JPH02134001A - Offset reflection mirror antenna - Google Patents

Abstract

PURPOSE:To improve the cross polarization characteristic with simple constitution by controlling the electric field distribution on an aperture face of a feeding horn so as to correct the asymmetry caused by offset feeding. CONSTITUTION:A feeding horn 2 being a primary radiator is provided opposite to a mirror surface 1 of an offset reflecting mirror and the feeding horn 2 applies offset feeding to the mirror surface 1. In this case, the electric field distribution on the aperture face 4 of the feeding horn 2 is controlled to control the asymmetry of the offset reflection mirror antenna system caused by the offset feeding. Thus, the offset reflection mirror antenna having an excellent cross polarization characteristic is obtained with simple constitution.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Field of Application) The present invention relates to an offset reflector antenna in which a feeding horn is arranged so as to provide offset feeding.

(Prior art) Offset reflector antennas, such as offset parabolic antennas, are generally configured so that other components such as a feeding horn do not block reflected waves from the reflector, and are highly efficient and have low sidewalls. It has the great advantage of being able to achieve robust high performance. For this reason, it has been used in various fields such as radar antennas, terrestrial micro communication relay antennas, satellite communication earth station antennas, satellite-mounted antennas, satellite broadcast receiving antennas, and wave generators for compact ranges. Wide (used for practical use.

On the other hand, problems with offset reflector antennas can be broadly divided into mechanical problems and electrical problems.

The mechanical problem is that the use of offset mirror surfaces complicates the mirror manufacturing process. This increases manufacturing costs and makes it difficult to achieve high manufacturing accuracy (mirror surface accuracy and setting accuracy). These problems are being solved with the progress and spread of precision machine tools.

On the other hand, the most characteristic electrical problems are:
Cross-polarized components are generated due to the asymmetry of the mirror system, which can be a major problem depending on the system. As means for improving the cross-polarization characteristics of an offset parabolic antenna, techniques listed in the following items (1) to (3) have already been proposed.

(1) Offset dual reflector antenna (Dual off
setreflector antenna) configuration, which cancels the cross-polarized wave component generated by the offset parabola (main reflector) with the cross-polarized wave component generated by the sub-reflector (offset hyperboloid or ellipsoid) (Reference: Tanaka, Mizusawa, °゛Elimination of cross polarization in offset double reflector°
゛, Journal of the Institute of Electronics, Information and Communication Engineers (B), Vol, 5g-
B.

No, 12. p, 643. December 1975).

(2) Using multiple power feeding horns (cluster horns),
A method that aims to reduce cross-polarized waves by controlling the excitation distribution of each horn (Reference: Chujo 9 Teshirogi, °゛Suppression of cross-polarized waves of offset parabola by array electric current゛゛, Showa 62
70th Anniversary of the Institute of Electronics, Information and Communication Engineers, 641. p,
3-83. (March 1986).

(3) A grid reflector with polarization selectivity is used as the mirror material of the reflector to suppress the generation of cross-polarized waves by restricting the direction of the mirror current (Reference: C
, C., Chen and C.F., Franklin.

”Ku-B and Multiple Beam A
ntenna, NΔSA C0NTRACT RE
PORT 154364. Dec, 1980. ).

(4) A grid plate with polarization selectivity is inserted into the reflecting mirror opening to transmit only the positive polarization component and block the passage of the cross polarization component (Reference: R3W, Gruner
arid W, J, English, “Ante
nna Design Studies for a U
,S,Domestjc 5aLcllit,eCom
sat, Technical Review, V
ol, 4. No, 2. p, 4131974).

(5) A grid plate with polarization selectivity is inserted into the space between the feeding horn and the reflecting mirror, and the polarization of the incident wave on the reflecting mirror is adjusted so that the polarization direction of the reflected waves from the reflecting mirror is aligned in a certain direction. Things that control direction (Reference: Nakamura.

Ando, Goto, ``Effect of suppressing cross-polarized waves by grid plate'', 1985 National Conference of the Optical and Radio Division of the Institute of Electronics, Information and Communication Engineers,
59. p, 1-59. (September 1985) (Problems to be Solved by the Invention) Among these, (1) has many practical examples, but has the disadvantage that it requires a sub-reflector and has a complicated configuration. Although (2) is originally suitable for satellite-mounted multi/shaped beam antennas based on cluster power feeding, it is not common because it has the disadvantage that the power feeding circuit becomes complicated. In (3), the manufacturing process of the reflecting mirror becomes complicated, and in (4) and (5),
A separate polarization grid plate is required to a greater or lesser extent. Also,
In (3), (4) and (5), a dual polarization antenna (or a circularly polarized antenna) cannot be configured, there is no unnecessary loss from the grid plate, the zytrobe is generated, and the characteristics are good over a wide band. It has drawbacks such as difficulty in obtaining a grid plate.

The present invention was made to solve the problems of the prior art described above, and an object of the present invention is to provide an offset reflector antenna having a simple configuration and good cross-polarization characteristics.

(Means for Solving the Problems) A feature of the present invention is that in an offset reflector antenna composed of an offset reflector and a feeding horn, a The reason is that the electric field distribution is controlled asymmetrically to suppress cross-polarized waves.

(Function) The present inventors focused on the electric field distribution of the aperture of the reflecting mirror and the feeding horn as a means for improving the cross-polarized wave characteristics.

The operating principle of the present invention will be explained using schematic diagrams.

FIG. 1 is a sectional view of an offset reflector antenna used in the present invention, where 1 is the mirror surface of the reflector, 1' is the aperture of the reflector, 2 is the feed horn, 4 is the aperture of the feed horn, and the offset The reflector antenna has an asymmetric structure with respect to the axis of the radiation beam. In an offset reflector antenna as shown in Figure 1, the electric field distribution at the conventional aperture is as follows:
Although the electric field distribution on the aperture surface 4 of the feeding horn 2 is symmetrical as shown in FIG. 2(a), the aperture surface of the reflecting mirror is 1', a horizontal component (A), which is the cause of cross-polarized waves, was generated as shown in FIG. 2(b). Therefore, in the present invention, as shown in FIGS. 2(c) and (d),
The electric field distribution on the aperture surface 4 of the feed horn 2 is made asymmetrical so that it has a horizontal component, and the electric field distribution on the aperture surface of the feed horn is adjusted so that the aperture surface 1' of the reflector has an ideal electric field distribution characteristic. It is controlled. That is, the polarization direction of the radiation wave from the feeding horn 2, which is the wave incident on the reflection mirror, is controlled so that the polarization direction of the reflected wave from the reflection mirror is aligned in a fixed direction.

(Example 1) FIGS. 3(a) to 3(c) show a first example according to the present invention, and are cross-sectional configuration diagrams of an opening surface of a power feeding horn.

A feeder horn 2, which is a primary radiator, is provided opposite the mirror surface 1 of the offset reflector, and the feeder horn 2 rotates the mirror surface 1 at an angle of θ.

Offset power is being fed at an angle of At that time, in the present invention, as shown in FIGS. 3(a) to (C), the power feeding horn 2
The axis 3 and the normal direction 5 of the aperture surface 4 do not match, and θ8
The opening surface of the power feeding horn 2 is configured to be inclined at an angle of .

First, FIG. 3(a) is a sectional view of an offset reflector antenna, in which the opening surface 4 of the feeding horn 2 is formed obliquely at an angle other than a right angle with respect to the axis 3 of the feeding horn 2. The opening surface 4 of the power feeding horn 2 is physically inclined with respect to the normal 5 of the horn 2.

FIG. 3(b) shows a configuration in which a plurality of horns are connected so that their horn shafts are bent, and FIG. 3(C) shows a structure in which the opening surface 4 of the power feeding horn 2 is arranged at right angles to the horn shaft 3. A flange 6 with an asymmetrical structure is placed at the end of the opening surface 4.
The horn opening 7 is constructed by adding the following.

As described above, in the first embodiment, the power feeding horn 2 is configured such that the normal 5 of the opening 7 or the opening surface 4 of the power feeding horn 2 is physically inclined with respect to the axis 3 of the feeding horn 2.

(Embodiment 2) FIGS. 4(a) to 4(b) show a second embodiment according to the present invention, and the difference from Embodiment 1 is that the opening 7 of the feeding horn 2 is connected to the shaft 3 of the feeding horn 2. On the other hand, the feeding horn 2 is configured such that the normal line 5 is equivalently inclined.

FIG. 4(a) shows the opening surface 4 and opening 7 of the power supply horn 2.
is perpendicular to the axis 3 of the feeding horn 2, but an asymmetrically structured choke 8. is attached to the flange 6 disposed in the opening 7. By adding ~8n, the feeding horn 2 is configured such that the normal line 5 is equivalently tilted. Note that although the figure shows an example in which the depth of the chokes 8.~8o is changed, Even if the interval between the chokes 8. to 8n is changed, the electrical characteristics (impedance) of the opening 7 similarly change, so that the normal line 5 can be made to tilt equivalently.

On the other hand, FIG. 4(b) is a cross-sectional view of a corrugated horn, in which the corrugated structure 9 of the opening surface 4 is configured to be asymmetrical in the upper and lower portions. In this way, by making the corrugated structure 9 asymmetric between the upper and lower portions, the propagation constant within the feeding horn 2 differs between the upper and lower portions, so that a phase difference is created, and the normal line 5 can be tilted equivalently.

FIG. 5 explains the effect of improving the cross-polarization level of the radiation pattern according to the present invention, and shows a cross-polarization pattern with θ as a parameter. In the figure, curve A is the radiation pattern of the main polarization component, curve B is the conventional radiation pattern, and curve C is the radiation pattern according to the present invention when θ is tilted by about 40 degrees. In addition, in curve C, θ
. =θ0. As is clear from the figure, in the present invention, the cross-polarization level is improved by more than 20 dB compared to the conventional method.

In addition, although the embodiment in which a conical horn is used as the power feeding horn 2 has been described above, the present invention is not limited to this and can be applied to horns of various shapes such as a pyramidal horn, a diagonal horn, a cross horn, etc. It is possible.

(Effects of the Invention) As described above, the present invention achieves offset reflection by controlling the electric field distribution on the aperture surface 4 of the feeding horn 2 so as to correct the asymmetry of the offset reflector antenna system caused by offset feeding. The cross-polarization characteristics of mirror antennas can be significantly improved.

By configuring the feeding horn 2 so that the normal direction 5 of the aperture surface 4 of the feeding horn 2 is physically or equivalently inclined from the axis 3 of the feeding horn 2, cross-polarization characteristics are improved with a simple configuration. be able to.

By configuring the opening 7 (4) of the power feeding horn 2 by adding an asymmetrically structured flange 6 to the opening surface 4 of the power feeding horn 2, the current feeding horn 2 can be easily improved.

By configuring the opening 7 (4) of the feeding horn 2 by adding asymmetrically structured chokes 88 to 8n to the opening surface 4 of the feeding horn 2, the current feeding horn 2 can be easily modified.

By configuring the feeding horn 2 with a corrugated horn that is asymmetrical to the corrugated tone structure 9, it can also be applied to a corrugated horn.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional configuration diagram of an offset reflector antenna used in the present invention, FIGS. )
and (d) are electric field distribution characteristic diagrams of the conventional feeding horn and the aperture surface of the reflecting mirror, and FIGS. 3(a) to (c) are the first embodiment according to the present invention. 4(a) to 4(b) are the second embodiment of the present invention, and FIGS. 4(a) and 4(b) are diagrams of the configuration of the feeding horn when the normal line 5 is tilted equivalently, FIG. 5 is a radiation pattern diagram showing radiation characteristics of the present invention and a conventional reflector antenna. 1 ・Mirror surface of the reflecting mirror, 1...° opening surface of the reflecting mirror, 2
...Feeding horn, 3...Axle of power feeding horn 2, 4.
Opening surface of the power supply horn 2. 5... Normal line of power supply horn 2, 6... Flange, 7
...Opening of the power supply horn 2, 8, ~8o...Choke, 9...Corrugated structure. Figure

Claims (5)

[Claims] (1) In an offset reflector antenna having a reflector and a feed horn arranged to offset feed the reflector, by making the electric field distribution on the aperture of the feed horn asymmetric, An offset reflector antenna characterized by having a symmetrical electric field distribution on the aperture surface. (2) The offset reflector antenna according to claim 1, wherein the normal direction (5) of the aperture surface of the feeding horn is inclined with respect to the axis (3) of the feeding horn. (3) The offset reflector antenna according to claim 1, wherein an asymmetrical flange is added to the opening of the feeding horn. (4) Claim 1 characterized in that a flange in which chokes are asymmetrically arranged is added to the opening of the power feeding horn.
Offset reflector antenna as described. (5) The offset reflector antenna according to claim 1, wherein the feeding horn is a corrugated horn having an asymmetric corrugated structure.