FR2903231A1 - PRINTED ANTENNA WITH TWO MAGNETIC BUCKLES, PRINTED CIRCUIT AND CORRESPONDING EMBEDDED ELECTRONIC DEVICE - Google Patents

Abstract

The invention relates to an antenna printed on a printed circuit (300) comprising at least a first magnetic loop (31) printed on a first face of the circuit, said first magnetic loop comprising two ends facing one another and defining a first slot (313) .according to the invention, such an antenna comprises a second magnetic loop (32) printed on a second face of the circuit, said second magnetic loop comprising two ends facing one another and defining a second slot and the first (31) and second (32) loops are not electrically connected.

Description

The field of the invention is that of receiving antennas and / or

  transmission of radio signals printed on printed circuits. More particularly, the invention relates to the implementation of such an antenna in an on-board electronic device, such as a car radio.

  The Bluetooth frequency band, between 2400 and 2483.5 MHz, has been chosen for many applications in wireless transmissions, in particular because it does not require a license and a wave transmitted in this frequency band is very rapidly attenuated (notably because of absorption by the water molecules present in the air) and can therefore be used for private transmissions over short distances. There are three main categories of Bluetooth antennas: dielectric antennas, printed antennas and RC antennas. The dielectric antenna is an antenna made of a dielectric material (of ceramic type for example) whose propagation mode is electric in the near field. This type of antenna is very sensitive to electrical interference generated by the metallic environment. As a result, the dielectric antenna must preferably be placed in a medium that is not very metallic and relatively spacious, such as, for example, at the front of a car radio (the facade is generally made of a non-metallic material).

  This dielectric antenna requires the implementation of a ceramic component which makes it expensive and cumbersome (it is difficult to integrate such an antenna). In addition, limitations on its implementation are problematic. RC antennas are cumbersome and also very sensitive to a metal environment. They are therefore not very effective in the automotive environment. Antennas printed directly on printed circuit boards (for example antennas printed in inverted F, also called PIFA for Printed Inverted Frequency Antenna in English, as described in US patent document US2004075610) do not require the use of ceramic components. and allow to obtain a small footprint. The propagation mode of a printed antenna may be an electrical propagation mode or a magnetic propagation mode. In the first case, the antenna is also very sensitive to a metallic environment and therefore inefficient in the automotive environment.

In the second case, the antenna is less sensitive to the metallic environment and makes it possible to obtain a greater gain, a better adaptation, a greater radiated power and / or an increased directivity with respect to a dielectric antenna. In particular, the printed loop antenna is known, as described in US Pat. No. 6,445,263, which comprises a magnetic loop. The particular shape of this loop antenna (in the form of a loop) makes it possible to obtain a magnetic propagation mode in the near field (which corresponds to a distance of less than about 3.8 cm from the antenna in the Bluetooth frequencies). It should be noted that beyond this distance of 3.8 cm (for Bluetooth frequencies), one is in the far field and the loop antenna no longer radiates only in magnetic mode but also in electric mode. There is also a double loop antenna as shown in FIG. 1. This type of double loop antenna 10 comprises a first magnetic loop 11 electrically connected to a second magnetic loop 12 by means of an electrical connection 15. magnetic loop 11 is in fact the antenna that radiates and the second magnetic loop 12 is generally used to match the impedance of the double loop antenna 10, so as, for example, to achieve an antenna adapted to 50 O.

However, a disadvantage of this double loop antenna is that it is bulky and is therefore not suitable for the realization of embedded systems of small dimensions. The invention particularly aims to overcome these disadvantages of the prior art.

More precisely, an object of the invention, in at least one of its embodiments, is to provide a printed antenna with a magnetic propagation mode which is not very cumbersome compared to existing solutions. Another object of the invention, in at least one of its embodiments, is to implement such an antenna whose electrical impedance and resonance frequency can be easily tuned. The invention, in at least one of its embodiments, still aims to provide such an antenna that is easy to achieve and for a low cost. These objectives, as well as others which will appear later, are attained by means of an antenna printed on a printed circuit comprising at least a first magnetic loop printed on a first face of the circuit, said first magnetic loop comprising two ends facing each other and defining a first slot. According to the invention, such an antenna comprises a second magnetic loop 2903231 3 printed on a second face of the circuit, said second magnetic loop comprising two ends facing one another and defining a second slot, the first and second loops not being electrically connected. The general principle of the invention therefore consists in implementing an electromagnetic coupling between two magnetic loops forming a printed antenna so as to be able to arrange the first and second loops respectively on the first and second faces of the printed circuit. Thus, the invention makes it possible to provide a printed antenna with a magnetic propagation mode that is not very cumbersome (because each of the loops is arranged on a different face of the printed circuit) compared with the existing solutions and in particular with respect to the double loop antenna mentioned above. In addition, the printed circuit technology makes it possible to reduce the cost of the antenna and to facilitate its production. It should be noted that such a structure goes against the prior art of the person skilled in the art. Indeed, starting from the conventional double loop antenna, and seeking to solve the problem of reducing the size of this antenna, it would optimize the choice of materials constituting it to reduce its size, but would not consider to remove the electrical connection. Even to consider that the skilled person, seeking to solve this problem, 20 would consider (what it is not encouraged to do) to have the first and second loops of the conventional loop antenna on the first and second faces of the printed circuit, it would have, for this purpose, an electrical connection at the edge of the circuit, which allows to arrange the loops on both sides of the circuit. In doing so, it would not obtain the antenna of the invention, the loops of which are not electrically connected. Advantageously, the width of the first slot is chosen so that the ends of the first loop and the first slot form a capacity for tuning the resonance frequency of the antenna whose value depends on the width of the first slot.

Thus, the proper choice of the width of the first slot allows tuning in particular the resonant frequency of the antenna. Preferably, at least one of the first and second magnetic loops comprises at least two loop segments whose widths are distinct. Thus, the choice of the widths of the loop segments constituting the first and / or the second magnetic loop makes it possible to match the impedance of the antenna. The invention also relates to a printed circuit comprising at least one antenna as described above.

2903231 4 The advantages of the printed circuit are the same as those of the antenna, they are not detailed further. The invention also relates to an onboard electronic device comprising at least one antenna as described above.

Other features and advantages of the invention will appear more clearly on reading the following description of a preferred embodiment, given as a simple illustrative and nonlimiting example, and the appended drawings, among which: Figure 1 shows a diagram of a conventional double loop antenna; FIGS. 2A and 2B show top views (FIG. 2A) and bottom views (FIG. 2B) of a printed circuit comprising a printed antenna according to a first embodiment of the invention; FIGS. 3A and 3B show a complete printed circuit (FIG. 3A) and the portion of this printed circuit (FIG. 3B) on which first and second magnetic loops of a printed antenna are arranged according to a second embodiment of FIG. invention; - Figure 4 shows a car radio based on a printed circuit comprising a printed antenna according to the invention. FIGS. 2A and 2B show top views (FIG. 2A) and bottom views (FIG. 2B) of part of a printed circuit 200 comprising a printed antenna 20 according to a first embodiment of FIG. the invention. The printed circuit 200 carries, on its first face (FIG. 2A), a first magnetic loop 21 comprising two ends 211 and 212 facing each other and defining a first slot 213. The circuit 200 also carries, on its second face (FIG. 2B) a second magnetic loop 22 comprising two ends 221 and 222 25 opposite one another and defining a second slot 223. This antenna 20 is designed to transmit in the Bluetooth frequency band and behaves as a resonant parallel RLC circuit. As illustrated by FIGS. 2A and 2B, the first and second loops are not electrically connected. These FIGS. 2A and 2B show only the part 30 of the printed circuit 200 on which the magnetic loops are arranged. FIGS. 3A and 3B show a complete printed circuit 300 (FIG. 3A) and the portion of this printed circuit 300 (FIG. 3B) on which are disposed first 31 and second 32 magnetic loops of a printed antenna. According to a second embodiment of the invention.

The printed circuit board 300 carries both the printed antenna 30 and an electronic circuit, the assembly constituting, for example, a car radio.

The first magnetic loop 31 is electromagnetically coupled with the second magnetic loop 32 and the printed antenna 30 operates in a magnetic propagation mode. The antenna 30 is thus particularly suited to the automotive context (small size and low sensitivity to the metal environment).

The second magnetic loop 32 (or 22 in the case of FIGS. 2A and 2B) is galvanically connected to the electronic circuit. The first magnetic loop 31 (or 21 in the case of FIGS. 2A and 2B) is the radiating portion of the printed antenna 30 (or in the case of FIGS. 2A and 2B) and determines its resonance frequency. The first 31 and second 32 magnetic loops consist of 10 segments of copper strip (which is conventionally used on printed circuit). Of course, the magnetic loops can be made of any other conductive material. For example, the second loop 32 consists of five segments 324, 325, 326, 327 and 328 forming substantially a rectangle. In FIG. 3B, segments 324, 325, 326, 327 and 328 have been shown with equal widths. Of course, the segments constituting the first 31 and second 32 magnetic loops may be of different widths such as the first 21 and second 22 loops of the first embodiment illustrated by FIGS. 2A and 2B. In the electrical sense, the first magnetic loop 31 made of copper can be modeled electrically by a coil LI associated with a resistor R1 (which represents part of the loss resistance of the printed antenna 30) and with a capacitor C1 below. described. This printed antenna 30 is designed to transmit in the Bluetooth frequency band, more precisely at the 2.45 GHz frequency, and behaves like a resonant parallel RLC circuit. It should be noted that the length of the copper track forming the first magnetic loop 31 must be equal to the wavelength at which the antenna transmits (in this case the Bluetooth wavelength, which is about 12 cm in the vacuum) divided by the refractive index of the circuit board 300. In this case, the length of the first loop is about 6 cm. The ends 311, 312 of the first magnetic loop 31 are positioned opposite one another and define a first slot 313 of small width. Thus, the two ends 311, 312 of the first magnetic loop 31 and the first slot 313 form the capacitor Cl.

The capacity C of the RLC circuit equivalent to the antenna 30 is equal to the sum of the capacitance C1 and capacitance C2. The capacitance C2 which is imposed by the width of the printed circuit 300 (generally C2 is of low value and has little effect on the capacitance C of the RLC circuit). The choice of the width of the first slot 313 makes it possible, in particular, to give the value of the capacitance C1 and thus that of the capacitance C of the circuit RLC equivalent to the antenna 30. This gives the resonance frequency of the antenna 30 at the desired frequency of 2.45GHz. Thus, thanks to the printed antenna of the invention, it is not necessary to use the use of additional capacity (as in some conventional antennas) to adjust the resonance frequency.

It should also be noted that the width of the copper strip segments constituting the first magnetic loop 31 also makes it possible to match the capacitance C1 and therefore the resonance frequency. The second magnetic loop 32 (galvanically connected to the electronic circuit) serves to supply the first magnetic loop 31 (the latter being the radiating part of the antenna) with the energy for the radiation. The second magnetic loop 32 is equivalent to an electrical circuit RL of resistance R2 and of inductance L2 and the first magnetic loop 31 is equivalent to an electrical circuit RLC of resistance R1, of inductance L1 and of capacitor C1. printed antenna 30 is equivalent to an electric circuit RLC, where R = 20 R1 + R2 + R3, L = L1 + L2 + L3 and C = C1 + C2 + C3 (as explained above, C2 not being related to the second magnetic loop 32 but to the printed circuit 3000) where R3, L3 and C3 are respectively resistors, inductance and equivalent capacity related to the influence of the environment of the antenna. By varying the values of the inner surface and the respective widths of the different copper strip segments constituting the second loop 32 (electromagnetically coupled to the first loop 31), the input impedance of the printed antenna 30 can be adjusted to any desired value, for example at 50Q. The input impedance of the printed antenna 30 may also be adjusted by varying the relative positioning of the first loop 31 relative to the second loop 32. It may be noted that the input impedance of the antenna printed 30 can also be adjusted by varying the respective widths of the different segments of copper strip constituting the first loop 31 or by varying the width of the slot 313 (which depends directly capacitance Cl).

Indeed, in accordance with the theory of mutual inductance (otherwise known as the theory of the transformer or inductive coupling), the impedance of the printed antenna 30 depends on the resistors R1, R2, inductors L1 L2 and capacitance C1 of 2903231. first and second loops 31, 32, these resistors, inductances and capacitors themselves depending in particular on the respective widths of the different copper strip segments constituting the first and second loop 31, 32. Once the second loop 32 is energized by the electronic circuit 3000, a current 12 flows in this second loop 32 and generates an electromagnetic field which excites the first loop 31 (equivalent to an oscillating circuit RI, L1, Cl) and therefore induces a current I1 which flows in this first loop 31 The first loop 31 being in resonance at the desired frequency forces an accurate distribution of the current on the segments of copper strip which the constitute, which leads to the realization of a Bluetooth band antenna. The first 31 and second 32 loops of the aforementioned first and second embodiments have a substantially rectangular shape. Of course, the first and second loops of an antenna according to the invention may have any shape, for example circular. Furthermore, the first and second loops of an antenna according to the invention may be identical or distinct. Thus, the impedance of a printed antenna according to the present invention is more stable and can be easily adapted (for example, by varying the value of the capacitance C2) with respect to a conventional electric antenna (having for equivalent circuit, a circuit R, L).

FIG. 4 shows a car radio 40 based on a printed circuit 41 comprising a printed antenna 42 according to the invention. The car radio 40 comprises the printed circuit 41 on which the antenna 42 is mounted and an electronic circuit to which the antenna 42 is electrically connected. A housing 44 comprising mechanical elements is mounted on the printed circuit 41.

The casing of the car radio comprises a frontage 43 as well as first 45, second 46 and third 47 plates.

Claims (5)

  An antenna printed on a printed circuit board (200, 300) comprising at least a first magnetic loop (21, 31) printed on a first face of the circuit, said first magnetic loop comprising two ends facing each other and defining a first slot (213, 313), characterized in that it comprises a second magnetic loop (22, 32) printed on a second face of the circuit, said second magnetic loop comprising two ends facing each other and defining a second slot (223), and said first (21, 31) and second (22, 32) loops are not electrically connected.   Antenna printed according to claim 1, characterized in that the width of said first slot (213, 313) is chosen so that the ends of the first loop (21, 31) and the first slot (213, 313) form a capacity for tuning the resonance frequency of the antenna whose value depends on the width of the first slot.   Antenna printed according to any one of claims 1 and 2, characterized in that at least one of said first (21, 31) and second (22, 32) magnetic loops comprises at least two loop segments whose widths are distinct.   A printed circuit for an on-board electronic device comprising at least one printed antenna according to any one of claims 1 to 3.   On-board electronic device comprising at least one printed antenna according to any one of claims 1 to 3.