JPH11150403A - Waveguide-microstrip line converter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a waveguide-microstrip line converter that conducts conversion with small loss at frequencies higher than frequencies of a Ka band. SOLUTION: This converter is provided with an input waveguide 1, a printed circuit board 2 made of a dielectric material and placed at the outside of the input waveguide 1, a probe 3 that penetrates through a guide wall of the input waveguide 1 and the printed circuit board 2, a dielectric material member 7 placed between the input waveguide 1 and the probe 3, and a micro-strip line 9 placed on the printed circuit board 2 and whose one end connects to one end of the probe 3. A plurality of through-holes 6 connecting electrically to a ground conductor so as to surround a part of the printed circuit board 2, through which the probe 3 is penetrated are provided in the printed circuit board 2. The plural through-holes and the part of the printed circuit board 2 between the probe 3 and the plural through-holes 6 configure a coaxial line with the probe 3 for a center conductor and the plural through-holes 6 for an outer conductor.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a waveguide-microstrip line converter used for an input part of a converter such as a microwave communication antenna.

[0002]

2. Description of the Related Art Conventionally, in a satellite broadcast receiving antenna using a waveguide-microstrip line converter, as shown in FIG.
The reflected radio wave is reflected by the reflecting mirror 21 and converged, and the converged radio wave is transmitted via a primary radiator 22 to a waveguide-microstrip line converter at an input portion of a low noise block down converter (hereinafter referred to as LNB) 23. Reach 30. The signal input to the waveguide-microstrip line converter 30 of the LNB 23 is then amplified by a low-noise amplifier (hereinafter, referred to as LNA). The signal line of the LNA is constituted by a microstrip line. I have.

FIG. 6 is a sectional view of a main part showing the structure of the waveguide-microstrip line converter 30. As shown in FIG.
In FIG. 6, 31 is an input waveguide having a rectangular cross section and a bottomed cylindrical shape, 32 is an LNA circuit board disposed outside the input waveguide 31 via a ground conductor 40, and 33 is the input A probe 34 penetrating through the tube wall of the waveguide 31 and the circuit board 32 is provided on the circuit board 32, and is a strip conductor 34 having one end connected to one end of the probe 33.
It is. The strip conductor 34, the circuit board 32,
The microstrip line 35 is constituted by the ground conductor 40 on the back surface of the circuit board 32. The input waveguide 31
Is a value (several hundred Ω) determined by the size and frequency of the input waveguide 31. In addition, the above LNA
Is designed so that the characteristic impedance becomes 50Ω. Different impedances of the input waveguide 31 and the microstrip line 35 are matched by the probe 33. In this waveguide-microstrip line converter 30, the position of the center axis of the probe 33 projecting inside the input waveguide 31 is set to the cavity 31a of the input waveguide 31 in order to reduce the reflection loss at the time of conversion. Λg / 4 (λ
The probe 33 is arranged so as to be separated by (g is the wavelength in the input waveguide 31).

In the portion of the input waveguide 31 through which the probe 33 passes, the probe 33 is surrounded by a dielectric member 37 and supported by the input waveguide 31. This probe 3
The portion surrounded by the dielectric member 37 constitutes a coaxial line having a characteristic impedance of 50Ω. Generally, as shown in FIG.
And an outer conductor 72 and a dielectric member 73 that insulates between the center conductor 71 and the outer conductor 72. The dielectric member 73 is usually made of a material having a small dielectric loss such as Teflon, but may use a space, that is, air as a dielectric. The characteristic impedance of the coaxial line is represented by the following equation, and the portion of the input waveguide 31 through which the probe 33 passes is designed using the following equation so that the characteristic impedance Zo becomes 50Ω.

[0005]

(Equation 1) ε _s : dielectric constant of dielectric d ₁ : diameter of probe d ₂ : outer diameter of dielectric (= inner diameter of outer conductor) Further, as shown in FIG. width was is W, the thickness is t, the thickness of the circuit board 32 between the ground conductor 40 and the strip conductor 34 h, the dielectric constant When epsilon _s, the characteristic impedance of the microstrip line 35,
The width W of the strip conductor, the thickness t, the thickness h of the circuit board 32,
Determined by the relative dielectric constant ε _s.

[0006]

In FIG. 6, the characteristic impedance of the microstrip line 35 and the portion of the input waveguide 31 through which the probe 33 penetrates are designed to be 50Ω, respectively. Since the portion through which 33 penetrates has an L (inductance) component and does not have a portion corresponding to the outer conductor of the coaxial structure, it is difficult to set the characteristic impedance to 50Ω. For this reason, impedance matching between the portion of the input waveguide 31 through which the probe 33 penetrates and the microstrip line 35 cannot be performed, which causes a problem that reflection loss increases and conversion loss increases. Even with such a conventional waveguide-microstrip line converter having a conventional structure, K
In the u-band frequency band (approximately 10.95 to 14.5 GHz), the conversion loss was not practically large. Therefore, this method is adopted for the Ku-band LNB and the like.
Above the a-band frequency band (approximately 17.7 to 21.2 GHz), the conversion loss has a value that cannot be ignored.

An object of the present invention is to provide a waveguide-microstrip line converter capable of performing low-loss conversion at a frequency higher than the frequency of the Ka band.

[0008]

According to a first aspect of the present invention, there is provided a waveguide-to-microstrip line converter comprising: a waveguide; a dielectric substrate disposed outside the waveguide; A probe penetrating the tube wall of the waveguide and the dielectric substrate, a dielectric provided between the waveguide and the probe, and a dielectric provided on the dielectric substrate; In a waveguide-microstrip line converter having a microstrip line having one end connected thereto, a plurality of through-holes electrically connected to a ground conductor so as to surround a portion of the dielectric substrate through which the probe penetrates. A hole is provided in the dielectric substrate.

According to the waveguide-microstrip line converter of the first aspect, a radio wave input to the waveguide is converted into a microstrip through a probe penetrating the waveguide and the dielectric substrate. It reaches the line. At this time, two different characteristic impedances of the waveguide and the microstrip line are matched by a probe. The above-described probe is used as a central conductor, and the waveguide is used as an external conductor,
A coaxial line is composed of the probe and the waveguide and a dielectric (a material such as Teflon or air) provided between the probe and the waveguide. A coaxial line is formed by the probe as a central conductor, a plurality of through-holes as external conductors, and a dielectric substrate between the probe and the plurality of through-holes and the probe and the plurality of through-holes. Therefore, the diameter of the probe as the center conductor of the coaxial line is adjusted, the diameter of the hole through which the probe of the waveguide as the outer conductor penetrates is adjusted, and the shape and arrangement of a plurality of through holes as the outer conductor are adjusted. The characteristic impedance of the coaxial line with the probe as the center conductor can be made approximately equal to that of the microstrip line, making it easy to match the impedance between the coaxial line with the probe as the center conductor and the microstrip line. Becomes Therefore, it is possible to perform conversion with less loss while matching the different impedances of the waveguide and the microstrip line, and particularly to a practical waveguide at a frequency higher than the Ka band, for example, the frequency of the Ku band.
A microstrip line converter can be realized.

According to a second aspect of the present invention, there is provided a waveguide-microstrip line converter, comprising: a waveguide; a dielectric substrate disposed outside the waveguide; a waveguide wall of the waveguide; A probe penetrating through the body substrate, a dielectric provided between the waveguide and the probe, and a microstrip line provided on the dielectric substrate and having one end connected to the probe. In the waveguide-microstrip line converter, a protrusion is provided on the waveguide so as to surround a portion of the dielectric substrate through which the probe penetrates.

According to the waveguide-microstrip line converter of the second aspect, a radio wave input to the waveguide is converted into a microstrip by a probe penetrating the waveguide and the dielectric substrate. It reaches the line. At this time, two different characteristic impedances of the waveguide and the microstrip line are matched by a probe. The above-described probe is used as a central conductor, and the waveguide is used as an external conductor,
A coaxial line is composed of the probe and the waveguide and a dielectric (a material such as Teflon or air) provided between the probe and the waveguide. Also, the probe is used as a central conductor, the projection of the waveguide is used as an external conductor, and a coaxial line is formed by a dielectric substrate between the probe and the projection of the waveguide and the projection of the waveguide. Is configured. Therefore, the diameter of the probe as the center conductor of the coaxial line is adjusted, the diameter of the hole through which the probe of the waveguide as the outer conductor penetrates is adjusted, the shape of the protrusion of the waveguide as the outer conductor, By adjusting the arrangement, etc., the characteristic impedance of the coaxial line with the probe as the center conductor can be made substantially equal to that of the microstrip line, and the impedance matching between the coaxial line with the probe as the center conductor and the microstrip line Becomes easier. For this reason, it is possible to perform conversion with less loss while matching different impedances of the waveguide and the microstrip line, and particularly to a practical waveguide-microstrip line at a frequency higher than the Ka band, for example, the frequency of the Ku band. A converter can be realized.

According to a third aspect of the present invention, there is provided a waveguide-microstrip line converter, comprising: a waveguide; a dielectric substrate disposed outside the waveguide; a waveguide wall of the waveguide; A probe penetrating through the body substrate, a dielectric provided between the waveguide and the probe, and a microstrip line provided on the dielectric substrate and having one end connected to the probe. In the waveguide-microstrip line converter, a conductive member to be connected to a ground conductor of a circuit formed on the dielectric substrate so as to surround a portion of the dielectric substrate through which the probe penetrates. It is characterized in that a projection is provided.

According to the waveguide-microstrip line converter of the third aspect, the radio wave input to the waveguide is converted into a microstrip through the probe penetrating the waveguide and the dielectric substrate. It reaches the line. At this time, two different characteristic impedances of the waveguide and the microstrip line are matched by a probe. The above-described probe is used as a central conductor, and the waveguide is used as an external conductor,
A coaxial line is composed of the probe and the waveguide and a dielectric (a material such as Teflon or air) provided between the probe and the waveguide. In addition, a coaxial line is constituted by the probe as a central conductor, the projection of the conductive member as an external conductor, and a dielectric substrate between the probe and the conductive member and the projection of the probe and the conductive member. . Therefore, the diameter of the probe as the center conductor of the coaxial line is adjusted, the diameter of the hole through which the probe of the waveguide as the outer conductor penetrates is adjusted, the shape of the protrusion of the conductive member as the outer conductor, By adjusting the arrangement, etc., the characteristic impedance of the coaxial line with the probe as the center conductor can be made substantially equal to that of the microstrip line, and the impedance matching between the coaxial line with the probe as the center conductor and the microstrip line Becomes easier. For this reason, the waveguide and the microstrip line can be converted with less loss while matching the different impedances of the waveguide and the microstrip line. A converter can be realized.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a waveguide-microstrip line converter according to the present invention will be described in detail with reference to the illustrated embodiments.

(First Embodiment) FIG. 1 is a top view of a waveguide-microstrip line converter according to a first embodiment of the present invention, and FIG. 2 is an enlarged sectional view taken along line II-II in FIG. FIG. This waveguide-microstrip line converter is used for an LNB (low noise block down converter) having the same antenna as the satellite broadcast receiving antenna shown in FIG.

1 and 2, reference numeral 1 denotes a cylindrical input waveguide having a rectangular cross section and a bottom, and 2 denotes an input waveguide above the input waveguide 1 via a ground conductor 10 (shown in FIG. 2). A circuit board 3 as a dielectric substrate disposed in a manner such that a probe 3 penetrates the tube wall of the input waveguide 1 and the circuit board 2 and 4 is provided on the circuit board 2 and one end of the probe 3 Is a ground pattern provided on the circuit board 2 so as to surround the periphery of the strip conductor 4 on the probe 3 side. The strip conductor 4, the circuit board 2 and the ground conductor 10 constitute a microstrip line 9. A plurality of through holes 6 for electrically connecting the ground pattern 5 and the ground conductor 10 on the back surface of the circuit board 2 are provided substantially in the semi-circumferential portion of the outer periphery of the portion of the circuit board 2 through which the probe 3 passes. I have. The probe 3 projecting into the cavity 1a of the input waveguide 1
Is located at the center of the input waveguide 1 from the bottom of the cavity 1a.
The probe 3 is arranged at a distance of / 4 (λg is the wavelength of the input waveguide 1) to reduce the reflection loss.

The above-mentioned probe 3 is used as a central conductor, and a plurality of through holes 6 on the outer periphery of the probe 3 are used as external conductors.
A structure corresponding to a coaxial line is obtained with the circuit board 2 made of a dielectric between the probe 3 and the plurality of through holes 6 and the probe 3 and the plurality of through holes 6. As shown in FIG. 2, the probe 3 of the input waveguide 1
A cylindrical dielectric member 7 is arranged between the input waveguide 1 and the probe 3 in the hole 8 through which the probe 3 serves as a center conductor and the input waveguide 1 serves as an outer conductor. The probe 3, the input waveguide 1 and the dielectric member 7 constitute a coaxial line.

As described above, the probe 3 of the circuit board 2
Is formed in a structure corresponding to a coaxial line so that the characteristic impedance formed by the waveguide penetrating part and the circuit board penetrating part of the probe 3 is close to 50Ω which is the same as the microstrip line 9. Therefore, at a frequency higher than the frequency of the Ka band, the input waveguide 1 and the microstrip line 9 can be converted with low loss while performing impedance matching.
Further, by using this waveguide-microstrip line converter, it is possible to realize an antenna capable of receiving radio waves having a frequency higher than the frequency of the Ka band with low loss.

(Second Embodiment) FIG. 3 is a top view of a waveguide-microstrip line converter according to a second embodiment of the present invention, and FIG. 4 is an enlarged sectional view taken along line IV-IV in FIG. FIG. This waveguide-microstrip line converter is used for the LNB of the same antenna as the satellite broadcast receiving antenna shown in FIG.

3 and 4, reference numeral 11 denotes an input waveguide having a rectangular cross section and a cylindrical shape having a bottom, and 12 denotes the input waveguide 1 described above.
4 is a circuit board as a dielectric substrate having a semicircular projection 12a disposed at the upper side of the ground conductor 20 (shown in FIG. 4). A probe 14 penetrating through the projection 12a of the board 2 is a strip conductor provided on the circuit board 12 and having one end connected to one end of the probe 13. The strip conductor 14, the circuit board 12 and the ground conductor 20 constitute a microstrip line 19. The above-mentioned circuit board 1
The waveguide 11 is provided with a protruding portion 11b which protrudes outward substantially in half of the outer peripheral portion of the portion through which the second probe 13 penetrates. The center axis of the probe 13 projecting into the cavity 11a of the input waveguide 11 is separated from the bottom of the cavity 11a of the input waveguide 11 by λg / 4 (λg is the wavelength of the input waveguide 11). The probe 13 is arranged to reduce the reflection loss.

The probe 13 is used as a central conductor, the projection 11b of the input waveguide 11 on the outer periphery of the probe 13 is used as an external conductor, and the probe 13 and the projection 11
A structure corresponding to a coaxial line is obtained with the probe 13, the protrusion 11 b, and the protrusion 12 a of the circuit board 12 using the protrusion 12 a of the circuit board 12 between b as a dielectric. As shown in FIG. 4, a cylindrical dielectric member 17 is disposed between the input waveguide 11 and the probe 13 in a hole 18 through which the probe 13 of the input waveguide 11 penetrates. Probe 13
Is the central conductor, the input waveguide 11 is the external conductor, the probe 13 and the input waveguide 11 and the probe 1
A coaxial line is constituted by the dielectric member 17 between the input waveguide 3 and the input waveguide 11.

As described above, the portion of the circuit board 12 through which the probe 13 passes has a structure corresponding to a coaxial line.
The characteristic impedance of the coaxial line formed by the penetrating portion of the waveguide of the probe 13 and the penetrating portion of the circuit board is set to be close to 50Ω which is the same as that of the microstrip line 19. Therefore, at a frequency higher than the frequency of the Ka band, the input waveguide 11 and the microstrip line 19 can be converted with low loss while performing impedance matching. Further, by using this waveguide-microstrip line converter, it is possible to realize an antenna capable of receiving radio waves having a frequency higher than the frequency of the Ka band with low loss.

In the first and second embodiments, the satellite broadcast receiving antenna using the waveguide-microstrip line converter of the present invention has been described. However, the present invention is applied to a microwave transmission line such as a transmitting antenna. It is needless to say that the present invention may be applied to other devices that use.

In the first and second embodiments, a waveguide having a rectangular cross section is used. However, the cross section of the waveguide is not limited to a rectangle, but may be a circle or another shape.

In the second embodiment, the projection is provided on the input waveguide 11 so as to surround the portion through which the probe 13 of the circuit board 12 as the dielectric substrate passes. The conductive member to be connected to the ground conductor in the circuit formed on the dielectric substrate may be provided with a protrusion so as to surround a portion through which the wire penetrates.

[0026]

As apparent from the above description, the waveguide-microstrip line converter according to the first aspect of the present invention comprises a waveguide, a dielectric substrate disposed outside the waveguide, and A probe penetrating the waveguide wall of the waveguide and the dielectric substrate,
In a waveguide-microstrip line converter having a dielectric provided between the waveguide and the probe, and a microstrip line provided on the dielectric substrate and having one end connected to the probe, A plurality of through holes electrically connected to a ground conductor are provided in the dielectric substrate so as to surround a portion of the dielectric substrate through which the probe penetrates.

Therefore, according to the waveguide-microstrip line converter of the first aspect of the present invention, the diameter of the probe as the center conductor constituting the coaxial line can be adjusted,
By adjusting the diameter of the hole through which the waveguide probe as an external conductor penetrates, or adjusting the shape and arrangement of multiple through holes as the external conductor, the characteristics of the coaxial line with the probe as the central conductor The impedance can be made substantially equal to that of the microstrip line, and impedance matching between the coaxial line having the probe as the center conductor and the microstrip line becomes easy. Therefore, the waveguide and the microstrip line can be matched with different impedances and can perform conversion with low loss.
A microstrip line converter can be realized. Also, by using this waveguide-microstrip line converter for a microwave communication antenna,
It is possible to provide a practical antenna with low loss at a frequency higher than the frequency of the Ka band, for example, the frequency of the Ku band.

According to a second aspect of the present invention, there is provided a waveguide-microstrip line converter, comprising: a waveguide; a dielectric substrate disposed outside the waveguide; and a waveguide wall of the waveguide. A probe penetrating through the dielectric substrate, a dielectric provided between the waveguide and the probe, and a microstrip line provided on the dielectric substrate and having one end connected to the probe. In the waveguide-microstrip line converter, a projection is provided on the waveguide so as to surround a portion of the dielectric substrate through which the probe penetrates.

Therefore, according to the waveguide-microstrip line converter of the second aspect of the present invention, the diameter of the probe as the center conductor constituting the coaxial line is adjusted, or the waveguide as the outer conductor is adjusted. The characteristic impedance of the coaxial line with the probe as the center conductor is adjusted by adjusting the inner diameter of the hole through which the probe penetrates, or by adjusting the shape and arrangement of the protrusion of the waveguide as an external conductor. This can be made substantially equal to the line, which facilitates impedance matching between the coaxial line having the probe as the center conductor and the microstrip line. Therefore, it is possible to realize a waveguide-microstrip line converter capable of performing conversion with less loss while matching different impedances of the waveguide and the microstrip line. In addition, by using this waveguide-microstrip line converter for a microwave communication antenna, a practical antenna with low loss at a frequency higher than the Ka band, for example, the frequency of the Ku band can be provided.

According to a third aspect of the present invention, there is provided a waveguide-microstrip line converter, comprising: a waveguide; a dielectric substrate disposed outside the waveguide; and a waveguide wall of the waveguide. A probe penetrating through the dielectric substrate, a dielectric provided between the waveguide and the probe, and a microstrip line provided on the dielectric substrate and having one end connected to the probe. In the waveguide-microstrip line converter, the conductive member to be connected to the ground conductor of the circuit formed on the dielectric substrate surrounds a portion of the dielectric substrate through which the probe penetrates. Part is provided.

Therefore, according to the waveguide-microstrip line converter of the third aspect of the present invention, the diameter of the probe as the center conductor constituting the coaxial line is adjusted, or the waveguide as the outer conductor is adjusted. The characteristic impedance of the coaxial line with the probe as the center conductor is adjusted by adjusting the inner diameter of the hole through which the probe passes, or by adjusting the shape and arrangement of the protrusion of the conductive member as an external conductor. This can be made substantially equal to the line, which facilitates impedance matching between the coaxial line having the probe as the center conductor and the microstrip line. Therefore, it is possible to realize a waveguide-microstrip line converter capable of performing conversion with less loss while matching different impedances of the waveguide and the microstrip line. In addition, by using this waveguide-microstrip line converter for a microwave communication antenna, a practical antenna with low loss at a frequency higher than the Ka band, for example, the frequency of the Ku band can be provided.

[Brief description of the drawings]

FIG. 1 is a top view showing a structure of a waveguide-microstrip line converter according to a first embodiment of the present invention.

FIG. 2 is an enlarged cross-sectional view of the waveguide-microstrip line converter as viewed from line II-II.

FIG. 3 is a waveguide according to a second embodiment of the present invention;
It is a top view which shows the structure of a microstrip line converter.

FIG. 4 is an enlarged cross-sectional view of the waveguide-microstrip line converter as viewed from line IV-IV.

FIG. 5 is a schematic diagram of a satellite broadcast receiving antenna.

FIG. 6 is a sectional view showing the structure of a conventional waveguide-microstrip line converter.

FIG. 7 is a sectional view showing a structure of a general coaxial line.

FIG. 8 is a sectional view of a main part showing a structure of a general microstrip line.

[Explanation of symbols]

 1,11: input waveguide, 2,12: circuit board, 3,13: probe, 4,14: strip conductor, 6: through hole, 9, 19: microstrip line, 10, 20: ground conductor, 11b ... A convex portion formed by a waveguide member, 21... A reflector of an antenna, 22... A primary radiator,... 23.

Claims (3)

[Claims] 1. A waveguide, a dielectric substrate disposed outside the waveguide, a probe penetrating the waveguide wall of the waveguide and the dielectric substrate, A waveguide-microstrip line converter comprising: a dielectric provided between a probe and a microstrip line provided on the dielectric substrate and having one end connected to the probe; A plurality of through holes electrically connected to a ground conductor are provided in the dielectric substrate so as to surround a portion through which the probe passes.
Microstrip line converter. 2. A waveguide, a dielectric substrate disposed outside the waveguide, a probe penetrating the waveguide wall of the waveguide and the dielectric substrate, A waveguide-microstrip line converter comprising: a dielectric provided between a probe and a microstrip line provided on the dielectric substrate and having one end connected to the probe; A waveguide-microstrip line converter, wherein a projection is provided on the waveguide so as to surround a portion through which the probe penetrates. 3. A waveguide, a dielectric substrate disposed outside the waveguide, a probe penetrating the waveguide wall of the waveguide and the dielectric substrate, A waveguide-microstrip line converter comprising: a dielectric provided between a probe and a microstrip line provided on the dielectric substrate and having one end connected to the probe; A projection formed on a conductive member to be connected to a ground conductor of a circuit formed on the dielectric substrate so as to surround a portion through which the probe penetrates. Stripline converter.