KR101575864B1 - branch line power divider - Google Patents

Abstract

The present invention relates to a power distributor including: a line formation unit which includes terminals on each of four corners formed to be separated from each other and has branch lines which are extended in the direction of connecting the corners to each other in the shape of a rectangular strip while the branch lines are attached to each other on each corner and are separated from each other in the middle in the direction of connecting the corners to each other; a capacitor formation unit which has four opposite plates which are formed on lower end portions of each branch line of the line formation unit to be extended to be longer than a separation distance of the branch line; a center ground formation unit formed in a center region encircled by the branch lines; and an inductance line formation unit having four inductance lines which are formed to be extended from each opposite plate to the center ground formation unit to have bent patterns. According to the present invention, the power distributor can have a small size.

Description

A branch line power divider applying a CRLH line

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a branch line power divider, and more particularly to a branch line power divider capable of downsized size.

The power divider is a circuit that divides input power by a predetermined ratio in an RF (Radio Frequency) circuit and distributes it to an output port. It distributes power at a desired ratio without power loss and isolates between output ports It is ideal to prevent changes in circuit characteristics due to the mutual influence of both ports.

It is also possible that the power divider is used as a power synthesizer by switching input / output ports.

The Wilkinson power divider, which is widely used as a power divider, is designed to have a designer's desired frequency band using a transmission line with right-handed (RH) characteristics. It is a microwave device used.

Also, as disclosed in Japanese Patent Application Laid-Open No. 10-2014-0146764, a composite right / left handed (CRLH) combination of a transmission line having RH (right-handed) characteristics and a transmission line having LH (left- A power divider having a structure in which a voltage is applied is also proposed.

Meanwhile, in recent years, there has been a demand for a structure capable of further downsizing the size of a power distributor in accordance with the miniaturization trend of products.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a power divider capable of downsizing an integrated size.

According to an aspect of the present invention, there is provided a power divider including terminals formed on four corner portions spaced apart from each other on a substrate, a branch line extending in a direction of connecting the corner portions to each other in the form of a rectangular band, Each of the branch lines being connected to each other at the corner portions and terminated at a middle portion in a direction of connecting the corner portions to each other; A capacitor forming part having four opposite plates each formed to extend from a lower end of each of the branch lines of the line forming part to a distance greater than a separation distance of the branch lines; A center ground forming portion formed in a central region surrounded by the branch lines; And an inductance line forming part having four inductance lines formed to extend from each of the opposite plates to the center ground forming part in a curved pattern.

In addition, a bottom ground forming portion is formed on a substrate formed of a glass material, a center portion is exposed to form the center ground forming portion, and a chromium plating layer is formed on the first dielectric layer formed on the bottom ground forming portion, Wherein the inductance line and the opposite plate are formed of copper and are joined to the center ground forming portion where the end of the inductance line is exposed, and the line forming portion is formed of a conductive material on the second dielectric layer formed on the opposite plate .

The line forming portion includes a first main line having a first branch line and a second branch line branched at a first corner portion serving as an input terminal and extending in mutually different directions; A third branch line whose one end is spaced apart from the end of the first branch line and extends along the extending direction of the first branch line, and the other end is a first output terminal; and a third branch line extending from the other end of the third branch line, A second main line having a fourth branch line extending in a direction parallel to the first main line; A fifth branch line spaced apart from an end of the second branch line so as to extend along an extending direction of the second branch line, and the other end being a second output terminal; a fifth branch line extending from the other end of the fifth branch line, A third main line having a sixth line extending along a line parallel to the line; A seventh branch line whose one end is spaced apart from the end of the fourth branch line and extends along the extension direction of the fourth branch line and whose other end is a third output terminal; And a fourth main line extending along a direction parallel to the sixth line and having an eighth line spaced apart from an end of the sixth line.

The capacitor forming portion may include a first opposing plate extending from the first branch line and the third branch line so as to extend beyond the spaced apart portion between the first branch line and the third branch line; A second opposite plate extending from a portion of the lower portion of the second branch line and the fifth branch line spaced apart from the second branch line and the fifth branch line; A third opposite plate extending from the fourth line and the seventh line to extend beyond the fourth line and the seventh line; And a fourth opposing plate extending from the sixth line and the eighth line at a position under the spaced-apart portion from the sixth line and the eighth line. The inductance line- A first inductance line formed in a curved pattern from the first facing plate to the ground forming portion; A second inductance line formed in a curved pattern from the second facing plate to the ground forming portion; A third inductance line formed in a curved pattern from the third facing plate to the ground forming portion; And a fourth inductance line formed in a curved pattern from the fourth opposite plate to the ground forming portion.

Preferably, the first and second dielectric layers are formed of SU-8 porter resistors.

The power divider according to the present invention provides an advantage that the size can be reduced.

1 is a perspective view of a power divider according to the present invention,
FIG. 2 is a perspective view showing an excerpt of a part of FIG. 1,
Figure 3 is an equivalent circuit for Figure 2,
4 is a process diagram showing a process of manufacturing the power divider of FIG.

Hereinafter, a power divider according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a power divider according to the present invention.

1, the power distributor 100 includes a substrate 110, a ground forming unit 120, a line forming unit 140, first to fourth opposing plates 151 to 154, first to fourth inductors And lines 161 to 164, respectively.

First, the line forming part 140 formed on the top of the substrate 110 is formed in the shape of a rectangular band and has a structure in which the middle parts are not connected to each other along the connecting direction of the four corner parts but are cut apart.

In other words, the line forming part 140 has the terminals 131 to 134 formed at four corner parts spaced apart from each other, and the first to the third line- Each of the first to eighth branch lines 141a to 144b has eight lines 141a to 144b, and each of the first to eighth branch lines 141a to 144b has a structure in which edges are mutually joined and terminated at a middle portion in the direction of connecting the edge portions have.

The line forming part 140 is divided into first through fourth main lines 141 to 144 for convenience of explanation.

The first main line 141 is a portion formed by the first branch line 141a and the second branch line 141b branched at the first corner portion to be the input terminal 131 and extending in mutually different directions.

The second main line 142 has a third branch line 142 having one end extended from the terminating end of the first branch line 141a and extending along the extending direction of the first branch line 141a and the other end being the first output terminal 132 And a fourth branch line 142b extending in parallel with the second branch line 141b from the other end of the third branch line 142a.

The third main line 143 is connected to the fifth branch line 143 having one end extending from the end of the second branch line 141b along the extending direction of the second branch line 141b and the other end being the second output terminal 133 And a sixth branch line 143b extending from the other end of the fifth branch line 143a along a direction parallel to the first branch line 141a.

The fourth main line 144 is connected to the seventh branch line 142b, one end of which is spaced apart from the end of the fourth branch line 142b and extends along the extending direction of the fourth branch line 142b and the other end thereof is the third output terminal 134 And an eighth branch line 144b extending along the direction parallel to the sixth branch line 143b from the other end of the seventh branch line 144a and spaced apart from the end of the sixth branch line 143b, .

The capacitor forming portion is formed of four first to fourth opposing plates 151 to 154 respectively formed to extend beyond the separation distance of the branch lines at the lower portions of the cut ends of the first to eighth branch lines of the line forming portion 140 have.

The first opposing plate 151 has a size larger than the spacing between the first branch line 141a and the third branch line 142a at the lower portion of the spacing between the first branch line 141a and the third branch line 142a And forms a capacitor equivalent to a part of the first branch line 141a and a part of the second branch line 142a, respectively.

The second opposing plate 152 is formed so as to extend beyond the portion between the second branch line 141b and the fifth branch line 143a under the portion where the second branch line 141b and the fifth branch line 143a are spaced apart from each other. .

The third opposing plate 153 is formed so as to extend beyond the fourth branch line 142b and the seventh branch line 144a at the lower portion of the fourth branch line 142b and the seventh branch line 144a, .

The fourth opposing plate 154 is extended beyond the portion between the sixth branch line 143b and the eighth branch line 144b below the sixth branch line 143b and the eighth branch line 144b, Respectively.

The second opposing plate 152 to the fourth opposing plate 154 also form an equivalent capacitor with respect to the opposing branch lines as the first opposing plate 151.

The inductance line forming portion is formed so as to extend from each of the first to fourth opposing plates 151 to 154 to the center ground forming portion 120a in a zigzag pattern.

That is, the first inductance line 161 is formed in a curved pattern from the first facing plate 151 to the center ground forming portion 120a.

The second inductance line 162 is formed in a curved pattern from the second facing plate 152 to the center ground forming portion 120a.

The third inductance line 163 is formed in a curved pattern from the third facing plate 153 to the center ground forming portion 120a.

The fourth inductance line 164 is formed in a curved pattern from the fourth opposing plate 154 to the center ground forming portion 120a.

The ground forming portion 120 includes a center ground forming portion 120a and a bottom ground forming portion 120b.

The central ground forming portion 120a is connected to each of the inductance lines 161 to 164 and is formed in a central region surrounded by the branch lines.

The bottom ground forming portion 120b is formed on the substrate 10 at a position lower than the position where the inductance lines 161 to 164 are formed and is covered by the first dielectric layer described later.

In this structure, branch lines and inductance lines 161 to 164 opposed to the respective opposing plates 151 to 154 function as an equivalent circuit as shown in Fig.

That is, each of the opposing plates disposed below the mutually spaced branch lines serves as two capacitors 201 and 202 in FIG. 3, and the inductance line connected between the two capacitors 201 and 202 functions as an inductor 205).

According to this structure, the power divider for 2.4 GHz can be manufactured in a size of about 3% of the area required in the conventional hybrid method, thereby providing a small size.

Hereinafter, a manufacturing process of such a power divider will be described with reference to FIG.

First, a bottom ground forming portion 120b is formed of a conductive material on a substrate 110 made of a glass material.

The bottom ground forming portion 120b is formed of chromium (Cr) material to a thickness of 30 nm first and chromium (Cr) to a thickness of 300 nm.

Next, a first dielectric layer 211 is formed by applying a photoresist material of SU-8 material on the bottom ground 120b, and a central portion of the first dielectric layer 211 is etched to form a central portion of the bottom ground layer 120b Etch to be exposed.

Next, a first conductive pattern layer 220 corresponding to the above-described opposite plate, inductance line, is formed from the bottom ground layer 120b of the exposed central portion.

The center portion of the first conductive pattern layer 220 is electrically connected to the bottom ground forming portion 120b to form the center ground forming portion 120a.

A second dielectric layer 212 is formed on the first conductive pattern layer 220 and a second conductive pattern layer 230 is formed on the second dielectric layer 212 to correspond to the line forming portion 230.

On the other hand, in the case of a power divider for 2.4 GHz, in the case of a line, the line width of the line forming portion is 210 mu m, the width of the inductance line is 20 mu m, the total length of the inductance line is 6,630 mu m, The length of the inductance line was 340 m, and the impedance was 35.35. In the case of the line, the line width of the line forming portion was 370 m, the inductance line width was 20 m, the total length of the inductance line was 5,190 m, And the length of the opposing plate is 270 탆. Thus, it can be manufactured in a small size having a width of 3.01 mm and a length of 3.07 mm.

110: substrate 120: ground forming part
140: Line forming portions 151 to 154: First to fourth opposing plates
161 to 164: First to fourth inductance lines

Claims (5)

A terminal is formed on each of the four corner portions spaced apart from each other on the substrate and has branch lines extending in a direction of connecting the corner portions in a rectangular band shape. A line forming part which is joined and terminated at a middle portion in a direction of connecting the corner parts to each other;
A capacitor forming part having four opposite plates each formed to extend from a lower end of each of the branch lines of the line forming part to a distance greater than a separation distance of the branch lines;
A center ground forming portion formed in a central region surrounded by the branch lines;
And an inductance line forming part having four inductance lines formed to extend from each of the opposite plates to the center ground forming part in a curved pattern. The method according to claim 1,
A bottom ground forming portion is formed on a substrate formed of a glass material, a center portion is exposed to form the center ground forming portion,
The center ground forming portion is exposed to the center ground forming portion, and the inductance line and the counter plate are formed of chromium and copper on the first dielectric layer formed of a dielectric material on the bottom ground forming portion, And the line forming portion is formed of a conductive material on a second dielectric layer formed on the opposite plate. The apparatus according to claim 2, wherein the line forming portion
A first main line having a first branch line and a second branch line branched at a first corner portion serving as an input terminal and extending in mutually different directions;
A third branch line whose one end is spaced apart from the end of the first branch line and extends along the extending direction of the first branch line, and the other end is a first output terminal; and a third branch line extending from the other end of the third branch line, A second main line having a fourth branch line extending in a direction parallel to the first main line;
A fifth branch line spaced apart from an end of the second branch line so as to extend along an extending direction of the second branch line, and the other end being a second output terminal; a fifth branch line extending from the other end of the fifth branch line, A third main line having a sixth line extending along a line parallel to the line;
A seventh branch line whose one end is spaced apart from the end of the fourth branch line and extends along the extension direction of the fourth branch line and whose other end is a third output terminal; And a fourth main line extending along a direction parallel to the sixth line and having an eighth line separated from an end of the sixth line. The plasma display panel according to claim 3, wherein the capacitor forming portion
A first opposing plate formed to extend beyond a portion of the first branch line and the third branch line spaced apart from the first branch line and the third branch line;
A second opposite plate extending from a portion of the lower portion of the second branch line and the fifth branch line spaced apart from the second branch line and the fifth branch line;
A third opposite plate extending from the fourth line and the seventh line to extend beyond the fourth line and the seventh line;
And a fourth opposing plate extending from the sixth line and the eighth line at a position under the spaced-apart portion from the sixth line and the eighth line,
The inductance line forming unit
A first inductance line formed in a curved pattern from the first facing plate to the ground forming portion;
A second inductance line formed in a curved pattern from the second facing plate to the ground forming portion;
A third inductance line formed in a curved pattern from the third facing plate to the ground forming portion;
And a fourth inductance line formed in a curved pattern from the fourth opposite plate to the ground forming portion. 5. The power divider of claim 4, wherein the first and second dielectric layers are formed of SU-8 porter resistors.

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