KR100862714B1 - Directional coupler - Google Patents

Abstract

A directional coupler is provided to facilitate installation thereof without increase of distance between two signal transmission lines by equalizing the distance between two signal transmission lines to the distance between first and second transmission lines. A directional coupler(100) includes first and second transmission line units, first and second dividing units, and a signal coupling unit. The first transmission line unit outputs an inputted first main signal. The second transmission line unit is independent of the first transmission line unit and outputs an inputted second main signal. The first dividing unit divides the first main signal inputted and outputted through the first transmission line unit. The second dividing unit divides the second main signal inputted and outputted through the second transmission line unit. The signal coupling unit couples a first divided signal through the first dividing unit with a second divided signal through the second dividing unit and outputs the coupled signal.

Description

Tap-changer {DIRECTIONAL COUPLER}

The present invention relates to a diverter, and more particularly, to a technique for branching a signal transmitted on a signal transmission path using differential signaling.

Conventionally, a single ended method has been adopted as a signal transmission method in mobile communication or various electronic devices. In the single-ended system, as shown in FIG. 3, when a signal is to be transmitted from point a to point b, the signal S is transmitted to the corresponding signal transmission path 311 with one signal transmission path 311 provided. Says how to send. However, when an unexpected shock or the like is applied at the point P1 as shown in FIG. 3 (a), the signal is distorted, and the signal arriving at the point b is eventually distorted by the shock as shown in FIG. 3 (b). The signal S 'is arrived. Therefore, the original signal S to be transmitted due to an impact generated on the signal transmission path 311 is not transmitted, resulting in the transmission of the signal S 'in a distorted state. I can't.

In order to solve the above problems in single-ended signal transmission, a proposed structure is low voltage differential signaling (low voltage differential signaling, hereinafter referred to as differential signaling). For reference, the differential signaling method was originally developed and used as a digital signal transmission method. In recent years, the differential signaling method has also been adopted as an analog signal transmission method. In general, the differential signaling method means that when the original signal to be transmitted is S, the original signal S to be transmitted has a low voltage having a phase difference of 180 degrees as referred to in FIG. After splitting into two signals S1 and S2, the divided two signals S1 and S2 are respectively transmitted through the first signal transmission path 411 and the second signal transmission path 412 spaced apart from each other. Next, the subtractor 413 subtracts two signals S1 and S2. According to the differential signaling method, even when an impact is applied at a point P2 on the first signal transmission path 411 and the second signal transmission path 412, the distortion of the S1 signal and the distortion of the S2 signal due to the shock cancel each other through subtraction. This allows the original signal S to be sent to arrive at point b. In the differential signaling scheme, a distance d between the two signal transmission paths 411 and 412 is as close as possible so that distortion of the signal transmitted through the two signal transmission paths 411 and 412 is closely related. It must be maintained.

On the other hand, a directional coupler (branch coupler) is installed at any point on the signal transmission path to branch the signal transmitted on the signal transmission path, thereby monitoring the signal transmitted on the signal transmission path or other branched It is an electronic component that makes it possible to use a signal for controlling signal transmission. Such a diverter is disclosed in Korean Utility Model Registration No. 20-0298260, Korean Patent Publication No. 2001-0092526, Korean Patent Publication No. 0164348, and the like.

FIG. 5 is a reference view schematically showing the conventional diverter 500 as described above. The conventional diverter 500 shown in FIG. 5 includes a transmission line part and a signal branch part.

As shown in FIG. 5, the transmission line unit includes a main signal input terminal 511, a main signal output terminal 512, and a main signal transmission line 513.

The main signal input terminal 511 serves as an input terminal to which a signal transmitted through an original signal transmission path is input.

The main signal output terminal 512 serves as an output terminal for outputting a signal input through the main signal input terminal 511 to a rear end of the original signal transmission path (after the branching point).

That is, the main signal input terminal 511 and the main signal output terminal 512 serve as a connection portion connected to the original signal transmission path.

The main signal transmission line 513 is provided to send an original signal input through the main signal input terminal 511 to the main signal output terminal 512.

The signal branch unit includes a branch line 521, a branch signal output terminal 522, an isolation terminal 523, and the like.

The branch line 521 is provided to branch the signal moving from the main signal input terminal 511 to the main signal output terminal 512 through the main signal transmission line 513 by electromagnetic induction.

The branch signal output terminal 522 branches from the branch line 521 to serve as an output terminal for outputting a branch signal to one side of the branch line 521.

The isolation port 523 is isolated from the branch line 521 and outputs a branch signal output from the branch line 521 to the other side of the branch line 521 to a characteristic impedance (for example, to prevent generation of a carrier wave by dissipation by 50 ohm-column). It serves to output to the isolation unit (IS) side for extinction. For reference, the isolation unit may be provided in the tap-off, and in this case, the isolation stage may not be provided.

According to the diverter 500 according to the related art as described above, the original signal S is input to the main signal input terminal 511 and then output through the main signal output terminal 512 through the main signal transmission line 513. The signal branched by the branch line 521 is output through the branch signal output terminal 522 to branch the signal transmitted on the signal transmission path.

However, the above-described branching system according to the related art is for branching a signal transmitted on a single-ended signal transmission path. When the branching device 500 according to the prior art is applied to a signal transmission path of a differential signaling method, that is, In the case of installing each of the two signal transmission paths using the two branching units 500, problems described below may occur.

As described above, in the differential signaling method, two signal transmission paths 411 and 412 should be spaced as close as possible. In the case of applying the conventional diverter 500, the two diverters are referred to as shown in FIG. In order to install 500 at two signal transmission paths 411 and 412, the distance between the two signal transmission paths 411 and 412 should be separated by a distance d 'suitable for installing the diverter 500. do. That is, the distance between the two signal transmission paths 411 and 412 should be spaced so that the physical space occupied by the two branching units 500 is secured. In such a case, the impact relationship between the two signals transmitted through the two signal transmission paths 411 and 412 is reduced by the wider separation distance d ', resulting in the effect of deteriorating the signal transmission effect of the differential signaling method. The cumbersomeness of installation that comes from having to install the diverter 500 on the two signal transmission paths 411 and 412 respectively.

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the prior art as described above, and provides a technique related to a branching system for branching a transmitted signal without compromising the effects of the differential signaling scheme in differential signaling scheme transmission. The purpose.

The branching apparatus according to the present invention for achieving the above object, the first transmission line unit for outputting the input first main signal; A second transmission line unit provided independently of the first transmission line unit and outputting an input second main signal; A first branching unit for branching and outputting the first main signal inputted and outputted through the first transmission line unit; A second branch unit for branching and outputting the second main signal input and output through the second transmission line unit; And a signal combiner configured to combine and output a first branch signal branched through the first branch unit and a second branch signal branched through the second branch unit. Characterized in that it comprises a.

The first transmission line unit may include a first input terminal to which the first main signal is input; A first output terminal for outputting the first main signal inputted through the first input terminal; And a first transmission line provided to transmit the first main signal input through the first input terminal to the first output terminal. The first branching part may include a first branching line for branching a signal on the first transmission line; A first connection line which transmits a first branch signal branched by the first branch line to the signal combiner; And a first isolation stage configured to output the first branch signal branched by the first branch line to the isolation unit side to the other side of the first branch line. To, to the second transmission line portion includes a second input terminal to which the call is given the second input; A second output terminal for outputting the second main signal inputted through the second input terminal; And a second transmission line provided to transmit the second main signal input through the second input terminal to the second output terminal. The second branching unit may include a second branching line for branching a signal on the second transmission line; A second connection line which transmits a second branch signal branched by the second branch line to the signal combiner; And a second isolation stage configured to output a second branch signal branched by the second branch line to the isolation means to the other side of the second branch line. The inclusion, and the signal combining unit, the transformer means to combine with the first connecting line and the first branch signal and the second branch signal coming through a second connecting line; A combined signal output stage for outputting a combined signal output to one side of the transformer means; And a ground terminal for outputting the combined signal output to the other side of the transformer means to the ground side. It is another feature to include a.

The first transmission line unit may include a first input terminal to which the first main signal is input; A first output terminal for outputting the first main signal inputted through the first input terminal; And a first transmission line provided to transmit the first main signal input through the first input terminal to the first output terminal. The first branching part may include a first branching line for branching a signal on the first transmission line; And a first connection line configured to transmit the first branch signal branched by the first branch line to the signal combiner. The second transmission line unit includes a second input terminal to which the second main signal is input; A second output terminal for outputting the second main signal inputted through the second input terminal; And a second transmission line provided to transmit the second main signal input through the second input terminal to the second output terminal. The second branching unit may include a second branching line for branching a signal on the second transmission line; And a second connection line configured to transmit a second branch signal branched by the second branch line to the signal combiner. The signal coupling unit includes: transformer means for coupling a first branch signal and a second branch signal coming through the first connection line and the second connection line; A combined signal output stage for outputting a combined signal output to one side of the transformer means; And a ground terminal for outputting the combined signal output to the other side of the transformer means to the ground side. And an isolation unit for isolating the first and second branch signals output to the other side of the first and second branch lines. It is characterized by another comprising a further.

The first connection line and the second connection line is characterized by another having the same length.

In addition, the operation method of the branching apparatus according to the present invention for achieving the above object, the first main signal branching step for branching the input and output the first main signal; A second main signal branching step of branching input and output second main signals; A first branch signal branched in the first main signal branching step; a signal branched from the first main signal branch; and a second branch signal branched in the second main signal branching step; Combining signal combining step; And a combined signal output step of outputting a combined signal combined in the signal combining step. Characterized in that it comprises a.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to FIGS. 1 to 4, but will be compressed or omitted for the sake of brevity.

<First Embodiment>

1A is a schematic diagram of a brancher 100 according to a first embodiment of the present invention.

The branch switch 100 according to the present embodiment includes a first transmission line portion, a second transmission line portion, a first branch portion, a second branch portion, a signal coupling portion, and the like.

The first transmission line unit includes a first input terminal 111, a first output terminal 112, a first transmission line 113, and the like.

The first main signal S1 (see FIG. 4) is input to the first input terminal 111.

The first main signal S1 input through the first input terminal 111 is output to the first output terminal 112.

The first transmission line 113 is provided to transmit the first main signal S1 input through the first input terminal 111 to the first output terminal 112.

The second transmission line unit includes a second input terminal 121, a second output terminal 122, a second transmission line 123, and the like.

The second main signal S2 (see FIG. 4) is input to the second input terminal 121.

The second main signal S2 input through the second input terminal 121 is output to the second output terminal 122.

The second transmission line 123 is provided to transmit the second main signal S2 input through the second input terminal 121 to the second output terminal 122.

The first branch part includes a first branch line 131, a first connection line 132, a first isolation end 133, and the like.

The first branch line 131 is provided to branch the signal on the first transmission line 113 by electromagnetic induction.

The first connection line 132 transmits the first branch signal branched by the first branch line 131 to one side of the first branch line 131 to one end of the transformer means 151 of the signal coupling unit. Do this.

The first isolation stage 133 serves to output the first branch signal branched by the first branch line 131 to the isolation unit IS to the other side of the first branch line 131.

The second branch part includes a second branch line 141, a second connection line 142, a second isolation end 143, and the like.

The second branch line 141 is provided to branch the signal on the second transmission line 123 by electromagnetic induction.

The second connection line 142 transmits the first branch signal branched by the second branch line 141 to one side of the second branch line 141 to the other end of the transformer means 151 of the signal coupling unit. Do this. The second connection line 142 should be provided to have the same length as the first connection line 132. This is because the first branch signal input through both input terminals of the transformer means 151 and the first branch signal 180 degrees out of phase with the first connection line 132 and the second connection line 142 having the same length. This is because the second branch signal having? May be synthesized into the original signal S and output. Accordingly, the second connection line 142 extending from the second branch line 141 relatively close to the first branch line 131 to the transformer means 151 has a line extending means D.

The second isolation end 143 outputs the second branch signal branched by the second branch line 141 to the other side of the second branch line 141 to the isolation unit IS.

The signal coupling unit includes a transformer means 151, a coupling signal output terminal 152, a ground terminal 153, and the like.

The transformer means combines the first branch signal and the second branch signal input through both input terminals A and B and outputs the combined signal using electromagnetic induction.

The combined signal output terminal 152 serves as an output terminal for outputting the combined signal output to one side of the transformer means 151 to the outside.

The ground terminal 153 serves to output the combined signal output to the other side of the transformer means 151 to the ground side.

According to the diverter 100 as described above, the first branch line with respect to the first main signal S1 that is output after being input through the first input terminal 111, the first transmission line 113, and the first output terminal 112. The first branch signal branched by 131 is input to the transformer means 151 through one input terminal A of the transformer means 151 via the first connection line 132, and the second input terminal 121. ), The second branch signal branched by the second branch line 141 to the second main signal S2 inputted through the second transmission line 123 and the second output terminal 122 and then output is a second connection line. It is input to the transformer means 151 through the other input terminal B of the transformer means 151 via the furnace 142. The first branch signal and the second branch signal respectively input to both input terminals A and B of the transformer means 151 are coupled by the transformer means 151 and output by the electromagnetic induction phenomenon. Here, the combined signal output to one side of the transformer means 151 is sent to the upper end for monitoring or to a separate means for controlling the strength of the transmission signal, etc., the coupled output to the other side of the transformer means 151 The signal exits through ground.

FIG. 1B shows a case in which the above-described brancher 100 is installed on a signal transmission path using differential signaling.

As shown in FIG. 1B, the separation distance between the two signal transmission lines 411 and 412 is provided to be equal to the separation distance between the first transmission line 113 and the second transmission line 123, and is divided at an arbitrary position. It can be seen that it is not necessary to widen the separation distance between the two signal transmission paths 411 and 412 to install the 100.

Second Embodiment

2 is a schematic diagram of a diverter 200 according to a second embodiment of the present invention.

The branch switch 200 according to the present embodiment includes a first transmission line part, a second transmission line part, a first branch part, a second branch part, a signal coupling part, an isolation part IS, and the like.

The first transmission line part includes a first input end 211, a first output end 212, a first transmission line 213, and the like.

The second transmission line unit includes a second input terminal 221, a second output terminal 222, a second transmission line 223, and the like.

The first branch part includes a first branch line 231 and a first connection line 232 connected to one side of the first branch line 231. Here, the other side of the first branch line 231 is connected to the isolation unit IS.

The second branch part includes a second branch line 241 and a second connection line 242 connected to one side of the second branch line 241. Similarly, the other side of the second branch line 241 is isolated. Connected to the negative IS.

The signal coupling unit includes a transformer means 251, a coupling signal output terminal 252, a ground terminal 253, and the like.

According to the tap-off 200 according to the second embodiment, there is no need to provide a separate isolation unit outside the tap-off 200.

Summarizing a common operation method of the branchers 100 and 200 according to the first and second embodiments of the present invention described above, the branchers 100 and 200 may have different signal transmission paths 411 and 412. The first main signal S1 and the second main signal S2 which are input and output through the second branch are respectively branched, and each branched first branch signal (a signal branched from the first main signal) and a second branch signal (second 2) a transmission path for transmitting signals through two signal transmission paths as in the differential signaling method by outputting the combined signal to the combined signal output terminals 152 and 252 after combining the two main signals). Will diverge the signal on the

On the other hand, the branching device (100, 200) according to the embodiment of the present invention described above has been described to be installed on the signal transmission path of the differential signaling method, but are respectively transmitted through two signal transmission paths spaced apart from each other If it is necessary to branch and output the two signals, it may be applied to any case.

Therefore, the detailed description of the present invention as described above has been made by the embodiments with reference to the accompanying drawings, but the above-described embodiment is only described with reference to the preferred examples of the present invention, the present invention is limited to the above embodiments only It should not be understood that the scope of the present invention is to be understood by the claims and equivalent concepts described below.

As described in detail above, the present invention has the following effects.

First, it is possible to branch signals transmitted through two signal transmission paths applied to differential signaling based signal transmission using one branching device, thereby providing good installation.

Second, since two transmission lines corresponding to two signal transmission lines and a branching line for branching signals transmitted from each transmission line can be standardized in one branching system, two signal transmissions are provided to install a branching system. It is not necessary to secure a wide physical separation interval between the furnace, it is possible to install a branch for branching the transmitted signal without compromising the effects of the differential signaling scheme.

1A is a schematic diagram of a branching machine according to a first embodiment of the present invention.

FIG. 1B is a schematic diagram showing that the branching device of FIG. 1A is installed on the signal transmission path of the differential signaling method of FIG.

2 is a schematic diagram of a branch according to a second embodiment of the present invention.

3 is a reference diagram for explaining signal transmission in a single ended manner.

4 is a reference diagram for explaining signal transmission using differential signaling.

5 is a schematic diagram of a tap-off according to the prior art.

FIG. 6 is a schematic diagram illustrating that the diverter of FIG. 5 is installed on the signal transmission path of the differential signaling method of FIG.

Explanation of symbols on the main parts of the drawings

100, 200: tap-off

111, 211: first input terminal

112, 212: first output stage

113, 213: first transmission line

121, 221: second input terminal

122, 222: second output stage

123, 223: second transmission line

131, 231: first branch line

132, 232: first connection line

133: first isolation unit

141, 241: second branch line

142, 242: second connection line

D: Track extension means

143: second isolation unit

151, 251: transformer means

152, 252: combined signal output terminal

153, 253: ground terminal

IS: Isolation Department

Claims (5)

A first transmission line unit for outputting an input first main signal; A second transmission line unit provided independently of the first transmission line unit and outputting an input second main signal; A first branching unit for branching and outputting the first main signal inputted and outputted through the first transmission line unit; A second branch unit for branching and outputting the second main signal input and output through the second transmission line unit; And A signal combiner configured to combine and output a first branch signal branched through the first branch unit and a second branch signal branched through the second branch unit; Turnout comprising a. The method of claim 1, The first transmission line unit, A first input terminal to which the first main signal is input; A first output terminal for outputting the first main signal inputted through the first input terminal; And A first transmission line provided to transmit the first main signal input through the first input terminal to the first output terminal; Including, The first branch portion, A first branch line for branching a signal on the first transmission line; A first connection line which transmits a first branch signal branched by the first branch line to the signal combiner; And A first isolation stage configured to output a first branch signal branched by the first branch line to the isolation unit side to the other side of the first branch line; Including; The second transmission line unit, A second input terminal to which the second main signal is input; A second output terminal for outputting the second main signal inputted through the second input terminal; And A second transmission line provided to transmit the second main signal input through the second input terminal to the second output terminal; Including, The second branch portion, A second branch line for branching a signal on the second transmission line; A second connection line which transmits a second branch signal branched by the second branch line to the signal combiner; And A second isolation stage for outputting a second branch signal branched by the second branch line to the isolation means side to the other side of the second branch line; Including; The signal coupling unit, Transformer means for coupling a first branch signal and a second branch signal coming through the first connection line and the second connection line; A combined signal output stage for outputting a combined signal output to one side of the transformer means; And A ground terminal for outputting a coupling signal output to the other side of the transformer means to the ground side; A turnout comprising a. delete The method of claim 2, The first connection line and the second connection line is characterized in that the branch having the same length. A first main signal branching step of branching input and output first main signals; A second main signal branching step of branching input and output second main signals; A first branch signal branched in the first main signal branching step; a signal branched from the first main signal branch; and a second branch signal branched in the second main signal branching step; Combining signal combining step; And A combined signal output step of outputting a combined signal combined in the signal combining step; Method of operation of the turnout comprising a.