FR3072535B1 - IMPEDANCE ADAPTATION METHOD BETWEEN A READER MOUNTED IN A MOTOR VEHICLE OPENER AND A MOBILE TERMINAL - Google Patents

Abstract

The present invention relates to an authentication reader (1 B) for a motor vehicle door, said reader (1 B) comprising a microcontroller (10B), a transmitter (20B), a first adaptation circuit (30- 1) and a first so-called "primary" antenna (L4). The reader (1B) comprises a second matching circuit (30-2) and a second so-called "primary" antenna (L6). The microcontroller (10B) is able to control the transmitter (20B) so that said transmitter (20B) alternately generates at least one electric current in said first matching circuit (30-1) allowing the first primary antenna (L4) to transmitting at least one electrical signal to a so-called "secondary" antenna of an authentication terminal, and at least one electric current in said second matching circuit (30-2) allowing the second primary antenna ( L6) to emit at least one electrical signal to a so-called "secondary" antenna of an authentication terminal.

Description

The present invention relates to the field of near field communication readers embedded in the opening of motor vehicles and more particularly relates to a method of impedance matching between a reader mounted in a motor vehicle door and a mobile terminal capable of communicating. on a near field communication link.

Nowadays, it is known to mount in a motor vehicle opening, for example at a door handle, a near-field communication reader to enable the authentication of a user and the unlocking of said opening.

Near Field Communication (CCP or NFC for Near Field Communication in English) is based on a short-range and high-frequency wireless communication technology, for example 13.56 MHz, allowing the exchange of information between peripherals up to a distance of a few centimeters, for example of the order of 10 cm.

In practice, when the user of a vehicle wishes to unlock the doors, he first places his authentication terminal near the reader. The reader then detects the presence of the terminal then proceeds to its authentication and unlocks the doors of the vehicle when the authentication is successful.

In a known solution, the reader comprises a so-called "primary" antenna and the terminal comprises a so-called "secondary" antenna. The reader is configured to periodically transmit, via said primary antenna, an electrical signal in the form of a pulse of short duration, for example a few tens of microseconds. The terminal can be passive or active. A passive terminal may for example be a card or a badge, while an active terminal may for example be a smartphone or a badge.

When the terminal approaches sufficiently close to the reader, for example less than 10 cm, the presence of the secondary antenna changes the voltage across the primary antenna. This modification is detected by the reader who deduces that a compatible terminal is nearby and then proceeds to the authentication of said terminal by obtaining and confirming an identifier stored in a memory area of the terminal.

FIG. 1 shows schematically a known solution of authentication reader 1A. In this solution, the authentication reader 1A comprises a microcontroller 10A, a transmitter 20A, a matching circuit 30A and a primary antenna L3. The microcontroller 10A controls the transmitter 20A to excite the primary antenna L3 through the matching circuit 30A. The adaptation circuit 30A optimizes the transfer of the electrical power generated by the transmitter 20A between the primary antenna L3 (source) and the secondary antenna (load, not shown). To this end, the matching circuit 30A comprises a first branch, connected firstly to the transmitter 20A by a first input terminal E1, and secondly to the primary antenna L3 by a first output terminal S1 , and a second branch connected on the one hand to the transmitter 20A by a second input terminal E2, and on the other hand to the primary antenna L3 by a second output terminal S2. The primary antenna L3 is connected between the first output terminal S1 and the second output terminal S2.

The first branch comprises an inductor L1 and a capacitor C1. A capacitor C2 is connected in parallel with a resistor R1 between the first output terminal S1 and the ground M. A capacitor C3 is connected between the midpoint of the inductance L1 and the capacitor C1 and the ground M.

The second branch comprises an inductor L2 and a capacitor C4. A capacitor C5 is connected in parallel with a resistor R2 between the second output terminal S2 and the ground M. A capacitor C6 is connected between the midpoint of the inductor L2 and the capacitor C4 and the ground M. The inductor L1 and the capacitor C3 form a first filter of "LC" type and the inductance L2 and the capacitor C6 form a second filter of "LC" type. By way of example: L1 = L2 = 220 nH, C3 = C6 = 1 nF, C1 = C4 = 128.2 pF,

C2 = C5 = 47 pF L3 = 1.7 μΗ

R1 = R2 = 5.1 kQ

The nature of the terminals can however vary significantly according to their type (passive badge, active smartphone ...) and each terminal has settings specific to its secondary antenna, including its resonance frequency, its quality factor and its coupling level with a primary antenna. Thus, the modification of the voltage at the terminals of the primary antenna by the terminal depends on the nature of said terminal. In particular, some terminals will decrease the voltage across the antenna L3 while others will increase, especially depending on whether their resonant frequency is lower or higher than the frequency at which the primary antenna works, by example 13.56 MHz. It then becomes difficult to design a reader to operate with a range of terminals working at significantly different resonance frequencies, for example for resonance frequencies between 12 MHz and 18 MHz.

There is therefore a need for a simple and effective reader solution operating with a wide variety of terminals. The invention firstly relates to an authentication reader for an opening of a motor vehicle, said reader comprising a microcontroller, a transmitter, a first matching circuit and a first antenna called "primary".

The reader is remarkable in that it comprises a second matching circuit, different from the first matching circuit, and a second so-called "primary" antenna, and in that the microcontroller is able to control the transmitter so that said transmitter alternatively generates at least one electric current in said first matching circuit allowing the first primary antenna to transmit at least one electrical signal to a so-called "secondary" antenna of an authentication terminal, and at least one an electric current in said second matching circuit enabling the second primary antenna to transmit at least one electrical signal to a so-called "secondary" antenna of an authentication terminal. The emission of alternating electrical signals by two different matching circuits makes it possible to detect a wide variety of authentication terminals, each matching circuit being adapted to enable the reader to detect the presence of terminals whose resonance frequency of the secondary antenna is less than or greater than an average value, corresponding for example to the working frequency of the primary antenna of the prior art solution described above, for example 13.56 MHz.

Preferably, the first matching circuit is configured to adapt the first primary antenna to a secondary antenna whose resonant frequency is lower than an average value (for example between 90% and 99.9% of said average value), and the second matching circuit is configured to adapt the second primary antenna to a secondary antenna whose resonant frequency is greater than said average value (for example between 100.1% and 110% of said average value).

Preferably, the first matching circuit comprises a branch connected on the one hand to the transmitter by an input terminal and on the other hand to the first primary antenna by an output terminal and comprising a first capacitor connected between the terminal d input and the output terminal, the first primary antenna being connected to ground, the first matching circuit further comprising a second capacitor connected on the one hand to the output terminal and on the other hand to the mass.

Advantageously, the branch further comprises an inductor, connected between the input terminal and the first capacitor, and a third capacitor, connected between the midpoint of said inductor and the first capacitor and the mass, thus forming a filter of the type "LC".

Advantageously, the first adaptation circuit further comprises a resistor connected in parallel with the first primary antenna between the output terminal and the ground.

Preferably, the second matching circuit comprises a branch connected on the one hand to the transmitter by an input terminal and on the other hand to the second primary antenna by an output terminal and comprising a first capacitor connected between the terminal d input and output terminal, the second primary antenna being connected to ground, the second matching circuit further comprising a second capacitor connected on the one hand to the output terminal and on the other hand to the mass.

Advantageously, the branch further comprises an inductor, connected between the input terminal and the first capacitor, and a third capacitor, connected between the midpoint of said inductor and the first capacitor and the mass, forming an LC filter.

Advantageously, the second adaptation circuit further comprises a resistor connected in parallel with the second primary antenna between the output terminal and the ground.

Advantageously, the cutoff frequency of the LC filter of the first matching circuit is different from the cutoff frequency of the LC filter of the second matching circuit. The invention also relates to a motor vehicle comprising at least one opening, said opening comprising a drive as presented above. The invention also relates to an authentication system for locking or unlocking at least one opening leaf of a motor vehicle, said system comprising at least one authentication terminal and a motor vehicle as presented above. The invention finally relates to a method of authenticating an authentication terminal by an authentication reader mounted in a motor vehicle door.

Said method, implemented by said reader, is remarkable in that it alternatively comprises the steps of generating at least one electric current in the first matching circuit enabling the first primary antenna to transmit at least one signal electrical supply to a so-called "secondary" antenna of an authentication terminal, and the generation of at least one electric current in the second matching circuit enabling the second primary antenna to emit at least one electrical signal to a secondary antenna of an authentication terminal. Other features and advantages of the invention will become apparent from the following description given with reference to the appended figures given by way of non-limiting examples and in which identical references are given to similar objects. - Figure 1 schematically illustrates an embodiment of a reader of the prior art. - Figure 2 schematically illustrates an embodiment of the system according to the invention. - Figure 3 schematically illustrates an embodiment of the reader according to the invention. - Figure 4 schematically illustrates an embodiment of the method according to the invention.

FIG. 2 diagrammatically shows a near-field communication authentication system according to the invention.

In this example, the system 0 comprises a first authentication terminal 2-1, for example a passive near field communication badge, and a second authentication terminal 2-2, for example a near field communication smart phone. The system 0 also comprises an authentication reader 1B mounted in an opening of a motor vehicle (not shown), for example in a door or a trunk, in particular in a door handle.

FIG. 3 shows schematically an embodiment of the authentication reader 1B according to the invention.

The reader 1B comprises a microcontroller 10B, a transmitter 20B, a first matching circuit 30-1, a first so-called "primary" antenna L4, a second matching circuit 30-2 and a second so-called "primary" antenna L6.

The first adaptation circuit 30-1 comprises a branch B1 connected on the one hand to the transmitter 20B by an input terminal E11 and on the other hand to the first primary antenna L4 by an output terminal S11, said branch B1 comprising a first capacity C7.

The first primary antenna L4 is connected between the output terminal S11 and the ground M.

The first matching circuit 30-1 further comprises a second capacitor C8 connected on the one hand to the output terminal S11 and on the other hand to the ground M.

In this preferred example, the branch B1 further comprises (but optionally) an inductance L5, connected between the input terminal E11 and the first capacitor C7, and a third capacitor C9, connected between the midpoint P1 of said inductor. L5 and the first capacitor C7 and the ground M. The inductance L5 and the third capacitor C9 form an LC filter for suppressing the harmonics of the 13.56 MHz signal.

Still in this example, the first matching circuit 30-1 finally (also optionally) comprises a resistor R3 connected in parallel with the first primary antenna L4 between the output terminal S11 and the ground M.

The second matching circuit 30-2 comprises a branch B2 connected on the one hand to the transmitter 20B by an input terminal E21 and on the other hand to the second primary antenna L6 by an output terminal S12, said branch B2 comprising a first capacity C10.

The second primary antenna L6 is connected between the output terminal S12 and the ground M.

The second matching circuit further comprises a second capacitor C11 connected on the one hand to the output terminal S12 and on the other hand to the ground M.

In this preferred example, the branch B2 further comprises (but optionally) an inductance L7, connected between the input terminal E21 and the first capacitor C10, and a third capacitor C12, connected between the midpoint P2 of said inductor. L7 and the first capacitor C10 and the mass M forming an LC filter.

Preferably, the cutoff frequency F1 of the LC filter of the first matching circuit 30-1, defined by

, is different from the cutoff frequency F2 of the LC filter of the second matching circuit 30-2, defined by

Still in this example, the second matching circuit furthermore (also optionally) comprises a resistor R4 connected in parallel with the second primary antenna L6 between the output terminal S12 and the ground M.

The microcontroller 10B is able to control the transmitter 20B so that said transmitter 20B alternately generates: at least one electric current in said first matching circuit 30-1 allowing the first primary antenna L4 to emit at least one electrical signal to destination of the secondary antenna of an authentication terminal 2-1,2-2, and • at least one electric current in said second matching circuit 30-2 allowing the second primary antenna L6 to transmit at least a signal

to the secondary antenna of an authentication terminal 2-1.2-2.

The values of the components of the first matching circuit 30-1 and the second matching circuit 30-2, in particular the capacitors C7, C8, C10 and C11, are chosen so that the first primary antenna L4 and the second primary antenna L6 are respectively adapted to a secondary antenna whose resonance frequency is lower or higher than the working frequency of the first primary antenna L4 or the second primary antenna L6 (or vice versa).

For example: L5 = 220nH, C9 = 1nF, C7 = 234pF, C8 = 153pF, R3 = 3.3kQ, L4 = 0.78μl, L7 = 220nH, C12 = 180pF, C10 = 74pF, C11 = 258 μF, R4 = 3.3 kΩ, L6 = 0.78 μM. The invention will now be described in its implementation with reference to FIG. 4.

The implementation of the invention consists in that the microcontroller 10B controls the transmitter 20B to generate alternately, in a step E1, at least one electric current in the first matching circuit 30-1, allowing the first primary antenna L4 to emit at least one electrical signal to the secondary antenna of an authentication terminal 2-1, 2-2, and, in a step E2, at least one electric current in the second circuit D 30-2 adaptation allowing the second primary antenna L6 to transmit at least one electrical signal to the secondary antenna of an authentication terminal 2-1,2-2.

The alternative generation of currents in the first matching circuit 30-1 and in the second matching circuit 30-2 makes it possible to adapt the first primary antenna L4 or the second primary antenna L6 to a secondary terminal antenna 2-1. , 2-2.

For example, the method according to the invention makes it possible to adapt one of the first primary antenna L4 or the second primary antenna L6 with the secondary antenna of a first terminal 2-1 whose resonance frequency is low and the other of the first primary antenna L4 or the second primary antenna L6 with a second terminal 2-2 whose resonance frequency is higher, thus making it possible to detect both the first terminal 2-1 and the second terminal 2 2.

Claims (10)

An authentication reader (1B) for a motor vehicle door, said reader (1B) comprising a microcontroller (10B), a transmitter (20B), a first adaptation circuit (30-1) and a first so-called "primary" antenna (L4), the reader (1 B) being characterized in that it comprises a second matching circuit (30-2) and a second so-called "primary" antenna (L6), and in that the microcontroller (10B) is able to control the transmitter (20B) so that said transmitter (20B) alternately generates: • at least one electric current in said first matching circuit (30-1) allowing the first primary antenna (L4 ) transmitting at least one electrical signal to a so-called "secondary" antenna of an authentication terminal (2-1, 2-2), and • at least one electric current in said second matching circuit (30-2) allowing the second primary antenna (L6) to transmit at least one signal l electric to a so-called "secondary" antenna of a terminal (2-1, 2-2) authentication. 2. The authentication reader (1 B) according to the preceding claim, wherein the first matching circuit (30-1) comprises a branch (B1) connected on the one hand to the transmitter (20B) by an input terminal. (E11) and secondly to the first primary antenna (L4) through an output terminal (S11) and comprising a first capacitor (C7) connected between the input terminal (E11) and the output terminal (S11) , the first primary antenna (L4) being connected to ground, the first matching circuit (30-1) further comprising a second capacitor (C8) connected on the one hand to the output terminal (S11). ) and on the other hand to the mass (M). 3. The authentication reader (1 B) according to the preceding claim, wherein the branch (B1) further comprises an inductor (L5), connected between the input terminal (E11) and the first capacitor (C7), and a third capacitor (C9), connected between the midpoint (P1) of said inductor (L5) and the first capacitor (C7) and the ground (M), thereby forming a filter of the "LC" type. 4. The authentication reader (1B) according to one of claims 2 or 3, wherein the first matching circuit (30-1) further comprises a resistor (R3) connected in parallel with the first primary antenna ( L4) between the output terminal (S11) and the ground (M). 5. The authentication reader (1 B) according to any one of the preceding claims, wherein the second matching circuit (30-2) comprises a branch (B2) connected on the one hand to the transmitter (20B) by a input terminal (E21) and secondly to the second primary antenna (L6) via an output terminal (S12) and comprising a first capacitor (C10) connected between the input terminal (E21) and the terminal of output (S12), the second primary antenna (L6) being connected on the other hand to ground (M), the second matching circuit (30-2) further comprising a second capacitor (C11) connected on the one hand at the output terminal (S12) and secondly at the ground (M). 6. The authentication reader (1 B) according to the preceding claim, wherein the branch (B2) further comprises an inductor (L7), connected between the input terminal (E21) and the first capacitor (C10), and a third capacitor (C12), connected between the midpoint of said inductor (L7) and the first capacitor (C10), and the ground (M), thereby forming an "LC" type filter. 7. The authentication reader (1 B) according to claims 3 and 6, wherein the cutoff frequency of the LC filter of the first matching circuit (30-1) is different from the cutoff frequency of the LC filter of the second circuit. adaptation (30-2). 8. Motor vehicle comprising at least one opening, said opening comprising an authentication reader (1 B) according to any one of the preceding claims. 9. System (0) for authenticating the locking or unlocking of at least one opening leaf of a motor vehicle, said system (0) comprising at least one terminal (2-1, 2-2) for authentication and a motor vehicle according to the preceding claim. 10. A method for authenticating an authentication terminal (2-1, 2-2) by an authentication reader (1 B) mounted in a motor vehicle door, said method implemented by said reader ( 1B), being characterized in that it comprises alternately the generating steps (E1) of at least one electric current in the first matching circuit (30-1) allowing the first primary antenna (L4) to transmitting at least one electrical signal to a so-called "secondary" antenna of an authentication terminal (2-1, 2-2), and generating (E2) at least one electric current in the second circuit adaptation circuit (30-2) enabling the second primary antenna (L6) to transmit at least one electrical signal to a secondary antenna of an authentication terminal (2-1, 2-2).