EP2047565B1 - Slot antenna and method for rfid - Google Patents

Abstract

The invention relates to a slot antenna, more particularly to a transmitting antenna for RFID, comprising an antenna contour board having a plurality of antenna slots and at least one control circuit for enabling the antenna contour board to transmit and/or receive electromagnetic radiation. The slot antenna is characterized in that in at least one antenna slot of the antenna contour board there is inserted a circuit board carrying a control circuit. The invention further relates to an RFID method involving the use of the slot antenna of the invention.

Description

The present invention relates in a first aspect to a slot antenna, in particular a transmitting antenna for RFID, according to the preamble of claim 1.

In a further aspect, the invention relates to a method for RFID.

A generic slot antenna has at least one antenna contour plate with a plurality of antenna slots and at least one drive circuit for exciting the antenna contour plate for emitting and / or receiving electromagnetic radiation.

Remote radio-frequency identification (RFID) technologies are used in a variety of different areas.

RFID technologies are used, for example, in the military sector, in identity documents, libraries and, in particular, in the field of industrial manufacturing technology and automation.

In industrial environments, difficulties are increasingly arising from the growing number of electrical and electronic devices arranged in confined spaces. In general, the task here is to keep interactions between these devices as low as possible and possibly eliminate them altogether. This includes in particular the utilization of all available frequency ranges, for example by transition to lower wavelengths.

It is also known to use slot antennas for short wavelengths. For example, slot antennas are from the documents WO 2004/062035 . EP 1 602 148 . EP 1 158 606 such as US 5,596,336 known.

Another slot antenna is in US 5,940,041 described. The slot antenna disclosed therein has an antenna contour plate with an antenna slot and a drive circuit for exciting the antenna contour plate for emitting and / or receiving electromagnetic radiation. In the antenna slot while a circuit board is plugged with a drive circuit.

Difficulties arise, for example, due to the ever-increasing complexity of the manufacturing processes, for example in a 3D production. In addition, new process steps will be introduced, for example at final inspections, which also include the RFID process.

Due to the variety of interference and interference of the RFID systems, e.g. Microwave heaters, Bluetooth devices or Wi-Fi networks can therefore cause unwanted interruptions in the connection between the reader or "reader" and the data carrier. This is particularly important because the number of disturbers will increase rather than decrease in the future.

The desired housing dimensions drastically reduce the number of integrable antennas. However, if a minimum sensitivity in the amount of known systems is required, the gain of the antennas must be identical, which appears hopeless when using previously known antennas.

Other types of antennas other than slot antennas are not known or are already eliminated due to increased space requirements.

The object of the invention is to provide a slot antenna, in particular for RFID applications, which allows a variety of applications and also has a particularly compact design. In addition, a method for RFID is to be specified, with which an increased functionality is achieved.

This object is achieved in a first aspect by the slot antenna having the features of claim 1.

In a second aspect of the invention, the object is achieved by the method having the features of claim 12.

Preferred embodiments of the slot antenna according to the invention and advantageous variants of the method according to the invention are the subject of the dependent claims.

The slot antenna of the above type is inventively further developed in that in at least one antenna slot, in particular from a rear side of the antenna contour plate, a circuit board is plugged with a drive circuit.

In the method according to the invention a slot antenna according to the invention is used and by varying the phase position of the drive circuits, a radiation direction of the radiation is selectively changed.

The drive circuit may include components of a feed system for coupling in the necessary drive or feed power. For example, a feed network with suitable drivers and matching circuits may be part of the drive circuit. If the slot antenna is also used for receiving electromagnetic radiation, the drive circuit may also include a receiving circuit or parts thereof.

As a core idea of the invention can be considered to use the existing antenna slots mechanically for accommodating or supporting printed circuit boards, on which the necessary drive circuits for the antenna are housed.

A first essential advantage of the invention can be seen in the fact that a particularly compact, ie space-saving arrangement is realized.

Another important advantage of the invention is that the dielectric properties of the printed circuit board material effectively cause a reduction of the antenna slots and thus a reduction of the wavelength.

As a core idea of the method according to the invention can be considered, in contrast to known RFID methods to change the emission direction of the transmitter or the reader by varying the phase differences between the individual drive circuits targeted.

In expedient variants of the antenna according to the invention, a plurality of antenna slots arranged in pairs are present in the antenna contour plate. It is particularly preferred if two pairs of transverse, in particular mutually perpendicular, slots are present, since then the polarization of the radiation can be selectively varied by suitable control of the slots. With suitable phase position of the respective control of the slots Such an antenna can also emit circularly polarized radiation, as a result of which the functionality of the antenna according to the invention and of the method according to the invention is considerably increased.

In principle, however, even a simple slot antenna with two collinear slots can be sufficient. Such an antenna transmits so-called magnetic dipole radiation with suitable control.

Embodiments in which a plurality of pairs of antenna slots are introduced into the antenna contour plate are preferred. For example, the antenna contour plate may have a rectangular arrangement of four antenna slots or a cross arrangement of likewise four antenna slots.

In a particularly preferred variant, a cross arrangement of likewise four antenna slots is arranged within a rectangular arrangement of four antenna slots. The antenna slots can be considered nested inside each other. The orientation of the cross-shaped antenna slots can be suitably chosen so that the antenna slots are substantially on the diagonal of the rectangular array. This slot arrangement allows a particularly compact design.

Expediently, the drive circuits each have electronic phase shifters for defined setting of a phase position of a drive signal.

The named particularly preferred antenna array with a rectangular arrangement and a cross arrangement of antenna slots located therein accordingly consists of a plurality of slot radiators which are each driven via an electronically adjustable phase shifter. The supply or the drive of the individual antenna slots via a perpendicular or transverse thereto printed circuit board. This circuit board includes the feed zone of the slot radiator, a matching network, the phase shifter, filters, polarization switching and a suitable drive interface. This embodiment is characterized by a particularly high functionality, since a redundancy of the system is achieved by the mutually tilted antenna slots. This means that even with loss of function of individual radiator elements no total failure occurs and such loss of function In any case, they can be partially compensated for by appropriate compensation measures.

In principle, the necessary drive power can be radiated from the drive circuits radiantly into the antenna contour plate. In view of the space requirements, however, the printed circuit boards in a surrounding region of the respective antenna slot are preferably galvanically coupled to the antenna contour plate, in the simplest case thus conductively connected.

In principle, individual antenna slots remain free, if there, possibly for reasons of space, no circuit board can be accommodated or this is not desirable for electrical reasons. However, the structure is simplified if a printed circuit board with a drive circuit is plugged into each antenna slot.

A further simplification is achieved if the same circuit boards are plugged into each antenna slots. By using the same circuit boards with identical drive circuits material can be saved to a considerable extent. In addition, there are significant advantages in terms of storage and significant cost savings are possible.

In principle, the influence of the dielectric properties of the printed circuit board material on the antenna radiation is particularly great when the antenna slots are largely filled by the printed circuit board. By way of example, the printed circuit board may have a tongue, which is received in an exact fit in the respective antenna slot.

Moreover, the higher the relative dielectric constant of the printed circuit board material, the greater the said effect. In principle, therefore, special dielectric materials can be used to achieve the desired miniaturization. However, the comparatively high costs limit the use of such materials.

The structure according to the invention, in which the printed circuit boards are inserted into the antenna slots, is therefore particularly economical because the substrate is efficiently concentrated essentially in the slot area.

The influence of the dielectric properties of the printed circuit board material can be increased if at least one printed circuit board is slightly above a transmitting side of the antenna contour plate survives. Finally, the effect of the inserted printed circuit boards can be further increased if protruding parts of the printed circuit boards are provided with a metallic structuring. For example, it is particularly easy to produce a metallic structuring which is formed from conductor track sections running transversely to the antenna contour plate on the protruding parts of the printed circuit boards.

The circuit boards expediently have a contact with the slot radiator in the region of the antenna slot.

Another important aspect of the slot antenna according to the invention can be seen in this context in that the location at which the feed or drive power is coupled into the antenna contour plate is particularly well defined. Compared to slot antennas from the prior art in which, for example, coaxial cables are soldered, this represents a considerable advantage. For example, the contacting between the antenna contour plate and the printed circuit board can take place by means of a conductor track region becoming increasingly narrower in the direction of the antenna contour plate on the printed circuit board. The location of the actual contact area is then defined very precisely.

The feeding of the slot can therefore be precise and in particular reproducible. This represents a considerable advantage with regard to the requirements for mass production. In this case, one is particularly completely free in the choice of feed points and thus receives an additional degree of freedom that can be used and varied targeted.

In a further preferred embodiment of the antenna according to the invention, the printed circuit boards are plugged into a stabilization plate on an opposite side of the antenna contour plate. This stabilization plate may in turn be a printed circuit board and carry other electronic or electrical components.

Fig. 1

ein Ausführungsbeispiel einer erfindungsgemäßen Schlitzantenne;

Fig. 2

eine Ansicht der Antennenkonturplatte der Antenne aus Fig. 1;

Fig. 3

eine Teilansicht der Antenne aus Fig. 1; und

Fig. 4

eine Veranschaulichung des erfindungsgemäßen Verfahrens.

Further advantages and features of the slot antenna according to the invention and the method according to the invention are described below with reference to the attached schematic figures. Hereby shows:

Fig. 1

an embodiment of a slot antenna according to the invention;

Fig. 2

a view of the antenna contour plate of the antenna Fig. 1 ;

Fig. 3

a partial view of the antenna Fig. 1 ; and

Fig. 4

an illustration of the method according to the invention.

An embodiment of the antenna 10 according to the invention will be described with reference to FIGS FIGS. 1 to 3 described. Corresponding components are each provided there with the same reference numerals.

The antenna 10 according to the invention has, as essential components, an antenna contour plate 20, a plurality of conductor plates 50 with drive circuits 40 arranged thereon, and a stabilization plate 60, which can likewise carry electronic components.

In the Fig. 2 shown antenna contour plate 20 has two mutually orthogonal antenna systems. The first antenna system consists of a rectangular array of four antenna slots 31 and the second slot system consists of four cross-shaped antenna slots 32. The cross-shaped antenna slots 32 are within the rectangle formed by the antenna slots 31 substantially on the diagonal.

The slit systems are therefore in one another and reduce the space required in this way. The problem of driving or feeding the antenna slots is achieved according to the invention by the plugged into the antenna slots 31, 32 printed circuit boards 50th

As in Fig. 3 1, a printed circuit board 50 inserted from a rear side 22 into the antenna contour plate 20 may also protrude slightly on a transmitting side 24 of the antenna contour plate 20. The effect of the dielectric properties of the printed circuit board material are thereby enhanced.

In addition, a projecting portion 54 of the circuit board 50, as also in Fig. 3 schematically shown, have a metallic pattern 52, which causes a field concentration in the antenna slot 30 and thus allows miniaturization. In the in Fig. 3 As shown, the metallic structure 52 consists of transverse to the antenna contour plate 20 extending conductor track sections.

By the in Fig. 1 shown construction, a variety of advantages are achieved. So are with the in Fig. 3 shown in detail construction technology also extremely close spaced antenna slots 31, 32 by the control boards 50, which also carry the electronic circuits 40, controllable.

Particularly preferably, all the antenna slots 31, 32 have identical dimensions, so that in each case uniform feed networks or more generally, printed circuit boards 50 with drive circuits 40 can be used.

Using materials having increased values of relative dielectric constant as the base material for the printed circuit boards 50, this contributes to higher field concentration in the slots and thus to miniaturization. The slot length can be reduced in this way.

At the same time this allows a reduction of the printed circuit boards 50 with the drive circuits 40. On the opposite side of the antenna contour plate 20, a stabilizing plate 60 is attached, which may also be a circuit board with other electrical and / or electronic components.

The in Fig. 1 shown construction with the rear stabilizing plate 60 is characterized overall by an excellent mechanical stability, with extremely compact design, from. The printed circuit boards 50 sitting transversely on the blanks or stamped parts with the drive circuits 40 can receive passive and active components.

At the same time, these drive circuits 40 serve to supply and to connect the antennas via galvanic coupling, in the simplest case therefore via a simple conductive connection. In comparison to radiation-coupled slot antennas this less space is needed.

It is also particularly advantageous if the drive circuits 40 each have electronic phase shifters, since then the beam lobe and / or the directional characteristic of the antenna can be selectively changed by the method according to the invention.

This will be closer with respect to Fig. 4 explained. There, an RFID reader 80 is shown, which is a slot antenna according to the invention of Fig. 3 having shown type. Reference numerals 13, 14, 15 are individual RFID tags at different Locations designated. In the case of a normally aligned beam, denoted by the reference numeral 11, TAG 13 is addressed, whereas in the deflected beam directions 12, 16 the TAGs 14 and 15 are addressed. The change in the directional characteristic of the antenna according to the invention is carried out by targeted adjustment of the phase shifter in the drive circuits 40 of the respective antenna slots 31, 32nd

This results in new applications. For example, a single tag can be tracked using the antenna according to the invention. In addition, individual TAGs can be specifically addressed and read out. A location with multiple readers at the same time is possible. Due to the well-defined directional characteristic of the antenna, certain solid angle ranges can furthermore be deliberately suppressed. This serves the interference suppression described above.

Several readers can be networked into a complex overall system and readers with high directivity and range can be realized. These then have a virtual larger aperture an increased spatial resolution in the location. Both near and far range detection can be realized thereby.

The present invention thus provides a miniaturizable slot antenna system, in particular for use in RFID readers. Such readers work particularly preferably in the microwave range, for example at 2.5 GHz.

An essential core idea of the method according to the invention is to selectively pivot an antenna directivity. With the use of the slot antennas according to the invention, a high-performance and compact antenna system is provided by which, moreover, costs can be saved and which is particularly favorable with regard to the construction and connection technology. The compactness of the antenna is understood in particular also to its reduced dimensions. Compared to the systems on the market, which are significantly larger than the slot antennas described here, a considerable advantage can be achieved thereby. Due to the possibility of beam pivoting, that is an electrically variable directional characteristic of the antenna construction, the density of the readers can be increased without the readers interfering with each other.

Potential interference, such as microwave heaters, can also be hidden. Furthermore, physical impairments can be compensated for and compensated by the immediate environment and the existing boundary conditions. Derived from this results in the possibility of tracking a volume.

Advantageously, the unavoidable in radio propagation zeros, due to stagnant waves, by means of frequency change or "frequency-hopping" and / or by the pivoting of the beam can be eliminated. To regulate the range can be suitably a control of the radiated power transmission, as well as a variation of the sensitivity by means of low-noise preamplifiers are made.

Therefore, with the slot antenna according to the invention so-called "phased-array antennas" can be realized in an advantageous manner. With such antennas, an extremely rapid pivoting of the beam and also a very flexible adaptation of the antenna characteristic can be realized.

Applications of the invention may result in addition to reading systems, data carriers, general radio links, radar sensors and positioning systems in the field of access detection in buildings.

Accordingly, the invention provides a compact, intelligent antenna system with the possibilities of polarization switching and beam steering as a whole.

Claims (15)

1. Slot antenna
   comprising an antenna contour board (20) having a plurality of antenna slots (30) and
   at least one control circuit (40) for stimulating the antenna contour board (20) to transmit and/or receive electromagnetic radiation,
   characterized in that
   in at least one antenna slot (30) of said antenna contour board (20) there is inserted a circuit board (50) carrying a control circuit (40).
2. Slot antenna according to claim 1,
   characterized in that
   said antenna contour board (20) includes a rectangular array of four antenna slots (31).
3. Slot antenna according to claim 1 or claim 2,
   characterized in that
   said antenna contour board (20) includes a cross-wise array of four antenna slots (32).
4. Slot antenna according to claim 3,
   characterized in that
   said cross-wise array of antenna slots (32) is arranged within said rectangular array of antenna slots (31).
5. Slot antenna according to any one of claims 1 to 4,
   characterized in that
   a circuit board (50) carrying a control circuit (40) is inserted in each antenna slot (30).
6. Slot antenna according to any one of claims 1 to 5,
   characterized in that
   identical circuit boards (50) are inserted in all of the antenna slots (30).
7. Slot antenna according to any one of claims 1 to 6,
   characterized in that
   said circuit boards (50) are galvanically coupled to said antenna contour board (20) in a region surrounding the respective antenna slot (30).
8. Slot antenna according to any one of claims 1 to 7,
   characterized in that
   at least one circuit board projects slightly beyond said antenna contour board (20) on its transmitting side (24).
9. Slot antenna according to claim 8,
   characterized in that
   a protruding portion (54) of said circuit board (50) is provided with a metallic structurization (52).
10. Slot antenna according to claim 9,
    characterized in that
    said metallic structurization (52) is in the form of conductor track portions (52) extending transversely to said antenna contour board (20) on the protruding portion (54) of said circuit boards (50).
11. Slot antenna according to any one of claims 1 to 10,
    characterized in that
    said circuit boards (50) are inserted in a stabilizing board (60) on a side (22) opposite to said antenna contour board (20).
12. Method for the operation of a slot antenna according to any one of claims 1 to 11, wherein the slot antenna has a plurality of control circuits (40),
    in which an emitting direction of the radiation is selectively altered by varying the phase relationship of the individual control circuits.
13. Method according to claim 12,
    characterized in that
    suitable selection of the phase relationship of the individual control circuits (40) stimulates said slot antenna to radiate circularly polarized radiation.
14. Method according to claim 12 or claim 13,
    characterized in that
    the control circuits (40), in each case, comprise electronic phase shifters and the beam lobe and/or the directional characteristic of the slot antenna is selectively varied by the electronic phase shifters.
15. Method according to any one of claims 12 to 14,
    characterized in that
    zero points occurring due to standing waves are eliminated by a change of frequency or "frequency hopping" and/or pivoting the beam.

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