EP1297590A1 - Slot antenna - Google Patents

Abstract

Es wird eine Schlitzantenne (1) vorgeschlagen, die zum Betrieb in mehreren Frequenzbereichen nutzbar ist. Die Schlitzantenne (1) umfasst eine von einer ein Bezugspotential bildenden elektrisch leitfähingen Grunfläche (5) abgesetzte erste elektrisch leitfähige Scheibe (10), die an ihrem Aussenrand (15) über mindestens einen ersten elektrisch leitfähigen Steg (20, 21, 22) mit der Grundfläche (5) verbunden ist. Die erste Scheibe (10) umfasst eine Aussparung (25). Oberhalb der Aussparung (25) ist eine zweite elektrisch leitfähige Scheibe (30) angeordnet, die an ihrem Aussenrand (35) über mindestens einen zweiten elektrisch leitfähigen Steg (40, 41, 42) mit der ersten Scheibe (10) verbunden ist. Der zweiten Scheibe (30) ist ein Antennenleiter (45) zugeführt.

Description

slot antenna

State of the art

The invention is based on a slot antenna according to the preamble of the main claim.

A combination flat antenna is already known from W097 / 41619, which combines a mobile radio antenna for an operating frequency of 900 MHz and a GPS antenna (Global Positioning System). The mobile radio antenna consists of a circular electrically conductive disk fed at its center, which is arranged above an electrically conductive base area. The circular disc is connected to the base area on its outer edge by three electrically conductive webs. This creates three circular slot antennas. The GPS antenna is designed as a patch antenna and arranged on the circular disc, so that both antennas can be combined in a compact design.

Advantages of the invention

The slot antenna according to the invention with the features of the main claim has the advantage that the first disc has a recess that above the Recess a second electrically conductive disc is arranged, which is connected at its outer edge via at least a second electrically conductive web with the first disc and that of the second disc

Antenna conductor is supplied. In this way, a cascaded slot antenna can be implemented, which requires only a single common supply by means of the antenna conductor. A radio antenna for two or more f frequency ranges can thus be produced with little effort and in a space-saving manner. A GPS patch antenna can then also be arranged on the second pane. Due to the increase of the invention from the above

Known slot antenna around at least one further resonator, several such resonators can be stacked on top of one another in a compact design.

Advantageous further developments and improvements of the slot antenna specified in the main claim are possible through the measures listed in the subclaims.

It is particularly advantageous that the first disk and the second disk each have an approximately circular circumference. In this way, an omnidirectional diagram without a preferred direction for the slot antenna can be realized as a directional characteristic.

Another advantage is that at least one of the disks is not designed with a circular circumference, but rather, for example, in the form of an n-corner, oval, elliptical or asymmetrical. This results in a distorted directional characteristic with preferred directions for the slot antenna. This distortion of the directional characteristic can be used specifically to compensate for environmental influences. For example, distortion of the directional characteristic of a Such slot antenna arranged on a vehicle, which are caused by the spars or roof edges of the vehicle, are counteracted in such a way that when the distortions caused by the spars or roof edges are superimposed with the distortions formed by the selected shape of the panes, approximately an omnidirectional diagram without preferred directions arises.

A further advantage in the case of disks with a circular circumference is that the circular area of the recess in the first disk is smaller than the circular area of the second disk. In this way, a flatter radiation in the elevation radiation diagram can be achieved with a concentric arrangement of the panes and the recess and with webs arranged at right angles to the panes. A concentric arrangement of the two disks allows concentric directional characteristics to be achieved for the resonators based on the two disks.

It is particularly advantageous that three webs are arranged between the first disk and the base area and that three webs are also arranged between the first disk and the second disk. In this way, each of the two resonators is designed as a multi-slot antenna, by means of which a relatively high transmission and / or reception bandwidth is achieved.

It is particularly advantageous that the webs between the base area and the first disk are rotated by 60 ° relative to the webs between the first disk and the second disk. In this way, mutual interference between the two resonators can be minimized. The current and voltage maxima occurring at the resonators do not coincide, but are electrically offset from each other by 180 °. This creates a current occupancy that enables good radiation at the operating frequency of each of the two resonators.

It is particularly advantageous that between the first

Disc and the second disc at least a third

Disk is provided, which also includes a recess that the third disk over at least one third web, in particular the at least one second

Web corresponds to the outer edge of the directly adjacent pane above it and is connected at its own outer edge via at least a fourth web to the directly adjacent pane below. In this way, a slot antenna can be realized with more than two resonators, each in a different one

Frequency range are resonant, so that a multi-band antenna with more than two frequency ranges for radiation and / or reception of signals can be realized. Through the

Layering the resonators on top of each other enables a compact and space-saving design to be realized.

drawing

Embodiments of the invention are shown in the drawing and explained in more detail in the following description. FIG. 1 shows a first exemplary embodiment of a slot antenna according to the invention and FIG. 2 shows a second exemplary embodiment of a slot antenna according to the invention.

Description of the embodiments

In FIG. 1, 1 denotes a slot antenna which has a first electrically conductive disk which is offset from an electrically conductive base area 5 which forms a reference potential 10 includes. The first disc 10 has an approximately circular outer edge 15. It is designed in the form of a circular ring due to a concentric and approximately circular first recess 25. At its outer edge 15, the first pane 10 is connected to the base 5 via a first electrically conductive web 20, a fourth electrically conductive web 21 and a fifth electrically conductive web 22. The webs 20, 21, 22 mentioned are approximately perpendicular to the first disk 10 and to the base 5 and are each offset from one another by approximately 120 °. A slot antenna element is thus formed between two adjacent webs. The first disk 10, the webs 20, 21, 22 and the base 5 thus form a first resonator element with three slot antenna elements for radiation and / or for receiving radio signals in a first frequency range with a first operating frequency of, for example, approximately 900 MHz as the center frequency of the first frequency range. The diameter of the outer edge 15 of the first disk 10 is to be selected so that the slot antenna elements formed by the three webs 20, 21, 22 each have a length of approximately half the first operating wavelength. The length of the respective slot antenna element corresponds to the length of the outer edge 15 of the first disc 10 between two adjacent webs.

According to FIG. 1, a second electrically conductive disc 30 is arranged above the first recess 25, which is circular in shape and is arranged concentrically with the first disc 10 and the first recess 25. Its diameter corresponds approximately to the diameter of the first recess 25. The second disk 30 is on its outer edge 35 via a second electrically conductive web 40, a sixth electrically conductive web 41 and a seventh electrically conductive web 42 with the first disk 10 connected, the second web 40, the sixth web 41 and the seventh web 42 likewise being approximately perpendicular to the second disk 30 and to the first disk 10. The second web 40, the sixth web 41 and the seventh web 42 contact the first disk 10 at the edge of the first recess 25. The second disk 30 forms with the second web 40, the sixth web 41, the seventh web 42 and the first Disk 10 is a second resonator element of the slot antenna 1. The second web 40, the sixth web 41 and the seventh web 42 are also each offset from one another by approximately 120 °. As in the case of the first resonator element, a slot antenna element is in each case again formed between adjacent webs of the second resonator element. Both the first resonator element and the second resonator element thus each have three slot antenna elements. Since the diameter of the second disc 30 corresponds approximately to the diameter of the first recess 25, the diameter of the second disc 30 is smaller than the diameter of the first disc 10, so that a smaller slot length is achieved for the three slot antenna elements there for the second resonator element. Thus, the second resonator element has a resonance at a second operating frequency which is greater than the resonance of the first resonator element at the first operating frequency and which represents the center frequency in a second frequency range for radiating and / or receiving radio signals. The slot length of the slot antenna elements of the second resonator element, ie the distance between two adjacent webs of the second resonator element are thus spaced apart by approximately half a second operating wavelength, the length of the outer edge of the second disk 30 between adjacent webs of the second resonator element forming this distance and approximately is equal to half the second operating wavelength. An antenna conductor 45 is fed to the second pane 30 via an opening 70 of the base area 5 that is small in comparison to the first recess 25 and is electrically conductively connected to the latter in the center of the second pane 30. However, the antenna conductor 45 is not connected to the first pane 10.

Using the two resonator elements described, the

Slot antenna 1 in two different frequency ranges

Transmitting and / or receiving radio signals are operated.

The second operating frequency can be around 1800 MHz, for example. Due to the circular arrangement of the first disc 10, the second disc 30 and the first

Recess 25 and the use of three each by about

Each of the two resonator elements of the slot antenna 1 has a rotationally symmetrical directional characteristic in the form of a

Omnidirectional diagram with vertical polarization. The respective radiation diagram in the vertical and the horizontal plane corresponds to that of a monopole, for example a lambda / 4 radiator. In addition, the

Slot antenna 1 according to FIG. 1 has an extremely low overall height. Nevertheless, the slot antenna 1 has by its

Version with three slots per resonator element a relatively high bandwidth for the two

Frequency ranges.

In the example described so far, the webs 20, 21, 22 of the first resonator element are arranged on the outer edge 15 of the first disk 10 and the webs 40, 41, 42 of the second resonator element are arranged on the outer edge 35 of the second disk 30. The webs can also be arranged closer to the respective center of the pane in the area of the outer edge 15, 35 of the respective pane. The base area 5 forms a reference potential for the first resonator element, whereas the second resonator element uses the first resonator element together with the base area 5 as a reference potential. With a suitable design and dimensioning of the webs 20, 21, 22 of the first resonator element and the webs 40, 41, 42 of the second resonator element, a resonance with the same impedance at the feed point of the slot antenna 1, i.e. at the connection point of the antenna conductor 45, can be obtained for both operating frequencies Realize in the center of the second disc 30 and thus in the so-called head point of the slot antenna 1, the impedance at the base point, ie at the connection point between the antenna conductor 45 and an adjoining antenna cable, can be, for example, 50 Ω. The connection point lies approximately in the plane of the base area 5. An additional feed network for impedance matching is therefore not required for either of the two resonator elements.

As can be seen from FIG. 1, the webs 20, 21, 22 of the first resonator element can be displaced relative to the webs 40, 41, 42 of the second resonator element by approximately 60 ° or with respect to the common longitudinal axis of the first disk 10 and the second disk 30 be twisted. In this way, the current and voltage maxima occurring at the two resonator elements do not coincide, but are out of phase by 180 °. This creates a current allocation that enables good radiation at both operating frequencies. A mutual influence of the two resonator elements is minimized in this way.

It can further be provided that the circular area of the first recess 25 is smaller than the circular area of the second Disk 30 is. In this way, the inner edge of the first disc 10 is below the outer edge 35 of the second disc

30 in the direction of the longitudinal axis of the two disks 10, 30 pulled inward, but without the antenna conductor 45 in

Contact the center of the slot antenna 1. The bridges 40,

41, 42 of the second resonator element then contact the first disk 10 further away from the inner edge of the first disk 10 than in the case in which the circular area of the second disk 30 and the circular area of the first recess 25 are approximately the same size. This causes the

Polar pattern for the second resonator element in the

Elevation radiation diagram becomes flatter.

Due to its flat design, the slot antenna 1 described is suitable both as a surface-mounted antenna, for example on a motor vehicle, and for installation in a trough made of electrically conductive material. In both cases, the slot antenna 1 can be provided with a cover made of a dielectric material. On a motor vehicle, there are installation positions for the slot antenna 1 on the vehicle roof, the tailgate, and possibly also on the front flap.

With the slot antenna 1 described, transmission and / or reception operation in two different frequency ranges is possible with a very low overall height and without an additional feed network.

In the example described in FIG. 1, each resonator element comprises three slots. However, this is only an exemplary arrangement. It is also possible to provide more or fewer slots, in each case two adjacent webs having to be arranged adjacent to one another at a distance of about half an operating wavelength, the distance being over the outer edge of the respective disc 10, 30 results. In the case of an arrangement of a resonator element with only one web, the slot runs from one free edge of the web to the other free edge of the web, wherein a dielectric fastening element opposite the web could be used to mechanically support the associated disk of the resonator element. In this case, too, the distance between the two free slot ends, which is defined via the outer edge, and thus the length of the slot must correspond to approximately half the operating wavelength of the resonator element. Provision can also be made for the first resonator element and the second resonator element to be provided with a different number of webs and thus slots. However, the version with three slots per resonator element offers an optimal relationship between the effort caused by the size, the material and the cost and the achievable benefit in the form of the achievable bandwidth in the respective frequency range. The implementation of a resonator element with three slots, each with a length of half an operating wavelength, results in a diameter of the associated disk of approximately half the operating wavelength. This prevents the antenna from radiating upwards in the elevation diagram. The radiation is therefore predominantly horizontal.

The slot antenna 1 with two resonator elements according to FIG. 1 can be used for mobile radio applications, for example in the 900 MHz and in the 1800 MHz frequency band of the GSM mobile radio network (Global System for Mobile Communications), the first resonator element for transmitting and receiving radio signals in the 900 MHz frequency band and the second resonator element for transmitting and receiving radio signals in the 1800 MHz frequency band is provided. The described concentric structure of the slot antenna 1 and the circular design of the outer edge 15 of the first disc 10 and the outer edge 35 of the second disc 30 offers the advantage of a rotationally symmetrical directional characteristic with an azimuthal omnidirectional diagram. However, they are also non-concentric arrangements of the two

Resonator elements and designs with a non-circular design of the outer edges 15, 35 of the two disks 10, 30 are possible. The slot antenna 1 can also be realized, for example, with an n-shaped, for example a triangular or a rectangular, with an oval, an elliptical or even an asymmetrical design of the outer edges 15, 35 of the panes 10, 30, in the case of the n-shaped ones Execution the corners could also be rounded. Such a slot antenna 1 thus has a distorted azimuthal omnidirectional diagram with preferred directions for the two resonator elements. Such a distortion of the azimuthal omnidirectional diagram can be used specifically for compensation with appropriate dimensioning of the outer edges 15, 35. For example, distortions of the radiation diagrams of the resonator elements of the slot antenna 1 when arranged on a motor vehicle can be counteracted if these distortions are caused by bars or roof edges of the motor vehicle, so that these distortions are compensated for by the distortions specified by the predefined distorted azimuthal omnidirectional diagram, so that almost a rotationally symmetrical omnidirectional diagram without preferred direction is created.

It can also be provided that only one of the two disks 10, 30 has its outer edge 15, 35 in the form of an n-corner, in oval or elliptical shape or asymmetrically, while the other of the two disks 10, 30 has an approximately circular circumference. In this case, only the directional characteristic of the resonator element of the disc with the non-circular outer edge is a distorted azimuthal omnidirectional diagram with preferred directions, whereas the directional characteristic of the resonator element of the disc with the circular outer edge is an azimuthal omnidirectional diagram without preferred directions. It can also be provided that the two resonator elements each have a disk with a differently shaped outer edge, without this being a circular outer edge, so that the two resonator elements have different directional characteristics with differently distorted azimuthal omnidirectional diagrams and preferred directions. Furthermore, it can be provided that the first recess 25 is not circular, but also in the form of an n-corner, oval, elliptical or asymmetrical.

The slot antenna 1 described can also be used in two different frequency ranges in such a way that a first frequency range for a first mobile radio network, for example the GSM mobile radio network and a second frequency range for a second mobile radio network, for example the E network, is provided, with the slot antenna 1 radio signals can be sent and received in the corresponding frequency bands.

Accordingly, one of the frequency bands can also be provided, for example, for a UMTS mobile radio network (Universal Mobile Telecommunications Systems).

However, it can also be provided, as shown in FIG. 2, to provide more than two reonator elements in the slot antenna 1 for realizing more than two frequency bands for transmitting and / or receiving radio signals. there In FIG. 2, the same reference symbols denote the same elements as in FIG. 1. A third electrically conductive disk 50 is arranged between the first disk 10 and the second disk 30, which also has a circular outer edge 65 and is concentric with the first disk 10 and the second disk 30 is arranged. The third disk 50 has a diameter that corresponds approximately to the diameter of the first recess 25. The third disk 50 is connected at its outer edge 65 to the underlying first disk 10 via a fourth web 60, an eighth web 61 and a ninth web not shown in FIG. 2, the third disk 50, the fourth web 60, the eighth web 61, the ninth web and the first disk 10 form a third resonator element. The webs of the third resonator element are approximately perpendicular to the first disk 10 and the third disk 50. They are each offset by approximately 120 ° from one another, so that again three slots are formed for the third resonator element. Since the diameter of the third disc 50 is smaller than the diameter of the first disc 10, the third resonator element will have a resonance at a third operating frequency that is greater than the first operating frequency. The distance between two adjacent webs of the third resonator element via the outer edge 65 of the third disk 50 in turn corresponds to approximately half the third operating wavelength.

The third disc 50 in turn has a second recess 55 concentric with the first disc 10 and the second disc 30, which is circular in shape and above which the second disc 30 with the second web 40, the sixth web 41 and the seventh web 42 in is arranged in the manner already described with reference to FIG. 1, the diameter of the second disk 30 being approximately the diameter corresponds to the second recess 55. The second disk 30 then forms the second resonator element with the second bridge 40, the sixth bridge 41 and the seventh bridge 42 and the third disk 50, the operating frequency of which is correspondingly greater than the third operating frequency.

Thus, the slot antenna 1 can be implemented with three different frequency bands for silking and / or receiving radio signals. In a corresponding manner, slot antennas with four and more resonator elements for four and more frequency ranges can also be implemented. As also described in the exemplary embodiment according to FIG. 1, the diameter of the first cutout 25 and / or the diameter of the second cutout 55 can also be selected to be smaller than the diameter of the respective overlying disc in order to achieve a flatter radiation in the elevation radiation diagram of the third resonator element and / or to achieve the second resonator element.

The slot antenna 1 can thus be operated at a number of different frequency ranges for transmitting and / or receiving radio signals, which corresponds to the number of disks 10, 30, 50 used, the operating frequency of the respective resonator element depending on the slot length on the outer edge 15, 35, 65 depends on the respective disc 10, 30, 50. According to FIG. 1 and FIG. 2, the diameter of a disk is larger, the less it is spaced from the base area 5.

In the exemplary embodiment according to FIG. 2, the antenna conductor 45 is fed centrally through the opening 70 of the base area 5, the first cutout 25 and the second cutout 55 of the second disk 30 and is connected to it in an electrically conductive manner. The second resonator element uses this third resonator element and the first resonator element together with the base area 5 as a reference potential. The third resonator element uses the first resonator element and the base area 5 as reference potential. The first resonator element uses the base area 5 as

Reference potential. The third disk 50 and the first disk 10 do not touch the antenna conductor 45. The first resonator element in the exemplary embodiment according to FIG. 2, like the first resonator element in the exemplary embodiment according to FIG. 1, is constructed. In the exemplary embodiment according to FIG. 2 and also in the exemplary embodiment according to FIG. 1, the antenna conductor 45 is guided over the opening 70 in the base area 5 without touching the base area 5.

Also in the embodiment according to FIG. 2 with more than two resonator elements, it is possible, in the manner already described for the embodiment according to FIG. 1, at least two of the resonator elements each with a different outer edge of the associated disk and / or with a different shape of the associated recess of the respective to provide the underlying disc.

Since the number of slots or webs of the individual resonators is variable, the lower-frequency resonator could also be at the top, but have fewer slots than the lower high-frequency.

Claims

Expectations

1. slot antenna (1) with a first electrically conductive disc (10) which is offset from an electrically conductive base surface (5) forming a reference potential and which has at its outer edge (15) via at least one first electrically conductive web (20, 21, 22) of the base area (5), characterized in that the first disc (10) comprises a recess (25), that above the recess (25) a second electrically conductive disc (30) is arranged, which is on its outer edge (35) is connected to the first disc (10) via at least one second electrically conductive web (40, 41, 42), and that an antenna conductor (45) is fed to the second disc (30).

2. slot antenna (1) according to claim 1, characterized in that the outer edge (15, 35) of the first disc (10) and / or the second disc (30) is approximately circular.

3. slot antenna (1) according to claim 1 or 2, characterized in that the recess (25) of the first disc (10) is approximately circular.

4. slot antenna (1) according to claim 1, 2 or 3, characterized in that the first disc (10) and / or second disc (30) is approximately in the form of an n-corner, in particular with rounded corners.

5. slot antenna (1) according to any one of the preceding claims, characterized in that the first disc (10) and / or the second disc (30) is approximately oval or elliptical.

6. slot antenna (1) according to any one of the preceding claims, characterized gekennze ch.net that the first disc (10) and / or the second disc (30) is asymmetrical.

7. slot antenna (1) according to claim 3, insofar as this is related to claim 2, characterized in that the circular area of the recess (25) of the first disk (10) corresponds approximately to the circular area of the second disk (30).

8. slot antenna (1) according to claim 3, insofar as this is related to claim 2, characterized in that the circular area of the recess (25) of the first disk (10) is smaller than the circular area of the second disk (30).

9. slot antenna (1) according to any one of the preceding claims, characterized in that the first disc (10) and the second disc (30) are arranged approximately concentrically.

10. slot antenna (1) according to any one of the preceding claims, characterized in that the webs (20, 21, 22, 40, 41, 42) are approximately perpendicular to the disks (10, 30) and the base (5).

11. slot antenna (1) according to any one of the preceding claims, characterized in that between the first disc (10) and the base (5) three webs (20, 21, 22) are arranged and that between the first disc (10) and three webs (40, 41, 42) are also arranged on the second disk (30).

12. slot antenna (1) according to claim 11, characterized in that dε & the three webs (20, 21, 22) between the base (5) and the first disc (10) are each offset by approximately 120 ° to each other and that the three Crosspieces (40, 41, 42) between the first disc (10) and the second disc (30) are also each offset by approximately 120 ° to one another.

13. slot antenna (1) according to claim 11 or 12, characterized in that the webs (20, 21, 22) between the base (5) and the first disc (10) relative to the webs (40, 41, 42) between the first disc (10) and the second disc (30) are rotated by 60 ° against each other.

14. slot antenna (1) according to any one of the preceding claims, characterized in that the slot antenna (1) can be operated at a number of different frequency ranges which corresponds to the number of disks used (10, 30), the respective operating frequency depending on the slot length Outer edge (15, 35) of the respective disc (10, 30) depends.

15. slot antenna (1) according to any one of the preceding claims, characterized in that by one or more adjacent webs (20, 21, 22); 40, 41, 42) between the base (5) and the first disc (10) each formed slots each have a length of about one have half the first operating wavelength and that the slots formed by one or more adjacent webs (40, 41, 42) between the first disc (10) and the second disc (30) each have a length of approximately half a second operating wavelength.

16. slot antenna (1) according to any one of the preceding claims, characterized in that the recess (25) of the first disc (iΦ) is arranged concentrically to the first disc (10).

17. slot antenna (1) according to any one of the preceding claims, characterized in that between the first disc

(10) and the second disc (30), at least one third disc (50) is provided, which likewise comprises a recess (55) that the third disc (50) has at least one third web, which in particular the at least one second web ( 40, 41, 42), with the outer edge (35) of the overlying directly adjacent disc (30) and on its own outer edge

(65) is connected via at least a fourth web (60, 61) to the directly adjacent pane (10) underneath.

18. slot antenna (1) according to any one of the preceding claims, characterized in that the diameter of a disc (10, 30) is larger, the less it is spaced from the base (5).