AT501350B1 - BROADBAND CIRCULAR ANTENNA - Google Patents

Description

2 AT 501 350 B1

The invention relates to a broadband omnidirectional antenna according to the preamble of claim 1.

From US 3829863 an antenna of the type mentioned is known. 5

Furthermore, from FR 2816442 A1 a television antenna cable is known, whose casing has a braided shield made of copper; such a sheath is not high frequency absorbing but reflects on the cable from the outside incident high-frequency radiation. The use of such a cable for broadband omni-directional antennas is not possible io.

In the case of omnidirectional antennas, various antenna bodies are known, either via a coaxial line, wherein an antenna body is connected to the center conductor and the second antenna element 15 is connected to the outer conductor surrounding the center conductor, or via a symmetrical feed line constructed from two asymmetric conductors Coaxial cables are connected. However, at higher operating frequencies, in particular at frequencies of more than 1 GHz, the problem arises that the radiation characteristic of such an antenna shows considerable distortions. 20 The aim of the invention is to avoid these disadvantages and to propose an omnidirectional antenna of the type mentioned, which shows a radiation characteristic even at higher operating frequencies, which has only small distortions. The invention is particularly aimed at optimizing the directional characteristic of broadband omnidirectional antennas, in particular to keep the antennas free from reflections that occur at the supply lines.

According to the invention, these objects are achieved in a broadband omnidirectional antenna of the type mentioned by the characterizing features of claim 1. The proposed measures ensure that the waves emitted by the antenna bodies are hardly reflected by the feed line (s), so that distortions in the radiation characteristic of the antenna are largely avoided. The proposed thickness of the sheath results in a particularly good attenuation of the reflections and therefore only very small distortions of the radiation characteristic, even if the antenna are operated at high frequencies of more than 1 or 2 GHz.

Furthermore, there is a very easy to produce high-frequency absorbing enclosure. Incidentally, by using an open-pore PU foam, the carbon particles may be simply introduced in such a manner that the foam is compressed and dipped in a liquid in which the carbon particles are dispersed and allowed to expand. When using a closed-cell polystyrene foam, the carbon particles can be mixed into the foamable mass. 45

By these measures of claim 2 it is ensured that the distance between the antenna bodies and the sheath is kept in a size which is too small to allow appreciable and the radiation characteristic influencing reflections. Thus, in order to avoid an unnecessary effort in the casing, it is expedient to provide the features of claim 3. Such a length of the sheath is sufficient to avoid disturbing reflections through the feed line.

Due to the features of the claim has the advantage that even at lower operating frequencies 55 distortions of the radiation characteristic can be avoided because at lower 3 AT 501 350 B1

Operating frequencies the sheath becomes less effective.

It is advantageous to provide the features of claim 5. The ferrite rings cause a subdivision of the length of the feed line (s), resulting in correspondingly small 5 distortions of the radiation characteristic. Instead of the ferrite rings and ferrite particles may be embedded in the sheath. Thus, it is also possible to introduce not only the carbon particles but also ferrite particles in the manner described above.

Due to the features of claims 6 and 7, there is the advantage of a simple application io the sheath. But it is also possible to apply the sheath in two parts in the form of half shells.

The invention will now be explained in more detail with reference to the drawing. 1 is a diagram showing the radiation of a broadband omnidirectional antenna with and without a sheath,

Fig. 2 to 5 schematically different embodiments of inventive omnidirectional antennas. FIG. 1 shows a section through the three-dimensional radiation characteristic of a broadband omnidirectional antenna. In this case, the curve 1 corresponds to an omnidirectional antenna 100 according to the invention with a casing 300 made of high-frequency-absorbing material. The curve 2 corresponds to a conventional omnidirectional antenna without sheathing the feed line. In this case, the curve 2 shows significant distortions of the radiation characteristic, which are characterized by the 25 deviations from a smooth kidney shape. These deviations are usually due to reflections of the waves emitted by the antenna bodies, in particular at the feed line (s).

FIG. 2 shows a first embodiment of an omnidirectional antenna 100 according to the invention. This has two cone-shaped antenna bodies 101, 102, wherein the antenna body 101 is connected to a center conductor 201 of a feed line 200. The second antenna body 102 is connected to an outer conductor 202 of the feed line 200. The feed line 200, which is connected to a plug 203, is provided with a sheath 300 made of a high frequency absorbing material. 35

The sheath expediently has a length of λ to 10 λ, wherein the thickness of the sheath is preferably λ / 20 to λ / 5.

Such a material may e.g. be made of plastic, in particular plastic foam, preferably 40 an open-pore PU foam, are embedded in the carbon particles. In this case, the carbon particles can be introduced into the foam in that it is immersed in the compressed state in a liquid in which carbon particles are dispersed, and is expanded therein, whereby the carbon particles penetrate into the open pores of the foam. In a closed-line polystyrene foam, the carbon-carbon particles can be introduced into the starting material to be foamed, after which this material mixed with the carbon particles is subsequently foamed.

Reflections of the waves emitted by the antenna bodies 101, 102 on the feed line 200 are attenuated or avoided by the jacket 300, which leads to distortions of the emission characteristic.

The embodiment of an omnidirectional antenna 100 according to the invention according to FIG. 3 differs from that according to FIG. 2 in that the axis of the antenna bodies 101, 102 runs perpendicular to the feed line 200. In this case, the limit distance a between the 55 antenna bodies 101, 102 facing the end of the enclosure 300 and the Antennenkörpem

Claims (7)

4 AT 501 350 B1 expediently λ / 20 to λ / 5. The embodiment of an omnidirectional antenna 100 according to the invention according to FIG. 4 essentially corresponds to that according to FIG. 3, but a balun 400 is provided near the antenna bodies 101, 102. In this case, the envelope 300 of the feed line 200 extends to a limit distance a of λ / 20 to λ / 5 to the balun 400 zoom. In the embodiment according to FIG. 5, a symmetrical feed line constructed of two asymmetrical coaxial lines 200 is provided, to which the two antenna bodies 101 and 102 are connected. A balun 400 is disposed near the plug 203. Furthermore, a common casing 300 of high-frequency-absorbing material is provided, which reaches up to a limit distance a to the antenna body 101,102. However, it can also be provided to provide each of the two symmetrical feeders 200 with a sheath 300. An omnidirectional antenna 100 according to the invention can be used for frequencies above 400 MHz, with no upward restrictions and the preferred frequency range between 2 GHz and 80 GHz, in which region the casing 300 contains only carbon particles. Foams are advantageously used with er = 3 - 20, pr = 0.8 to 1.2, preferably about 1.0, and tan δ = 0 At operating frequencies of the omnidirectional antenna 100 between 400 MHz and 2 GHz, it is expedient either on or in add additional ferrite particles to the cladding, or attach ferrite rings to the cladding. As a result, distortion of the radiation characteristic is reduced in this frequency range, in which the jacket coated with carbon particles is less effective, and at higher frequencies, the effectiveness of the ferrite decreases in order to reduce distortions. 1. Broadband omnidirectional antenna for higher operating frequencies, in particular 1 to 100 GHz, preferably 2 to 80 GHz with two antenna bodies (101, 102) which are each connected to a feed line (200), wherein optionally the two feed lines (200) a center conductor (201) connected to said one antenna body (101) and having a sheath conductor (202) electrically insulated from and surrounding said center conductor (201) and connected to said other antenna body (102) the surface of the feed line (s) (300) optionally ferrites are arranged, characterized in that each of the feed lines (200) or the feed lines together in the antenna near area with a high frequency absorbing sheath (300) made of plastic, in particular a foamed material, such as open-pore PU foam or closed-cell polystyrene foam, in which carbon particles are dispersed, is provided, whose thickness is λ / 30 to λ / 2, preferably λ / 20 to λ / 5. 2. omnidirectional antenna according to claim 1, characterized in that the sheath (300) on the feed line (s) (200) to form a limit distance (a) of λ / 30 to λ / 2, preferably λ / 20 to λ / 5, to the antenna bodies (101, 102) is arranged. 3. omnidirectional antenna according to claim 1 or 2, characterized in that the length of the sheath (300), which starts at a limit distance (a) from the antenna bodies (101, 102), 1 / λ to 10 / λ. 5 AT 501 350 B1 4. omnidirectional antenna according to one of claims 1 to 3, characterized in that for operating frequencies less than 1 to 2 GHz, in particular 400 MHz to 1 GHz, the sheath (300) in addition to carbon particles and ferrite material, e.g. dispersed ferrite particles. 5. omnidirectional antenna according to claim 4, characterized in that the ferrite material in the form of spaced-apart rings on the sheath (300) is applied. 6. omnidirectional antenna according to one of claims 1 to 5, characterized in that the sheath (300) is integrally formed. 7. omnidirectional antenna according to one of claims 1 to 6, characterized in that the casing (300) is cylindrical and optionally foamed on the feed line (200) or wound in the form of at least one layer around the feed line (s) (200) around is. For this purpose 2 sheets of drawings