KR101710867B1 - Dielectric waveguide - Google Patents

Abstract

The present invention relates to a dielectric waveguide. The dielectric waveguide according to an embodiment comprises: a resonator block which is made of dielectric material and of which a surface is metalized; an insertion hole which is provided in the resonator block; and a tuning rod which is inserted into the insertion hole and is arranged to change the impedance of the resonator block according to depth inserted in the insertion hole to perform impedance matching.

Description

{DIELECTRIC WAVEGUIDE}

Embodiments of the present invention relate to waveguides, and more particularly to dielectric waveguides.

Unlike a general waveguide in which a signal is transmitted through a dielectric medium waveguide, signals are transmitted through a dielectric medium. When a dielectric waveguide is fabricated, dielectric waveguide performance and errors are generated due to the uniformity of the medium and machining errors. Conventionally, in order to match the performance of the dielectric waveguide, a method of grinding and tuning a part of the dielectric waveguide is used. In this case, there is a possibility that the electromagnetic wave leakage occurs, the impedance becomes large, and the signal loss becomes large.

Korean Patent Publication No. 10-2010-0001970 (2010.01.06)

Embodiments of the present invention provide a dielectric waveguide capable of easily tuning resonance characteristics.

A dielectric waveguide according to an exemplary embodiment is a dielectric waveguide, comprising: a resonator block made of a dielectric material and having a surface metallized; An insertion hole provided in the resonator block; And a tuning rod inserted in the insertion hole and adapted to perform impedance matching by varying the impedance of the resonator block according to the depth of insertion into the insertion hole.

Wherein the dielectric waveguide includes: a support plate that is mounted on a surface of the resonator block and is provided to correspond to the insertion hole and has a through hole into which the tuning rod is inserted; And a tuning rod fixing unit fixing the tuning rod to the support plate.

The tuning rod fixing part may be screwed with the tuning rod so that a lower surface thereof is in close contact with the supporting plate.

A dielectric waveguide according to another exemplary embodiment includes a plurality of resonator blocks made of a dielectric material, the surface of which is metallized and arranged in a line; At least one bridge provided between the resonator blocks and connecting adjacent resonator blocks; An insertion hole provided in the plurality of resonator blocks and the at least one bridge, respectively; And a tuning rod inserted in an insertion hole of a portion of the plurality of resonator blocks and the at least one bridge where impedance matching is required to change an impedance of a corresponding portion according to a depth of the insertion hole, .

Wherein the dielectric waveguide includes: a support plate that is mounted on a surface of the resonator block and is provided to correspond to the insertion hole and has a through hole into which the tuning rod is inserted; And a tuning rod fixing unit fixing the tuning rod to the support plate.

The tuning rod fixing part may be screwed with the tuning rod so that a lower surface thereof is in close contact with the supporting plate.

The dielectric waveguide includes a first mode converter connected to a resonator block provided at one side of the plurality of resonator blocks and converting a propagation mode of a signal input from the outside; And a second mode conversion unit connected to a resonator block provided at the other of the plurality of resonator blocks and reconverting a propagation mode of a signal transmitted through the plurality of resonators to a propagation mode at the time of input, .

Wherein the first mode conversion unit and the second mode conversion unit each have an insertion hole and a tuning rod is inserted into an insertion hole of a portion of the first mode conversion unit and the second mode conversion unit that requires impedance matching, Matching can be performed.

Wherein the first mode conversion unit includes: a first body connected to a resonator block provided at one side of the plurality of resonator blocks and made of a dielectric material; A first connector connection part mounted on one surface of the first body and electrically connected to the external signal transmission device; A first connector pin electrically connected to the first connector connection portion and protruding inward of the first body at the first connector connection portion; And a first tube 1-1 electrically connected to the first connector pin inside the first body and provided along a longitudinal direction of the first body, and a second tube 1-1 bent in a downward direction from the end of the first tube 1-1 And a first transformer including the first and second tubes.

The second mode conversion unit may include a second body connected to a resonator block provided at the other of the plurality of resonator blocks, the second body being made of a dielectric material; A second connector connector mounted on one surface of the second body and electrically connected to the external signal transmitting device; A second connector pin that is electrically connected to the second connector connection portion and protrudes inward of the second body at the second connector connection portion; And a second-1 pipe body that is electrically connected to the second connector pin inside the second body and is provided along the longitudinal direction of the second body, and a second-first pipe body that is bent downward at the end of the second- And a second transformer including a second -2 tube body.

The tuning rod may be such that a flexible plate fixed to the upper portion of the insertion hole is provided at the upper portion.

The insertion hole may be formed along the longitudinal direction of the dielectric waveguide, and the soft plate may be provided to cover the insertion hole at an upper portion of the insertion hole.

According to the embodiment of the present invention, it is possible to independently impedance match each of the regions (mode converter, resonator, bridge, etc.) of the dielectric waveguide. Even if errors occur in the manufacturing process of the dielectric waveguide, The characteristics can be easily tuned. That is, since the resonance characteristics of the dielectric waveguide after the manufacturing process can be freely tuned, the mass production of the dielectric waveguide can be ensured.

1 is a perspective view of a dielectric waveguide according to an exemplary embodiment of the present invention;
2 is a cross-sectional view of a dielectric waveguide according to an exemplary embodiment of the present invention;
3 is a cross-sectional view showing a dielectric waveguide in which the impedance matching unit of the present invention is omitted;
4 is a view showing resonance performance of a general dielectric waveguide in which an impedance matching part is not formed in a resonator block
5 is a view showing resonance performance of a dielectric waveguide in which an impedance matching unit is formed in a resonator block according to an embodiment of the present invention;
6 is a view showing another form of the impedance matching unit according to the exemplary embodiment
7 is a view showing another embodiment of the impedance matching unit according to the exemplary embodiment

Hereinafter, specific embodiments of the dielectric waveguide of the present invention will be described with reference to FIGS. 1 to 7. FIG. However, this is an exemplary embodiment only and the present invention is not limited thereto.

In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intention or custom of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

The technical idea of the present invention is determined by the claims, and the following embodiments are merely a means for efficiently describing the technical idea of the present invention to a person having ordinary skill in the art to which the present invention belongs.

On the other hand, directional terms such as the top, bottom, one side, the other, and the like are used in connection with the orientation of the disclosed figures. Since the elements of the embodiments of the present invention can be positioned in various orientations, directional terms are used for illustrative purposes and not limitation.

FIG. 1 is a perspective view showing a dielectric waveguide according to an exemplary embodiment of the present invention, and FIG. 2 is a sectional view showing a dielectric waveguide according to an exemplary embodiment of the present invention. The dielectric waveguide according to the exemplary embodiment can be applied to various electronic components used for RF signal transmission such as a filter, a coupler, a transmission line, a directional coupler, and a distributor.

1 and 2, the dielectric waveguide 100 includes a first mode conversion unit 102, a resonator block 104, an iris 106, a second mode conversion unit 108, and an impedance matching unit 110 ).

In an exemplary embodiment, the dielectric waveguide 100 may be of a rectangular parallelepiped shape. The dielectric waveguide 100 has a top surface 100a and a bottom surface 100b opposed to the top surface 100a and provided parallel to the top surface 100a, A second side surface 100d provided to vertically connect the other end portion of the upper surface 100a and the lower surface 100b and a second side surface 100d extending perpendicularly to the longitudinal direction of the dielectric waveguide 100. [ And a back surface 100f provided at the other end of the dielectric waveguide 100 in the longitudinal direction. However, the shape of the dielectric waveguide 100 is not limited thereto. The dielectric waveguide 100 may be made of a dielectric material having a dielectric constant of at least 1, and the surface of the dielectric waveguide 100 may be metalized to block the radio wave transmitted through the dielectric waveguide 100 from going out.

The first mode converter 102 converts an electromagnetic wave mode of an externally input signal. For example, the first mode conversion unit 102 may convert a TEM (Tranverse Electro Magnetic) mode signal input from the outside into a TE (Tranverse Electric) mode. The first mode converter 102 may be provided on one side of the dielectric waveguide 100 in the longitudinal direction. The first mode conversion unit 102 may include a first body 111, a first connector connection unit 113, a first connector pin 115, and a first transformer 117.

The first body 111 is made of a dielectric. The first body 111 may have a rectangular parallelepiped shape, but is not limited thereto. The first connector connection portion 113 may be mounted on the front surface of the first body 111. However, the present invention is not limited thereto, and the first connector connection portion 113 may be mounted on the side surface or the upper surface of the first body 111. [ In an exemplary embodiment, the first connector connection 113 may be electrically connected to a signal transmission device such as a coaxial cable or the like. The first connector pin 115 is electrically connected to the first connector connection portion 113. The first connector pin 115 may protrude from the rear of the first connector connection portion 113. That is, the first connector pin 115 may protrude from the rear of the first connector connection part 113 to the inside of the first body 111.

The first transformer 117 is electrically connected to the first connector pin 115 inside the first body 111. The first transformer 117 may be provided in the form of an empty tube. The inner wall of the first transformer 117 can be metallized. The first connector pin 115 can be inserted into the first transformer 117 and electrically connected thereto. The first transformer 117 includes a first tube body 117a provided along the longitudinal direction of the first body 111 and a second tube body 117b bent downwardly from the end of the first tube body 117a, (117b). The distance from the front surface of the first body 111 to the first tube body 117b may be? / 4 (where? Is a wavelength of a signal propagating through the dielectric waveguide).

When a coaxial cable (not shown) is connected to the first connector connection part 113, a signal of a TEM (Tranverse Electro Magnetic) mode of a coaxial cable (not shown) is transmitted from a first transformer 117 to a TE (Tranverse Electric) Mode signal.

At least one resonator block 104 may be provided. When there are a plurality of resonator blocks 104, the resonator blocks 104 may be arranged in a line along the longitudinal direction of the dielectric waveguide 100. However, it should be understood that the resonator blocks 104 may be arranged in various forms depending on the field in which the dielectric waveguide 100 is used, the structure in the product, and the like. For example, the resonator blocks 104 may be arranged in a "b" shape or a "c" shape. The resonator block 104 is made of a dielectric. The resonator block 104 may have a rectangular parallelepiped shape, but is not limited thereto.

An iris 106 may be provided between each resonator block 104. The iris 106 may be provided symmetrically on the first side face 100c and the second side face 100d of the dielectric waveguide 100. [ The iris 106 may be partially cut in the inner vertical direction of the dielectric waveguide 100 at the first side face 100c and the second side face 100d, respectively. However, the present invention is not limited thereto, and the iris 106 may be provided in a zigzag form (i.e., alternately) in the first side face 100c and the second side face 100d of the dielectric waveguide 100, 100c, and the second side surface 100d. Signal transmission is performed between the previous resonator block 104 and the next resonator block 104 in the section where the iris 106 is formed between the resonator blocks 104 arranged in a line.

That is, a bridge 150 connecting adjacent resonator blocks 104 may be provided between the resonator blocks 104 arranged in a line. The bridge 150 may be provided at a position corresponding to the iris 106. In this case, the width of the bridge 150 is narrower than the width of the resonator block 104. Transmission of the signal can be performed between the resonator blocks 104 through the bridge 150. FIG.

The second mode converter 108 converts the electromagnetic wave mode of the signal propagating through the dielectric waveguide 100. For example, the second mode converter 108 may convert the signal of the TE mode that proceeds through the dielectric waveguide 100 into the TEM mode. The second mode converter 108 may be provided on the other side of the dielectric waveguide 100 in the longitudinal direction. The second mode conversion unit 102 may include a second body 121, a second connector connection unit 123, a second connector pin 125, and a second transformer 127.

The second body 121 is made of a dielectric. The second body 121 may have a rectangular parallelepiped shape, but is not limited thereto. The second connector connection part 123 may be mounted on the back surface of the second body 121. However, the present invention is not limited thereto, and the second connector connection portion 123 may be mounted on a side surface or an upper surface of the second body 121. In an exemplary embodiment, the second connector connection 123 may be electrically connected to a signal transmission device such as a coaxial cable or the like. The second connector pin 125 is electrically connected to the second connector connector 123. The second connector pin 125 may protrude from the second connector connection part 123 to the inside of the second body 121.

The second transformer 127 is electrically connected to the second connector pin 125 inside the second body 121. The second transformer 127 may be provided in the form of an empty tube. The inner wall of the second transformer 127 can be metallized. The second connector pin 125 can be inserted into the second transformer 127 and electrically connected thereto. The second transformer 127 includes a second tube body 127a provided along the longitudinal direction of the second body 121 and a second tube body 127b bent downward from the end of the second tube body 127a. (127b). The distance from the back surface of the second body 121 to the second -2 tube body 127b may be? / 4 (where? Is the wavelength of the signal traveling through the dielectric waveguide).

Here, when a coaxial cable (not shown) is connected to the second connector connection part 123, a TE mode signal traveling in the dielectric waveguide 100 is converted from the second transformer 127 to the TEM mode, And may be transmitted to the coaxial cable (not shown) through the connector connection part 123.

The impedance matching unit 110 tunes the resonance characteristics of the dielectric plate 100. The impedance matching unit 110 may include a tuning rod 131, a support plate 133, and a tuning rod fixing unit 135.

The tuning rod 131 may be inserted into the insertion hole provided in the dielectric waveguide 100. 3 is a cross-sectional view of a dielectric waveguide in which the impedance matching unit 110 of the present invention is omitted. Referring to FIG. 3, at least one insertion hole 141 may be formed in the dielectric waveguide 100. The insertion hole 141 may be formed at a predetermined depth from the upper surface 100a of the dielectric waveguide 100 toward the lower surface 100b. The insertion hole 141 may be provided in at least one of the first body 111, the resonator block 104, the bridge 150, and the second body 121. In the exemplary embodiment, the insertion hole 141 may be provided in the first body 111, the resonator block 104, the bridge 150, and the second body 121, respectively. The tuning rod 131 is inserted into the insertion hole 141 of the first body 111, the resonator block 104, the bridge 150, and the second body 121, . The tuning rod 131 may be provided to have a diameter corresponding to the inner diameter of the insertion hole 141. In this embodiment, the tuning rod 131 is shown in a cylindrical shape, but the present invention is not limited thereto. Further, the tuning rod 131 may be provided in various forms other than the rod (or rod) form.

3, the insertion holes 141 are formed in the first body 111, the resonator block 104, the bridge 150, and the second body 121, respectively, and are formed to have the same depth. However, And the depth of the insertion hole 141 can be adjusted differently. The insertion hole 141 may be formed from the upper surface 100a to the lower surface 100b of the dielectric waveguide 100 as needed. The inside of the insertion hole 141 may be provided so as not to be metallized (for example, metal coated). The first body 111 and the second body 121 may have a plurality of insertion holes 141 spaced apart from each other.

Here, by inserting the tuning rod 131 into the insertion hole 141, impedance matching can be performed by changing the impedance of the corresponding portion. Specifically, the inductance and the capacitance of the corresponding portion vary depending on the length of the tuning rod 131 inserted into the insertion hole 141. For example, as the length of insertion of the tuning rod 131 into the insertion hole 141 becomes longer (that is, the distance from the lower surface 100b of the dielectric waveguide 100 becomes closer), the capacitance of the portion increases And the inductance value is generated when the tuning rod 131 contacts the bottom surface of the insertion hole 141 and is short-circuited. In this way, the inductance and the capacitance of the corresponding portion can be changed through the tuning rod 131, so that the tuning rod 131 functions as a kind of LC resonance circuit together with the resonator block 104 or the iris 106.

The support plate 133 may be provided in contact with the upper surface 100a of the dielectric waveguide 100. The support plate 133 may be provided on the upper surface 100a corresponding to the insertion hole 141 into which the tuning rod 131 is inserted. A through hole 133a corresponding to the insertion hole 141 may be formed in the support plate 133. Here, the tuning rod 131 is inserted into the insertion hole 141 through the through hole 133a in a state where the support plate 133 is seated on the upper surface 100a. The support plates 133 may be provided individually in units of the tuning rods 131, but are not limited thereto and may be provided to cover the plurality of tuning rods 131. For example, when the tuning rod 131 is inserted into the insertion hole 141 formed in each of the first body 111, the resonator block 104, the bridge 150, and the second body 121, The plate 133 may be provided along the upper surface 100a from one longitudinal side of the dielectric waveguide 100 to the other side.

The tuning rod fixing part 135 serves to fix the tuning rod 131 to the support plate 133. [ In an exemplary embodiment, tuning rod fixture 135 can be coupled with tuning rod 131 in a threaded manner. For example, the tuning rod fixing part 135 may be provided in a hollow form so that the upper end of the tuning rod 131 is inserted. The inner wall of the tuning rod fixing part 135 and the outer peripheral surface of the tuning rod 131 may be provided with threads corresponding to each other. The tuning rod fixing part 135 can be screwed to the tuning rod 131 so that the lower surface thereof is in close contact with the support plate 133. [ Thereby, the tuning rod 131 is prevented from shaking, and it is possible to prevent the electromagnetic wave from leaking out from the insertion hole 141 which is not metallized. At this time, the support plate 133 prevents the dielectric waveguide 100 from being broken or damaged by tightening the tuning rod fixing portion 135.

According to the embodiment of the present invention, since each region (mode converter, resonator, bridge, etc.) of the dielectric waveguide 100 can be impedance-matched independently, an error in the manufacturing process of the dielectric waveguide 100 occurs The performance characteristics of the dielectric waveguide 100 can be easily tuned. That is, since the resonance characteristics of the dielectric waveguide 100 can be freely tuned after the manufacturing process, the mass production of the dielectric waveguide 100 can be ensured.

FIG. 4 is a view showing a resonant performance of a general dielectric waveguide without an impedance matching part in a resonator block, and FIG. 5 is a view showing a resonant performance of a dielectric waveguide in which an impedance matching part is formed in a resonator block according to an embodiment of the present invention . Here, it is assumed that the insertion loss of the dielectric waveguide is less than 0.1 dB and the reflection loss is more than 20 dB in the 7.25 to 7.75 GHz band. Ceramic with a dielectric constant of 11 was used as the dielectric waveguide.

Referring to FIG. 4, when the impedance matching unit and the insertion hole are not formed in the resonator block, the insertion loss of the dielectric waveguide in the 7.25 GHz band is 1.3129 dB, which is less than the target performance. In the 7.25 GHz band and the 7.75 GHz band, the return loss is 6.2949 dB and 19.2207 dB, respectively, which is lower than the target performance.

5, when the insertion hole and the impedance matching unit are formed in each resonator block, the dielectric waveguide has insertion loss of less than 0.1 dB (specifically, 0.0454 dB and 0.0409 dB) in the 7.25 GHz band and the 7.75 GHz band, Is satisfied. Also, it can be seen that the return loss in the 7.25 GHz band and the 7.75 GHz band both exceed 20 dB (specifically, 26.3074 dB and 25.4964 dB).

Thus, by forming the insertion hole and the impedance matching portion in each resonator block, the resonance performance of the dielectric waveguide can be easily tuned.

6 is a view showing another form of the impedance matching unit according to the exemplary embodiment.

Referring to FIG. 6, the impedance matching unit 110 may include a flexible plate 161. The flexible plate 161 may be made of a flexible metal material. The flexible plate 161 may be adhered or welded to the surface of the resonator block 104 and fixed. Alternatively, means for securing the flexible plate 161 to the resonator block 104 may be provided. Here, the tuning unit 161a may be provided so as to protrude downward from the flexible plate 161. That is, the tuning unit 161a may be formed to protrude downward from the flexible plate 161 and be inserted into the insertion hole 141. The tuning unit 161a may be provided in such a manner that the flexible plate 161 extends downward by pressing the flexible plate 161 from above. At this time, the length of the tuning section 161a can be adjusted according to the pressure of the upper portion of the flexible plate 161. Alternatively, after a plurality of flexible plates 161 having different lengths of the tuning section 161a are provided, a flexible plate 161 having a length of an appropriate tuning section 161a may be selected and used according to each of the resonator blocks 104 have.

7, after the insertion hole 141 is formed along the longitudinal direction of the dielectric waveguide 100, the flexible plate 161 is fixed to the upper portion of the insertion hole 141, and the resonator block 104 and the iris 106 may be formed by pressing the flexible plate 161 at a portion where tuning is required. Here, the size and shape of the tuning unit 161a may be variously changed. The flexible plate 161 may be provided to cover the insertion hole 141 formed along the longitudinal direction of the dielectric waveguide 100.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, I will understand. Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by equivalents to the appended claims, as well as the appended claims.

100: dielectric waveguide
102: first mode conversion section
104: Resonator block
106: Iris
108: Second mode conversion section
110: Impedance matching unit
111: First body
113: first connector connection
115: first connector pin
117: first transformer
121: Second body
123: second connector connection
125: second connector pin
127: second transformer
131: Tuning Load
133: Support plate
133a: Through hole
135: Tuning rod fixing portion
141: insertion hole
150: Bridge
161: Flexible plate
161a: Tuning unit

Claims (12)

As a dielectric waveguide,
A resonator block made of a dielectric material and having a surface metallized;
An insertion hole provided in the resonator block;
A tuning rod inserted in the insertion hole and adapted to perform impedance matching by varying an impedance of the resonator block according to a depth of the insertion hole;
A support plate that is mounted on a surface of the resonator block and is provided to correspond to the insertion hole and has a through hole into which the tuning rod is inserted; And
And a tuning rod fixing section for fixing the tuning rod to the support plate.
delete The method according to claim 1,
The tuning-
And the lower surface is threaded with the tuning rod so as to be in close contact with the support plate.
A plurality of resonator blocks made of a dielectric material and metallized on the surface thereof and arranged in a line;
At least one bridge provided between the resonator blocks and connecting adjacent resonator blocks;
An insertion hole provided in the plurality of resonator blocks and the at least one bridge, respectively; And
A tuning rod inserted in an insertion hole of a portion of the plurality of resonator blocks and the at least one bridge where impedance matching is required and performing impedance matching by varying an impedance of a corresponding portion according to a depth inserted into the insertion hole; Includes a dielectric waveguide.
The method of claim 4,
The dielectric waveguide includes:
A support plate that is mounted on a surface of the resonator block and is provided to correspond to the insertion hole and has a through hole into which the tuning rod is inserted; And
And a tuning-rod fixing section for fixing the tuning rod to the support plate.
The method of claim 5,
The tuning-
And the lower surface is threaded with the tuning rod so as to be in close contact with the support plate.
The method of claim 4,
The dielectric waveguide includes:
A first mode converter connected to a resonator block provided at one side of the plurality of resonator blocks and converting a propagation mode of a signal input from the outside; And
Further comprising a second mode conversion unit connected to a resonator block provided on the other of the plurality of resonator blocks and reconverting a propagation mode of a signal transmitted through the plurality of resonators to a propagation mode upon input, .
The method of claim 7,
Wherein the first mode conversion unit and the second mode conversion unit are provided with insertion holes, respectively,
Wherein a tuning rod is inserted in an insertion hole of a portion of the first mode converter and the second mode converter that requires impedance matching to perform impedance matching.
The method of claim 7,
Wherein the first mode converter comprises:
A first body connected to a resonator block provided at one side of the plurality of resonator blocks, the first body being made of a dielectric material;
A first connector connection part mounted on one surface of the first body and electrically connected to the external signal transmission device;
A first connector pin electrically connected to the first connector connection portion and protruding inward of the first body at the first connector connection portion; And
A first tube body which is electrically connected to the first connector pin inside the first body and is provided along the longitudinal direction of the first body and a second tube body which is bent downward at a terminal end of the first tube body; A dielectric waveguide comprising a first transformer comprising a first and a second tube.
The method of claim 7,
Wherein the second mode conversion unit comprises:
A second body connected to a resonator block provided on the other of the plurality of resonator blocks, the second body being made of a dielectric material;
A second connector connector mounted on one surface of the second body and electrically connected to the external signal transmitting device;
A second connector pin that is electrically connected to the second connector connection portion and protrudes inward of the second body at the second connector connection portion; And
A second-first tube body electrically connected to the second connector pin inside the second body, the second-first tube body being provided along the longitudinal direction of the second body, and the second-first tube body bent downwardly from a longitudinal end of the second- 2-2. A dielectric waveguide comprising a second transformer comprising a tubular body.
As a dielectric waveguide,
A resonator block made of a dielectric material and having a surface metallized;
An insertion hole provided in the resonator block;
A tuning rod inserted in the insertion hole and adapted to perform impedance matching by varying an impedance of the resonator block according to a depth of the insertion hole; And
And a flexible plate fixed to the upper portion of the insertion hole,
Wherein the tuning rod is provided with a flexible plate fixed on the upper portion of the insertion hole by being pushed from above.
The method of claim 11,
The insertion hole is formed along the longitudinal direction of the dielectric waveguide,
Wherein the flexible plate is provided covering the insertion hole at an upper portion of the insertion hole.

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