EP3078120A1

EP3078120A1 - Resonant concentrator for improving the coupling between a chip card body and its electronic module

Info

Publication number: EP3078120A1
Application number: EP14825360.2A
Authority: EP
Inventors: BAUMGARTNER Stefan DANLER; Benjamin Mear; Deborah Teboul
Original assignee: Smart Packaging Solutions SAS
Current assignee: Smart Packaging Solutions SAS
Priority date: 2013-12-05
Filing date: 2014-12-03
Publication date: 2016-10-12
Also published as: FR3016491A1; WO2015082781A1; FR3016491B1

Abstract

The invention relates to an inductive coupling device, in particular a chip card with contactless operation, comprising on the one hand an electronic module with contactless operation exhibiting a resonant frequency of the module (F_o), and comprising on the other hand a support provided with a system of antennas (L1,L2) consisting of an antenna (Ll) in the ID1 format and a concentrator antenna (L2), this system of antennas (L1,L2) exhibiting a primary resonant frequency (F_op), characterized in that it comprises a resonant capacitor (C2) connected in parallel across the terminals of the concentrator antenna (L2), in such a way as to create a secondary resonant frequency (F_oc) of the concentrator antenna (L2), which is close to the resonant frequency (F_o) of the electronic module

Description

The invention relates to antennas of the type used for contactless smart cards and electronic passports, and more specifically the so-called amplification antennas. "Booster" in English terminology and which are (interface electromagnetically between the antenna of the electronic module of the smart card and the antenna of the smart card reader.

State of the art there already exists in the state of the art, a standard concentrator, made by an inductor arranged in the body of the smart card.

There is then a system of two antennas in the smart card body, namely a standard format antenna called ID1, called ID1 antenna, intended to be electromagnetically coupled with an external reader, and a concentrator antenna (still more simply designated as the concentrator) close to the format of an electronic module for a smart card, arranged in the card body or on a cover page of an electronic passport booklet. This concentrator antenna is intended to be coupled electromagnetically magnetically with the antenna of the module, and it is connected directly with the antenna ID1.

A network of adjustable capacitors connected in series with the two aforementioned antennas makes it possible to resonate the entire antenna system at a determined operating frequency. Antenna system therefore means the antenna ID1, the concentrator antenna, and the adjustable capacity for adjusting the resonance frequency of the assembly.

The above-mentioned antenna system is electromagnetically coupled to an electronic module which also has an antenna disposed at the periphery of the electronic module and called the antenna of the module, whether it be for example the electronic module of a card smart contactless, or that of a passport electronic. The antenna of the module is limited in terms of the number of turns, the reduced size of the module, it must also receive an electronic chip and possibly galvanic contacts ISO 7816-2 type, for example for so-called dual cards , with contact and non-contact operation.

This known antenna system works and is a clear progress, especially compared to smart cards without concentrator. However, it is still possible to improve the performance of the system, by seeking to minimize radiofrequency energy losses between the module and the concentrator.

In addition, the performance of the antenna system is sensitive to the value of the capacity of the chip used, which varies from one component to another, some chips having a low capacity. Indeed, the antenna of the module being limited in number of turns, its inductance will be relatively low, and the resonance frequency which is determined by the inductance of the antenna of the module and by the capacity of the chip, will then be far from the operating frequency of the card body antenna system. In the worst case, the product, whether it is a contactless smart card or an ePassport, may not meet the standards in force (ISO 14443 and 10373-6).

Document EP 1 385 120 A1 discloses a resonant system in another application context. It has a single capacitance whose value is chosen to obtain a target resonant frequency, but this system has only one resonance frequency.

Another reason for the search for improvement is that the market trend is towards the use of single-sided microelectronic modules of smaller size, which reduces the space available for the antenna of the module, and therefore reduces the number of turns or turns of this antenna. The difference between the resonance frequency of the antenna of the module and the resonance frequency of the antenna system of the card body can cause energy losses in the transmission, and a poor coupling between the antenna system of the body card, and the antenna of the electronic module. The invention will be described with reference to the usual terminology of the components of a contactless smart card or of a dual smart card, it being understood that it can be transposed without limitation to other products of different format, such as electronic passports.

Goals of the invention

A general object of the invention is therefore to provide an improved antenna system structure, particularly for the body of a contactless smart card or for an electronic passport, and which has the aforementioned disadvantages.

Another more specific object of the invention is to compensate for the loss of energy due to the increasing distance between the two resonance frequencies, namely the resonant frequency of the antenna of the module, and the resonant frequency of the system. antennas of the card body, and therefore consequently to improve the operating performance of the overall system.

SUMMARY OF THE INVENTION According to the principle of the invention, a capacitance is added at the terminals of the concentrator, which makes it possible to improve the communication performances, and in particular the quality of the electromagnetic coupling between the antenna system of the card body. and the antenna of the module, the value of this additional capacity is calculated so that the concentrator resonates at a frequency close to that of the antenna of the electronic module.

In practice, the capacitance C of the chip is measured for a given type of chip, the inductance L of the electronic module which will contain this chip, which gives a resonance frequency Fo of the electronic module which is given by the formula: Fo - 1 / 2I1VLC. The resonant frequency of the antenna system is calculated similarly, with an inductance corresponding to the overall inductance of the antenna ID1 and the concentrator, and a low capacitance which is that of the antenna system. These two resonance frequencies are, for reasons previously mentioned, offset, which affects the communication performance of the product

In its basic principle, the invention therefore consists in creating, by adding a capacitor in parallel with the concentrator, a second resonant frequency of the antenna system of the card body, calculated to be close to the resonance frequency of the the antenna of the module, which significantly improves the communication performance.

In an advantageous variant of the invention, the concentrator is in fact made up of two concentrators situated facing each other, and the added capacity is then that which is formed by these two concentrators situated facing one of the other. In addition, the offsets of the two concentrator surfaces due to the manufacturing process are neutralized by means of an additional compensating capacitor, which can be implemented in the form of a compensation pad connected to the terminals of these two concentrators. this compensation pad is for example made by two facing surfaces, and the surface is calculated in such a way that the resulting capacity allows to compensate for the frequency offset.

The invention therefore more precisely relates to an inductively coupled device, in particular a contactless smart card, comprising on the one hand an electronic module with contactless operation having a resonant frequency of the module (F ₀ ), and comprising on the other hand a support provided with an antenna system (L1, L2) constituted by an antenna (L1) in the ID1 format and a concentrator antenna (L2), this antenna system (L1, L2) having a primary resonance frequency (Fop), characterized in that it comprises a resonant capacitance (C2) connected in parallel across the concentrator antenna (L2), so as to create a second resonant frequency of the concentrator antenna (L2 ), called secondary resonant frequency (Foc), closest to the resonance frequency (F ₀₎ of the electronic module, in this manner _/ the hub itself is resonant at a resonant frequency close to the frequency of re module sound. According to a first embodiment of the invention, the resonant capacitance (C2) of the concentrator (L2) is formed by two metal surfaces at least partially facing each other, connected to the terminals of the concentrator (L2).

In an improved variant of the invention, the metal surfaces that form the added capacitor correspond to the surfaces of two partially superposed concentrators, that is to say that the concentrator antenna (L2) is in the form of conductive turns arranged on two sides of the support and the resonance capacitance (C2) of the concentrator is formed by the superposition of turns of the concentrator antenna (L2).

In addition, the invention provides that the offsets in the positioning of these two concentrators under the effect of tolerances of the manufacturing process can be neutralized by means of a compensation capacity.

According to a first embodiment of the capacity compensation means, a portion, for example a half of the surface of the turns of the concentrator antenna (L2), is arranged in staggered relation with another part, for example the other half turns.

According to another embodiment of the capacity compensation means, the latter is constituted by a compensation pad whose surface and shape are designed so that a drift of the capacitance resonant in one direction due to an offset of turns, is compensated by a drift of this capacity of the same amplitude in the other direction due to the compensation pad.

Other features and advantages of the invention will appear on reading the detailed description and the accompanying drawings in which:

FIG. 1 illustrates the equivalent diagram of a conventional system of

inductively coupled technology;

FIG. 2 represents the frequency response of the system of FIG. 3 illustrates the equivalent diagram of the resonant concentrator system according to the invention;

FIG. 4 represents the frequency response of the system according to

the invention, showing two resonance peaks; FIG. 5 illustrates a real embodiment of a system according to the invention, corresponding to the equivalent diagram of FIG. 3;

FIGS. 6A and 6B show two concentrators with turns

superimposed, provided with a compensation pad, in two different states; FIG. 7 represents a cross-section of the frequency adjustment capacity of the concentrator of the system of FIG. 5;

FIG. 8 represents a cross-section of the adjustment capacity achieved using the two concentrators of FIG. 6. Detailed description

Referring to FIG. 1, there is shown the equivalent electrical diagram of a known smart card 1 with contactless operation provided with a concentrator. The smart card 1. comprises a card body 2 and an electronic module 3. The card body 2 comprises an antenna system, namely an antenna 4 in ID1 format, equivalent to a capacitor C in series with an inductor L1. , and an antenna 5 or concentrator, equivalent to an inductor L2.

The electronic module 3 comprises a chip 6 having a resistor R and a capacitance C, and at the terminals of the chip, the antenna 7 of the module, equivalent to an inductor L3,

As shown in FIG. 2, the module 3 has a resonance frequency F, for example 32 Mhz in the example shown.

The antenna system of the card body is equivalent to an antenna ID1 in the form of an inductance inductance L1, connected in series with a concentrator antenna in the form of a inductance inductor L2, and with an adjustable capacitance C1. Capacity adjustment is done in particular by a known method of material removal, known as "trimming", which makes it possible to precisely adjust the capacitance C1 and consequently the resonance frequency F _0p of the antenna system 4,5. , knowing that or

The antenna system 4.5 of the card body 2 has a resonance frequency, called primary resonance frequency, noted Fo _Pf typically quite remote (for example 14 Mhz) of the resonance frequency F _0M of the module, for the reasons explained above.

As explained above, this difference between the resonance frequency of the antenna of the module and the resonant frequency of the antenna system of the card body causes energy losses in the transmission, and a poor coupling between the transmission system and the transmission system. antennas of the card body, and the antenna of the electronic module.

In FIG. 3, only the equivalent diagram of the antenna system 4.5 of the card body corresponding to the invention is shown. It differs from the previous one in that a capacity 8, of value C2, connected in parallel with the antenna 5 of the concentrator which has an impedance L2, has been added.

As can be seen in the frequency response of the system of FIG. 3 "represented in FIG. 4, the antenna system 4.5 now has two resonance peaks, namely the peak corresponding to the previous FOP primary resonance frequency, and a second peak corresponding to a secondary resonant frequency Foc (36 Mhz in the example shown) much closer to the resonance frequency FOM of the module 3.

Thanks to the addition of the capacitor C2, the new resonant frequency of the concentrator, denoted Foc, is brought close to the resonance frequency of the module. It is now in the vicinity of 35 MHz, the difference with the resonance frequency of the module is now only 3 MHz.

The value C2 of the resonant capacitance 8 is chosen so that the secondary resonance peak Foc is close to the resonance frequency of the module 3. The electronic module 3 and the card body 2 now resonating at close frequencies, the performance of contactless communication of the smart card with a remote reader finds improved.

Referring to Figures 5 to 8, the embodiments of the C2 capability are explained.

As shown in FIGS. 5 and 7, this added capacitor C2 can be made for example by adding two conductive surfaces 10, 11 opposite one another on both sides of the support 9 when it is a question of a concentrator single-sided These surfaces 10, 11 are then connected to the terminals of the concentrator 5,

Alternatively, as shown in FIGS. 6 and 8, this capacitor C2 can be made by superimposing tracks 12, 13 of the concentrator 5 on one face with respect to the other, in the case of a double-sided concentrator. In this case, the capacitance C2 formed by the superposition of the tracks 12, 13 depends on the superposition surface. In order to compensate for the variations of the superposition surface, due for example to the tolerances of the manufacturing processes, it may be provided that in a part of the concentrator (for example the left half in the example shown, to the left of the axis of symmetry M), the tracks 12, 13 are superimposed, and in the right half of the concentrator 5, the tracks 12, 13 are offset in staggered rows. In this way, if during the manufacturing process of the concentrator antennas of several successive devices, the alignments of the turns 12, 13 of the left part vary, the alignments of the right part will vary in opposite directions, so that the capacitor C2 will be substantially constant.

In addition to or instead of this measurement, provision may be made for a means for compensating for the capacitance variation C2, in the form of a compensation pad 17, the shape and surface of which are designed in such a way that derives from the resonant capacitance C2 in one direction due to a shift of turns of the concentrator 5, or compensated by a drift of this capacitance of the same amplitude in the other direction.

In another advantageous variant embodiment, the resonant capacitance 8 is configured to be adjustable towards a target value, in particular by removal of material, which makes it possible to further optimize the value of the secondary resonance frequency Foc,

It should be noted that the embodiment with single-sided concentrator is easier to industrialize but with poorer performance, and the embodiment with a double-sided concentrator is more difficult to industrialize because the tracks are superimposed, with positioning tolerances of turns which can generate variations of capacity from one product to another. But the implementation of a compensation pad, as diagrammatically in FIG. 6, or the use of an adjustable capacity 8, makes it possible to control the offset of the tracks of one face with respect to the tracks of the other face.

The shape of the compensation pad is obtained by simulation of offsets of the two sets of tracks relative to each other in all directions in the plane of the card. By iterations from the most usual offsets (in frequency of occurrence and in amplitude), we obtain a form of compensation pad that minimizes the total capacitance variations, that is to say the variations due to both the offset of the tracks and variations in the opposite direction due to the compensation pad.

Advantages of the invention

Ultimately, the invention makes it possible to achieve the goals set. In addition, it reduces the time needed to test the feasibility of an antenna system or to industrialize a system already tested.

The radiofrequency performance of the assembly consisting of the concentrator of the card body and the antenna of the electronic module are increased thanks to the resonant concentrator.

The proposed solution combines the advantages of smart card technology without a physical connection between the module and the antenna, with the possibility of obtaining optimal radio frequency performance, approaching those of wired technology.

In addition, the device according to the invention offers the possibility of limiting the frequency shifts from one component to the other, which are generally due to the lamination of the components. The result is an easier industrialization.

Claims

1 - Inductively coupled device, in particular a contactless smart card, comprising on the one hand a non-contact electronic module having a resonant frequency of the module (Fo), and on the other hand comprising a support provided with an antenna system (L1, L2) consisting of an antenna (L1) in ID1 format and a concentrator antenna (L2), this antenna system (L1, L2) having a primary resonant frequency (Fo _P ) , characterized in that it comprises a resonant capacitance (C2) connected in parallel across the concentrator antenna (L2), able to create a second resonant frequency of the concentrator antenna (12), called secondary resonance frequency ( Foc), close to the resonance frequency (FOM) of the electronic module

2 - Device according to claim 1, characterized in that said concentrator consists of two concentrators located opposite one another, and in that said resonant capacitance is formed by the equivalent capacity of said two concentrators,

3 - Device according to claim 2, characterized in that the resonant capacitance (C2) of the concentrator (L2) is formed by two metal surfaces at least partially opposite, connected to the terminals of the concentrator (L2).

4 - Device according to any one of claims 1 to 3 _r characterized in that the concentrator antenna (L2) is formed as conductive turns disposed on two sides of the support and in that the resonance capacitance (C2) concentrator is achieved by the superposition of turns of the concentrator antenna (L2). 5 - Device according to claim 4, characterized in that it comprises a capacitance compensation means (16) adapted to compensate for variations of the secondary resonance frequency (F _0c ) from one device to another under the effect of the manufacturing process,

6 - Device according to claim 5, characterized in that said capacity compensation means (16) consists of a staggered arrangement of a portion of the surface of the turns of the concentrator antenna (L2), and a provision screw with respect to another part of the surface of the turns of the antenna -concentrator (L2).

7 - Device according to claim 5, characterized in that the capacity compensation means (16) is constituted by a compensation pad (17) designed so that a drift of the resonant capacitor (C2) in one direction due to a shift of turns of the concentrator (L2), is compensated by a drift of this capacitance of the same amplitude in the other direction.

8 - Device according to claim 5, characterized in that the capacity compensation means (16) is constituted by the use of an adjustable resonant capacitor (C2) connected in parallel across the concentrator antenna.