WO2012050358A1

WO2012050358A1 - Bias tee and a tilt-angle adjusting unit using the same

Info

Publication number: WO2012050358A1
Application number: PCT/KR2011/007577
Authority: WO
Inventors: 김호용; 박철근; 이승철; 오건석
Original assignee: 주식회사 에이스테크놀로지
Priority date: 2010-10-15
Filing date: 2011-10-12
Publication date: 2012-04-19

Abstract

The present invention relates to a tilt-angle adjusting unit which is integrated inside an antenna. The tilt-angle adjusting unit comprises: an RF board part for transmitting, to a phase shifter, the RF signal in an input RF signal and a direct current power source; and a first DC board part which is physically separated from the RF board part. Here, only the direct current power source in the input RF signal and the direct current power source is transmitted to the first DC board part by the RF board part.

Description

Bias-tee and tilt angle adjustment unit using it

The present invention relates to a bias-tee and an tilt angle adjusting unit integrated inside the antenna while using the same.

An antenna is an element that outputs a beam in a specific direction for transmitting and receiving an RF signal, and it is necessary to change the direction of the beam. This process of varying the direction of the beam is called an inclination angle adjustment process, the device used to adjust the inclination angle is an inclination angle adjustment unit.

Currently, in order to adjust the inclination angle of an antenna, in particular a base station antenna, the administrator has to climb to the position where the antenna is installed and connect the inclination angle adjusting unit to the antenna and then adjust the inclination angle of the antenna. In addition, after the inclination angle of the antenna was adjusted, the inclination angle adjusting unit had to be separated and recovered. These processes caused a lot of inconvenience for managers.

It is an object of the present invention to provide an inclination angle adjustment unit integrated inside the antenna so as to conveniently adjust the inclination angle of the antenna.

Another object of the present invention is to provide an inclination angle adjustment unit implemented in a structure in which the RF board and the DC board part are physically separated to improve the intermodulation distortion (PIMD) characteristic.

Another object of the present invention is to provide a bias-tee (BIAS-T) having PSR layers made of PSR (Photo Solder Resist).

In order to achieve the above object, the inclination angle adjustment unit used in the antenna according to an embodiment of the present invention includes an RF board unit for transmitting the RF signal of the input RF signal and the DC power supply to a phase variable; And a first DC board part physically separated from the RF board part. Here, only the DC power of the RF signal input to the RF board unit and the DC power is transferred to the first DC board unit.

An inclination angle adjustment unit used in an antenna according to another embodiment of the present invention includes an RF board unit for transmitting the RF signal of an input RF signal and a DC power supply to a phase variable unit; And a first DC board portion. Here, a first ground is formed on one surface of the RF board part, a second ground is formed on one surface of the first DC board part, and the first ground and the second ground are physically separated.

According to an embodiment of the present invention, the bias-tee includes: a first substrate; A second substrate positioned on the first substrate and facing the first substrate; At least one signal line arranged over the first substrate; A coupling line arranged over the second substrate; And a PSR layer (Photo Solder Resist Layer) arranged on an upper surface of the signal line or an upper surface of the coupling line. Here, the signal line and the coupling line face each other.

According to another embodiment of the present invention, the bias-tee may include a substrate; A conductive plate positioned on the substrate and facing the substrate; At least one signal line arranged over the substrate; A dielectric layer arranged on the conductive plate; And a PSR layer (Photo Solder Resist Layer) arranged on an upper surface of the signal line.

Since the inclination angle adjusting unit according to the present invention is integrated and implemented in the antenna, there is an advantage in that it is convenient to adjust the inclination angle of the antenna.

In addition, since the RF board and the DC board unit included in the tilt angle adjustment unit of the present invention are physically separated, there is an advantage that the PIMD characteristic of the antenna can be improved.

In addition, since the bias-tee of the tilt angle adjusting unit of the present invention uses PSR layers having a low dielectric constant, there is an advantage that the PIMD characteristic of the antenna can be improved.

1 is a block diagram illustrating an antenna according to an embodiment of the present invention.

2 is a view showing an inclination angle adjusting unit according to a first embodiment of the present invention.

3 is a view showing an inclination angle adjusting unit according to a second embodiment of the present invention.

4 is a view showing an inclination angle adjusting unit according to a third embodiment of the present invention.

FIG. 5 is a graph showing RF-DC isolation characteristics of the tilt angle adjusting unit of FIG. 2.

FIG. 6 is a graph illustrating a PIMD characteristic of the inclination angle adjusting unit of FIG. 2.

FIG. 7 is a graph illustrating RF-DC isolation characteristics of the tilt angle adjusting unit of FIG. 3.

8 is a graph illustrating a PIMD characteristic of the inclination angle adjusting unit of FIG. 3.

FIG. 9 is a graph illustrating RF-DC isolation characteristics of an inclination angle adjusting unit in which the RF board unit and the DC board unit are not separated.

FIG. 10 is a graph illustrating PIMD characteristics of an inclination angle adjusting unit in which an RF board unit and a DC board unit are not separated.

FIG. 11 is a cross-sectional view illustrating a structure of a bias tee taken along line II ′ of FIG. 2 according to an embodiment of the present invention.

12 is a cross-sectional view illustrating a bias-tee according to another embodiment of the present invention.

[Description of the code]

100: inclination angle adjustment unit 102: electric motor

104: phase shifter 106: radiation element

200: RF board section 202: DC board section

210: first connection part 212: second connection part

214: DC blocker 216: RF signal blocker

220: first surge current protection unit 222: modem

224: DC path portion 226: inrush current protection portion

228: adjusting unit 230: second surge current protection unit

232: relay block unit 234: control unit

236: EEPROM 238: motor drive unit

240: first cable 242: second cable

300: RF board section 302: First DC board section

304: second DC board portion 400: RF board portion

402: DC board section

1100: coupling substrate 1102, 1104: signal line

1106: ground 1108: coupling line

1110: first PSR layer 1112: second PSR layer

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, the antenna of the present embodiment, in particular, the antenna for the base station, includes an inclination angle adjusting unit 100, an electric motor 102, a phase shifter 104, and at least one radiation element 106.

The inclination angle adjusting unit 100 is a unit for adjusting the tilting, that is, the inclination angle of the beam output from the antenna, and is formed on one surface of a reflector (not shown) and applies a predetermined DC power supply DC to the electric motor 102. To control the driving of the electric motor 102.

According to an embodiment of the present invention, the inclination angle adjusting unit 100 may include a bias tee (BIAS-T) that blocks DC, and the bias tee may include a PSR layer (Photo Solder Resist Layer). . Detailed description thereof will be described later.

The motor 102 is driven in response to the DC power applied from the inclination angle adjusting unit 100, and in particular, the rotational speed or the rotational force of the motor 102 may be determined according to the magnitude of the DC power.

According to one embodiment of the invention, the rotating shaft of the electric motor 102 is connected to the phase shifter 104 through a shaft (not shown).

The phase shifter 104 changes the phase of the RF signals applied to the radiation elements 106 according to the driving of the electric motor 102. Specifically, when the rotational speed of the electric motor 102 changes, the position of the arm (not shown) of the phase shifter 104 is changed, and as a result, the phases of the RF signals provided to the radiation elements 106 are changed. . As a result, the direction of the beam output from the radiating elements 106 is changed, that is, the tilt angle of the antenna is changed.

In summary, the inclination angle adjusting unit 100 controls the electric motor 102 to adjust the degree of phase variation of the phase variable 104, and the inclination angle of the antenna is determined according to the adjusted degree of phase variation. In addition, the manager may vary the inclination angle of the antenna to a desired angle through a method of controlling the inclination angle adjusting unit 100 from the outside. Of course, the inclination angle of the antenna may be automatically made by a computer.

According to one embodiment of the invention, the antenna comprises a reflecting plate, the radiation elements 106 are arranged on the upper surface of the reflecting plate, the inclination angle adjusting unit 100 and the phase shifter 104 is the back of the reflecting plate Can be arranged to.

Referring to FIG. 2, the inclination angle adjusting unit 100 of the present embodiment includes an RF board unit 200, an RF signal blocking unit 216, and a DC board unit 202.

The RF board unit 200 serves to supply an RF signal input from the outside to the phase shifter 104.

Connections

210 and 212, which are conductors, and a DC blocking unit 214 are formed on an upper surface of the RF board 204 of the RF board unit 200, and a ground (not shown) may be formed on the rear surface of the RF board 200. Can be. As a result, the RF signal input through the first cable 240 is transmitted through the first connector 210, the DC blocker 214, the second connector 212, and the second cable 242. Is delivered.

However, since the DC blocking unit 214 blocks DC as a bias-T, only the RF signal is transmitted to the second cable 242 even though the RF signal and the DC are input through the first cable 240. . According to an embodiment of the present invention, the DC blocking unit 214 may be formed of a capacitor.

The RF signal blocking unit 216 is connected between the RF board unit 200 and the DC board unit 202 and serves to block the RF signal. Specifically, the RF signal and DC input through the first cable 240 are input to the RF signal blocking unit 216 through the first connection unit 210, the RF signal of the input RF signal and DC is an RF signal It is blocked by the blocking unit 216 and only DC is transmitted to the DC board unit 202. According to an embodiment of the present invention, the RF signal blocking unit 216 may be formed of an inductor.

The DC board unit 202 serves to drive an electric motor, for example, a motor, which drives the phase variableer 104, and includes a first surge current protection unit 220, a modem 222, and a DC path unit 224. ), An inrush current protection unit 226, an adjusting unit 228, a second surge current protection unit 230, a relay block unit 232, a control unit 234, an EEPROM 236, and a motor driving unit 238. Can be.

The first surge current protection unit 220 serves to protect the elements of the DC board unit 202 by blocking a surge current due to lightning. Specifically, the first surge current protection unit 220 blocks the surge current when the surge current is input through the first connection unit 210 and the RF signal blocking unit 216.

The DC input to the first surge current protection unit 220 is branched to the modem 220 and the DC path unit 224.

The DC path unit 224 serves to provide a DC path.

The inflow current protection unit 226 protects the elements of the DC board unit 202 from high voltage that may be generated initially when the power of the inclination angle adjusting unit 100 is turned on.

The DC input from the DC path portion 224 to the inflow current protection portion 226 is provided to the adjusting portion 228.

The adjusting unit 228 adjusts the driving of the motor driving unit 238 under the control of the control unit 234. For example, the adjusting unit 228 adjusts the magnitude of the DC to control the rotation speed, the rotating force, and the like of the motor driving unit 238. . As a result, the degree of phase variation of the phase variableer 104 may vary according to the control of the adjusting unit 228.

According to an embodiment of the present invention, the ground (not shown) is formed on the rear surface of the DC board unit 202.

In summary, an RF signal and DC are input through the first cable 240, and the RF signal is transmitted to the phase shifter 104 through the second cable 242, and the DC is the DC board unit 202. Is transmitted to drive the motor drive unit 238. Therefore, the RF signal is transmitted to the radiation elements through the phase shifter 104, the phase of the RF signal transmitted to the radiation elements is controlled by the motor driver 238.

According to another embodiment of the present invention, the DC may be provided to the motor driving unit 238 through the second surge current protection unit 230, the relay block unit 232, and the control unit 234. In this case, however, only the RF signal is input through the first cable 240. That is, only one of the two DCs is supplied to the DC board portion 202.

Hereinafter, the physical structure of the inclination angle adjustment unit 100 will be described.

As shown in FIG. 2, the RF board unit 200 and the DC board unit 202 may be physically separated from each other, and may be blocked by, for example, a partition wall. As a result, the ground of the RF board unit 200 and the ground of the DC board unit 202 are physically separated.

The inclination angle adjusting unit 100 uses many active elements that use a power source, and is integrated into the antenna along with a passive element such as the phase shifter 104. As such, when the active element and the passive element are used together, there is a possibility that the intermodulation distortion (PIMD) characteristic of the antenna is deteriorated. Therefore, in order to integrate the tilt angle adjusting unit 100 into the antenna, the PIMD characteristic must be considered.

The antenna of the present invention integrates the tilt angle adjusting unit 100 in consideration of the PIMD characteristic, but physically separates the RF board 200 and the DC board 202 included in the tilt angle adjusting unit 100. Physically separating the RF board unit 200 and the DC board unit 202 in this way, the PIMD characteristics are superior to those in which the RF elements and the DC elements are used in one board, which is confirmed in the attached experimental graphs. .

Referring to FIG. 3, the inclination angle adjusting unit 100 of the present embodiment includes an RF board unit 300, a first DC board unit 302, a second DC board unit 304, and an RF signal blocking unit 320. do.

Unlike in the first embodiment in which the DC board portion 202 is made of one, in this embodiment, the DC board portion 302 and the second DC board portion 304 are separated. As a result, the ground formed on the back of the RF board 300, the ground formed on the back of the first DC board 302, and the ground formed on the back of the second DC board 304 are physically separated.

The first DC board portion 302 may include only the first surge current protection portion 322, and the second DC board portion 304 may include the remaining DC elements. Here, the RF signal blocking unit 320 is electrically connected between the first connection unit 310 and the first DC board unit 302 of the RF board unit 300.

In summary, the RF board unit 300, the first DC board unit 302, and the second DC board unit 304 are physically separated from each other. As a result, the PIMD characteristic of the inclination angle adjustment unit 100 of the present embodiment can be improved than the inclination angle adjustment unit 100 of the first embodiment. The actual experimental result will be described in detail with reference to the accompanying drawings.

Although the first DC board unit 302 is illustrated as including the first surge current protection unit 322 above, the first DC board unit 302 may be implemented in a structure including a DC element other than the first surge current protection unit 322. have.

Referring to FIG. 4, the inclination angle adjusting unit 100 of the present embodiment includes an RF board unit 400, a DC board unit 402, and an RF signal blocking unit 416.

That is, the DC board portion 402 of this embodiment is composed of one DC board portion as in the first embodiment, but does not include the first surge current protection portion. In this case, the RF signal blocking unit 402 may be electrically connected between the first connection unit 410 and the DC path unit of the RF board unit 400.

Summarizing the first to third embodiments, the RF board unit and the DC board unit are physically separated to improve PIMD characteristics, and preferably, the DC board unit is separated into two or more again. In electrical terms, the ground of the RF board section and the ground of the DC board section are separated.

Hereinafter, the isolation characteristics and PIMD characteristics of the inclination angle adjustment units 100 of various embodiments will be described.

FIG. 5 is a graph showing the RF-DC isolation characteristic of the tilt angle adjusting unit of FIG. 2, and FIG. 6 is a graph showing the PIMD characteristic of the tilt angle adjusting unit of FIG. 2. FIG. 7 is a graph showing the RF-DC isolation characteristic of the tilt angle adjusting unit of FIG. 3, and FIG. 8 is a graph showing the PIMD characteristic of the tilt angle adjusting unit of FIG. 3. FIG. 9 is a graph showing RF-DC isolation characteristics of the inclination angle adjustment unit in which the RF board unit and the DC board unit are not separated, and FIG. 10 is a view illustrating the inclination angle adjustment unit in which the RF board unit and the DC board unit are not separated. It is a figure which shows the graph which displayed PIMD characteristic.

Looking at the RF-DC isolation, the isolation angle of the inclination angle adjustment unit (hereinafter referred to as "first inclination angle adjustment unit") in which the RF board portion and the DC board portion are not separated is about -20 dB as shown in FIG. 9. The isolation degree of the inclination angle adjustment unit 100 of the second (hereinafter referred to as "second inclination adjustment unit") is about -30㏈ as shown in Fig. 5, and the inclination angle adjustment unit 100 of the Fig. 3 (hereinafter referred to as "third inclination adjustment"). Isolation of the " unit " is about -60 Hz as shown in FIG. That is, the isolation degree is excellent in the order of the third inclination angle adjustment unit, the second inclination angle adjustment unit, and the first inclination angle adjustment unit. This is because three boards are physically separated from each other in the third tilt angle adjusting unit, two boards are physically separated from each other in the second tilt angle adjusting unit, and the first tilt angle adjusting unit is formed of one board. Because.

Looking at the PIMD characteristics, the PIMD of the first inclination angle adjustment unit is about -57㏈ as shown in FIG. 10, and the PIMD of the second inclination angle adjustment unit is about -85㏈ as shown in FIG. The PIMD of the third tilt angle adjustment unit is about -112 kPa as shown in FIG. That is, the PIMD characteristic is excellent in the order of the third inclination angle adjustment unit, the second inclination angle adjustment unit, and the first inclination angle adjustment unit. That is, if the inclination of the inclination angle adjusting unit is excellent, it can be seen that the PIMD characteristics are also excellent.

In summary, the inclination angle adjusting unit of the present embodiment physically separates the RF board and the DC board part, and in particular, physically separates the DC board part into a plurality of boards to improve PIMD characteristics.

Hereinafter, the structure of the bias-tee 214 as the DC blocking unit of the present invention will be described. Of course, the bias-tee 214 may be used for other elements in addition to the inclination angle adjustment unit 100.

FIG. 11 is a cross-sectional view illustrating a structure of a bias tee taken along line II ′ of FIG. 2 according to an embodiment of the present invention. Although the tilt angle adjustment unit of FIG. 2 is taken as an example, the structure of the bias-tee 214 applies to other embodiments as well.

Referring to FIG. 11A, the bias-tee 214 of the present embodiment is implemented with a capacitor, and includes an RF substrate 204, a coupling substrate 1100,

signal lines

1102 and 1104, and a ground 1106. And a coupling line 1108, a first PSR layer 1110 and a second PSR layer 1112.

The coupling substrate 1100 is positioned to be spaced apart from the upper portion of the RF substrate 204 and faces the RF substrate 204.

Signal lines

1102 and 1104 are formed on top of the RF substrate 204 as conductors and are spaced apart from each other. Thus, the direct current does not pass through the bias tee 214 and is blocked.

Ground 1106 is formed on the back side of the RF substrate 204.

The coupling line 1108 is formed on one surface of the coupling substrate 1100 as a conductor and is arranged to face the

signal lines

1102 and 1104. In particular, the coupling line 1108 is arranged at least partially overlapping with the

respective signal lines

1102 and 1104.

The first PSR layer 1110 is formed on the

signal lines

1102 and 1104 and is made of PSR.

The second PSR layer 1112 is formed on the coupling line 1108 and is made of PSR. Here, the second PSR layer 1112 is in close contact with the first PSR layer 1110 and spaced apart from each other. As a result, the RF signal transmitted through the first signal line 1102 is coupled and transmitted to the second signal line 1104.

According to another embodiment of the present invention, the bias-tee 214 of this embodiment is an RF substrate 204, a coupling substrate 1100,

signal lines

1102 and 1104 as shown in FIG. 11 (B). , A ground 1106, a conductive plate 1120, a PSR layer 1110, and an adhesive portion 1122. That is, the conductive plate 1120, for example, a plate made of copper may simultaneously serve as a coupling line and a substrate. Accordingly, the thickness of the bias tee 214 may be thin, and the bias tee 214 may be more stably implemented by using the adhesive part 1122.

In short, the bias-tee 214 of this embodiment uses

PSR layers

1110 and 1112. In general, when layers of high dielectric constant are arranged between the

substrates

204 and 1100, a high capacitance creates a possibility that the layers of material are in contact with each other. As a result, the PIMD characteristic of the inclination angle adjusting unit may be lowered. Accordingly, the present invention forms

PSR layers

1110 and 1112 made of PSR having a low dielectric constant between the

substrates

204 and 1100, and the PSR layers 1110 and 1112 are in contact with each other because the PSR has a low dielectric constant. It is unlikely to degrade PIMD properties.

12 is a cross-sectional view illustrating a bias-tee according to another embodiment of the present invention. However, the reference numerals are used for the convenience of description.

Referring to FIG. 12A, the bias-tee 214 of the present embodiment includes an RF substrate 204, a coupling substrate 1100,

signal lines

1102 and 1104, a ground 1106, and a coupling line ( 1108 and PSR layer 1110. That is, in the bias-tee of this embodiment, the second PSR layer 1112 does not exist.

Referring to FIG. 12B, the bias tee 214 of the present embodiment includes an RF substrate 204, a coupling substrate 1100,

signal lines

1102 and 1104, a ground 1106, and a coupling line ( 1108 and PSR layer 1112. That is, in the bias-tee of the present embodiment, the first PSR layer 1110 does not exist.

That is, the bias tee 214 of the present invention may have one PSR layer or two PSR layers between the

substrates

204 and 1100. Of course, three or more PSR layers may be present between the

substrates

204 and 1100.

The embodiments of the present invention described above are disclosed for the purpose of illustration, and those skilled in the art having various ordinary knowledge of the present invention may make various modifications, changes, and additions within the spirit and scope of the present invention. Should be considered to be within the scope of the following claims.

Claims

RF board unit for transmitting the RF signal of the input RF signal and the DC power supply to the phase variable; And

A first DC board part physically separated from the RF board part,

The inclination angle adjusting unit used in the antenna, characterized in that only the direct current power of the RF signal input to the RF board portion and the direct current power supply to the first DC board portion.
According to claim 1, The inclination angle adjustment unit,

And an RF signal blocking unit electrically connecting the RF board unit and the first DC board unit to block the RF signal.

The first DC board unit,

A surge current protection unit protecting the first DC board unit from a surge current;

An inrush current protection unit to protect the elements of the first DC board unit from an overvoltage;

An adjusting unit connected to the inflow current protection unit; And

Including a motor driving unit connected to the adjustment unit,

The DC power is transferred to the motor driving unit through the RF signal blocking unit, the surge current protection unit and the adjusting unit, wherein the motor driving unit controls an electric motor driving the phase shifter according to the DC power source. Tilt angle adjustment unit used for antennas.
According to claim 1, The inclination angle adjustment unit,

An RF signal blocking unit to block the RF signal; And

Further comprising a second DC board portion,

The RF signal blocking unit is electrically connected to the RF signal unit and the second DC board unit, and the second DC board unit provides the DC power transmitted through the RF signal blocking unit to the first DC board unit, and the RF And the signal portion, the first DC board portion and the second DC board portion are physically separated from each other, and the second DC board portion protects the tilt angle adjustment unit from a surge current.
The method of claim 1, wherein the RF board unit,

An RF substrate;

A first connection part formed on one surface of the RF substrate, the first connection part being a conductor to which a first cable is connected;

A second connection part formed on one surface of the first RF substrate, the second connection part being a conductor to which a second cable is connected while being separated from the first connection part;

A DC blocking unit electrically connected to the first connection unit and the second connection unit between the first connection unit and the second connection unit; And

And a ground formed on a surface of the RF substrate facing the surface on which the first and second connection portions are formed.
The method of claim 4, wherein the DC blocking unit,

A first substrate which is the RF substrate;

A second substrate positioned on the first substrate and facing the first substrate;

At least one signal line arranged over the first substrate;

A coupling line arranged over the second substrate; And

The PSR layer is arranged on the upper surface of the signal line or the coupling line,

The signal line and the coupling line face each other, a first PSR layer of the PSR layers is arranged on an upper surface of the signal line, and a second PSR layer of the PSR layers is arranged on an upper surface of the coupling line. Two signal lines are arranged on the first substrate, wherein the first PSR layer and the second PSR layer face each other, and the signal lines are spaced apart from each other.
The method of claim 1, wherein a first ground is formed on one surface of the RF board, and a second ground is formed on one surface of the first DC board.

And the first ground and the second ground are physically separated.
RF board unit for transmitting the RF signal of the input RF signal and the DC power supply to the phase variable; And

Including a first DC board,

A first ground is formed on one surface of the RF board, a second ground is formed on one surface of the first DC board, and the first ground and the second ground are physically separated from each other. Tilt angle adjustment unit.
The method of claim 7, wherein the inclination angle adjustment unit,

RF of the RF signal input to the RF board unit and the DC power only the DC power is transferred to the first DC board unit, electrically connecting the RF board unit and the first DC board unit, RF for blocking the RF signal Further comprising a signal blocking unit,

The first DC board unit,

A surge current protection unit protecting the first DC board unit from a surge current;

An inrush current protection unit to protect the elements of the first DC board unit from an overvoltage;

An adjusting unit connected to the inflow current protection unit; And

Including a motor driving unit connected to the adjustment unit,

The DC power is transferred to the motor driving unit through the RF signal blocking unit, the surge current protection unit, and the adjusting unit, and the motor driving unit controls an electric motor driving the phase shifter according to the DC power source. Tilt angle adjustment unit used for antennas.
The method of claim 7, wherein the inclination angle adjustment unit,

An RF signal blocking unit to block the RF signal; And

Further comprising a second DC board portion,

The RF signal blocking unit is electrically connected to the RF signal unit and the second DC board unit, and the second DC board unit provides DC power transmitted through the RF signal blocking unit to the first DC board unit. A third ground is formed on one surface of the second DC board portion, and the first ground, the second ground, and the third ground are electrically separated from each other, and the second DC board portion protects the inclination angle adjusting unit from a surge current. Tilt angle adjustment unit used for an antenna, characterized in that.
The method of claim 7, wherein the RF signal unit,

An RF substrate;

A first connection part formed on one surface of the RF substrate, the first connection part being a conductor to which a first cable is connected;

A second connection part formed on one surface of the first RF substrate, the second connection part being a conductor to which a second cable is connected while being separated from the first connection part;

A DC blocking unit electrically connected to the first connection unit and the second connection unit between the first connection unit and the second connection unit; And

And the first connection portion and the second connection portion are formed on a surface of the RF substrate facing the surface on which the first ground is formed.
The method of claim 10, wherein the DC blocking unit,

A first substrate which is the RF substrate;

A second substrate positioned on the first substrate and facing the first substrate;

At least one signal line arranged over the first substrate;

A coupling line arranged over the second substrate; And

The PSR layer is arranged on the upper surface of the signal line or the coupling line,

The signal line and the coupling line face each other, a first PSR layer of the PSR layers is arranged on an upper surface of the signal line, and a second PSR layer of the PSR layers is arranged on an upper surface of the coupling line. Two signal lines are arranged on the first substrate, wherein the first PSR layer and the second PSR layer face each other, and the signal lines are spaced apart from each other.
A first substrate;

A second substrate positioned on the first substrate and facing the first substrate;

At least one signal line arranged over the first substrate;

A coupling line arranged over the second substrate; And

It includes a PSR layer (Photo Solder Resist Layer) arranged on the upper surface of the signal line or the coupling line,

And the signal line and the coupling line face each other.
The semiconductor device of claim 12, wherein a ground is formed on a surface of the first substrate that faces the surface on which the signal line is formed, and a first PSR layer of the PSR layers is arranged on an upper surface of the signal line, and a first one of the PSR layers is formed. 2 PSR layer is arranged on the upper surface of the coupling line,

And the first PSR layer and the second PSR layer face each other.
The method of claim 12, wherein two signal lines are arranged on the first substrate.

And the signal lines are spaced apart from each other.
Board;

A conductive plate positioned on the substrate and facing the substrate;

At least one signal line arranged over the substrate;

A dielectric layer arranged on the conductive plate; And

And a photo solder resist layer (PSR) arranged on an upper surface of the signal line.
16. The bias-tee of claim 15 wherein the dielectric layer is an adhesive tape.