JP2016134639A - Polarization separation circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a polarization separation circuit capable of reducing transmission of a high order mode in a high frequency band to a common terminal.SOLUTION: On the common waveguide 4 side of a central waveguide 7, first rectangular branch waveguides 6a-6d having first rectangular branch terminals 3a-3d for transmitting polarization of a low frequency band are provided. Furthermore, second rectangular branch waveguides 9a-9d having second rectangular branch terminals 8a-8d, and separating a high order mode in a high frequency band, in a direction where the wide face crosses the tube axis direction of the central waveguide 7, is provided on the common axis waveguide 5 side of the central waveguide 7.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a polarization separation circuit of two orthogonally polarized two frequencies used mainly in a VHF band, a UHF band, a microwave band, and a millimeter wave band.

  In a circularly polarized antenna feeding circuit that uses a plurality of frequency bands, such as an antenna system for satellite communication, a waveguide circuit that separates two orthogonally polarized waves (TE11 mode, which is a fundamental mode) in each frequency band is used. It is done. As one of such waveguide circuits, there is a polarization separating circuit called OMJ (Ortho-Mode Junction) of two orthogonally polarized two frequency bands. This circuit has a common terminal that transmits polarized waves in two frequency bands, a coaxial terminal that transmits polarized waves in the high frequency band, and a branch terminal that transmits polarized waves in the low frequency band (for example, non-patent) Reference 1).

FIG. 9 is a perspective view for explaining the configuration of a conventional polarization separation circuit. As shown, the polarization separation circuit includes a common terminal 1, a coaxial terminal 2, a branch terminal 3, a common waveguide 4, a coaxial waveguide 5, a branch waveguide 6, and a central waveguide 7. ing.
The common waveguide 4 and the coaxial waveguide 5 are connected to each other via a tapered central waveguide 7. The common terminal 1 is connected to one end of the common waveguide 4, and the coaxial waveguide 5 is connected to one end of the coaxial waveguide 5. A coaxial terminal 2 is provided. Further, four branching waveguides 6 are provided at intervals of 90 degrees in the circumferential direction through coupling holes 7a to 7d on the tube wall of the tapered central waveguide 7 (each of which is respectively referred to as the branching waveguides 6a to 6d). Are connected to each other, and branch terminals 3 (referred to as branch terminals 3a to 3d, respectively) are provided at one ends of the branch waveguides 6a to 6d. Here, the common waveguide 4 and the coaxial waveguide 5 are circular, and the branched waveguides 6a to 6d are rectangular. The wide surfaces of the branched waveguides 6a to 6d are tube axes. It is provided so as to be parallel to the direction.

  Next, the operation will be described. When two orthogonal polarizations in two frequency bands are input from the common terminal 1, two polarization terminals 3a and 3c facing each other in the low frequency band and two polarizations orthogonal in the two frequency bands The signals are output to two opposing branch terminals 3b and 3d different from the branch terminals 3a and 3c. Further, when two polarized waves in the high frequency band are input, they are output to the coaxial terminal 2. For this reason, by providing a circuit that synthesizes and separates each of two opposing branch terminals for the low frequency band, and a circuit that separates two orthogonal polarized waves for the high frequency band, the orthogonality of the two frequency bands is provided. Are separated. Here, a circuit for synthesizing / separating branch terminals and a circuit for separating polarized waves in a high frequency band are not shown.

  In the conventional polarization separation circuit, the central waveguide 7 has a tapered structure. By selecting the diameter of the coaxial terminal 2 so that the fundamental mode is cut off in the low frequency band, good fundamental mode transmission characteristics between the common terminal 1 and the branch terminals 3a to 3d are realized in the low frequency band. By making the central waveguide 7 tapered, a good fundamental mode transmission characteristic between the common terminal 1 and the coaxial terminal 2 is realized in a high frequency band.

US2002 / 0187760A1, Dec.12, 2002, “Symmetric orthomode coupler for cellular application”, TRW

  In the conventional polarization separation circuit, when the separation between the two frequency bands is wide, if the diameter of the common terminal 1 is selected so that the fundamental mode (TE11 mode) becomes the propagation mode in the low frequency band, the higher order in the high frequency band The mode becomes the propagation mode. For this reason, there is a problem that an unnecessary higher-order mode generated at a connection portion between the tapered central waveguide 7 and the branching waveguide 6 is transmitted to the common terminal 1 in a high frequency band.

  The present invention has been made in order to solve the above-described problems. To a common terminal of a high-order mode (a TM11 mode which is the lowest-order high-order mode coupled with the TE11 mode) in a high frequency band. An object of the present invention is to obtain a polarization separation circuit that can reduce transmission of light.

  A polarization separation circuit according to the present invention includes a tapered hollow central waveguide having first and second coupling holes in a tube wall, one end connected to the wide-diameter end of the central waveguide, and the other end One end is connected to the narrow end of the central waveguide and the other end is connected to the high frequency band. A coaxial waveguide serving as a coaxial terminal for transmitting a wave, and a first rectangular branch terminal having one end connected to the first coupling hole of the central waveguide and the other end transmitting a polarized wave in a low frequency band One end is connected to the first rectangular branch waveguide and the second coupling hole of the central waveguide, and the other end is the second rectangular branch terminal, and the wide surface is the tube axis direction of the central waveguide. And a second rectangular branch waveguide that separates higher-order modes in the high frequency band.

  In the polarization separation circuit according to the present invention, one end is connected to the second coupling hole of the central waveguide, the other end is the second rectangular branch terminal, and the wide surface intersects the tube axis direction of the central waveguide. Since the second rectangular branch waveguide provided in the direction and separating the higher-order mode in the high-frequency band is provided, transmission of unnecessary higher-order modes to the common terminal in the high-frequency band can be reduced. It is possible to realize good transmission characteristics only in the mode.

1 is a perspective view showing a configuration of a polarization beam splitting circuit according to Embodiment 1 of the present invention. It is explanatory drawing which shows the electric field distribution of each mode of the polarization splitting circuit by Embodiment 1 of this invention. It is explanatory drawing which shows the relationship between TM11 mode of the polarization splitting circuit by Embodiment 1 of this invention, and a 2nd rectangular branch waveguide. Explanatory drawing which shows the calculation result of TE11 mode and TM11 mode which are output to a common terminal when one TE11 mode is input from a coaxial terminal in the high frequency band of the polarization separation circuit according to Embodiment 1 of the present invention. It is. It is sectional drawing which shows the structure of the polarization splitting circuit by Embodiment 2 of this invention. It is sectional drawing which shows the structure of the polarization splitting circuit by Embodiment 3 of this invention. It is sectional drawing which shows the structure of the polarization splitting circuit by Embodiment 4 of this invention. It is explanatory drawing of the effect of the polarization separation circuit by Embodiment 4 of this invention. It is a perspective view which shows the structure of the conventional polarization separation circuit.

Embodiment 1 FIG.
FIG. 1 is a perspective view showing the configuration of a polarization beam splitting circuit according to Embodiment 1 of the present invention.
The polarization separation circuit shown in FIG. 1 includes a common terminal 1, a coaxial terminal 2, first rectangular branch terminals 3a to 3d, a common waveguide 4, a coaxial waveguide 5, and a first rectangular branch waveguide. 6a-6d, central waveguide 7, second rectangular branch terminals (high-order mode branch terminals) 8a-8d, second rectangular branch waveguides (high-order mode branch waveguides) 9a-9d I have.

  The common waveguide 4 and the coaxial waveguide 5 are connected to each other via a tapered central waveguide 7. The common terminal 1 is connected to one end of the common waveguide 4, and the coaxial waveguide 5 is connected to one end of the coaxial waveguide 5. A coaxial terminal 2 is provided. In addition, the first rectangular branch waveguides 6a to 6d are arranged at intervals of 90 degrees in the circumferential direction through coupling holes (first coupling holes) 7a1 to 7d1 on the tube wall of the tapered central waveguide 7. Four are connected, and first rectangular branch terminals 3a to 3d are provided at one ends of the first rectangular branch waveguides 6a to 6d. The first rectangular branch waveguides 6a to 6d and the first rectangular branch terminals 3a to 3d of the first embodiment are the same as the branch waveguides 6a to 6d and the rectangular branch terminals 3a to 3a configured as shown in FIG. It corresponds to 3d. Furthermore, a coupling hole (second coupling hole) is formed on the tube wall of the tapered central waveguide 7 on the side different from the installation side of the first rectangular branch waveguides 6a to 6d. Four second rectangular branch waveguides 9a to 9d are connected to each other at intervals of 90 degrees in the circumferential direction through 7a2 to 7d2, and second rectangular branch terminals 8a to 8d are provided at one end. Here, the common waveguide 4 and the coaxial waveguide 5 are circular, and the first rectangular branch waveguides 6a to 6d and the second rectangular branch waveguides 9a to 9d are rectangular. The wide surfaces of the first rectangular branch waveguides 6a to 6d are parallel to the tube axis direction, and the wide surfaces of the second rectangular branch waveguides 9a to 9d cross the tube axis direction. Is provided. The first rectangular branch waveguides 6 a to 6 d and the second rectangular branch waveguides 9 a to 9 d are installed so as to be perpendicular to the tapered surface of the central waveguide 7. Note that the first and second coupling holes 7d1, 7c2, 7d2, the first rectangular branch terminal 3d, and the first rectangular branch waveguide 6d do not appear in FIG.

  Next, the operation of the polarization separation circuit according to the first embodiment will be described. When two orthogonally polarized waves (TE11 mode) in two frequency bands are input from the common terminal 1, one polarized wave in the low frequency band is opposed to the two first rectangular branch terminals 3a and 3c facing each other. One polarized wave is output to two opposing first rectangular branch terminals 3b and 3d that are different from the two first rectangular branch terminals 3a and 3c. Further, two polarized waves (TE11 mode) in the high frequency band are output to the coaxial terminal 2. On the other hand, when orthogonally polarized waves are input to each of two opposing branch terminals, the two polarized waves are output from the common terminal 1. In addition, when two polarizations in the high frequency band are input from the coaxial terminal 2, they are output from the common terminal 1.

  FIG. 2 is a diagram showing the electric field distribution in each mode. Here, when the circle diameter of the common terminal 1 is selected so that the separation between the low frequency band and the high frequency band is wide and the fundamental mode (TE11 mode) is transmitted in the low frequency band, Consider the case where the mode up to the TM11 mode is the propagation mode. That is, in the high frequency band, the TM01 mode, the TE21 mode, and the TM11 mode, which are higher than the basic mode, become the propagation modes.

  When the TE11 mode is input from the coaxial terminal 2 in the high frequency band, it is coupled to the higher-order mode generated in the discontinuous portion to which the first rectangular branch waveguides 6a to 6d are connected, and the common waveguide is used. Will be transmitted to the tube 4. However, each mode has different symmetry, and the higher-order mode that is easily coupled with the TE11 mode is only the TM11 mode having the same symmetry (having an electric wall and a magnetic wall).

  FIG. 3 is a diagram showing the relationship between the TM11 mode and the second rectangular branch waveguides 9a to 9d. As shown in FIG. 3 (a), the TM11 mode is coupled to the second rectangular branch waveguides 9a and 9c by arranging the wide surface so as to intersect the tube axis direction, so that the second rectangular branch terminal is connected. Output to 8a and 8c. Note that the TM11 mode in the direction orthogonal to the figure is coupled to the second rectangular branch waveguides 9b and 9d and output to the second rectangular branch terminals 8b and 8d. For this reason, the effect that it is not transmitted to the common waveguide 4 is acquired. On the other hand, since the position of the branch waveguide where the TE11 mode, which is the fundamental mode, is coupled is different from the position where the TM11 mode is coupled, the TE11 mode is the second rectangular branch waveguides 9a to 9d (branch waveguides for higher-order modes). Tube). For this reason, the TE11 mode, which is the fundamental mode, is transmitted to the common waveguide 4 with little influence from the second rectangular branch waveguides 9a to 9d. Further, the polarization in the low frequency band is hardly affected because the second rectangular branch waveguides 9a to 9d are cut off. Since the first rectangular branch waveguides 6a to 6d are generally provided with a low-pass filter that cuts off the high frequency band, the polarization in the high frequency band is the first rectangular branch waveguide 6a to 6d. It is not transmitted to 6d.

In addition, when arrange | positioning so that a wide surface may become parallel to a pipe-axis direction, as shown in FIG.3 (b), a narrow surface cross | intersects a pipe-axis direction. At this time, the TM11 mode is not coupled to any of the second rectangular branch waveguides 9a to 9d. That is, the second rectangular branch waveguides 9a and 9c are not coupled because the width of the waveguide is narrow and cut off, and the second rectangular branch waveguides 9b and 9d are not coupled because an electric field hardly occurs. .
From this point, the TM11 mode is coupled to the second rectangular branch waveguides 9a to 9d by arranging the wide surfaces of the second rectangular branch waveguides 9a to 9d so as to intersect the tube axis direction. Then, it can be output from the second rectangular branch terminals 8a to 8d.

  FIG. 4 is a diagram illustrating calculation results of the TE11 mode and the TM11 mode output to the common terminal 1 when one TE11 mode is input from the coaxial terminal 2 in the high frequency band. The result of having confirmed the effect of this Embodiment by electromagnetic field calculation is shown. A conventional configuration in which the first rectangular branch waveguides 6a to 6d are loaded with a waffle iron type low-pass filter that blocks high frequency band polarization, and the second rectangular branch waveguides 9a to 9d are not provided. And the configuration according to the present embodiment in which the second rectangular branch waveguides 9a to 9d are provided. In the figure, the characteristic around the coupling amount 0 dB indicates the amount of the TE11 mode output from the common waveguide 4 when the TE11 mode is input from the coaxial waveguide 5, and the coupling amount around −20 to −30 dB is shown. The characteristic indicates the amount of TM11 mode output from the common waveguide 4 when the TE11 mode is input from the coaxial waveguide 5. Further, ◯ indicates the characteristics of the conventional configuration, and Δ indicates the characteristics of the configuration of the first embodiment.

  As shown in the figure, in the conventional configuration, the TM11 mode is output about −20 dB, whereas in the configuration according to the present invention, the output TM11 mode is about −26 dB, which can be confirmed to be improved by about 6 dB ( (See arrow 100). The reduced 6 dB portion of the TM11 mode is output to the second rectangular branch waveguides 9a to 9d. At this time, it can also be confirmed that the TE11 mode output from the common terminal 1 is hardly affected by the second rectangular branch waveguides 9a to 9d.

  In FIG. 1, the first rectangular branching waveguides 6a to 6d are shown not to be loaded with a low-pass filter. However, as shown in the electromagnetic field calculation, a waffle iron type low-pass filter or a corrugated type is used. A low-pass filter or the like may be loaded.

  In addition, the first rectangular branch waveguides 6a to 6d are shown as being provided on the tube wall of the tapered central waveguide 7, but the connection between the tapered central waveguide 7 and the common waveguide 4 is shown. You may provide so that a part may be straddled.

  Further, an iris or other matching element may be provided at the connection portion of the first rectangular branch waveguides 6a to 6d and the second rectangular branch waveguides 9a to 9d.

  In the above example, the case where four second rectangular branch waveguides 9a to 9d are provided at intervals of 90 degrees in the circumferential direction of the central waveguide 7 is shown. Only the second rectangular branch waveguides 9a and 9b may be used. As described above, when the second rectangular branch waveguides 9a and 9b are provided in two pieces, the processing becomes easier and the cost can be reduced. Also, a configuration in which three second rectangular branch waveguides are provided at intervals of 90 degrees may be employed.

  In the above example, the second rectangular branch waveguides 9 a to 9 d are provided on the coaxial waveguide 5 side of the central waveguide 7, but may be provided on the common waveguide 4 side.

  As described above, according to the polarization separation circuit of the first embodiment, the tapered hollow central waveguide having the first and second coupling holes in the tube wall and the wide diameter of the central waveguide. One end is connected to the end, and the other end is connected to the common waveguide for transmitting two orthogonal polarized waves in the low frequency band and the high frequency band, and one end is connected to the narrow-diameter end of the central waveguide. A coaxial waveguide having the other end as a coaxial terminal for transmitting polarization in the high frequency band, and one end connected to the first coupling hole of the central waveguide, and the other end being polarized in the low frequency band One end is connected to the first rectangular branch waveguide serving as the first rectangular branch terminal for transmitting the signal, and the second coupling hole of the central waveguide, and the other end is used as the second rectangular branch terminal. Is provided in a direction crossing the tube axis direction, and includes a second rectangular branch waveguide that separates higher-order modes in the high frequency band. Can reduce transmission of the main high-order modes, thus, it can realize excellent transmission characteristics of only the desired mode.

  Further, according to the polarization separation circuit of the first embodiment, the first rectangular branch waveguide is located on the common waveguide side of the central waveguide, and the second rectangular branch waveguide is the central waveguide. Since the tube is positioned on the coaxial waveguide side, transmission to the common terminal of the higher order mode can be surely reduced.

  In addition, according to the polarization separation circuit of the first embodiment, since the second rectangular branch waveguide is provided in plural at intervals of 90 degrees in the circumferential direction of the central waveguide, it is common in the high frequency band. Unnecessary higher-order mode transmission to the terminal can be reduced, and therefore, good transmission characteristics only in the desired mode can be realized.

  In addition, according to the polarization separation circuit of the first embodiment, four or two second rectangular branch waveguides are provided, so that a symmetrical configuration is not required for a common terminal in a higher frequency band. High-order mode transmission can be reduced.

Embodiment 2. FIG.
FIG. 5 is a cross-sectional view showing the configuration of the polarization separation circuit according to the second embodiment of the present invention.
Similarly to the first embodiment, the polarization separation circuit according to the second embodiment includes the common terminal 1, the coaxial terminal 2, the first rectangular branch terminals 3a to 3d, the common waveguide 4, and the coaxial waveguide 5. The first rectangular branch waveguides 6a to 6d, the central waveguide 7, the second rectangular branch terminals 8a to 8d, the second rectangular branch waveguides 9a to 9d, and the second rectangular The branch waveguides 9a to 9d are provided with non-reflection terminators 10a to 10d. The non-reflective terminators 10a to 10d are terminators that absorb higher-order modes in a high frequency band, are provided in the second rectangular branch waveguides 9a to 9d, and are connected to the second rectangular branch terminals 8a to 8d. It is connected. Since other configurations are the same as those of the first embodiment shown in FIG. 1, the corresponding parts are denoted by the same reference numerals and description thereof is omitted. In FIG. 5, the first and second coupling holes 7b1, 7d1, 7b2, and 7d2, the first rectangular branch terminals 3b and 3d, the first rectangular branch waveguides 6b and 6d, and the second rectangular branch terminal. 8b and 8d, the second rectangular branch waveguides 9b and 9d, and the non-reflection terminators 10b and 10d do not appear.

  Since the basic operation of the polarization separation circuit according to the second embodiment is the same as the operation of the polarization separation circuit according to the first embodiment, description of the operation is omitted here. However, in the second embodiment, the high-order modes in the high frequency band of the second rectangular branch waveguides 9a to 9d are absorbed by the non-reflection terminators 10a to 10d.

  As described above, according to the polarization separation circuit of the second embodiment, the second rectangular branch waveguide includes the non-reflection terminator that absorbs the higher-order mode in the high frequency band. In addition to having the same effect as in the first mode, unnecessary high-order modes are absorbed by the non-reflecting terminator, so that an effect of eliminating the circuit for separation / synthesis provided for each second rectangular branch terminal is obtained.

Embodiment 3 FIG.
FIG. 6 is a cross-sectional view showing the configuration of the polarization separation circuit according to the third embodiment of the present invention.
As in the first embodiment, the polarization separation circuit according to the third embodiment includes the common terminal 1, the coaxial terminal 2, the first rectangular branch terminals 3a to 3d, the common waveguide 4, and the coaxial waveguide 5. The first rectangular branch waveguides 6a to 6d, the central waveguide 7, the second rectangular branch terminals 8a to 8d, the second rectangular branch waveguides 9a to 9d, and the second rectangular The branch waveguides 9a to 9d are provided with high-pass filters 11a to 11d. The high-pass filters 11a to 11d are provided in the second rectangular branch waveguides 9a to 9d, and are connected to the second rectangular branch terminals 8a to 8d. Since other configurations are the same as those of the first embodiment shown in FIG. 1, the corresponding parts are denoted by the same reference numerals and description thereof is omitted. In FIG. 6, the first and second coupling holes 7b1, 7d1, 7b2, and 7d2, the first rectangular branch terminals 3b and 3d, the first rectangular branch waveguides 6b and 6d, and the second rectangular branch terminal. 8b and 8d, the second rectangular branch waveguides 9b and 9d, and the high-pass filters 11b and 11d do not appear.

  Since the basic operation of the polarization separation circuit according to the third embodiment is the same as the operation of the polarization separation circuit according to the first embodiment, the description of the operation is omitted here. However, in the third embodiment, the low-frequency band signals leaking into the second rectangular branch waveguides 9a to 9d are blocked by the high-pass filters 11a to 11d. That is, in the vicinity of the cutoff frequency of the polarization in the low frequency band, there is a possibility that the signal leaks somewhat to the second rectangular branch terminals 8a to 8d. In the third embodiment, since the high-pass filters 11a to 11d are provided in the second rectangular branch waveguides 9a to 9d, more reliable cutoff can be performed in the low frequency band. The influence on the polarization can be reduced.

  As described above, according to the polarization separation circuit of the third embodiment, the second rectangular branch waveguide includes the high-pass filter, and thus has the same effect as that of the first embodiment. The influence on the polarization in the low frequency band can be further reduced.

Embodiment 4 FIG.
FIG. 7 is a cross-sectional view showing a configuration of a polarization beam splitting circuit according to Embodiment 4 of the present invention.
Similarly to the first embodiment, the polarization separation circuit according to the fourth embodiment includes the common terminal 1, the coaxial terminal 2, the first rectangular branch terminals 3a to 3d, the common waveguide 4, and the coaxial waveguide 5. , First rectangular branch waveguides 6a to 6d, a central waveguide 7, second rectangular branch terminals 8a to 8d, and second rectangular branch waveguides 9a to 9d. Here, the basic configuration is the same as that of the first embodiment, but the second rectangular branch waveguides 9a to 9d of the fourth embodiment are coaxially guided deeper than the taper angle of the central waveguide 7. Inclined toward the wave tube 5 side. In FIG. 7, the first and second coupling holes 7b1, 7d1, 7b2, and 7d2, the first rectangular branch terminals 3b and 3d, the first rectangular branch waveguides 6b and 6d, and the second rectangular branch terminal. 8b and 8d and the second rectangular branch waveguides 9b and 9d do not appear.

  Since the basic operation of the polarization separation circuit according to the fourth embodiment is the same as the operation of the polarization separation circuit according to the first embodiment, description of the operation is omitted here. However, in the fourth embodiment, since the second rectangular branch waveguides 9a to 9d are installed to be inclined deeper than the taper angle of the central waveguide 7, the central waveguide 7 and the second rectangular branch waveguide are disposed. Mode conversion with the terminals 8a to 8d is performed smoothly.

FIG. 8 is a diagram showing a comparison of the direction of the electric field at the connecting portion between the central waveguide 7 and the second rectangular branch waveguides 9a to 9d. FIG. When the rectangular branch waveguides 9a to 9d are provided, (b) is a case where the second rectangular branch waveguides 9a to 9d are provided inclined with respect to the tapered surface of the fourth embodiment.
The arrow in the figure indicates the direction of the electric field, and the configuration of (b) with a deeper taper angle than the configuration shown in (a) is the center waveguide 7 and the second rectangular branch waveguide. It can be seen that the change in the direction of the electric field at 9a to 9d and the connecting portion is small (see thick arrows). Therefore, mode conversion is performed smoothly, and the effect of increasing coupling can be obtained.

  As described above, according to the polarization separation circuit of the fourth embodiment, the second rectangular branch waveguide is provided to be inclined to the coaxial waveguide side deeper than the taper angle of the central waveguide. Therefore, in addition to the same effects as in the first embodiment, the TM11 mode coupling is further increased, and the TM11 mode transmitted to the common waveguide can be further reduced.

  Even if the non-reflecting terminator according to the second embodiment is applied to the polarization separation circuit according to the fourth embodiment, as in the second embodiment, unnecessary higher-order modes are generated by the non-reflecting terminator. There is also an effect that a circuit that is absorbed and separated and combined becomes unnecessary.

  In addition, even if the high-pass filter according to the third embodiment is applied to the polarization separation circuit according to the fourth embodiment, the polarization in the low frequency band is achieved by the high-pass filter as in the third embodiment. There is also an effect that the influence on can be further reduced.

  In the present invention, within the scope of the invention, any combination of the embodiments, or any modification of any component in each embodiment, or omission of any component in each embodiment is possible. .

  DESCRIPTION OF SYMBOLS 1 Common terminal, 2 coaxial terminal, 3a-3d 1st rectangular branch terminal, 4 common waveguide, 5 coaxial waveguide, 6a-6d 1st rectangular branch waveguide, 7 center waveguide, 7a1 to 7d1 first coupling hole, 7a2 to 7d2 second coupling hole, 8a to 8d second rectangular branch terminal, 9a to 9d second rectangular branch waveguide, 10a to 10d non-reflective terminator, 11a to 11d High pass filter.

Claims (7)

A tapered hollow central waveguide having first and second coupling holes in the tube wall;
A common waveguide having one end connected to the wide diameter end of the central waveguide and the other end serving as a common terminal for transmitting two orthogonally polarized waves in a low frequency band and a high frequency band;
A coaxial waveguide having one end connected to the narrow-diameter end of the central waveguide and the other end serving as a coaxial terminal for transmitting polarization in a high frequency band;
A first rectangular branch waveguide having one end connected to the first coupling hole of the central waveguide and the other end serving as a first rectangular branch terminal for transmitting a polarization in a low frequency band;
One end is connected to the second coupling hole of the central waveguide, the other end is a second rectangular branch terminal, and a wide surface is provided in a direction intersecting the tube axis direction of the central waveguide, A polarization separation circuit comprising: a second rectangular branch waveguide that separates a high-order mode in a high frequency band.   The first rectangular branch waveguide is located on the common waveguide side of the central waveguide, and the second rectangular branch waveguide is on the coaxial waveguide side of the central waveguide. The polarization separation circuit according to claim 1, wherein the polarization separation circuit is located.   3. The polarization separation circuit according to claim 1, wherein a plurality of the second rectangular branch waveguides are provided at intervals of 90 degrees in the circumferential direction of the central waveguide.   4. The polarization separation circuit according to claim 3, wherein four or two of the second rectangular branch waveguides are provided.   5. The device according to claim 1, wherein the second rectangular branch waveguide includes a non-reflection terminator that absorbs a higher-order mode in the high-frequency band. 6. Polarization separation circuit.   The polarization separation circuit according to any one of claims 1 to 5, wherein the second rectangular branch waveguide includes a high-pass filter.   The second rectangular branching waveguide is provided to be inclined toward the coaxial waveguide deeper than a taper angle of the central waveguide. The polarization separation circuit according to claim 1.

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