JPH077882B2 - Piping method for waveguide for polarization splitter - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a demultiplexing device for sharing a feed horn of a cluster-fed reflector antenna in a microwave or millimeter wave region with two orthogonal polarizations. It is a thing.

(Prior Art) A cluster feeding antenna is an antenna that feeds power with a plurality of horns each having a reflecting mirror near the focal point, as shown in FIG. In FIG. 9, 1001 is a reflecting mirror, 1002, 103, 1004
Is a primary radiator horn, 1005 is a power distribution / phase adjusting circuit, 1006, 1007, 1008 are horns 1004, 1003, 1002, respectively.
The direction of the beam emitted from. In addition, 1009 is positive in the upward direction with respect to the elevation angle. A combination of a collection of horns and an electrode distribution / phase adjusting circuit is called a feeding cluster. The cluster-fed antenna of FIG. 9 has horns 1002, 1003, 1004 arranged in the vertical cross section of the reflector.
By properly selecting the excitation intensity of each horn, a radiation pattern with a low side rope can be realized in the vertical plane.

FIG. 10 is for explaining the principle that the cluster-fed antenna shown in FIG. 9 has a low side rope characteristic.
Reference numerals 10,1011,1012 are radiation patterns when only the horns 1002,1003,1004 are operated. Further, 1013 is a combined pattern when all the horns are operated.

Radiation patterns 1011 and 1012 are φ with respect to the radiation pattern 1010.
The axes are translated leftward or rightward, respectively. 10 to achieve a low side rope pattern
11,1012 must be offset from 1010 by one side rope to the left or right. The size of the horn for realizing such a shift amount is shown, for example, in Japanese Patent Application No. 59-51115. The excitation and phase of the output for each horn of the power distribution and phase adjustment circuit must be flat within the required frequency band.

As a technique for sharing the orthogonal polarization in such a cluster feeding antenna, a method using a polarization grid plate as shown in FIG. 8 is known. Fig. 8 assumes an offset Cassegrain antenna mounted on a satellite, which is orthogonalized by a polarization grid plate (2002).
The two polarized wave feed clusters (2003, 2004) are spatially separated from each other, which enables the antenna to share the polarized wave. In FIG. 8, 2000 is the main reflecting mirror, 2001 is the sub-reflecting mirror, 2006 is the main radio wave emission direction, 2007 is the satellite body, and 20 is the main body.
08 is a tower. However, the method using such a polarization grid plate has drawbacks such as large power loss because the feed waveguide is long, and heavy weight of the polarization grid plate and the feed waveguide. Further, in the multi-beam antenna that radiates a plurality of beams by the polarization sharing technique using the polarization grid plate as shown in FIG. 8, there is a constraint that the inclinations of the polarizations of the respective beams must be aligned in parallel. there were.

On the other hand, a polarization splitter is known as a technique for sharing orthogonal polarizations in the same feed horn. Examples of the appearance of the demultiplexer are shown in Figs. 11 to 13. In these polarized waves, a horizontal branch port (1) and a direct port (2) that can connect two orthogonal polarizations coming from a square or circular waveguide (3) connected to a horn to a rectangular waveguide. Can be separated into However, the conventional demultiplexer is used for one horn, and when a plurality of horns are used like a cluster feed antenna, the polarized wave of the horn is shared by the demultiplexers. The waveguide piping method was not known.

(Problems to be Solved by the Invention) An object of the present invention is to insert a horn cluster of a cluster-fed antenna between two polarizations orthogonal to each other so as to be inserted between the cluster horn and a power distribution / excitation adjusting circuit. It is to realize a polarization splitter. Since the amplitude and phase of the output from the power distribution / excitation adjusting circuit to each horn must be at the desired values and flat within the prescribed frequency band, pipe the waveguide with an electrical length. is necessary. The present invention proposes a demultiplexer capable of being piped while satisfying this requirement.

(Means for Solving the Problems) The feature of the present invention for achieving the above-mentioned object is that a plurality of N / N (N is a natural number of 2 or more) plural demultiplexers (101, 102,
,, 10N) in which a waveguide for piping is connected to a lateral branch port, (a) a straight waveguide (11, 12, ..., 1N) of the same length, and (b) a bending angle of 90 H-plane bent waveguide (20
1,202, ..., 20N) and (c) Series waveguides (21,22, ..., 2) of length l ₂₁ , l ₂₂ , ..., l _2N
N) and (d) E-plane curved waveguide (301,
302, ..., 30N), (e) Linear waveguides (31,32, ..., 3N) of the same length, and (f) E-plane bend with the same dimension of bending angle θ as in (d). Waveguides (401,402, ..., 40N) and (g) straight waveguides (41,42, ..., 4) of length l ₄₁ , l ₄₂ , ..., l _4N
N) and is connected in this order, or at least one of (a) and (e) is connected in that order, and the linear waveguides (21, 22, ,, 2N, 41,42, ..., 4N) length l ₂₁ , l ₂₂ , ..., l _2N and l ₄₁ , l ₄₂ , ..., l _4N between l ₂₁ ＋ l ₄₁ ＝ l ₂₂ ＋ l ₄₂ ＝ There is a relationship of l _2N + l _4N , and the curved waveguides (301, 302,
, 30N, 401, 402, ..., 40N) with a bending angle θ of 90 ° or less.

(Operation) With the above configuration, the power distribution / excitation adjusting circuit has the desired amplitude and phase output to each horn, and the electrical lengths are aligned so that they are flat within the prescribed frequency band. In addition, there is provided a demultiplexer capable of actual phase without the respective pipes colliding with each other.

(Embodiment) FIG. 1 is a diagram for explaining the basic configuration of the present invention. In the lateral branching port (1) of the i-th demultiplexer (10i) of the N demultiplexers, (a) straight waveguide (1i) of the same length (b) with a bending angle of 90 ° H-shaped curved waveguide (20
i) (c) Linear waveguide of length l ₂ i (2i) (d) E-screen curved waveguide (30) of the same size with bending angle θ
i) (e) Straight waveguide (3i) with the same length (f) E-plane curved waveguide (40i) (g) with the same dimension of bending angle θ as in (d) ( ₄ ) Length l ₄ i Of the linear waveguides (4i) in this order, and the sum of the lengths l ₂ i and l ₄ i of the linear waveguides (2i, 4i) in (c) and (g) above forms the feeding cluster. Piping should be made equal to all the demultiplexers connected to all the horns. As a result, from the horizontal branch port (1) of the demultiplexer (10i) to the last straight waveguide (4
The electric length up to the opening (4) in i) is the same for all the demultiplexers, and the pipes connected to the plurality of demultiplexers can be arranged so as not to collide with each other.

Among the waveguides (a) to (g) above, (a) or (e) or both (a) and (e) may be omitted. In addition, the curved waveguides (30i, 40)
The bending angle θ in i) is more than 0 ° and 90 ° or less.

The demultiplexer has various appearances as shown in Figs. 11, 12, and 13, but in the embodiment shown in Figs. 1, 2, 3, and 5, the demultiplexer having the appearance shown in Fig. 11 is used. We will represent it with a vessel.

Embodiments in which such a basic configuration is applied to a 90 horn cluster and a 7 horn cluster are complicated as shown in FIGS. 2, 3 and 5, and therefore the reference numerals of the demultiplexer and the waveguide are as follows.
Only the i = 4th one in FIG. 2 is given, and the others are omitted. FIG. 4 and FIG. 6 are front views of the arrangement of the horns corresponding to these embodiments. The horn opening may be circular, but it is represented by a square opening in FIGS. 3 and 6.

Fig. 2 shows that the bending angle of the E-plane curved waveguide is 90 °.
This is an example applied to a 9 horn cluster in a × 3 square array, and FIG. 3 is an example applied to a 9 horn cluster with a bending angle of 45 °. FIG. 4 shows an example in which the bending angle of the E-plane bending waveguide is 90 ° and the waveguide is applied to a 7-horn cluster in a triangular array. It can be seen that in any of the examples, the electrical lengths are uniform and the pipes can be formed without the waveguides colliding with each other.

The above embodiment can be easily extended to a horn cluster having an arbitrary number of horns.

FIG. 7 is an example in which the polarization demultiplexing device (2003) of the present invention is applied to a cluster power feeding unit of an offset Cassegrain antenna mounted on a satellite. In FIG. 7, 2011 is a horn and 2013 is a power distribution / phase adjusting circuit. Compared to the conventional polarization sharing using the polarization grid plate (2002) shown in FIG. 8, the power supply waveguide from the transponder in the satellite body (2007) to the power supply section can be shortened, and loss can be reduced. is there. In addition, even if the polarization splitter (2012) is added, the polarization grid plate (20
02) and its indicating structure are not required, so that the synthesis of the tower (2008) can be made low, resulting in weight reduction. Furthermore, in a multi-beam antenna that uses a polarization demultiplexing device as shown in FIG.
It is possible to arbitrarily change the inclination of the independent polarization for each beam. In a satellite-mounted antenna that irradiates a beam obliquely downward, the inclinations of horizontally polarized waves or vertically polarized waves at two points separated from each other on the earth are not necessarily parallel when viewed from the satellite. The advantage of being able to set the polarization inclination arbitrarily for each beam is that the inclination of the polarization can be made almost the same when viewed from the ground at any point of the antenna beam irradiation area on the earth, that is, horizontally or vertically, for example. There is.

(Effects of the Invention) As described above, according to the polarization demultiplexing device of the present invention, the cluster feed horn can be shared by orthogonal polarizations by the waveguide pipe having the uniform electric length. In cluster feeding, it is necessary to flatten the amplitude and phase of the output to each horn within the required band, so if the piping is not uniform in electrical length, phase adjustment is difficult, but this difficulty does not exist.

Further, when this is applied to a satellite sub-reflector antenna, it is possible to reduce the loss and the weight by shortening the feed waveguide and eliminating the need for a polarization grid plate. further,
The effect is large, such that each beam of the multi-beam can be set independently.

[Brief description of drawings]

FIG. 1 shows a waveguide piping method which is a basic configuration of the present invention.
9 and 9 are diagrams for explaining one demultiplexer, FIG. 2 and FIG.
FIG. 4 is a diagram showing an embodiment when the present invention is applied to a horn cluster, FIG. 4 is a front view of a horn array corresponding to the embodiment of FIGS. 2 and 3, and FIG. FIG. 6 is a view showing an embodiment when the present invention is applied, FIG. 6 is a front view of a horn array corresponding to the embodiment of FIG. 5,
FIG. 7 is a diagram in which the polarization demultiplexing device of the present invention is applied to a satellite-mounted offset sub-reflector antenna, and FIG. 8 is a diagram showing a satellite-mounted offset sub-reflector antenna in which polarization is shared by a polarization grid plate, FIG. 9 is a principle diagram of a cluster feeding antenna, FIG. 10 is a diagram for explaining that the side rope can be lowered in the cluster feeding antenna, FIGS. 11 and 12
FIG. 13 and FIG. 13 are diagrams showing examples of the polarization demultiplexer. In the figure, 1 is a branching port of a demultiplexer, 2 is a direct port, 3 is a square or circular waveguide through which two polarizations orthogonal to each other pass, 11,12, ..., 1i, 21,22, ..., 2i , 31,32, ..., 3i, 41,42, ..., 4i is a straight waveguide, 301,302, ..., 30i, 401,402, ..., 40i is an E-plane curved waveguide with a bending angle θ, 1001 is a reflecting mirror, 1002, 1003, 1004 are horns, 1005 are power distribution / phase adjusting circuits, 1006, 1007, 1008 are radiation beam directions, 1009 are elevation angles, 101
0,1011,1012 is a radiation pattern, 1013 is a synthetic radiation pattern, 2000 is a main reflection mirror, 2001 is a sub-reflection mirror, 2002 is a polarization grid plate, 2003, 2004 is a feeding cluster, 2005 is a feeding waveguide, and 2006 is The beam direction of the main radio wave, 2007 is the satellite body, 2008 is the tower, 2011 is the horn, 2012 is the polarization splitter of the present invention, and 2013 is the power distribution / phase adjusting circuit.

Claims (1)

[Claims] 1. A piping method for connecting a waveguide for piping to lateral branch ports of a plurality of demultiplexers (101, 102, ..., 10N) of a number N (N is a natural number of 2 or more): Straight waveguides (11, 12, ..., 1N) of the same length, and (b) H-plane curved waveguide (20) of the same size with a bending angle of 90 °.
1,202, ..., 20N), and (c) a straight waveguide (21,22, ..., 2) of length l ₂₁ , l ₂₂ , ..., l _2N
N) and (d) E-plane curved waveguide (301,
302, ..., 30N), (e) Linear waveguides (31,32, ..., 3N) of the same length, and (f) E-plane bend with the same dimension of bending angle θ as in (d). Waveguides (401,402, ..., 40N) and (g) straight waveguides (41,42, ..., 4) of length l ₄₁ , l ₄₂ , ..., l _4N
N) and are connected in this order, or at least one of (a) and (e) is omitted and connected in that order, and the linear waveguides (21, 22, …, 2N,
41,42, ..., 4N) length l ₂₁ , l ₂₂ , ..., l _2N and l ₄₁ , l ₄₂ , ...,
between _{l 4N, l 21 + l 41} = l 22 + l 42 = ... l 2N + l are related to _4N, and the (d) and curved waveguide (f) (301, 302,
, 30N, 401, 402, ..., 40N) has a bending angle θ of 90 ° or less.