KR20110076195A - Apparatus and method for radio frequency path to provide input into dual polarization satellite antenna - Google Patents

Abstract

PURPOSE: A frequency signal transmission method and device thereof are provided to transmit a high frequency signal even in case of one among three frequency signal switch is malfunction. CONSTITUTION: An input terminal(221~223) generates an input signal. A radio frequency signal switch(211~213) selects n numbers of input signal among input signals from each of an input terminal. An output terminal(224~227) receives the selected n number of input signal. The first input signal and the second input signal is include in the n numbers of input signal. The second input signal is inputted via neighboring high frequency signal switch.

Description

High frequency signal transmission method and apparatus for dual polarized satellite communication signal supply {APPARATUS AND METHOD FOR RADIO FREQUENCY PATH TO PROVIDE INPUT INTO DUAL POLARIZATION SATELLITE ANTENNA}

One embodiment of the present invention relates to a high frequency signal transmission method and apparatus for supplying a dual polarized satellite communication signal.

The present invention belongs to the field of electrical / electronic technologies mounted on satellites. In the technical field related to satellites, it is very important to implement reliable and reliable technology rather than applying new technology.

Recently, researches on satellite observation for observing the earth, moon, planet, etc. have been actively conducted. These satellite observations are able to precisely grasp and provide cloud conditions, distribution, and changes on the earth, and greatly profess to improve the forecast of the weather. In addition, quantitative data such as sea level, atmospheric vertical temperature, moisture structure, wind and moisture distribution are extracted. It can also be used to find traces of water on the moon or to explore other undiscovered planets.

Such image data on satellite observation is becoming larger, and various communication systems for rapid transmission to the ground are being developed.

Among them, the communication technology using the high frequency dual polarization characteristics can double the transmission band of the currently developed modulator, and it is being used by a small number of earth observation satellites which are currently in orbit.

An embodiment of the present invention is to transmit a high frequency signal between a modulator and a dual polarized antenna by using a high frequency signal switch in a variety of stable paths, and overcomes the failure of the related equipment and maintains a dual polarized wave communication function and It is an object to provide the device.

An apparatus for transmitting high frequency signals according to an embodiment of the present invention includes an input terminal for generating an input signal, a high frequency signal switch for selecting n input signals among input signals from each of the input terminals, and the selected n input signals. And an output terminal receiving a signal, wherein the high frequency signal switch includes a first input signal input from an arbitrary input terminal and a second input signal input through a neighboring high frequency signal switch, wherein the n input signals are input. Select.

The high frequency signal transmission method according to an embodiment of the present invention comprises the steps of inputting an input signal generated at an input terminal to a high frequency signal switch, a first input signal input from any input terminal in the high frequency signal switch, neighboring high frequency Selecting n input signals, including a second input signal input via a signal switch, and receiving the selected n input signals from an output means.

According to an embodiment of the present invention, the high frequency signal transmission device may be configured with three high frequency signal switches having a high reliability and a simple structure, thereby implementing a stable transmission structure of a modulated high frequency signal.

According to an embodiment of the present invention, even if a failure occurs in one of the three high frequency signal switches, a normal high frequency signal can be transmitted, and each of three modulators and two dual polarized antennas connected to the input and output terminals of the device, respectively. Even if one failure occurs, the normal double polarized communication function can be maintained.

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings and accompanying drawings, but the present invention is not limited to or limited by the embodiments.

1 is a view showing the external connection of the high frequency signal transmission apparatus according to an embodiment of the present invention.

As illustrated in FIG. 1, the high frequency signal transmission device may receive the first to third input signals 101 to 103 to generate the first to fourth output signals 104 to 107. At this time, the high frequency signal transmission device may receive the transmission path adjustment signal inputs 131 to 133 of each of the high frequency signal switches included therein, and may transmit the transmission path status display outputs 134 to 136 of each of the high frequency signal switches. .

That is, the high frequency signal transmission device may make the first to third input signals 101 to 103 into the first to fourth output signals 104 to 107 which are dual polarized signals by the high frequency signal switch.

2 is a view showing the configuration of a high frequency signal transmission apparatus according to an embodiment of the present invention.

Referring to FIG. 2, the high frequency signal transmitting apparatus 200 may include input terminals 221 to 223, high frequency signal switches 211 to 213, and output terminals 224 and 225.

The input terminals 221 ˜ 223 include a first peripheral controller 221, a sub modulator 222, and a second peripheral controller 223. The output terminals 224 and 225 are the right circular polarization signal input terminal 224 of the first antenna, the left circular polarization signal input terminal 225 of the first antenna, the right circular polarization signal input terminal 226 of the second antenna, and the left circular polarization of the second antenna. And a signal input terminal 227.

Here, the first and second antennas may be a "double polarization antenna" including a "right polarization signal input terminal" and a "left polarization signal input terminal". Further, the signal input to the right circular polarization signal input terminal is a "right polarization signal", and the signal input to the left circular polarization signal input terminal is a "left circular polarization signal".

The input signal 201 generated by the first peripheral controller 221 is input to the first high frequency signal switch 211, and the input signal 202 generated by the sub modulator 222 is the second high frequency signal switch 212. The input signal 203 generated by the second peripheral device 223 may be input to the third high frequency signal switch 213.

The high-frequency signal switches 211 to 213 select two input signals from among input signals, and include a right polarization signal input terminal 224 of the first antenna, a left circular polarization signal input terminal 225 of the first antenna, or The right polarization signal input terminal 226 of the second antenna may be transmitted to the eddy circular polarization signal input terminal 227 of the second antenna.

For example, the second high frequency signal switch 212 may transmit the input signal to the first high frequency signal switch 211 or the third high frequency signal switch 213.

Herein, an input signal directly input from any of the input terminals 221 to 223 is referred to as a "first input signal", and an input signal input to another high frequency signal switch via a neighboring high frequency signal switch 212 is " Second input signal ".

In an embodiment, the first high frequency signal switch 211 transfers the first input signal 201 input from the first peripheral device 221 to the right polarization signal input terminal 224 of the first antenna (J1 -J3) or Alternatively, the first input signal 201 may be transferred to the right polarization signal input terminal 226 of the second antenna by switching the switch J1-> J3-> J4-> J2. In addition, the first high frequency signal switch 211 transfers the second input signal 202 input from the second high frequency signal switch 212 to the right circular polarization signal input terminal 224 of the first antenna by switching the switch J4 to J3. Alternatively, the second input signal 202 may be transmitted (J4 → J2) to the right polarized wave signal input terminal 226 of the second antenna.

In another embodiment, the second high frequency signal switch 212 inputs the first input signal 202 input from the sub-modulator 222 to the first high frequency signal switch 211 through a switch J3-> J1, Alternatively, the first input signal 202 may be inputted to the third high frequency signal switch 213 by switching the switch J3 to J2.

In another embodiment, the third high frequency signal switch 213 transfers the first input signal 203 input from the second peripheral device 223 to the left circular polarization signal input terminal 225 of the first antenna (J2 → J4). Alternatively, the first input signal 203 may be transferred to the left circular polarization signal input terminal 227 of the second antenna by switching the switch J2-> J4-> J3-> J1. In addition, the third high frequency signal switch 213 switches the second input signal 202 input from the second high frequency signal switch 212 to the left circular polarization signal input terminal 225 of the first antenna by switching J3 to J4. Alternatively, the second input signal 202 may be transmitted (J3 → J1) to the left circular polarization signal input terminal 227 of the second antenna.

3 is a diagram illustrating an example of setting a high frequency signal transmission path according to an embodiment of the present invention.

Referring to the table shown in FIG. 3, the high frequency signal transmission device 200 receives an input signal from two input terminals except for one of three input terminals inactive, and outputs two of the four output terminals. I can deliver it. Hereinafter, an embodiment along the path will be described.

* PATH 1 *

In the path 1, two input terminals among the three input terminals, the first peripheral unit 221 and the second peripheral unit 223, are used to input two output terminals of the four output terminals (the first antenna). Right input, first antenna left input), a case where the signal is transmitted to the right circular polarization signal input terminal 224 of the first antenna and the left circular polarization signal input terminal 225 of the first antenna will be described as an example.

The first input signal 201 of the first peripheral controller 221 is input to the first high frequency signal switch 211, and the first input signal 203 of the second peripheral controller 223 is connected to the third high frequency signal switch ( 213). The first high frequency signal switch 211 transmits the first input signal 201 to the right polarization signal input terminal 224 of the first antenna. In addition, the third high frequency signal switch 213 transfers the first input signal 203 to the left circular polarization signal input terminal 225 of the first antenna.

That is, in this case, the second high frequency signal switch 212 and the second antennas 226 and 227 are not used. Therefore, the high frequency signal transmitting apparatus 200 may generate two outputs (a right polarization signal and a left circular polarization signal of the first antenna) with two inputs.

4 is a diagram illustrating an example of setting a mode for operating a high frequency signal switch according to an embodiment of the present invention.

Referring to FIG. 4, in the case of "path 1", the first high frequency signal switch 211 and the third high frequency signal switch 213 are 2-input, 2-output, and "mode 1 (J3↔J1, J4↔). J2) ". The first high frequency signal switch 211 may transmit the first input signal of the first peripheral device 221 to the right polarization signal input terminal 224 of the first antenna according to "J1-> J3" of the mode 1. In addition, the third high frequency signal switch 213 may transmit the first input signal of the second peripheral device 223 to the left circular polarization signal input terminal 225 of the first antenna according to "J2-> J4" of the mode 1.

* PATH 2 *

In the path 2, two input terminals among the three input terminals, the first peripheral unit 221 and the second peripheral unit 223, are used to input two output terminals of the four output terminals (second antenna). Right input, second antenna left input), a case where the signal is transmitted to the right circular polarization signal input terminal 226 of the second antenna and the left circular polarization signal input terminal 227 of the second antenna will be described as an example.

The first input signal 201 of the first peripheral controller 221 is input to the first high frequency signal switch 211, and the first input signal 203 of the second peripheral controller 223 is connected to the third high frequency signal switch ( 213). The first high frequency signal switch 211 switches the first input signal 201 to the right polarization signal input terminal 226 of the second antenna. In addition, the third high frequency signal switch 213 switches the first input signal 203 and transmits it to the left circular polarization signal input terminal 227 of the second antenna.

In this case, the second high frequency signal switch 212 and the first antennas 224 and 225 are not used. Therefore, the high frequency signal transmission device 200 may generate two outputs (right circular polarization signal and left circular polarization signal of the second antenna) with two inputs.

Referring to FIG. 4, in the case of "path 2", the first high frequency signal switch 211 and the third high frequency signal switch 213 are 2-input, 2-output, and are in "mode 2 (J3↔J4)". Corresponding. The first high frequency signal switch 211 may transmit the first input signal of the first peripheral device 221 to the right polarization signal input terminal 226 of the second antenna according to "J1-> J3- > J4- >J2" of mode 2. have. In addition, the third high frequency signal switch 213 transfers the first input signal of the second peripheral device 223 to the left circular polarization signal input terminal 227 of the second antenna according to "J2-> J4- > J3- >J1" of mode 2. I can deliver it.

* Path 3 *

In the path 3, two input terminals among the three input terminals, the first peripheral controller 221 and the sub-modulator 222, the input signal is two output terminals of the four output terminals, the right side of the first antenna A case where the polarization signal input terminal 224 is transmitted to the left circular polarization signal input terminal 225 of the first antenna will be described as an example.

The first input signal 201 of the first peripheral controller 221 is input to the first high frequency signal switch 211, and the first input signal 202 of the sub modulator 222 is the second high frequency signal switch 212. Is entered. The first high frequency signal switch 211 transmits the first input signal 201 to the right polarization signal input terminal 224 of the first antenna. In addition, the second high frequency signal switch 212 transfers the first input signal 202 to the third high frequency signal switch 213 (J3 → J2). The third high frequency signal switch 213 transfers the second input signal 202 transmitted from the second high frequency signal switch 212 to the left circular polarization signal input terminal 225 of the first antenna through a switch J3-> J4.

In this case, the second antennas 226 and 227 are not used. Therefore, the high frequency signal transmission device 200 can produce two outputs with two inputs.

Referring to FIG. 4, in the case of "path 3", the first high frequency signal switch 211 corresponds to "mode 1", the second high frequency signal switch 212 corresponds to "mode 2", and the third high frequency signal. The signal switch 213 corresponds to "mode 2". The first high frequency signal switch 211 may transmit the first input signal of the first peripheral device 221 to the right polarization signal input terminal 224 of the first antenna according to "J1-> J3" of the mode 1. In addition, the second high frequency signal switch 212 transmits the first input signal of the sub-modulator 222 to the third high frequency signal switch 213 according to "J3-> J2" of the mode 2, and the third high frequency signal switch ( 213 may transmit the second input signal transmitted from the second high frequency signal switch 212 to the left circular polarization signal input terminal 227 of the first antenna according to "J3-> J4" according to the mode 2.

* PATH 4 *

In path 4, of the three input terminals, two input terminals, the first peripheral controller 221 and the sub-modulator 222, are used to input the input signals of the two output terminals of the four output terminals, the second antenna. The case where the signal is transmitted to the right circular polarization signal input terminal 226 and the left circular polarization signal input terminal 227 of the second antenna will be described as an example.

The first input signal 201 of the first peripheral controller 221 is input to the first high frequency signal switch 211, and the first input signal 202 of the sub modulator 222 is the second high frequency signal switch 212. Is entered. The first high frequency signal switch 211 transmits the first input signal 201 to the right circular polarization signal input terminal 226 of the second antenna by switching the switch J1-> J3-> J4-> J2. In addition, the second high frequency signal switch 212 transfers the first input signal 202 to the third high frequency signal switch 213 (J3 → J2). The third high frequency signal switch 213 transfers the second input signal 202 transmitted from the second high frequency signal switch 212 to the left circular polarization signal input terminal 227 of the second antenna.

In this case, the first antennas 224 and 225 are not used. Therefore, the high frequency signal transmission device 200 can produce two outputs with two inputs.

Referring to FIG. 4, in the case of "path 4", the first high frequency signal switch 211 corresponds to "mode 2", the second high frequency signal switch 212 corresponds to "mode 2", and the third high frequency The signal switch 213 corresponds to "mode 1". The first high frequency signal switch 211 transmits the first input signal of the first peripheral device 221 to the right polarization signal input terminal 226 of the second antenna according to "J1-> J3- > J4- >J2" of mode 2. In addition, the second high frequency signal switch 212 transfers the first input signal of the sub-modulator 222 to the third high frequency signal switch 213 according to "J3->J2" of the mode 2, and the third high frequency signal. The signal switch 213 may transfer the second input signal transmitted from the second high frequency signal switch 212 to the left circular polarization signal input terminal 227 of the second antenna according to "J3->J1" according to mode 1.

* PATH 5 *

In the path 5, two input terminals among the three input terminals, the second peripheral controller 223 and the sub-modulator 222, the input signal is two output terminals of the four output terminals, the right side of the first antenna A case where the polarization signal input terminal 224 is transmitted to the left circular polarization signal input terminal 225 of the first antenna will be described as an example.

The first input signal 202 of the sub-modulator 222 is input to the second high frequency signal switch 212, and the first input signal 203 of the second peripheral modulator 223 is the third high frequency signal switch 213. Is entered. The second high frequency signal switch 212 transfers the first input signal 202 to the first high frequency signal switch 211 through a switch J3-> J1. In this case, the first high frequency signal switch 211 transfers the first input signal 202 to the right circularly polarized signal input terminal 224 of the first antenna by switching J4 to J3. In addition, the third high frequency signal switch 213 transfers the first input signal 203 to the left circular polarization signal input terminal 225 of the first antenna.

In this case, the second antennas 226 and 227 are not used. Therefore, the high frequency signal transmission device 200 can produce two outputs with two inputs.

Referring to FIG. 4, in the case of "path 5", the first high frequency signal switch 211 corresponds to "mode 2", the second high frequency signal switch 212 corresponds to "mode 1", and the third high frequency signal. The signal switch 213 corresponds to "mode 1". The first high frequency signal switch 211 transmits the second input signal 202 transmitted from the second high frequency signal switch 212 to the right-circular polarization signal input terminal 224 of the first antenna according to "J4-> J3" of mode 2. In addition, the third high frequency signal switch 213 may transmit the first input signal 203 to the left circular polarization signal input terminal 225 of the first antenna according to "J2-> J4" of mode 1. .

5 is a flowchart illustrating a procedure of a high frequency signal transmission method according to an embodiment of the present invention.

Referring to FIG. 5, in the high frequency signal transmission method, an input signal generated at the input terminals 221 to 223 is input to the high frequency signal switches 211 to 213 (501). For example, the input terminals 221 ˜ 223 include a first peripheral controller 221, a sub modulator 222, and a second peripheral controller 223, and the output terminals 224 and 225 have a right-circular polarization signal of the first antenna. The input terminal 224 may include a left circular polarization signal input terminal 225 of the first antenna, a right circular polarization signal input terminal 226 of the second antenna, and a left circular polarization signal input terminal 227 of the second antenna. In this case, the input signal 201 generated by the first peripheral controller 221 is input to the first high frequency signal switch 211, and the input signal 202 generated by the sub modulator 222 is the second high frequency signal switch. The input signal 203 generated by the second peripheral device 223 may be input to the third high frequency signal switch 213.

The high frequency signal transmission method includes two input signals including a first input signal input from an arbitrary input terminal in the high frequency signal switches 211 to 213 and a second input signal input through a neighboring high frequency signal switch. Select (502).

The high frequency signal transmission method determines an output terminal for transmitting the two selected input signals in consideration of a first identifier of the selected first input signal or a second identifier of the second input signal (503).

In an exemplary embodiment, the first high frequency signal switch 211 may convert the first input signal 201 input from the first peripheral device 221 into the right polarization signal input terminal 224 of the first antenna or the right polarization signal of the second antenna. It may be delivered to the input terminal 226.

In another embodiment, the second high frequency signal switch 212 switches the first input signal 202 input from the sub-modulator 222 to the first high frequency signal switch 211 or the third high frequency signal switch 213. Can be entered.

In another embodiment, the third high frequency signal switch 213 receives the first input signal 203 input from the second peripheral device 223 and the left circle polarization signal input terminal 225 of the first antenna or the left circle of the second antenna. The polarization signal may be transmitted to the input terminal 227.

The high frequency signal transmitting method transmits the selected two input signals to the determined output means (504).

Further, embodiments of the present invention include a computer readable medium having program instructions for performing various computer implemented operations. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the media may be those specially designed and constructed for the purposes of the present invention, or they may be of the kind well-known and available to those having skill in the computer software arts. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tape, optical media such as CD-ROMs, DVDs, and magnetic disks, such as floppy disks. Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like.

While specific embodiments of the present invention have been described so far, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims and the claims.

1 is a view showing the external connection of the high frequency signal transmission apparatus according to an embodiment of the present invention.

2 is a view showing the configuration of a high frequency signal transmission apparatus according to an embodiment of the present invention.

3 is a diagram illustrating an example of setting a high frequency signal transmission path according to an embodiment of the present invention.

4 is a diagram illustrating an example of setting a mode for operating a high frequency signal switch according to an embodiment of the present invention.

5 is a flowchart illustrating a procedure of a high frequency signal transmission method according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

200: high frequency signal transmission device

201 to 203: input signal

211 ~ 213: high frequency signal switch

221 ~ 223: Input terminal (modulator)

224 ~ 227: Output terminal (antenna)

Claims (8)

An input terminal for generating an input signal; A high frequency signal switch for selecting n input signals among input signals from each of the input terminals; And Output terminal receiving the selected n input signals Including, The high frequency signal switch, And the n input signals including a first input signal input from an arbitrary input terminal and a second input signal input through a neighboring high frequency signal switch. The method of claim 1, The high frequency signal switch, And selecting the first input signal or the second input signal from input terminals other than an input terminal which is inactivated. The method of claim 1, The input signal includes an identifier relating to an input terminal, The high frequency signal switch, And an output terminal for transmitting the selected n input signals in consideration of a first identifier of the selected first input signal or a second identifier of the second input signal. The method of claim 1, The input terminal includes at least one of a first peripheral controller, a second peripheral controller and a sub-modulator, The high frequency signal switch, A high frequency signal transmission device receiving an input signal from an input terminal except any one of the first and second peripheral units or the sub-modulator. The method of claim 1, The output terminal includes a right circular polarization signal input terminal of the first antenna, a left circular polarization signal input terminal of the first antenna, a right circular polarization signal input terminal of the second antenna, and a left circular polarization signal input terminal of the second antenna, The right circular polarization signal input terminal of the first antenna, the left circular polarization signal input terminal of the first antenna, Receiving the n input signals from the high frequency signal switch, The right circular polarization signal input terminal of the second antenna, the left circular polarization signal input terminal of the second antenna, And receiving the n input signals from the high frequency signal switch. Inputting an input signal generated at an input terminal to a high frequency signal switch; Selecting n input signals, including a first input signal input from an arbitrary input terminal in the high frequency signal switch and a second input signal input through a neighboring high frequency signal switch; And Receiving the selected n input signals from an output means High frequency signal transmission method comprising a. The method of claim 6, Selecting the n input signals, Selecting the first input signal or the second input signal from input terminals other than an input terminal that is inactive; High frequency signal transmission method comprising a. The method of claim 6, The input signal includes an identifier relating to an input terminal, Determining an output terminal to transfer the selected n input signals in consideration of a first identifier of the selected first input signal or a second identifier of the second input signal; Further comprising, a high frequency signal transmission method.

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