the number of accelerations counted and the position of the smart card in space, it can be planned to selectively activate the first function, the second function or another function, according to at least one of: the number of accelerations of the smart card counted in the predetermined time window, and the position of the smart card in space.

For example : if a user presents the front side of the smart card on a reader with acceleration in a substantially vertical direction within a predetermined time window, then the first function is activated, for example a cash payment in a first currency; if a user presents the reverse side of the smart card on a reader with acceleration in a substantially vertical direction within a predetermined time window, then the second function is activated, for example a deferred or installment payment in a first currency; if a user presents the front side of the smart card on a reader with two accelerations in a substantially vertical direction within a predetermined time window, then a third function is activated, for example a cash payment in a second currency; if a user presents the reverse side of the smart card on a reader with two accelerations in a substantially vertical direction within a predetermined time window, then a fourth function is activated, for example a deferred or installment payment in a second currency.

Nomenclature

10 first secure element

20 second secure element

30 antenna of a concentrator

31 first connection pole of the antenna of a concentrator

32 second antenna connection pole of a concentrator

40 three-dimensional position sensor

50 power management device

61 first switch

62 second switch

70 microcontroller

Claims

1. Contactless smart card including:

A first face and a second face, opposite the first face,

At least one module,

A first secure element (10), electrically connected at least to the first connection pole (31) of the antenna of the concentrator (30), and configured to be able to perform a first function,

Characterized in that the smart card further comprises:

2. Smart card according to claim 1, in which the first secure element (10) is electrically connected to the second connection pole (32) of the antenna of the concentrator (30), and is configured as master; the second secure element (20) is electrically connected to the first secure element (10), and is configured as a slave, the three-dimensional position sensor (40) being electrically connected at least to the first secure element (10), activation of the master inhibiting the slave, and activation of the slave by the master inhibiting the master.

3. Smart card according to claim 1, in which the first connection pole (31) of the antenna of the concentrator (30) is further connected to the second secure element (20), and further comprising: a microcontroller (70 ), and a first switch (61) controlled by the microcontroller (70) and capable of selectively adopting: o a first position in which the second connection pole (32) of the concentrator antenna (30) is electrically connected to the first element secure (10) and o a second position in which the second connection pole (32) of the antenna of the concentrator (30) is electrically connected to the second secure element (20), the signal from the three-dimensional position sensor (40) being sent to the microcontroller (70) to control the position of said first switch (61); the smart card further comprising a power management device (50), electrically powered by the antenna of the concentrator (30), and configured to control the electrical power of at least the microcontroller (70) and the position sensor three-dimensional (40).

4. Smart card according to claim 1, in which: the first secure element (10) is not electrically connected directly to the second secure element (20), the first secure element (10) is electrically connected at least to the first pole connection (31) of the antenna of the concentrator (30) via a first switch (61), and further comprising: a microcontroller (70), said first switch (61), controlled by the microcontroller (70) and capable of adopting selectively: o a first position in which the first connection pole (31) of the antenna of the concentrator (30) is electrically connected to the first secure element (10), and o a second position in which the first connection pole (31) of the antenna of the concentrator (30) is electrically connected to the second secure element (20); a second switch (62) controlled by the microcontroller (70) and able to selectively adopt: o a first position in which the second connection pole (32) of the antenna of the concentrator (30) is electrically connected to the first secure element (10 ), and o a second position in which the second connection pole (32) of the antenna of the concentrator (30) is electrically connected to the second secure element (20), the signal from the three-dimensional position sensor (40) being sent towards the microcontroller (70) for controlling the position of said first switch (61) and said second switch (62), said first switch (61) and said second switch (62) being configured to simultaneously adopt the first position or the second position; the smart card further comprising a power management device (50), electrically powered by the antenna of the concentrator (30), and configured to control the electrical power of the microcontroller (70) and the three-dimensional position sensor (40) .

5. Smart card according to any one of claims 3 or 4, wherein at least one of said first switch (61) and said second switch (62) is a solid state relay.

6. Smart card according to claim 1, further comprising: a microcontroller (70), electrically connected to the three-dimensional position sensor (40), and which comprises: o a first general purpose input-output port (GPIO), connected to the power connection pad (Vcc) of the first secure element (10), and through which a first binary power signal can pass; o a second general-purpose input-output port (GPIO), connected to the power connection pad (Vcc) of the second secure element (20), and through which a second binary power signal can pass; in which : the ground of the first secure element (10) is connected to the ground of the second secure element (20) and to the ground of the microcontroller (70), the smart card further comprises a power management device (50), electrically powered by the antenna of the concentrator (30), and configured to control the electrical power of the microcontroller (70) and the three-dimensional position sensor (40). chip according to claim 1, further comprising a microcontroller (70), electrically connected to the three-dimensional position sensor (40), and which comprises: o a first general purpose input-output port (GPIO), connected to the connection pad of the mass of the first secure element (10), and through which a first binary power signal can pass; o a second general-purpose input-output port (GPIO), connected to the ground connection pad of the second secure element (20), and through which a second binary power signal can pass; a power management device (50), electrically powered by the antenna of the concentrator (30), and configured to control the electrical power of the microcontroller (70), of the three-dimensional position sensor (40), of the first secure element (10 ) and the second secure element (20). chip according to claim 1, further comprising: a microcontroller (70), electrically connected to the three-dimensional position sensor (40), and which comprises: o a first general purpose input-output port (GPIO), connected to a pad clock signal connection or to a reset connection pad of the first secure element (10), and through which a first clock signal or a first reset signal can pass respectively; o a second general purpose input-output port (GPIO), connected to a clock signal connection pad or to a reset connection pad of the second secure element (20), and through which a second signal can pass clock or a first reset signal respectively; a power management device (50), electrically powered by the antenna of the concentrator (30), and configured to control the electrical power of the microcontroller (70), of the three-dimensional position sensor (40), of the first secure element (10 ) and the second secure element (20).

9. Smart card according to any one of claims 3 to 8, in which the microcontroller (70) is configured to: detect accelerations of the smart card in a predetermined direction, using the signal from the three-dimensional position sensor (40). ), count the number of accelerations of the smart card in a predetermined time window, selectively activate the first function, the second function or another function, according to at least one of: o the number of accelerations of the smart card counted in the predetermined time window, and o the position of the smart card in space.