KR20040037588A - Interference signal cancellation system and relay system therefor - Google Patents

Abstract

PURPOSE: An apparatus for cancelling a transmission feedback signal and a relay system using the same are provided to have a broad frequency characteristic and increase the capacity of the entire system by cancelling the transmission feedback signal and preventing the oscillation of a repeater. CONSTITUTION: An ID signal generator(301) generates an ID signal for cancelling a transmission feedback signal. A signal converter having the first phase shifter(306) and a variable attenuator(307) converts a phase and a level of a signal sampled from an output signal of a repeater. A controller(308) compares the ID signal inputted from the ID signal generator(301) with an ID signal included in an original signal received through a receiving antenna(200), and outputs a control signal to the signal converter for minimizing the ID signal included in the original signal. A signal coupler receives the control signal from the controller(308), couples the original signal received through the receiving antenna(200) with the signal converted in the signal converter, and outputs a signal in which the transmission feedback signal is cancelled to the repeater.

Description

Transmission feedback signal removing device and relay system using the same {INTERFERENCE SIGNAL CANCELLATION SYSTEM AND RELAY SYSTEM THEREFOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless communication system, and more particularly, to a transmission feedback signal removing device and a relay system including the same in a wireless communication system for removing a part of a signal transmitted from a transmitting antenna of a repeater to a receiving antenna. .

In order to increase the reach of radio waves in a wireless communication system, the output power of a transmitter may be increased, but the transmission power cannot be increased indefinitely. Therefore, a receiver located far from the transmitter may receive a weak signal or cannot receive a transmission signal due to a path loss. In addition, even though the receiver is a short distance from the transmitter, a radio shadow area that is impossible to receive due to the terrain and features of the region where the receiver is located occurs. A repeater is used to remove the radio shadow area. The repeater receives a weak signal transmitted through a transmission path through a reception antenna, and then amplifies the signal of the same frequency and transmits the signal through a transmission antenna.

1 shows a conventional relay system.

In this relay system, however, as shown in FIG. 1, a transmission feedback signal is generated in which part of a signal transmitted through the transmission antenna 1 is re-received as an interference signal through the reception antenna 2, and such a transmission feedback signal is generated. Since the same frequency as the signal received from the other repeater 3 or the base station causes the amplifier to self-oscillate in the process of amplifying and retransmitting the received signal. Since the oscillation of the repeater may operate as a noise source throughout the repeater installation area, it may cause system paralysis. Therefore, when the repeater is used, the repeater oscillation should be prevented.

In order to prevent the repeater oscillation, conventionally, a frequency conversion repeater is used, and the transmission / reception frequency of the frequency conversion repeater has a specific frequency separation, and the frequency separation is performed using a bandpass filter located at the front end of the transmission / reception. It is possible to obtain sufficient isolation between the receiving antennas. However, when using a frequency conversion repeater, there is a disadvantage that can not efficiently use the frequency resources allocated for the service.

On the other hand, the same frequency repeater has an advantage in terms of efficiency of frequency, but because the transmission and reception frequencies are the same, a separate means for obtaining sufficient isolation between the transmission and reception antennas is required.

2 illustrates a relay system including an apparatus for canceling a conventional transmission feedback signal disclosed in Korean Patent 1999-018548.

In the relay system including the conventional transmission feedback signal removing device, as shown in FIG. 2, a transmission signal input from an external transmission system is distributed to transmit a transmission signal of one side to an external transmission antenna 10. In the power distribution unit 20 and the transmission feedback signal removing unit 30 and the transmission antenna 10 for receiving a different transmission signal among the transmission signals distributed by the power distribution unit, delaying for a predetermined time, attenuating the magnitude, and shifting the phase. Power synthesizing means 40 for combining the transmission signal inputted through the external reception antenna 50 and the transmission signal input from the interference canceling means 30 to remove the transmission signal input through the reception antenna 50. It consists of.

However, since the distance between the two antennas is changed according to the installation position of the transmission antenna and the reception antenna, the transmission feedback signal removal device has a disadvantage in that the time delay is adjusted accordingly. However, in order to change the time delay of the RF frequency, it is necessary to adjust the length of the coaxial cable. Therefore, each time a repeater is installed, a time delay is measured and a delay line has to be processed accordingly. In addition, when signal attenuation occurs due to changes in the surrounding environment, it cannot be actively compensated for.

Therefore, the present invention is to solve such a problem, in consideration of the effect of the delay line to remove the transmission feedback signal of a wide frequency range, and the transmission feedback signal removal device that can actively cope with changes in the surrounding environment of the repeater and including the same It is an object to provide a relay system.

1 is a view showing a conventional relay system.

2 is a diagram illustrating a relay system including a device for removing a conventional transmission feedback signal.

3 is a diagram illustrating a relay system including an apparatus for removing a transmission feedback signal according to an exemplary embodiment of the present invention.

4 is a diagram illustrating an embodiment in which a controller is implemented as a digital device in a relay system according to an embodiment of the present invention.

FIG. 5 is a diagram illustrating another embodiment in which a controller is implemented as a digital device in a relay system according to an embodiment of the present invention.

6 is a diagram illustrating a relay system including an apparatus for removing an applied transmission feedback signal from two paths according to another embodiment of the present invention.

*** Description of the symbols for the main parts of the drawings ***

100: transmit antenna 200: receive antenna

301: ID signal generator 305: amplifier

306: first phase shifter 307: first variable attenuator

308: controller 309: first delay line

400: repeater 600: digital controller

In order to achieve the above technical problem, the apparatus for removing a feedback feedback signal according to an aspect of the present invention removes a transmission feedback signal in which a part of a transmission signal of a transmission antenna flows into a reception antenna in a repeater for transmitting and receiving signals in a wireless communication system. An apparatus for removing a transmission feedback signal, comprising: an ID signal generator for generating an ID signal as a reference signal for removing the transmission feedback signal; A signal converter for converting a phase and a magnitude of the sampled signal from the output signal of the repeater; ID signal included in the original signal received by the reception antenna, wherein the ID signal is an ID signal generated by the ID signal generator and transmitted back to the reception antenna through the transmission antenna; and an ID input from the ID signal generator. A controller for comparing the signals and outputting a control signal to the signal converter to minimize an ID signal included in the original signal; And

And a signal combiner for combining the signal converted by the signal converter and the original signal received by the reception antenna to output the signal from which the transmission feedback signal has been removed to the repeater.

The signal converter,

A first phase converter configured to receive an output signal of the controller and adjust a phase of a signal sampled from the output signal of the repeater; And a first variable attenuator receiving the output signal of the controller and adjusting the magnitude of the signal input through the first phase shifter.

In addition, according to an aspect of the present invention, an apparatus for removing a feedback feedback signal includes: a first power divider for distributing power of an ID signal generated by the ID signal generator; A first power combiner for outputting the output signal of the repeater and the output signal of the first power divider to output to the transmission antenna; A second power combiner for sampling the output signal of the repeater; A third power combiner for detecting the ID signal from the signal received by the reception antenna and outputting the ID signal to the controller; And a fourth power combiner which detects the ID signal from the output signal of the signal combiner and outputs the ID signal to the controller.

In addition, a delay time is inserted between the signal combiner and the first variable attenuator, and the signal output through the relay is applied to the signal combiner via the second power combiner, the first phase shifter, and the first variable attenuator. The apparatus may further include a first delay line configured to equalize a delay time applied to the signal combiner through the transmission antenna, the receive antenna, and a third power combiner.

In addition, the amplifier may further include an amplifier inserted between the second power combiner and the first phase shifter to compensate for signal loss through the second power combiner, the first phase shifter, the first variable attenuator, and the first delay line. Can be.

The controller,

Outputs a control signal to the first phase shifter and the first variable attenuator such that a signal passing through the first phase shifter and the first variable attenuator is equal in magnitude to the transmission feedback signal introduced into the reception antenna and is 180 ° out of phase. ,

A first filter receiving the output signal of the first power divider and detecting only an ID signal; A second filter receiving the output signal of the third power combiner and detecting only an ID signal; A third filter receiving the output signal of the fourth power combiner and detecting only an ID signal; A first power detector configured to generate an analog voltage according to the magnitude of an ID signal which is an output signal of the first filter; A second power detector for generating an analog voltage according to the magnitude of an ID signal which is an output signal of the second filter; A third power detector for generating an analog voltage according to the magnitude of an ID signal which is an output signal of the third filter; A first analog to digital (AD) converter for converting an analog voltage output from the first power detector into a digital signal; A first analog to digital (AD) converter for converting an analog voltage output from the second power detector into a digital signal; A third analog to digital (AD) converter for converting the analog voltage output from the third power detector into a digital signal; A controller configured to receive output signals of the first to third AD converters and output control signals of the first phase converter and the first variable attenuator; A first digital to analog (DA) converter for converting the first phase converter control signal output from the controller into an analog signal; And a second DA converter converting the first variable attenuator control signal output from the controller into an analog signal.

In addition, the controller,

A first filter receiving the output signal of the first power divider and detecting only an ID signal; A second filter receiving the output signal of the third power combiner and detecting only an ID signal; A third filter receiving the output signal of the fifth power combiner and detecting only an ID signal; A power detector for generating an analog voltage according to the magnitude of an ID signal which is an output signal of the first to third filters; An analog to digital (AD) converter for converting an analog voltage output from the power detector into a digital signal; A controller which receives an output signal of the AD converter and outputs control signals of the first phase converter and the first variable attenuator; A first digital to analog (DA) converter for converting the first phase converter control signal output from the controller into an analog signal; A second DA converter converting the first variable attenuator control signal output from the controller into an analog signal; And a switch inserted between the first to third filters and the power detector, and configured to transmit an output signal of the first to third filters to the power detector according to a control signal of the controller.

In this case, the signal converter,

A second phase converter configured to receive an output signal of the controller and adjust a phase of a signal input through the second power divider; And a second variable attenuator configured to receive an output signal of the controller and adjust a magnitude of a signal input through the second phase shifter.

Transmission feedback signal removal device according to a feature of the present invention,

A second power divider for distributing power of the output signal of the repeater sampled by the second power combiner and outputting the power to the first phase converter and the second phase converter; And a fifth power combiner for combining the received signal passing through the third power combiner with the signal output through the second variable attenuator, and outputting a signal from which the transmit feedback signal is removed from the received signal to the repeater. do.

In addition, a signal inserted between the fifth power combiner and the second variable attenuator, and the signal output through the relay is passed through the second power combiner, the second power divider, the second phase shifter, and the second variable attenuator. A second delay line configured to equalize a delay time applied to a five power combiner and a delay time applied to the fifth power coupler through the transmission antenna, the reception antenna, and a third power combiner; A sixth power combiner which detects the ID signal from the output signal of the fifth power combiner and outputs the ID signal to the controller; And a signal inserted between the second power combiner and the second power divider, the signal through the second power combiner, the first phase shifter, the first variable attenuator and the first delay line and the second power combiner, the second phase. The apparatus may further include an amplifier configured to compensate for loss of a signal through the converter, the second variable attenuator, and the second delay line.

At this time, the controller,

A control signal is transmitted to the first phase shifter and the first variable attenuator such that a signal passing through the first phase shifter and the first variable attenuator is equal in magnitude and 180 degrees out of phase with a first transmission feedback signal introduced into the reception antenna. The second phase shifter and the second variable such that the signal passing through the second phase shifter and the second variable attenuator are equal in magnitude to the second transmission feedback signal introduced into the reception antenna and have a 180 ° difference in phase. Output a control signal to the attenuator.

According to another aspect of the present invention, a relay system may include: a relay system of a wireless communication system, comprising: a repeater for amplifying a signal received by a reception antenna and transmitting it externally through a transmission antenna; And a transmission feedback signal removing device for removing a transmission feedback signal in which a part of the transmission signal of the transmission antenna of the repeater flows into the reception antenna.

The transmission feedback signal removal device,

An ID signal generator for generating an ID signal which is a reference signal for removing the transmission feedback signal; ID signal included in the original signal received by the reception antenna, wherein the ID signal is an ID signal generated by the ID signal generator and transmitted back to the reception antenna through the transmission antenna; and an ID input from the ID signal generator. A controller for comparing a signal and outputting a control signal for converting a phase and a magnitude of a sampled signal from an output signal of the repeater to minimize an ID signal included in the original signal; A signal converter which receives a control signal from the controller and converts a phase and magnitude of a sampled signal from an output signal of the repeater; And a signal combiner for combining the signal converted by the signal converter and the original signal received by the reception antenna to output the signal from which the transmission feedback signal has been removed to the repeater.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings the most preferred embodiment that can be easily carried out by those of ordinary skill in the art as follows.

3 is a diagram illustrating a relay system including an apparatus for removing a transmission feedback signal according to an exemplary embodiment of the present invention.

As shown in FIG. 3, the apparatus for removing a feedback feedback signal of the present invention generates an ID signal that generates an ID signal, which is a reference signal for detecting the magnitude and phase of a signal fed back from the transmitting antenna 100 to the receiving antenna 200. Generator 301, a first power divider 302 for distributing the output of the ID signal generator 301, a first power combiner for combining the output signal of the repeater 400 with the output signal of the first power divider 302 ( 303), the output signal of the repeater 400 sampled by the second power combiner 304 and the second power combiner 304 that samples a portion of the output signal of the repeater 400 and transmits it to the amplifier 305. The third and fifth power combiners 310 and 312 and the first and second amplifiers 305 to detect the magnitude information of the ID signal from the signal fed back to the receiving antenna 200 and output to the controller 308. The output signal of the power splitter 302 and the output signals of the third and fifth power combiners 310 and 312 are received. The control signals of the controller 308 and the controller 308 outputting control signals for adjusting the first phase shifter 306 and the first variable attenuator 307 to analyze the correlation of these signals to minimize the ID signal. Accordingly, the signal received by the first phase shifter 306, the first variable attenuator 307, and the reception antenna 200 varying the phase and magnitude of the transmission feedback signal and the transmission feedback signal output from the first variable attenuator 307. The fourth power combiner 311 and the first delay line 309 for equally adjusting the time delay of the reception signal and the transmission feedback signal of the receiving antenna 200. 3 illustrates the reception antenna 200, the transmission antenna 100, and the repeater 400 for convenience of description.

Referring to the operation of the transmission feedback signal removal device configured as described above in detail as follows.

The receiving antenna 200 receives the original received signal and the feedback signal of the transmitting antenna 100 at the same time, and the output signal of the receiving antenna 200 is applied to the third power combiner 310. Meanwhile, the output signal of the repeater 400 is sampled by the second power combiner 304, applied to the amplifier 305, amplified by the amplifier 305, and then the first phase converter 306 and the first variable attenuator. It passes through the 307 and the first delay line 309 and the same size as the transmission feedback signal applied to the receiving antenna 200, it is adjusted so that the phase is 180 degrees. In this case, the amplifier 305 outputs the output signal of the repeater 400 through the second power combiner 304, the first phase converter 306, the first variable attenuator 307, and the first delay line. When the loss up to the input to the 311) is greater than the loss up to the input to the fourth power combiner 311 via the transmitting antenna 100 and the receiving antenna 200 serves to compensate for the loss of this signal. .

When the signal having the same magnitude as the transmission feedback signal applied to the reception antenna 200 and having a phase difference of 180 ° is combined with the reception signal including the transmission feedback signal through the fourth power combiner 311, the fourth power combiner ( In 311), only the original signal from which the transmission feedback signal has been removed is output. Therefore, the transmission feedback signal is removed from the signal applied to the fourth power combiner 311 from the receiving antenna 200 and the amplifier 305 at the output of the fourth power combiner 311 and only the original received signal is present.

On the other hand, the controller 308 compares the magnitude of the ID signal input through the third power combiner 310 and the first power divider 302 to monitor the degree of coupling due to environmental changes between the transmitting and receiving antennas. In addition, the controller 308 monitors the degree of removal of the transmission feedback signal by the magnitude of the ID signal input through the fifth power combiner 312, and minimizes the magnitude of the ID signal input through the fifth power combiner 312. The first phase shifter 306 and the first variable attenuator 307 are controlled to be effective. At this time, since the ID signal has a small frequency difference from the original input signal, the ID signal removal amount is similar to that of the transmission feedback signal induced by the reception antenna 200. Therefore, the transmission feedback signal can be eliminated by controlling the first phase shifter 306 and the first variable attenuator 307 so that the magnitude of the ID signal is minimum.

In addition, the signal is induced from the output terminal of the repeater 400 through the second power combiner 304, the first power combiner 303, and the transmit antenna 100 to the receive antenna 200 through the free space, and again. A delay time for the path from the third power combiner 310 to the fourth power combiner 311 and the amplifier 305 through the second power combiner 304 from the output terminal of the repeater 400; First through the first phase shifter 306, the first variable attenuator 307 and the first delay line 309, the delay time for the path to the output to the fourth power combiner 311 is the same It adjusts the delay line 309, which can eliminate the transmission feedback signal over a wide frequency range.

Meanwhile, the controller 308 of FIG. 3 may be implemented as the digital controller 600, which is illustrated in FIG. 4.

As shown in FIG. 4, the digital controller 600 includes first to third filters 601, 611, and 621, first to third power detectors 602, 612, and 622, and first to third A / s. D converters 603, 613, 623, controller 604, and first and second D / A converters 605, 606.

The first filter 601 detects only the ID signal from the output signal of the repeater 400 output through the first power divider 302, and the first power detector 602 detects the ID detected by the first filter 601. Generates an analog voltage based on the magnitude of the signal. The analog voltage generated by the first power detector 602 is converted into a digital signal by the first A / D converter 603, and the controller 604 receives the digital signal output by the first A / D converter 603. Watch.

In addition, the controller 604 is a repeater through an ID signal output from the third power combiner 310 and input through the second filter 611, the second power detector 612, and the second A / D converter 613. To monitor the environmental change, and the ID signal input through the third power detector 622 and the third A / D converter 623 through the fifth power combiner 312 to the third filter 621 is minimum. A control voltage for controlling the first phase shifter 306 and the first variable attenuator 307 is generated to be. The first and second D / A converters 605 and 606 convert the output signal of the controller 604 into an analog signal again.

In this case, in order to detect the ID signal more precisely, each of the power detectors 601, 612, and 622 may be implemented by subdividing into a frequency converter, a filter, and a power detector.

Meanwhile, the digital controller 600 of FIG. 4 may be implemented as shown in FIG. 5.

That is, as shown in FIG. 5, the controller 604 controls the switch 640 so that the output signals of the first to third filters 601, 611, and 621 are sequentially applied to the power detector 632. The number of power detectors 632 and A / D converters 633 may be reduced to one.

The above-described transmission feedback removing device is an example of a device for removing a transmission feedback signal when the frequency characteristic is good, and a time difference between the first transmission feedback signal and the second transmission feedback signal reaching the reception antenna 200 may vary. In this case (a few us), since the magnitude difference between the first transmission feedback signal and the second transmission feedback signal is large, the influence of the second transmission feedback signal can be ignored.

However, although there is a time difference between the second transmission feedback signal and the first transmission feedback signal due to the surrounding environment of the repeater 400, if the difference in signal strength is similar to 10 dB or less, the influence of the second transmission feedback signal cannot be ignored. .

FIG. 6 is an embodiment of a transmission feedback signal removing device for a case where the transmission feedback signal has two independent paths as described above.

In general, different paths mean different time delays. Therefore, in order to eliminate the transmission feedback signal having two independent paths, a phase shifter, a variable attenuator and a delay line for each path are required.

That is, as shown in FIG. 6, the ID signal generator 301 and the ID signal generating an ID signal which is a reference signal for detecting the magnitude and phase of the signal fed back from the transmission antenna 100 to the reception antenna 200. A first power divider 302 that distributes the output of the generator 301, a first power combiner 303 that combines the output signal of the repeater 400 with the output signal of the first power divider 302, and the repeater 400. An amplifier that amplifies the output signal of the repeater 400 sampled by the second power combiner 304 and the sampled output signal of the second power combiner 304 and the second power combiner 304 with a minimum distortion ( 305, a second power divider 312 for distributing the output signal of the amplifier 305, and third and third units for detecting the magnitude information of the ID signal from the signal fed back to the receiving antenna 200 and outputting the magnitude information of the ID signal to the controller 308. 5, and the seventh power combiner 310, 312, 322, the output signal of the first power divider 302 and the third, fifth and seventh The first phase shifter 306, the first variable attenuator 307, and the second phase shifter 316 to receive the output signals of the output couplers 310, 312, 322 and correlate these signals to minimize the ID signal. ) And a controller 308 for outputting a control signal for adjusting the second variable attenuator 317, and a first phase converter 306 for varying the phase and magnitude of the transmission feedback signal according to the control signal of the controller 308. The first variable attenuator 307, the second phase shifter 316, the second variable attenuator 317, and a combination of the signal received by the reception antenna 200 and the transmission feedback signal output from the first variable attenuator 307 4 the power combiner 311 and the received signal of the sixth power combiner 321 and the receiving antenna 200 to combine the signal received by the receiving antenna 200 and the transmission feedback signal output from the second variable attenuator 317 and First and second delay lines for equally adjusting the time delay of the transmission feedback signal ( 309, 319).

Here, the controller 308 compares the magnitudes of the ID signals inputted through the third power combiner 310 and the first power divider 302 to monitor the degree of coupling due to environmental changes between the transmitting and receiving antennas. The removal degree of the transmission feedback signal is monitored by the magnitude of the ID signal inputted through the seventh power combiner 312 and 322. In addition, the first phase converter 306 and the first variable attenuator 307 are controlled to minimize the magnitude of the ID signal input through the fifth power combiner 312, and is input through the seventh power combiner 322. The second phase shifter 316 and the second variable attenuator 317 are controlled to minimize the magnitude of the ID signal.

In addition, the signal is induced from the output terminal of the repeater 400 through the second power combiner 304, the first power combiner 303, and the transmit antenna 100, through the free space, to the receive antenna 200, and again. Delay time for the first path from the third power combiner 310 to the fourth power combiner 311 and the amplifier 305 through the second power combiner 304 from the output terminal of the repeater 400. ), The second power divider 312, the first phase shifter 306, the first variable attenuator 307, and the first delay line 309 after passing through the fourth power combiner 311. Adjust the first delay line 309 so that the delay time for the two paths are the same, and the amplifier 305 through the second power combiner 304 from the delay time for the first path and the output terminal of the repeater 400. The sixth power after passing through the second power divider 312, the second phase shifter 316, the second variable attenuator 317, and the second delay line 319. The controls the second delay line 319, a second delay time for the third path from being output to the stapler unit 321 to be the same. This eliminates the transmission feedback signal over a wide frequency range.

The drawings and detailed description of the invention are merely exemplary of the invention, which are used for the purpose of illustrating the invention only and are not intended to limit the scope of the invention as defined in the appended claims or claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described above, when the transmission feedback signal removing device according to the embodiment of the present invention is used, the transmission feedback signal can be removed to prevent oscillation of the same frequency repeater, thereby having a wide frequency characteristic, thereby increasing the capacity of the entire system. There is.

In addition, since the magnitude and phase of the transmission feedback signal are controlled through the ID signal, it is possible to actively compensate for environmental changes.

Claims (13)

In the transmission feedback signal removing device for removing a transmission feedback signal in which a part of the transmission signal of the transmission antenna is introduced into the reception antenna in the repeater relaying the transmission and reception signal in a wireless communication system, An ID signal generator for generating an ID signal which is a reference signal for removing the transmission feedback signal; A signal converter for converting a phase and a magnitude of the sampled signal from the output signal of the repeater; ID signal included in the original signal received by the reception antenna, wherein the ID signal is an ID signal generated by the ID signal generator and transmitted back to the reception antenna through the transmission antenna; and an ID input from the ID signal generator. A controller for comparing the signals and outputting a control signal to the signal converter to minimize an ID signal included in the original signal; Receiving a control signal from the controller and A signal combiner for combining the signal converted by the signal converting unit with the original signal received by the receiving antenna and outputting a signal from which the transmission feedback signal is removed to the repeater Transmission feedback signal removal device comprising a. The method of claim 1, The signal converter, A first phase converter configured to receive an output signal of the controller and adjust a phase of a signal sampled from the output signal of the repeater; And A first variable attenuator receiving an output signal of the controller and adjusting a magnitude of a signal input through the first phase shifter; Transmission feedback signal removal device comprising a. The method of claim 1, A first power divider for distributing power of the ID signal generated by the ID signal generator; A first power combiner for outputting the output signal of the repeater and the output signal of the first power divider to output to the transmission antenna; A second power combiner for sampling the output signal of the repeater; A third power combiner for detecting the ID signal from the signal received by the reception antenna and outputting the ID signal to the controller; And A fourth power combiner which detects the ID signal from the output signal of the signal combiner and outputs the ID signal to the controller Transmission feedback signal removal device further comprising. The method of claim 3, A delay time inserted between the signal combiner and the first variable attenuator so that a signal output through the relay is applied to the signal combiner via the second power combiner, the first phase shifter, and the first variable attenuator; A first delay line configured to equalize a delay time applied to the signal combiner via a transmit antenna, a receive antenna, and a third power combiner Transmission feedback signal removal device further comprising. The method of claim 3, An amplifier inserted between the second power combiner and the first phase shifter to compensate for signal loss through the second power combiner, the first phase shifter, the first variable attenuator and the first delay line Transmission feedback signal removal device further comprising. The method of claim 2, The controller, Outputs a control signal to the first phase shifter and the first variable attenuator such that a signal passing through the first phase shifter and the first variable attenuator is equal in magnitude to the transmission feedback signal introduced into the reception antenna and is 180 ° out of phase. doing Transmission feedback signal removal device. The method of claim 3, The controller, A first filter receiving the output signal of the first power divider and detecting only an ID signal; A second filter receiving the output signal of the third power combiner and detecting only an ID signal; A third filter receiving the output signal of the fourth power combiner and detecting only an ID signal; A first power detector configured to generate an analog voltage according to the magnitude of an ID signal which is an output signal of the first filter; A second power detector for generating an analog voltage according to the magnitude of an ID signal which is an output signal of the second filter; A third power detector configured to generate an analog voltage according to the magnitude of an ID signal which is an output signal of the third filter; A first analog to digital (AD) converter for converting an analog voltage output from the first power detector into a digital signal; A first analog to digital (AD) converter for converting an analog voltage output from the second power detector into a digital signal; A third analog to digital (AD) converter for converting the analog voltage output from the third power detector into a digital signal; A controller configured to receive output signals of the first to third AD converters and output control signals of the first phase converter and the first variable attenuator; A first digital to analog (DA) converter for converting the first phase converter control signal output from the controller into an analog signal; And A second DA converter converting the first variable attenuator control signal output from the controller into an analog signal Transmission feedback signal removal device comprising a. The method of claim 3, The controller, A first filter receiving the output signal of the first power divider and detecting only an ID signal; A second filter receiving the output signal of the third power combiner and detecting only an ID signal; A third filter receiving the output signal of the fifth power combiner and detecting only an ID signal; A power detector for generating an analog voltage according to the magnitude of an ID signal which is an output signal of the first to third filters; An analog to digital (AD) converter for converting an analog voltage output from the power detector into a digital signal; A controller which receives an output signal of the AD converter and outputs control signals of the first phase converter and the first variable attenuator; A first digital to analog (DA) converter for converting the first phase converter control signal output from the controller into an analog signal; A second DA converter converting the first variable attenuator control signal output from the controller into an analog signal; And A switch inserted between the first to third filters and the power detector and sending an output signal of the first to third filters to the power detector according to a control signal of the controller; Transmission feedback signal removal device comprising a. The method of claim 3, The signal converter, A second phase converter configured to receive an output signal of the controller and adjust a phase of a signal input through the second power divider; A second variable attenuator receiving an output signal of the controller and adjusting a magnitude of a signal input through the second phase shifter; More, A second power divider for distributing power of the output signal of the repeater sampled by the second power combiner and outputting the power to the first phase converter and the second phase converter; and A fifth power combiner for combining the received signal passing through the third power combiner with the signal output through the second variable attenuator, and outputting a signal from which the transmit feedback signal is removed from the received signal to the repeater; Transmission feedback signal removal device further comprising. The method of claim 9, A fifth power coupler inserted between the fifth power combiner and the second variable attenuator, and the signal output through the relay is passed through the second power combiner, the second power divider, a second phase shifter, and a second variable attenuator; A second delay line configured to equalize a delay time applied to the combiner with a delay time applied to the fifth power combiner through the transmission antenna, the reception antenna, and a third power combiner; And A sixth power combiner which detects the ID signal from the output signal of the fifth power combiner and outputs the ID signal to the controller Transmission feedback signal removal device further comprising. The method of claim 10, A signal inserted through the second power combiner, the first phase shifter, the first variable attenuator, and the first delay line and the second power combiner, the second phase shifter inserted between the second power combiner and the second power divider Amplifier for compensating for signal loss through second variable attenuator and second delay line Transmission feedback signal removal device further comprising. The method of claim 9, The controller, A control signal is transmitted to the first phase shifter and the first variable attenuator such that a signal passing through the first phase shifter and the first variable attenuator is equal in magnitude and 180 degrees out of phase with a first transmission feedback signal introduced into the reception antenna. Output A control signal is transmitted to the second phase shifter and the second variable attenuator such that a signal passing through the second phase shifter and the second variable attenuator is equal in magnitude to the second transmission feedback signal introduced into the reception antenna and is 180 ° out of phase. To output Transmission feedback signal removal device. In the relay system of the wireless communication system, A repeater for amplifying a signal received by the reception antenna and transmitting the result to the outside through the transmission antenna; And Transmission feedback signal removal device for removing a transmission feedback signal of a part of the transmission signal of the transmission antenna of the repeater flows into the reception antenna Including; The transmission feedback signal removal device, An ID signal generator for generating an ID signal which is a reference signal for removing the transmission feedback signal; ID signal included in the original signal received by the reception antenna, wherein the ID signal is an ID signal generated by the ID signal generator and transmitted back to the reception antenna through the transmission antenna; and an ID input from the ID signal generator. A controller for comparing a signal and outputting a control signal for converting a phase and a magnitude of a sampled signal from an output signal of the repeater to minimize an ID signal included in the original signal; A signal converter which receives a control signal from the controller and converts a phase and magnitude of a sampled signal from an output signal of the repeater; And A signal combiner for combining the signal converted by the signal converting unit with the original signal received by the receiving antenna and outputting a signal from which the transmission feedback signal is removed to the repeater Relay system comprising a.