DE3209513A1 - Eccentric Parabolic Antenna with Low Cross Polarization - Google Patents

Abstract

The present invention relates to a microwave antenna with an eccentric parabolic dome as the main reflector, the cross-polarization component of which is to be reduced. For this purpose a feed system is provided which generates the radiation from a Huygens source. The feed system is dimensioned and aligned with the parabolic dome in such a way that the radiation field is converted into a flat field after reflection on the dome.

Description

AEG-TELEFUNKEN PTL-BK / Th / white

Nachrichtenentechnik GmbH BK 82/41

Theodor-Stern-Kai 1

D-6000 Frankfurt 70

Eccentric parabolic antenna with low cross polarization

The present invention relates to a microwave antenna consisting of an eccentric parabolic dome with a a feed system containing a horn antenna.

In order to increase the frequency economy, large message bundles are generally sent simultaneously to two orthogonal polarizations transfer. In order to ensure high transmission quality, come in this case because of their good Angle and reflection attenuation eccentric parabolic antennas such as horn parabolic or so-called mussel antennas (cf.

A. Heilmann: Antennen, 3rd part, Bibliographisches Institut, 1970, pp. 94, 95). A disadvantage with these antennas is that they have high cross polarization. The dash-dotted lines in the radiation diagram of FIG. 1 Cusps next to the sharp zero point in the main beam direction (9 = 0 °) give the cross-polarization component the radiation again.

- 4 - BK 82/41

The invention now lies in the Aut '^ itH' /.u^rundt ;, egg in * microwave antenna of the type mentioned at the outset to indicate the lowest possible cross-polarization component in the radiation diagram having.

The object is achieved according to the invention in that the horn antenna the parabolic dome illuminates via an auxiliary reflector, with the radiation emanating from the auxiliary reflector which corresponds to such a Huygens source, the axis of which coincides with the focal axis of the parabolic dome.

Appropriate embodiments of the invention can be found in the subclaims emerged.

The measures according to the invention allow an eccentric Realize parabolic antenna with very low cross polarization in a compact design.

Based on an embodiment shown in the drawing the invention will now be explained in more detail. Show it:

Fig. 1a a Huygens source,

Fig. 1b shows the illustration of the circular field lines Huygens source in a planar projection plane, 2 shows an eccentric parabolic dome with a feed system in a side view and

3 shows the radiation diagram of an eccentric parabolic dome.

The unwanted cross-polarization component in the radiation diagram an eccentric parabolic antenna ideally disappears, if it succeeds, the one emanating from the feed system To give the radiation field such a shape that after reflection on the parabolic mirror it is in an exactly plane Field is converted. One comes closest to this requirement if one looks at the radiation field of a parabolic mirror Huygensschen source offers.

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Fig. 1a shows such a Huygens source. Your characteristic is that all field lines on a spherical surface form small circles that all have one thing in common Point, the Huygens point HP, tangent. If you judge a Huygenssehe Source on a parabolic mirror in such a way that its axis HA (that is the straight line through the Huygens point and the center of the spherical source) coincides with the focal axis of the parabolic, the radiation becomes the Huygens source after reflection on the parabolic mirror in a plane radiation field, as shown in FIG. 1b, in converted to the aperture plane. On the mathematical proof that with such an image the on a spherical surface Small circles lying down in horizontal and vertical straight lines should be dispensed with here. Let it be in that Related to the theory of conformal mapping.

In the previous statements regarding the transfer of a Huygens radiation field in a plane radiation field is of a complete centric paraboloid as The reflector has run out.

Now, however, a radiation source should be used for an eccentric parabolic dome are specified, whose field also after the reflection in the aperture plane of the parabolic dome in a possible plane field is transformed to reduce the cross-polarization component of the field.

Fig. 2 shows a parabolic dome 1 with a feed system 2, which meets the above requirement very well. Around To illustrate the design of the feed system 2 more clearly, it has been drawn greatly enlarged compared to the spherical cap 1.

The feed system 2 consists of a horn antenna 3 and a mechanically connected auxiliary reflector 4, which the Has the shape of an ellipsoidal section. In fact, the ellipsoid section 4 is on the one hand by the on the ellipsoid

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Horn wall placed on the edge and on the other hand completely shielded laterally by a truncated cone 5 which is also placed on the ellipsoid edge and intersects with the horn. The bundle of rays exits the feed system through the opening 6 of this truncated cone and reaches the parabolic dome 1. The ellipsoidal auxiliary reflector 4 is aligned with the horn radiator 3 and the parabolic dome 1 so that its first focal point F1 lies on the horn axis and its second focal point F2 with which the parabolic dome coincides. It is also important to dimension the ellipsoidal section so that a beam a lying in the horn axis hits the center of the aperture of the dome after the reflection on the auxiliary reflector 4 and after the subsequent reflection on the parabolic dome 1. In addition, the horn and the auxiliary reflector are to be dimensioned in such a way that the outermost marginal rays b and c of the bundle of rays emerging from the feed system, which intersect at the focal point F1, enclose an angle which does not exceed a maximum beam expansion angle φ determined by the dimensions of the dome. The size of the jet outlet opening 6 of the feed system must also be selected in accordance with this angle φ. Their diameter d depends on the beam expansion angle φ and the operating wavelength λ in the following way: d =. _{λ #}

A relationship between the angle 9, which is the lowest Marginal ray c encloses with the focal axis PBA of the parabolic dome, the angle p which the uppermost marginal ray b with the paraboloid focal axis PBA includes, half the expansion angle y of the horn, the angle of inclination? the horn axis with respect to the focal axis EPA of the ellipsoid section and the angle connecting the two focal points F1 and F2 α between the ellipsoid focal axis EPA and the paraboloid focal axis PBA is by the two relationships

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φ φ

tan -ρ- + tan - ^ -

cos γ = cos α - sin α

_sin Q- O ₅ ^{Sin γ} = ^Siny

φ U = m 5 O ψ O 96 O y 27 , 7 ° y 36 , 6 °

sin
given.

In a specific exemplary embodiment, the angles just listed have the following values:

- 'u = ⁹¹ ° 15

α = 16.6 °

This results in an angle φ between the focal axis PBA of the parabolic dome and the central beam a of approximately 60 °. The diameter d of the jet outlet opening 6 of the feed system on which this is based is approximately 1.2 ... 1.5λ. An ellipsoidal section can be used as an auxiliary reflector, the distance between the two focal points F1 and F2 being in the range of 6 ... 10λ.

The radiation diagram shown in FIG. 3 shows a clear improvement of the eccentric according to the invention Parabolic antenna compared to conventional eccentric parabolic antennas with regard to the cross-polarization component. there is with χ the co-polarized field, with y the cross-polarized field of a known antenna and with ζ the cross-polarized field Field of an antenna according to the invention characterized by about 20 dB compared to the otherwise occurring cross-polarization component y is decreased.

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Claims (6)

-X- AEG-TELEFUNKEN PTL-BK / Th / white Nachrichtenentechnik GmbH BK 82/41 Theodor-Stern-Kai 1 D-6000 Frankfurt 70 Claims ; 1 .1 microwave antenna consisting of an eccentric parabolic dome with a horn antenna containing
Feed system, characterized in that the horn radiator (3) illuminates the parabolic dome (1) via an auxiliary reflector (4), the radiation emanating from the auxiliary reflector corresponding to that of such a Huygens source whose axis coincides with the focal axis (PBA) of the parabolic dome
coincides. 2. Microwave antenna according to claim 1, characterized in that the horn antenna (3) is a grooved horn. 3 · Microwave antenna according to claim 1, characterized in that the auxiliary reflector (4) is the cutout of a
Is an ellipsoid whose one focal point (F1) is on the
Axis of the horn antenna (3) lies and its second
Focal point (F2) with which the parabolic dome (1) coincides. - 2 - BK 82/41 4. Microwave antenna according to claim 3, characterized in that the cutout (4) of the ellipsoid is dimensioned and aligned with the parabolic dome (1) in such a way that a beam (a) lying in the horn axis after reflection on the ellipsoid cutout (4) and after subsequent reflection on the parabolic dome (1) hits the center of the aperture of this parabolic dome. 5- microwave antenna according to one of the preceding claims, characterized in that the ellipsoidal section (4) is laterally shielded on the one hand by the horn wall placed on the ellipsoidal edge and on the other hand by a truncated cone (5) placed on the ellipsoidal edge and intersecting with the horn, its opening (6) lies in the vicinity of the second focal point (F2) and represents the exit opening for the bundle of rays directed onto the parabolic dome (1). 6. Microwave antenna according to claim 5, characterized net gekennzeich in that the outlet opening (6) of the feed system (2) 120 ° 150 °
has a diameter d = '- ^ —-— · λ, where φ the maximum expansion angle of the illuminating the parabolic dome Beam is.