JP2024019776A - Power combiner/distributor - Google Patents

Abstract

To provide a power combiner/distributor that can be used in a high frequency band and high power, and can be installed in a small space.SOLUTION: A power combiner/distributor W1 includes a main body part 1 having a void formed therein, a radial line 2 formed in a gap inside the main body part 1, a plurality of coaxial terminals 3 arranged concentrically with respect to the center of the radial line 2 on the outer periphery of the radial line 2 and installed on the outer periphery side of the main body part 1, a coaxial line 4 whose one end is connected to the coaxial terminal 3 and whose other end is connected to the outer circumference of the radial line 2, and a TM01 mode circular waveguide 5 that is installed vertically in the center of the main body 1, an impedance conversion unit is provided in the radial line 2, a mode conversion unit 6 is installed in the center of the radial line 2, and the mode conversion unit 6 excites the TM01 mode in the circular waveguide and performs impedance matching between the radial line 2 and the circular waveguide 5.SELECTED DRAWING: Figure 1

Description

The present invention relates to a power combiner/divider, and more particularly, to a power combiner/divider used for combining or distributing high power in the microwave band or millimeter wave band.

2. Description of the Related Art Conventionally, as one means for obtaining high power output, a power combiner is known which combines a plurality of input powers to obtain high output power. This power combiner includes a plurality of input terminals for inputting power and an output terminal for outputting the combined power. Further, the power combiner functions as a power divider when the input end is used as the output end and the output end is used as the input end. Therefore, in this specification, both the "power combiner" and the "power divider" are referred to as the "power combiner/divider."

Various configurations of the power combiner/divider described above have been proposed.
For example, Patent Document 1 discloses a power combiner/distributor having a configuration in which a central coaxial line is used as a connection line to an output end for outputting combined power (or an input end for inputting power to be distributed). is proposed. The power combiner/distributor disclosed in Patent Document 1 includes a main body portion with a gap formed inside, a central coaxial plug provided approximately at the center of the main body portion, and a power combiner/distributor provided in a concentric circle around the central coaxial plug. a plurality of peripheral coaxial connectors arranged in the main body and installed in the main body, a radial line formed in a gap inside the main body, one end connected to the central coaxial connector, and the other end connected to the central part of the radial line. The central coaxial line is connected to the radial line, and the peripheral coaxial line is connected at one end to the peripheral coaxial connector and at the other end to the outer periphery of the radial line. This power combiner/distributor functions as a power combiner when the central coaxial plug is used as an output terminal and the peripheral coaxial plugs are used as input terminals, and the central coaxial plug is used as an input terminal and the peripheral coaxial plugs are output terminals. When used as a terminal, it functions as a power divider.

Further, for example, Patent Document 2 proposes a configuration of a waveguide type power combiner/divider using a waveguide line having a smaller transmission loss than a coaxial line.
In the waveguide type power combiner/distributor disclosed in Patent Document 2, a plurality of TE10 mode rectangular waveguides are arranged so that their axial directions are radial, and a TM01 mode circular waveguide is arranged at the center of the radial direction. A waveguide is arranged perpendicular to the radial plane. In addition, in this waveguide type power combiner/divider, each of the plurality of rectangular waveguides has one end connected to the outer circumferential side of one end of the circular waveguide, and the axial direction of the rectangular waveguide, The axial direction of the circular waveguide is perpendicular.

Patent No. 5630916 Patent No. 5816768

By the way, the above-mentioned conventional technology has the following problems.
The power combiner/divider described in Patent Document 1 has a configuration in which a central coaxial line is used as a connection line to an output terminal for outputting the combined power (or an input terminal for inputting the power to be distributed). Because of this, the frequency and power that can be supported are limited, and there are limits to the use of high frequency bands and high power.

On the other hand, the waveguide type power combiner/divider described in Patent Document 2 has a circular conductor in the connection line to the output terminal for outputting the combined power (or the input terminal for inputting the power to be distributed). Since a configuration using a wave tube is adopted, it is suitable for use in a high frequency band and high power compared to the configuration described in Patent Document 1.
However, when the waveguide-type power combiner/divider described in Patent Document 2 is used as a power combiner, for example, a plurality of rectangular waveguides and a waveguide output end of a power amplifier are connected to each other by a connecting waveguide. They have to be connected to each other using pipes, making the routing complicated and requiring a large installation space.
Further, it is not suitable for miniaturizing a device incorporating the waveguide type power combiner/divider described in Patent Document 2.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a power combiner/distributor that can be used in a high frequency band and with high power, and can be installed in a small space.

A first aspect of the present invention, which has been made to solve the above problems, includes a main body portion having a gap formed inside, a radial line formed in the gap inside the main body portion, and a radial line formed in the outer circumferential portion of the radial line. a plurality of coaxial terminals arranged concentrically with respect to the center of the radial line and installed on the outer circumferential side of the main body; one end connected to the coaxial terminal and the other end connected to the outer circumference of the radial line; A connected coaxial line and a TM01 mode circular waveguide provided perpendicularly in the center of the main body and communicating with the radial line, the coaxial line being provided for each coaxial terminal. When the circular waveguide is used as an output terminal and the coaxial terminal is used as an input terminal, it functions as a power combiner, and when the circular waveguide is used as an input terminal and the coaxial terminal is used as an output terminal, it functions as a power combiner. A power combiner/distributor configured to function as a power divider, wherein one or more stages of impedance conversion sections are provided on the radial line, a mode conversion section is installed in the center of the radial line, The mode converter excites the TM01 mode in the circular waveguide and performs impedance matching between the radial line and the circular waveguide.

As described above, the power combiner/distributor of the first aspect of the present invention has a TM01 mode circular waveguide on the "output side of the combined power (or input side of the power to be distributed)" connected to the radial line. The mode converter is installed in the center of the radial line. This mode converter excites the TM01 mode in the circular waveguide and performs impedance matching between the radial line and the circular waveguide.
That is, the power combiner/distributor of the first aspect of the present invention, like the power combiner/distributor described in Patent Document 1, is capable of connecting the output side of the combined power (or the power to be distributed) connected to the radial line. The configuration is such that a TM01 mode circular waveguide is used instead of a central coaxial line for the connection line on the ``input side''.
Therefore, according to the first aspect of the present invention, the problem of "frequency and power being limited" of the power combiner/divider described in Patent Document 1 is resolved, and use in higher frequency bands and higher power is possible. A possible power combiner/divider is provided.
Further, in the power combiner/distributor according to the first aspect of the present invention, the input terminal for inputting the power to be combined (or the output terminal for outputting the power to be distributed) is a coaxial terminal. Unlike the waveguide type power combiner/divider described in 2, the configuration does not include a plurality of rectangular waveguides. Therefore, according to the present invention, a flexible coaxial cable can be connected to a coaxial terminal, making routing easier and allowing space-saving installation.

Further, a second aspect of the present invention provides a main body portion having a gap formed therein, a radial line formed in the gap inside the main body portion, and a radial line formed in the outer circumferential portion of the radial line with respect to the center of the radial line. a plurality of coaxial terminals arranged concentrically and installed on the outer peripheral side of the main body; a coaxial line having one end connected to the coaxial terminal and the other end connected to the outer peripheral part of the radial line; A TM01 mode circular waveguide is provided perpendicularly to the center of the main body and communicates with the radial line, and the coaxial line is provided for each coaxial terminal, and the coaxial line is provided for each coaxial terminal, and the circular waveguide When the tube is used as an output terminal and the coaxial terminal is used as an input terminal, it functions as a power combiner, and when the circular waveguide is used as an input terminal and the coaxial terminal is used as an output terminal, it functions as a power divider. A power combiner/distributor having one or more stages of impedance conversion sections on the radial line, a mode conversion section installed in the center of the radial line, and a power combiner/distributor including the circular waveguide and the other impedance conversion sections. A converter that converts the circular waveguide mode TM01 mode to the rectangular waveguide mode TE10 mode is connected to the end, and the inner wall of the circular waveguide smoothly converts the mode from TM01 mode to TE10 mode. A mode suppressor for conversion is arranged to suppress phase shift distortion and transmission loss.

The power combiner/distributor of the second aspect of the present invention is similar to the first aspect described above, and is connected to the connection line on the "output side of the combined power (or input side of the power to be distributed)" connected to the radial line. The configuration uses a TM01 mode circular waveguide instead of a central coaxial line. Therefore, according to the second aspect of the present invention, the problem of "frequency and power being limited" of the power combiner/divider described in Patent Document 1 is resolved, and use in higher frequency bands and higher power is possible. A possible power combiner/divider is provided.
Further, in the power combiner/distributor of the second aspect of the present invention, as in the first aspect described above, the input terminal for inputting the power to be combined (or the output terminal for outputting the power to be distributed) is coaxial. Since it is a terminal, a flexible coaxial cable can be connected to the coaxial terminal, making routing easier and allowing space-saving installation.

Further, in the power combiner/distributor of the second aspect of the present invention, a converter is provided at the other end of the circular waveguide to convert from the TM01 mode, which is the circular waveguide mode, to the TE10 mode, which is the rectangular waveguide mode. is connected.
This configuration was adopted because the power transmission path is usually configured with a rectangular waveguide.
According to the above configuration of the present invention, the power combiner/brancher of the present invention can be easily incorporated into a transmission line constituted by a rectangular waveguide.

Further, it is desirable that a high impedance section be provided in parallel with the coaxial line at a connection between the coaxial line and the radial line.
In this way, by providing the high impedance section, it is possible to prevent unnecessary reactance from occurring, and as a result, the influence caused by manufacturing errors (such as variations in performance) can be suppressed.

Further, it is preferable that the impedance conversion section provided in the radial line is a quarter wavelength type impedance conversion section.
This configuration was adopted because by employing the configuration of a quarter-wavelength impedance conversion section, it is possible to design a matching condition within the required frequency bandwidth.

According to the present invention, it is possible to provide a power combiner/divider that can be used in a high frequency band and with high power, and can be installed in a small space.

1 is a schematic diagram showing a cross section for explaining the configuration of a power combiner/divider according to a first embodiment of the present invention. FIG. 1 is a schematic diagram for explaining the configuration of a power combiner/divider according to a first embodiment of the present invention. FIG. 2 is a schematic diagram showing a mode state at a connection portion between a radial line and a circular waveguide of the power combiner/divider according to the first embodiment of the present invention. FIG. 2 is a schematic diagram showing a cross section of a power combiner/divider according to a second embodiment of the present invention. FIG. 3 is a schematic diagram for explaining the configuration of a mode suppressor according to a second embodiment of the present invention. FIG. 7 is a schematic diagram showing a cross section of a power combiner/distributor according to a third embodiment of the present invention.

《First embodiment》
First, a power combiner/divider according to a first embodiment of the present invention will be explained using FIGS. 1 to 3.
Here, FIG. 1 is a schematic diagram showing a cross section for explaining the configuration of the power combiner/divider of the first embodiment. FIG. 2 is a schematic diagram for explaining the configuration of the power combiner/divider of the first embodiment. FIG. 3 is a schematic diagram showing the mode state at the connection between the radial line and the circular waveguide of the power combiner/divider of the first embodiment.

As shown in FIGS. 1 and 2, the power combiner/distributor W1 of the first embodiment includes a main body 1 having a gap formed therein, a radial line 2 formed by the gap inside the main body 1, A plurality of coaxial terminals 3 are arranged concentrically around the center of the radial line 2 on the outer periphery of the radial line 2 and installed at equal intervals on the outer periphery side of the main body 1, and one end is connected to the coaxial terminal 3. It also includes a coaxial line 4 whose other end is connected to the outer periphery of the radial line 2, and a TM01 mode circular waveguide 5 which is vertically provided in the center of the main body 1 and communicates with the radial line 2. ing.
Note that the coaxial line 4 is provided for each coaxial terminal 3. Further, the void inside the main body 1 is formed in a circular shape in plan view from the center of the main body 1 to the outer periphery.

Note that the power combiner/divider W1 functions as a power combiner when the circular waveguide 5 is used as an output terminal and the coaxial terminal 3 is used as an input terminal. Further, the power combiner/divider W1 functions as a power divider when the circular waveguide 5 is used as an input terminal and the coaxial terminal 4 is used as an output terminal.

Furthermore, the radial line 2 is provided with one or more stages of impedance conversion sections (three stages of impedance conversion sections in the example shown in FIGS. 1 and 2).
Further, a mode conversion section 6 is provided at the center portion (circular center portion) of the radial line 2 . This mode converter 6 converts the transmission mode from the radial line 2 (or circular waveguide 5) to the circular waveguide 5 (or radial line 3).
Each component will be explained in order below.

The main body portion 1 includes a “lid portion 1a and a box portion 1b” formed of a conductor. Moreover, the lid body part 1a is formed in a circular shape in a plan view, and an opening 1a1 is formed in the center of the upper surface side.
Note that the inner diameter of the opening 1a1 is the same as the inner diameter of the circular waveguide 5. A circular waveguide 5 is connected to the outer edge of this opening 1a1.

The box body part 1b has a circular shape in plan view (has the same diameter as the lid body part 1a), and has a concave shape on one side (the top surface) and a concave shape on the other side (the bottom surface). ) has a flat bottom. A stepped portion is formed concentrically from the center of the concave upper surface. In the first embodiment, a circular center portion is formed at the center of the upper surface, and three step portions are formed concentrically around the outer periphery of the circular center portion.

Then, the top surface of the box body part 1b and the bottom surface of the lid body part 1a are made to face each other, and the lid body 1a is placed and fixed on the top surface of the box body part 1b, thereby forming a circular box-shaped main body part in a plan view. 1 is formed, and a gap having a stepped portion is formed inside the main body portion 1 by the lower surface of the lid portion 1a and the upper surface of the box portion 1b (the upper surface on which the stepped portion is formed). There is. The gap having the stepped portion becomes the radial line 2 and also forms an impedance conversion portion, and this impedance conversion portion performs impedance matching between the coaxial terminal 3 and the circular waveguide 5. Note that the symbol "R" in FIG. 2 indicates the distance from the center of the radial line 2. Further, the range indicated by the symbol "L2" in FIG. 2 indicates the range in the radial direction of the impedance conversion section provided in the radial line 2.

Further, the configuration of the impedance conversion unit provided in the radial line 2 is not particularly limited, but it is possible to use a configuration such as "Chebyshev 1/4 wavelength multi-stage type" or "maximally flat 1/4 wavelength multi-stage type". desirable. This is because by adopting a configuration of a quarter-wavelength multi-stage impedance conversion section, it is possible to design a matching condition within the required frequency bandwidth. Note that in the first embodiment, the impedance conversion section is configured with three stages of 1/4 wavelength.
Further, since the principle of the 1/4 wavelength multi-stage impedance conversion section is a well-known technique, detailed explanation will be omitted.

Note that the impedance (Z) of the radial line 2 decreases from the center of the radial line 2 toward the outer circumference in inverse proportion to the distance R from the center of the radial line 2. Therefore, when multiple stages of impedance conversion sections are provided in the radial line 2, the impedance of each stage of the impedance conversion section is not constant within its "1/4 wavelength" range, making the design of the impedance conversion section complicated. This problem arises.

Therefore, in the first embodiment, the "height (H) of the radial line 2" is set to "the height (H) from the center of the radial line 2" so that the impedance of each stage is constant within the range of "1/4 wavelength". The above problem is solved by simplifying the design and manufacturing of the impedance conversion section by increasing the distance R in proportion to the distance R.

Specifically, as shown in FIG. 2, the height (H1) of the first step adjacent to the center of the radial track 2 is proportional to the distance R from the center of the radial track 2. I'm trying to get bigger. Furthermore, the height (H2) of the second stepped portion from the center of the radial line 2 is designed to increase in proportion to the distance R from the center of the radial line 2. Similarly, the height (H3) of the third step from the center of the radial track 2 is designed to increase in proportion to the distance R from the center of the radial track 2. . In this way, in the first embodiment, the above problem is solved by setting the height (H (H1, H2, H3)) for each stage in correspondence with the distance (R).

The mode converter 6 is formed of a semi-spherical or semi-ellipsoidal metal body, and is provided at the circular center of the radial line 2 so that its center line coincides with the center of the radial line 2. It is being The mode converter 6 excites the TM01 mode in the circular waveguide 2 and performs impedance matching between the radial line 2 and the circular waveguide 5.
Furthermore, the mode converter 6 smoothly converts the transmission mode from the radial line 2 to the circular waveguide 5 and from the circular waveguide 5 to the radial line 2.

Further, the circular waveguide 5 is a straight tube having both ends penetrated, and flanges are formed at both ends.
The circular waveguide 5 has a flange on one end side (lower end side) of the lid body 1a so that its inner peripheral side surface is substantially flush with the inner peripheral side surface of the opening 1a1 of the lid body 1. It is placed on the outer edge of the opening 1a1 in the center of the top surface, and is connected and fixed to the top surface of the lid body 1a. In this way, the inside of the cylinder of the circular waveguide 2 communicates with the radial line 2.

In the power combiner/divider W1 configured as described above, the mode converter 6 provided in the radial line 2 changes the mode state at the connection between the radial line 2 and the circular waveguide 5 as shown in FIG. It becomes as shown in .
By arranging the mode conversion section 6 made of a metal body having a hemispherical or semiellipsoidal shape as shown in the figure, a smooth flow of the electric field is generated along the smooth surface, and smooth mode conversion is performed.
Furthermore, by making the shape spherical, the mode converter 6 has a higher power resistance and can be used at high power.

In this way, the power combiner/divider W1 of the first embodiment has a circular waveguide in which the "output side of the combined power (or input side of the power to be distributed)" connected to the radial line 2 is in the TM01 mode. 5, and a mode converter 6 is installed in the center of the radial line 2. Further, the mode converter 6 excites the TM01 mode in the circular waveguide 5 and performs impedance matching between the radial line 2 and the circular waveguide 5.
That is, the power combiner/distributor W1 of the first embodiment, like the power combiner/divider described in Patent Document 1, is connected to the radial line 2 on the output side of the combined power (or the power to be distributed). The configuration is such that a TM01 mode circular waveguide 5 is used instead of a central coaxial line as the connection line on the input side of the input side. Therefore, according to the first embodiment, the problem of "frequency and power being limited" of the power combiner/divider described in Patent Document 1 is resolved, and it is possible to use it in a higher frequency band and higher power. A power combiner and distributor W1 is provided.

Further, in the power combiner/distributor W1 of the first embodiment, the input terminal for inputting the power to be combined (or the output terminal for outputting the power to be distributed) is a coaxial terminal, and as described in Patent Document 2 Unlike the waveguide-type power combiner/distributor described in 2007, it does not have a configuration including a plurality of rectangular waveguides. Therefore, according to the first embodiment, a flexible coaxial cable can be connected to the coaxial terminal 3, making routing easier and allowing space-saving installation.

《Second embodiment》
Next, a power combiner/divider according to a second embodiment of the present invention will be described using FIGS. 4 and 5.
Here, FIG. 4 is a schematic diagram for explaining the configuration of the power combiner/divider of the second embodiment. FIG. 5 is a schematic diagram for explaining the configuration of a mode suppressor according to the second embodiment.

The power combiner/distributor W2 of the second embodiment connects the circular/rectangular waveguide converter 8 to the upper end of the circular waveguide 5 of the power combiner/distributor W1 of the first embodiment, and A mode suppressor 7 is added to the inside of the wave tube 5, and the configuration is the same as that of the first embodiment except that a circular/rectangular waveguide converter 8 and a mode suppressor 7 are added. be.
Therefore, in the description of the second embodiment, the same components as in the first embodiment are given the same reference numerals, and the description will be omitted or simplified.

As shown in FIG. 4, in the power combiner/distributor W2 of the second embodiment, a circular/rectangular waveguide converter (hereinafter simply referred to as "converter") 8 is connected to the upper end of the circular waveguide 5. At the same time, a flat mode suppressor 7 (see FIG. 5) is formed on the inner wall of the cylinder of the circular waveguide 5 to have a width that is approximately the same length as the inner diameter of the circular waveguide 5. installed.
The reason why the converter 8 is provided in this manner is that the power transmission path is normally constructed of a rectangular waveguide.

The converter 8 described above also includes a circular waveguide section 8a having the same diameter as the circular waveguide 5, and a rectangular waveguide section 8b connected to the outer peripheral side of the upper end of the circular waveguide section 8a. It is formed in a substantially L-shape in cross-sectional view, with openings formed at both ends and penetrating through the ends. Specifically, the converter 8 has an opening formed at one end (lower end) formed by a circular waveguide section 8a, and an opening formed at the other end (lower end) formed by a rectangular waveguide section 8b. An opening is formed at the left end (when facing inside). Further, in the converter 8, the axial direction of the circular waveguide section 8a and the axial direction of the rectangular waveguide section 8b are perpendicular. Note that the converter 8 has flanges formed at both ends.

Further, in the converter 8, the flange at one end (lower end) constituted by the circular waveguide portion 8a is aligned with the flange at the upper end of the circular waveguide 5, and the flange at the upper end of the circular waveguide 5 It is connected to the. Note that a rectangular waveguide (not shown) serving as a power transmission path can be connected to the other end of the converter 8 constituted by the rectangular waveguide section 8b.

When the power combiner/divider W2 of the second embodiment functions as a power combiner, this converter 8 changes the power passing through the converter 8 from the TM01 mode, which is the circular waveguide mode, to the rectangular waveguide mode. It is converted to TE10 mode which is a wave tube mode. In addition, when the power combiner/divider W2 functions as a power divider, this converter 8 changes the power passing through the converter 8 from the rectangular waveguide mode TE10 mode to the circular waveguide mode. Converted to TM01 mode.

Moreover, the mode suppressor 7 provided in the cylinder of the circular waveguide 5 is for smooth mode conversion from TM01 mode to TE10 mode (or from TE10 mode to TM01 mode), and suppresses phase shift distortion and Transmission loss can be suppressed. That is, the mode suppressor 7 is a component for smoothly performing mode conversion between the TM01 mode and the TE10 mode, and functions to suppress phase shift distortion and transmission loss.

Note that the mode suppressor 7 is formed of a metal plate.
Furthermore, the mode suppressor 7 is installed parallel to both the transmission direction of the circular waveguide 5 and the transmission direction of the rectangular waveguide section 8b, and at the center of the circular waveguide 5 (see FIG. 5). .

In this way, according to the second embodiment, in addition to the effects of the first embodiment described above, the power combiner/brancher W2 can be easily installed in the transmission path configured by the rectangular waveguide. can be incorporated. Further, in the second embodiment, a converter 8 for converting from TM01 mode to TE10 mode (or from TE10 mode to TM01 mode) is provided, but the mode suppressor 7 enables smooth mode conversion. Phase distortion and transmission loss can be minimized.

《Third embodiment》
Next, a power combiner/divider according to a third embodiment of the present invention will be described using FIG. 6.
Here, FIG. 6 is a schematic diagram for explaining the configuration of the power combiner/divider of the third embodiment.

The power combiner/divider W3 of the third embodiment includes a high impedance section 9 in parallel with the coaxial line 4 at the connection between the coaxial line 4 and the radial line 2 of the power combiner/divider W2 of the second embodiment. This embodiment is the same as the second embodiment except that the configuration of the high impedance section 9 is added.
Therefore, in the description of the third embodiment, the same components as in the second embodiment are given the same reference numerals, and the description will be omitted or simplified.

As shown in FIG. 6, the power combiner/distributor W3 of the third embodiment is located near the outer periphery of the upper surface of the box portion 1b constituting the main body portion 1, and connects the coaxial line 4 and the radial line 2. A gap portion (high impedance portion) 9 extending from the top surface toward the bottom portion is formed in the portion.

Specifically, in the power combiner/distributor W3 of the third embodiment, the height dimension (h) of the gap 9 is an odd number multiple of the "1/4 wavelength" of the microwave or millimeter wave. Further, the opening of the gap portion (high impedance portion) 9 is electrically open. By configuring the gap 9 in this way, a high impedance part where the impedance of the grounding part can be ignored is provided at the connection part between the coaxial line 4 and the radial line 2, and the opening is in an electrically open state. By doing so, unnecessary reactance can be prevented from occurring, and the influence caused by manufacturing errors (variation in performance) can be suppressed.
That is, according to the third embodiment, in addition to the effects of the first and second embodiments described above, it is possible to further suppress "variation in performance" caused by manufacturing errors.

As described above, according to the embodiments (first to third embodiments) of the present invention, a power combiner/divider that can be used in a high frequency band and with high power and can be installed in a small space is provided. can be provided.

Note that the present invention is not limited to the embodiments described above (first to third embodiments), and various changes can be made within the scope of the gist thereof.

For example, the high impedance section 9 of the third embodiment may be added to the configuration of the power combiner/divider W1 of the first embodiment described above.

W1, W2, W3... Power combiner/distributor 1... Main body part 1a... Lid body part (main body part)
1b...Box part (main body part)
2... Radial line 3... Coaxial terminal 4... Coaxial line 5... Circular waveguide 6... Mode converter 7... Mode suppressor 8... Circular/rectangular waveguide converter (converter)
8a...Circular waveguide section (transducer)
8b...Rectangular waveguide section (transducer)
9...Gap part (high impedance part)

Claims (4)

A main body portion with a void formed inside;
a radial line formed in a gap inside the main body;
a plurality of coaxial terminals arranged concentrically with respect to the center of the radial line on the outer circumference of the radial line and installed on the outer circumference side of the main body;
a coaxial line having one end connected to the coaxial terminal and the other end connected to the outer periphery of the radial line;
a TM01 mode circular waveguide provided vertically in the center of the main body and communicating with the radial line;
The coaxial line is provided for each coaxial terminal,
Functions as a power combiner when the circular waveguide is used as an output terminal and the coaxial terminal is used as an input terminal,
A power combiner/divider that functions as a power divider when the circular waveguide is used as an input terminal and the coaxial terminal is used as an output terminal,
One or more stages of impedance conversion sections are provided on the radial line,
A mode converter is installed in the center of the radial line,
A power combiner/divider, characterized in that the mode converter excites the TM01 mode in the circular waveguide and performs impedance matching between the radial line and the circular waveguide. A main body portion with a void formed inside;
a radial line formed in a gap inside the main body;
a plurality of coaxial terminals arranged concentrically with respect to the center of the radial line on the outer circumference of the radial line and installed on the outer circumference side of the main body;
a coaxial line having one end connected to the coaxial terminal and the other end connected to the outer periphery of the radial line;
a TM01 mode circular waveguide provided vertically in the center of the main body and communicating with the radial line;
The coaxial line is provided for each coaxial terminal,
Functions as a power combiner when the circular waveguide is used as an output terminal and the coaxial terminal is used as an input terminal,
A power combiner/divider that functions as a power divider when the circular waveguide is used as an input terminal and the coaxial terminal is used as an output terminal,
One or more stages of impedance conversion sections are provided on the radial line,
A mode converter is installed in the center of the radial line,
A converter for converting from the TM01 mode, which is a circular waveguide mode, to the TE10 mode, which is a rectangular waveguide mode, is connected to the other end of the circular waveguide,
A mode suppressor is disposed on the inner wall of the circular waveguide for smooth mode conversion from TM01 mode to TE10 mode, thereby suppressing phase shift distortion and transmission loss. Synthetic distributor. 3. The power combiner/divider according to claim 1, wherein a high impedance section is provided in parallel with the coaxial line at a connection between the coaxial line and the radial line. 4. The power combiner/divider according to claim 1, wherein the impedance converter provided in the radial line is a quarter-wavelength impedance converter.

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