DE102007059168B4 - Communication module with slot antenna - Google Patents

Abstract

Communication module for radio frequency communication comprising a radio module (7, 7 ') having a chip (8) and a slot antenna (2, 19, 27) having an opening (4),
- wherein the radio module (7, 7 ') has an electrically coupled to the chip (8) magnetic coupling antenna (10),
The data and / or the energy being transmitted by coupling between the slot antenna (2, 19, 27) and the magnetic coupling antenna (10),
The radio module (7, 7 ') being positioned in a region of the slot antenna (2, 19, 27) in which the slot antenna (2, 19, 27) has the highest magnetic field strength,
- Wherein the magnetic coupling antenna (10) is arranged together with the chip (8) in an electrically non-conductive potting and
- Wherein the potting body non-positively or non-positively and positively connected to the slot antenna (2, 19, 27).

Description

The invention relates to a communication module for a radio frequency communication comprising a chip having a radio module and an antenna, wherein the antenna is provided with an opening.

Wireless communication modules in a miniaturized design and in particular without their own energy supply find in logistics with the Radio Frequency Identification (RFID) a rapidly increasing distribution, which allows a very inexpensive realization under a variety of application situations. Particularly aggravating conditions arise when using the communication modules on large, electrically conductive surfaces. This can be metal surfaces, but also containers with z. As aqueous solutions.

From the DE 20 2007 006 597 U1 a patch antenna with a capacitive coupling of a transponder chip is known. The patch antenna is basically suitable for use on larger, electrically conductive surfaces. However, a disadvantage is the relatively complicated construction of the patch antenna from a sequence of dielectric and electrically conductive layers. The application of the transponder chip is also required individually. Antenna structure and contacting lead to a technological effort that may cause inadequate economic efficiency.

From the DE 10 2006 029 248 A1 a communication module for radio frequency communication is known, which consists of a slot antenna on the one hand and on the other hand of a transponder module, which can be manufactured separately. The transponder module essentially has a chip. Furthermore, the transponder module has two contact surfaces which are arranged on surfaces of the transponder module facing away from one another and ensure contact between the transponder module and the slot antenna. Since the slot antenna has a very high connection impedance at the contact point described, suitable designs are proposed which also allow impedance matching. A disadvantage of this known solution is that the surfaces of the antenna facing away from one another are to be contacted with contact surfaces of the transponder module. In addition, such internals at the point of contact of the antenna because of the highest impedance existing there disturbing effect on the radio technical properties.

From the post-published DE 10 2006 062 308 A1 For example, a communication module for radio frequency communication is known, which contains a radio module with a chip and an antenna. The chip and the antenna are applied to a film and attached by gluing to an opening of a slot antenna or fixed by a potting compound.

From the WO 2006/028707 A1 a communication module for a radio frequency communication is known, which has a radio module on the one hand and an antenna on the other hand. The radio module has a chip and a magnetic coupling antenna connected to the chip, so that data and / or energy can be transmitted by coupling between the antenna and the magnetic coupling antenna. A disadvantage of the known communication module is that for coupling between the antenna and the coupling antenna of the radio module, the antenna designed as a dipole antenna has an additional loop section in which the coupling antenna is arranged. As a result, the dimensioning of the dipole antenna must be greater than if no electromagnetic coupling with the radio module would be provided.

It is therefore an object of the invention to develop a communication module in such a way that the supply of a high-frequency signal is improved in a radio module with a low production cost.

The object is solved by the patent claim 1.

The particular advantage of the invention is that the antenna effect of a metallic component can be used with an opening for feeding or transmitting a high-frequency signal without a module having the chip must be galvanically coupled to the antenna. The basic idea of the invention is to position a radio module containing a chip and a magnetic coupling antenna in a region of the antenna in which the highest magnetic field strength forms on the antenna. The high-frequency signal is thus impressed into the radio module by coupling the antenna with the magnetic coupling antenna of the radio module. The transmission of the high-frequency signal thus takes place by means of a relatively large antenna, which is delimited by a metallic surface, and a relatively small magnetic coupling antenna (conductor loop), which is arranged integrated in the radio module.

A basic idea of the invention is therefore to couple an antenna and a radio module via the magnetic field, for example a slot antenna, in that the radio module is composed of only a very short magnetic coupling coupling loop with the connected radio chip and this Radio module is placed in the place of highest magnetic field strength of the slot antenna.

The slot antenna has the highest electric field strength in the open aperture in the central region of the two opposing surfaces. On the other hand, it has the highest magnetic field strength at the slot ends. By this property, it transforms the received radio wave with the free space impedance in the center of the antenna into a strong electric field and at the narrower antenna sides into a magnetic field. This can be coupled out with the short magnetic frame of the radio module and fed to the radio electronics or the radio chip.

In one embodiment of the invention, the small magnetic frame may be formed as a chip carrier, so that manufacturing may be done with standard technologies of mounting and encapsulating the semiconductor technology.

In a further embodiment, the radio chip can be embedded in a trim part or functional part made of plastic. The slot antenna is then formed by a label from a label carrier having a metallization or otherwise electrically conductive layer in which the slot antenna is machined. This makes it possible to tune the communication module by simply changing the label to different frequencies.

In another embodiment, the antenna arc is designed as a circular arc, so that the radio module can be placed simultaneously on both slot ends, whereby the sensitivity is improved. At the same time a lesser influence of the position of communication module and reader is achieved.

Embodiments of the invention are explained below with reference to the drawings.

Show it:

1 a perspective view of a slot antenna with marked magnetic field lines at the slot ends,

2 a top view of a radio module,

3 a top view of a with a slot antenna and arranged at a slot end radio module communication module according to a first embodiment,

4 a perspective view of a communication module according to another embodiment,

5 a perspective view of a communication module with an annular slot antenna,

6 a top view of a carrier tape for receiving a chip and a magnetic coupling antenna (conductor loop),

7 a plan view of a communication module with an antenna having an oval-shaped opening,

8th a plan view of a communication module according to 7 wherein the antenna has projecting metal rods in a central region, and

9 a plan view of a communication module according to another embodiment with two each arranged at the ends of the opening radio modules.

A communication module 1 consists on the one hand of an antenna 2 made of a sheet metal body 3 and an opening 4 is formed. How out 1 can be seen, the antenna can 2 For example, be designed as a slot antenna, wherein the opening 4 is formed by a slot of predetermined length L. The antenna 2 consists of a temperature-stable metal material, which may for example be mounted on a component of a motor vehicle or injected, for example, in a plastic lid of a garbage can.

The opening 4 the slot antenna 2 is formed as a recess formed by the electrically conductive metal body (sheet metal) 3 is surrounded. The length L of the slot 4 is tuned to the wavelength of the high-frequency signal to be transmitted. The length L of the opening 4 the slot antenna 2 corresponds to half the wavelength or a multiple of half the wavelength of the feeding high-frequency alternating current (high-frequency signal). The high-frequency signal is preferably operated in the vicinity of the UHF range (868 MHz, 2.45 GHz).

Out 1 is by specifying magnetic field lines 5 It can be seen that the maximum magnetic field strength at slot ends 6 of the slot 4 established.

The communication module 1 also has a in 2 illustrated radio module 7 on, essentially from a chip 8th and a conductor loop 10 is formed. The chip 8th is about contact surfaces 9 with the conductor loop having an antenna function (loop antenna) 10 electrically conductive contacted. The chip 8th and the conductor loop 10 are on an electrically non-conductive support 11 arranged.

According to a first embodiment of the invention according to 3 has the communication module 1 the slot antenna 2 on, at the front end portion 12 the radio module 7 is attached non-positively and / or positively and / or cohesively. For example, the wireless module 7 by bonding to the front end region 12 the slot antenna 2 be attached. The radio module 7 is thus located in an area of the slot antenna 2 in which the slot antenna 2 having the highest magnetic field strength. The high frequency signal - and thus the data and / or energy - thus becomes subject to electromagnetic coupling between the slot antenna 2 and the conductor loop 10 into the radio module 7 coupled. Preferably, the length L of the antenna 2 to the length of the conductor loop 10 Voted. The length of the conductor loop 10 can be from the attenuation of the antenna 2 and / or be dependent on the impedance of the on-chip circuit. The radio module 7 can be directly at the end of the slot 6 the opening 4 or near the slot end 6 be attached.

An embodiment of the invention according to 4 differs from the communication module 1 according to 3 in that a metal body 13 with opposite mounting flanges 14 is provided so that the communication module 15 In a simple way to functional components can be fastened. The design of the slot antenna 2 and the radio module 7 agree with the previous embodiment.

The same components or component functions of the different embodiments are provided with the same reference numerals.

According to a further embodiment of a communication module 16 according to 5 is a square metal body 17 with end opposite mounting flanges 18 provided, which has an annular slot 19 as an antenna. The radio module 7 is in the range of an end 20 of the ring slot 19 arranged. The annular slot 19 is formed as a circular ring cutout, which extends along an obtuse angle, for example 300 °. The length of the annular slot 19 is approximated to half the wavelength of the high frequency signal (operating frequency) or to a multiple of half the wavelength of the high frequency signal.

In 6 is a carrier 21 (Chip Carrier) for the assembly of a multiplicity of radio modules 7 and the subsequent enclosure with known per se methods of semiconductor technology. In an electrically conductive carrier tape 22 the antenna rings become conductor loops 23 elaborated. So that they are not lost, they stay with bars 24 stand on the edge strip. At the open ends of the conductor loops 23 becomes the chip 8th placed and contacted. After casting the thus formed component containing the chip 8th and the conductor loop 23 be the edge strips along the line 25 separated.

According to a further embodiment of a communication module 26 according to 7 is a plate-shaped metallic antenna 27 with an oval or ellipsoidal opening 28 intended. The radio module 7 is at a front edge 29 the oval opening 28 fastened, wherein the attachment preferably in a region of a contour of the oval opening 28 takes place, which has the strongest curvature. The length of the oval opening 28 is - as described above - adapted to the wavelength of the high frequency signal.

According to a further embodiment of a communication module 30 according to 8th is - as according to the embodiment according to 7 - An oval-shaped opening 32 each with projecting in a central region webs 33 provided, which is symmetrical to a longitudinal axis of the oval-shaped opening 32 abut each other. As a result, the formation of the electric and magnetic field can be improved.

According to a further embodiment of a communication module 34 according to 9 is a slot antenna 2 - As according to the embodiment according to 3 - intended. In contrast to the previous embodiments are at the antenna 2 two radio modules 7 . 7 ' placed. The one radio module 7 is at a first slot end 6 , the other radio module 7 ' at the opposite end of the slot 6 ' the slot-shaped opening 4 attached. Advantageously, thereby the use of different radio services, modulations or codes are made possible.

How out 4 can be seen, the chip can 8th of the radio module 7 also on a slit end 6 remote side of the radio module 7 be arranged. In the embodiment according to 3 is the chip 8th on one end of the slit 6 . 12 facing side of the radio module 7 arranged.

According to an embodiment of the invention, not shown, the antenna 2 also be formed open at a slot end. One end of the antenna 2 thus has an opening from which the slot 4 corresponding to the predetermined length in the longitudinal direction of the antenna 2 extends. The radio module 7 is on a side facing away from the open end side in the end region 12 of the slot 4 arranged. This embodiment essentially corresponds to the embodiment according to FIG 4 in which the metal body 13 at the end of the slot 6 , no radio module 7 is assigned, is cut off.

Claims (5)

Communication module for radio frequency communication comprising a chip ( 8th ) radio module ( 7 . 7 ' ) and a slot antenna ( 2 . 19 . 27 ) with an opening ( 4 ), - the radio module ( 7 . 7 ' ) one electrically with the chip ( 8th ) connected magnetic coupling antenna ( 10 ), the data and / or the energy being coupled between the slot antenna ( 2 . 19 . 27 ) and the magnetic coupling antenna ( 10 ), the radio module ( 7 . 7 ' ) in an area of the slot antenna ( 2 . 19 . 27 ), in which the slot antenna ( 2 . 19 . 27 ) has the highest magnetic field strength, - wherein the magnetic coupling antenna ( 10 ) together with the chip ( 8th ) is arranged in an electrically non-conductive potting and - wherein the potting body frictionally or non-positively and positively with the slot antenna ( 2 . 19 . 27 ) connected is. Communication module according to claim 1, characterized in that the slot antenna ( 2 . 19 . 27 ) one on the length of the magnetic coupling antenna ( 10 ) of the radio module ( 7 . 7 ' ) has tuned length (L). Communication module according to claim 1 or 2, characterized in that the length (L) of the opening ( 4 ) of the slot antenna ( 2 . 19 . 27 ) is tuned to the wavelength of the high-frequency signal to be transmitted. Communication module according to one of claims 1 to 3, characterized in that the length (L) of the opening ( 4 ) of the slot antenna ( 2 . 19 . 27 ) corresponds to half the wavelength or a multiple of half the wavelength of the high-frequency signal to be transmitted. Communication module according to one of claims 1 to 4, characterized in that the radio module ( 7 . 7 ' ) at one end ( 6 . 6 ' ) of the slot of the slot antenna ( 2 ) is arranged.

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