DE3525553A1 - Directional antenna - Google Patents

Abstract

In the case of a parabolic reflector antenna which is supplied at the focus directly from the primary radiator (4), influencing of the reflection (which influencing acts independently for two orthogonal linear polarizations) for compensation of the feedback reflection from the parabolic reflector (3) on to the primary radiator (1) can be achieved in that, in addition to a vertex plate (8) which is optimized for one polarization plane with respect to the reflector separation and diameter and whose surface forms a first reflection plane (1), a second reflection plane (2) of identical dimensions is introduced at a suitable distance in front of said first reflection plane (1) which second reflection plane (2) acts exclusively in the other polarization, that is to say in the orthogonal polarization. A directional antenna constructed in accordance with the invention can be used as a satellite or directional-radio antenna for double-polarization operation. <IMAGE>

Description

The invention relates to a directional antenna a parabolic reflector and one in its focus its radiation center arranged primary emitters Direct feeding of the parabolic reflector in its Vertex area in a central arrangement a flat circular crown with a metallic surface has in relation to the reflector surface in Direction to the focal point by such a measured distance is offset that the reflected from the crown plate Field share by 180 ° in phase with the rest Field is shifted and thus with respect to the Primary emitter is compensated in its effect.

A parabolic reflector fed directly from the focus antenna has a relatively high feedback re flexion of the incident wave from the parabolic reflector shell back into the primary heater. This retroactive effect must usually be taken by suitable measures, e.g. B. com pensatorial type, reduced to adverse effects Avoidance of transmission quality.

A known way of compensatory Ver Avoiding this retroactive reflection is that in the book by S. Silver: "Microwave Antenna Theory and Design", McGraw-Hill Book Company, 1949, pages 443-447 given crown plate. It is a flat circular plate with an optimized through knife that is centered in the apex of the parabol  is arranged and against this by a reflector certain distance is moved. This distance is like that dimensioned so that the reflected from the top plate Field share by 180 ° in phase with the rest Field is shifted and thus with respect to the primary spotlight can be compensated for in its effect. The Use of such a top plate is in Parabolic antennas very effective with a single Polarization are operated. But have to at the same time transmit two orthogonal linear polarizations a corresponding effect is only possible with of such an apex plate if the characteristic course of reflection on the Frequency band seen, the same for both polarizations or at least very similar. Kick bigger Differences in the course of the reflection about Frequency band seen at the two polarizations, as a rule, neither can be used for both polarizations equally favorable distance of the top plate from Find parabolic reflector. A reflection compensation is therefore only very imperfectly possible.

The object of the invention is in one of the Focal point directly fed parabolic antenna one for both planes of polarization largely apart to achieve independent reflection influence.

According to the invention, which is based on a directional antenna relates to this type, this task solved in that for the simultaneous transmission of Waves with two mutually orthogonal linear Polarizations are the distance of a first plane of reflection forming crest plate for the waves of one Polarization level is optimized and also parallel before that a second reflection plane at a defined distance  of the same dimensions is provided exclusively in the other, d. H. in the first Polarization plane orthogonal polarization plane is effective, and that the distance of the second reflection plane to the reflector and thus also the distance between the two reflection planes is defined in such a way that that of field portion reflected around the second reflection plane 180 ° in phase compared to that on the parabolic reflector reflected field is shifted and thus with respect to the effect of the primary radiator is compensated.

The second reflection plane can, for example, thereby be created in that at a defined distance the apex one towards the second polar structure oriented parallel to each other other trending, metallic, d. H. reflective Elements is built up only for this second bottom larization is effective. Execution options for these elements exist e.g. B. in the form of perpendicular of the top plate standing certain strips Height, which is the defined distance between the two Reflective planes, or in the form of parallel wires running towards each other, which are defined in the Distance in front of the top plate, for example on a Insulating body are attached. The elements mentioned can also be passed through on a metal-clad plate Realize etching.

For the defined distance between the two Reflection levels result in different values, each after whether the parallel, right reflecting elements of the second reflection level ver tical or horizontal. It is advisable, here the one of the two profiles mentioned directions (vertical or horizontal) of the reflective Select items where the smaller of the two defined distances between the two Re levels of inflection.  

The dimensioning and electrical optimization of the Structure for generating the second plane of reflection, d. H. the determination of the effective reference level for the Re flexion as well as the distance between the reflective Elements depends on the frequency range and the eigen stem from the primary radiator.

The invention is illustrated below in one in three Figures illustrated embodiment explained.

Show it

Fig. 1 in side view, the diagram of an antenna according to the invention,

Fig. 2 is a plan view of a mounted in the apex region of a directional antenna according to the invention Kompen sationseinrichtung for two independent orthogonal polarizations,

Fig. 3 is a side view of the compensation device shown in Fig. 2.

Fig. 1 shows a side view of the schema of a formed according to the invention, directional antenna with a parabolic reflector 3 and, arranged in the focal point with its radiation center primary radiators 4. The directional antenna is thus fed directly from the focal point by the primary radiator 4 . The primary radiator 4 is equipped with a polarization switch so that it can be fed at an input 6 for horizontal and at an input 7 for vertical polarization. In the apex area of the parabolic reflector 3 , a flat circular apex plate 8 with a metallic surface is attached in a centric arrangement, which is offset from the reflector surface in the direction of the focal point by a dimensioned distance d such that the field portion reflected by the upper surface of the apex plate 8 is around 180 ° in phase with respect to the rest of the field and thus its effect is compensated for in relation to the primary radiator 4 . The surface of the apex plate 8, however, acts only for the horizontally polarized radiation components as a reflection plane for reasons given in detail later. With simultaneous transmission of electromagnetic waves with horizontal or vertical polarization, the distance d of the top plate 8 forming a first reflection plane 1 is thus optimized for the horizontally polarized waves. The diameter of the flat apex plate 8 is also optimized. The crown plate 8 has an effect so as reflection plane solely for horizontal polari catalyzed waves because plate parallel prior to this apex a second reflective layer 2 is provided measurements of the same Ab 8, that is, only in the other in the vertical polarization is effective and thus the horizontally polarized waves. The distance of the second reflection plane 2 to the parabolic reflector 3 and thus also the distance h between the two reflection planes 1 and 2 is defined so that the reflected from the second reflection plane 2 field component shifted 180 ° in phase from the reflected on the parabolic reflector 3 Field is. For the reflection compensation of the vertically polarized waves, the reflection plane 2 with a distance of d + h from the parabolic reflector 3 and for the reflection compensation of the horizontally polarized waves, the surface of the apex plate 8 is responsible as a reflection plane 1 with a distance d from the parabolic reflector 3 .

The second reflection plane 2 is created in that at a distance h in front of the apex plate 8, which forms the first reflection plane 1 with its metallic surface, a structure oriented in the direction of the vertical polarization plane is built up from metallic, ie reflecting elements running parallel to one another, which is only for the Vertical polarization are effective.

In FIGS. 2 and 3 can be used for the antenna according to Fig. 1 compensation device, the reflector is non-reactive for two independent orthogonal polarizations shown in a plan view and a side view in detail. Here are perpendicular to a crown plate 8 , which forms the first reflection plane 1 , perpendicular sheet strips 5 are introduced , which have a height h , which corresponds to the distance between the two reflection planes 1 and 2 . The compensation of horizontally polarized waves takes place by means of the apex plate 8 and the compensation of vertically polarized waves on the reflection plane 2 , which is given by the ends of the vertically extending sheet metal strips 5 . For the height of the sheet metal strips 5 h to give different values, depending on whether the sheet metal strips 5 are placed horizontally or vertically. It is advisable to choose the combination with the smaller value for the height h . The dimensioning and electrical optimization of the sheet metal strip structure, ie the determination of the effective reference planes 1 and 2 for the reflection and the distance a between the reflecting sheet metal strips 5, depends on the frequency range and on the properties of the primary radiator 4 according to FIG. 1.

The distance a between the equidistant sheet metal strips 5 is less than a wavelength in the exemplary embodiment and the height of these sheet metal strips 5 is less than a quarter wavelength. With the arrangement shown in FIGS . 2 and 3, with a 3 m parabolic reflector antenna in the frequency range 1.9 to 2.3 GHz, an independent adjustment of the reflection factor in vertical and horizontal polarization could be carried out with good results.

Claims (9)

1. Directional antenna with a parabolic reflector and a focal point arranged in its focal point with its radiation center for direct feeding of the parabolic reflector, which has a flat circular apex plate with a metallic surface in its apex area in a central arrangement, which is opposite the reflector surface in the direction of the focal point by one the distance is such that the field portion reflected by the apex plate is shifted in phase by 180 ° with respect to the rest of the field and thus its effect is compensated in relation to the primary radiator, characterized in that for the simultaneous transmission of waves with two to one another orthogonal linear polarizations, the distance (d) of the apex plate ( 8 ) forming a first reflection plane ( 1 ) is optimized for the waves of the one polarization plane and additionally parallel in front of it at a defined distance (h) a second reflection plane ( 2 ) of the same dimensions vo is rgesehen which is effective exclusively in the other, ie in the direction orthogonal to the first polarization plane (1) plane of polarization (2), and that the distance of the second reflection plane (2) to the reflector (3) and thus also the distance (h) between the two reflection planes ( 1 , 2 ) is defined in such a way that the field component reflected by the second reflection plane ( 2 ) is shifted in phase by 180 ° in relation to the field reflected on the parabolic reflector ( 3 ) and thus in relation to the primary radiator ( 4 ) its effect is compensated. 2. Directional antenna according to claim 1, characterized in that the second reflection plane ( 2 ) is constructed from a structure oriented in the direction of the second polarization plane from parallel to each other, metallic elements ( 5 ), ie reflective elements, which are only for in the second Polarization plane polarized waves is effective. 3. Directional antenna according to claim 2, characterized in that the elements forming the second reflection plane ( 2 ) are formed by sheet metal strips ( 5 ) which are mounted perpendicular to the apex plate ( 1 ) and parallel to one another and one of the defined distance (h) have two heights of reflection ( 1 , 2 ) corresponding height. 4. Directional antenna according to claim 2, characterized in that the elements forming the second reflection plane ( 2 ) by brought at a defined distance (h) in front of the apex plate ( 1 ), mutually parallel wires are formed. 5. Directional antenna according to claim 4, characterized in that an insulating body on the apex plate ( 1 ) is attached to hold the wires. 6. Directional antenna according to claim 2, characterized in that the elements forming the second reflection plane ( 2 ) are realized on a metal-clad plate by etching. 7. Directional antenna according to one of claims 2 to 6, characterized in that there are different values for the distance (h) between the two reflection planes ( 1 , 2 ), depending on whether the mutually parallel reflecting elements of the second reflection plane ( 2 ) are placed vertically or horizontally. 8. directional antenna according to claim 7, characterized in that that of the two addressed (vertical or horizontal) Ver running directions of the reflecting elements ( 5 ) is selected, in which the smaller of the two distances (h) between the two reflection planes ( 1 , 2 ) results. 9. Directional antenna according to one of claims 2 to 8, characterized in that the distance (h) between the two reflection planes ( 1 , 2 ) and the distance (a) between the reflective elements ( 5 ) of the respective frequency range and properties of the respective primary radiator ( 4 ) depends.