FR3071366A1 - ANTENNA, ELECTRONIC MODULE AND COMMUNICATION ASSEMBLY COMPRISING SUCH ANTENNA - Google Patents

Abstract

An antenna (3) comprises a printed circuit (4) carrying a radiating element (2) on one of its faces. The antenna also comprises an insert (9) on the printed circuit (4), said insert (9) comprising a ground plane (6) of the antenna (3), said ground plane (6) being distance from said printed circuit (4). An electronic module (1) and a communication set are also described.

Description

Antenna, Electronic module and communication set including ONE SUCH ANTENNA

Technical field to which the invention relates

The present invention relates generally to the field of radio frequency antennas.

It relates more particularly to an antenna, an electronic module and a communication assembly comprising such an antenna.

TECHNOLOGICAL BACKGROUND

Patch type radio frequency antennas are known which include a ground plane and a radiating element separated from this ground plane by a dielectric substrate. These antennas are used in particular in transmitter or receiver systems for controlling (opening / closing) the doors of a motor vehicle.

Object of the invention

The present invention proposes to improve the design of radio frequency antennas and in particular the antennas on board for example in a vehicle.

More particularly, an antenna is proposed according to the invention comprising a printed circuit carrying a radiating element on one of its faces, characterized in that it comprises an insert on the printed circuit, said insert comprising a ground plane from the antenna, said ground plane being at a distance from said printed circuit.

The use of the insert allows greater flexibility in the distance between the ground plane and the radiating element in the usual design of this type of antenna. This variable distance between the ground plane and the radiating element then makes it possible to obtain a bandwidth for the antenna that is adaptable and sufficient for the intended use.

Other non-limiting and advantageous characteristics of the antenna according to the invention, taken individually or in any technically possible combination, are the following:

- said insert is mounted on the printed circuit, on a face opposite to that comprising the radiating element;

- The region of said opposite face located to the right of the radiating element is devoid of conductive element;

- the region of said opposite face located to the right of the radiating element is devoid of electronic components;

- said insert is connected to a conductive track located on the face of the printed circuit opposite the radiating element;

- Said insert comprises a plurality of openings.

The invention also provides an electronic module comprising such an antenna.

This electronic module may further comprise an electronic circuit connected on the one hand to the radiating element and on the other hand to the insert, and / or an impedance matching circuit connected to said antenna.

The invention also provides a communication assembly comprising a box and the antenna, in which said box can for example be made of an electromagnetically neutral material.

Detailed description of an exemplary embodiment

The description which follows with reference to the appended drawings, given by way of nonlimiting examples, will make it clear what the invention consists of and how it can be carried out.

In the accompanying drawings:

- Figure 1 is a sectional view of an electronic module comprising an antenna according to the invention;

- Figures 2a and 2b are respectively top and bottom views of an exemplary embodiment of said electronic module;

- Figure 3 is a view of the housing that can contain the electronic module;

- Figure 4 represents a simulation of the losses by reflection related to the adaptation of the antenna without and in the presence of neighboring metal surface; and

- Figure 5 shows possible examples for the installation of the communication assembly in a motor vehicle.

Figure 1 shows a sectional view of an electronic module 1 usable for example in a vehicle such as a motor vehicle.

The electronic module 1 comprises an electronic circuit 5 and an antenna 3. The antenna 3 comprises a part of a printed circuit 4, a radiating element 2 and an insert 9. The electronic circuit 5 comprises a (other) part of the circuit printed 4, different from that included in the antenna 3.

The printed circuit 4 consists of one or more thin layers of copper, separated by an insulating material. The printed circuit has a standard thickness, typically 0.8 mm.

The radiating element 2 is printed on the upper layer of the printed circuit 4. The radiating element 2 is therefore flat and made of conductive material, typically of metallic material (here copper).

The region of the lower layer of the printed circuit 4 located in line with the radiating element is devoid of conductive elements or electronic components. The radiating element 2 is in turn connected to the electronic circuit 5 via a conductive track 13 located on the upper layer of the printed circuit 4.

The electronic circuit 5 comprises for example an integrated circuit 15, itself connected to the antenna 3 via the conductive track 13. The integrated circuit 15 can for example correspond to a control circuit when the antenna 3 operates in transmission. As a variant, when the antenna 3 operates on reception, the integrated circuit 15 makes it possible to measure the voltage across the terminals of the antenna 3 and thus to determine the electromagnetic signal received by the antenna 3. In practice, the electronic module 1 could be a transceiver (or "transceiver" according to the designation of origin Anglo-Saxon sometimes used). In FIG. 2a representing a top view of the electronic module 1, the element 20 corresponds to the feed point of the antenna 3.

The insert 9 is mounted on the face of the printed circuit 4 opposite to that comprising the radiating element 2. The insert 9 is therefore mounted at the lower layer of the printed circuit 4. In practice, the insert 9 is by example fixed to the printed circuit 4 by soldering. Alternatively, it can also be fitted with plug-in connectors (or "press-fit" according to the designation of origin Anglo-Saxon) which will be fitted into transverse openings appropriately sized on the printed circuit 4. The part insert 9 comprises a bottom, which forms a ground plane 6 of the antenna 3, and side walls 7. The thickness of the insert 9, that is to say the height of the side walls, is between 2 mm and 5 mm.

The ground plane 6 is thus located at a distance from the printed circuit 4, by being for example parallel to the printed circuit 4.

The insert 9 forms, by assembling the ground plane 6 and the side walls 7, an external metal cavity. The volume of air 17 contained in the external cavity formed by the insert 9 (or, as a variant, another dielectric material, for example an electrically insulating gel (neutral gel), contained in this external cavity as explained below) as well as the insulating material of the printed circuit 4 together form a dielectric substrate of the antenna

3.

The insert 9 is connected to a conductive track 11 located on the face of the printed circuit 4 opposite the radiating element 2. This conductive track 11 makes it possible to connect the insert 9 to the electronic circuit 5, precisely at a ground point of the electronic circuit 5 (for example to a ground terminal of the integrated circuit 15). This track 11 carries the overall mass of the system. It is located on the face of the printed circuit 4 opposite the radiating element 2.

The ground plane 6 has openings 8 (these openings having a generally circular shape). These openings allow the passage of an electrically insulating gel as explained below. These openings are shown in the bottom view of the electronic module proposed by FIG. 2b.

The use of the insert 9 makes it possible to overcome the distance imposed between the ground plane 6 and the radiating element 2 in the usual design of this type of antenna. The variable distance (depending on the thickness of the insert 9 chosen) between the ground plane 6 and the radiating element 2 then makes it possible to obtain a bandwidth for the antenna 3 adaptable and sufficient for the intended use.

The electronic circuit 5 also includes an impedance matching circuit 10. This impedance matching circuit 10 typically includes passive electronic components. This impedance matching circuit 10 is connected to the antenna 3. It is placed before the injection point, which constitutes the point of electrical connection to the antenna 3. This injection point is supplied for example by a microstrip line (or "microstrip" according to the Anglo-Saxon designation of origin) or strip lines (or "strip-lines" according to the Anglo-Saxon designation of origin).

The electronic module 1 can in practice be integrated into a housing 30 to form a communication assembly 35. An example of such a housing 30 is shown in FIG. 3. After mounting the electronic module 1 in the housing 30, in this example , the free spaces of the housing 30 can be filled with an electrically insulating gel so that the electronic module 1 is immersed in this electrically insulating gel which will allow the formation of a tight barrier around the electronic module 1. In this exemplary embodiment , as already indicated, the dielectric substrate of the antenna 3 will be constituted by the insulating material of the printed circuit 4 and by the electrically insulating gel.

The design of the electronic module 1 makes it possible to take account of the thickness constraints fixed for said housing 30, here a thickness less than 6 mm. The housing 30 is made of non-metallic material (for example plastic), or of electromagnetically neutral material, which does not disturb the operation of the antenna 3. This housing 30 has no influence on the directivity and radiation from the antenna 3, including in the case where this box 30 is fixed to a metal structure of a vehicle 40 or in the vicinity thereof. FIG. 5 also shows possible examples for the installation of the communication assemblies 35 in the motor vehicle 40.

FIG. 4 represents a simulation of the losses by reflection linked to the adaptation of the antenna 3 when the box 30 is or is not fixed to a metal structure.

This is the case, for example, in the case of an antenna used for transmitting signals of the Bluetooth type, in a frequency band between 2.4 GHz and 2.5 GHz.

In Figure 4, the abscissa axis corresponds to the frequency f of the signal transmitted in GigaHertz (GHz). The ordinate axis corresponds to the reflection coefficient S11, expressed in decibels (dB), characterizing the ratio comparing the power reflected by the antenna with respect to the power introduced into the antenna, for the range of frequencies of interest.

The solid line curve corresponds to a simulation when the communication assembly 35 is not fixed to a metal structure. The discontinuous curve corresponds to a simulation when the communication assembly 35 is fixed to a metal structure (typically a metal structure of the vehicle 40 equipped with the communication assembly 35 described above). Each of these curves shows a minimum peak reflecting a low reflected power, therefore lost, for the antenna 3 studied in the zone of frequencies of interest. In addition, the two curves merge almost over the entire range of frequencies of interest, which shows good stability of the antenna 3 over its bandwidth whether or not this antenna 3 is in contact with a metallic structure. . Finally, the graph in FIG. 4 illustrates the fact that the antenna 3 is not mismatched when the communication assembly 35 is placed against a metallic structure, the ground plane 6 being directed towards the metallic structure and the element radiating 2 located opposite the metallic structure (that is to say that the ground plane 6 is then located between the metallic structure and the radiating element 2). The antenna 3 is not unsuitable whatever the size of this metallic structure. The communication assembly 35, comprising the box 30 and the electronic module 1, could therefore be used as a beacon for transmitting an electromagnetic signal (this signal being transmitted via the antenna 3 described above), by example for detecting the proximity of an identifier (carried by the driver of the vehicle 40) and / or by being integrated into any one of several locations of the metallic structure of the vehicle 40, as schematically represented in FIG. 5.

The antenna 3 as integrated in the electronic module 1 can for example be used in practice for applications in which the frequencies used are between 1700 MHz and 6000 MHz.

Claims (11)

1. Antenna (3) comprising a printed circuit (4) carrying a radiating element (2) on one of its faces, characterized in that it comprises an insert (9) on the printed circuit (4), said insert (9) comprising a ground plane (6) of the antenna (3), said ground plane (6) being at a distance from said printed circuit (4). 2. Antenna (3) according to claim 1, wherein said insert (9) is mounted on the printed circuit (4), on a face opposite to that comprising the radiating element (2). 3. Antenna (3) according to claim 2, in which the region of said opposite face situated in line with the radiating element (2) is devoid of conducting element. 4. Antenna (3) according to claim 2 or 3, wherein the region of said opposite face located in line with the radiating element (2) is devoid of electronic components. 5. Antenna (3) according to any one of claims 1 to 4, wherein said insert (9) is connected to a conductive track (11) located on the face of the printed circuit (4) opposite the radiating element (2). 6. Antenna (3) according to any one of claims 1 to 5, wherein said insert (9) comprises a plurality of openings (8). 7. Electronic module (1) comprising an antenna (3) according to any one of claims 1 to 6. 8. Electronic module (1) according to claim 7, comprising an electronic circuit (5) connected on the one hand to the radiating element (2) and on the other hand to the insert (9). 9. Electronic module (1) according to claim 7 or 8, comprising an impedance matching circuit (10) connected to said antenna (3). 10. Communication assembly comprising a box (30) and an antenna (3) according to any one of claims 1 to 9. 11. The communication assembly according to claim 10, wherein said housing (30) is made of an electromagnetically neutral material.