KR101051731B1 - Wireless interference elimination repeater and its implementation method - Google Patents

Abstract

The present invention relates to a radio interference cancellation repeater used in a mobile communication system. The wireless interference signal elimination repeater of the present invention estimates an interference channel from a received signal by receiving a signal, generates a virtual interference signal from the estimated interference channel and a signal fed back, and removes the interference signal. It minimizes the possibility of oscillation and reduces the error of interference channel estimation, thus improving the performance of the radio interference elimination repeater.

Wireless interference elimination repeater, interference channel, interference signal,

Description

Wireless interference elimination repeater and its implementation method {MOBILE ICS REPEATER AND MATERIALIZING METHOD FOR THE SAME}

The present invention relates to a radio interference cancellation repeater used in a mobile communication system.

In general, in the mobile communication system, a repeater is installed to cover a radio shading area in which a base station installation cost is burdened, thereby satisfying the service quality of the mobile communication in the corresponding area.

Therefore, the repeater is connected to the base station to substantially extend the cell radius of the base station, which is divided into a wired repeater and a wireless repeater according to the connection method with the base station.

The wired repeater can maintain good call quality because the communication between the repeater and the base station is wired, but the installation cost or equipment is expensive compared to the wireless repeater, so the lease cost is considerable.

On the other hand, since the wireless repeater communicates wirelessly between the repeater and the base station, the call quality is lower than that of the wired repeater, but the installation and operation costs are low. Therefore, if a wireless repeater is installed in a narrow space where electromagnetic waves are shielded by the structure, such as the basement inside a building, it can be utilized more appropriately than an expensive wired repeater.

However, if the wireless repeater is installed in an open area, such as the inside of a building, a part of the transmission signal output through the transmission antenna of the wireless repeater may be fed back to the reception antenna and mixed with the original signal. When the radio repeater oscillates due to the interference of the signal mixed with the feedback signal and the original signal, it becomes difficult for the radio repeater to provide a normal service, and in the worst case, may cause a failure of the base station. Because of this problem, wireless repeaters have been used only in limited places, such as the basement inside buildings where signal interference does not occur well.

However, the advantages of the wireless repeater that the installation and operation cost is cheaper than the wired repeater is still a big attraction, and the technology to remove the interference of the feedback signal has emerged, and thus can eliminate the interference of the feedback signal. The wireless repeater to which the present technology is applied is called a wireless interference signal cancellation repeater or an interference cancellation system (ICS) repeater.

Figure 1 shows a block diagram of a conventional wireless interference signal cancellation repeater, the conventional wireless interference signal removal repeater is a donor antenna 10, the receiver 20, the digital converter 30, the interference signal cancellation unit ( 40, an analog converter 50, a transmitter 60, and a service antenna 70.

The donor antenna 10 receives the RF signal from the base station and outputs it to the receiver 20.

The receiver 20 receives a signal received from the donor antenna 10, amplifies, downconverts, and filters the output signal to the service antenna 70.

The digital converter 30 converts the analog signal output from the receiver 20 into a digital signal and outputs the digital signal.

The interference signal removing unit 40 removes the interference signal by adding the reverse phase of the interference signal and the digital signal converted by the digital conversion unit 30, and the filter tap estimator 46, the interference signal generator 42, and the interference signal canceller And (42).

The filter tap estimator 46 receives a signal output from the interference signal canceller 40, and estimates the coefficient of the interference channel using the adaptive signal such as an LMS or RLS algorithm.

The interference signal generator 42 receives a signal output from the interference signal remover 40 and generates a virtual interference signal using the input signal and the coefficient of the interference channel estimated by the filter tap estimator 46. In this case, when the generated virtual interference signal is ideal, it is the same as the signal input through the actual interference channel.

The interference signal remover 42 generates an antiphase signal of the interference signal generated by the interference signal generator 42, and removes the interference signal by adding the generated antiphase signal and the signal input through the digital converter 30. .

The analog converter 50 converts the signal from which interference is removed through the interference signal remover 40 and outputs the analog signal.

The transmitter 60 up-converts, filters, and amplifies the analog signal converted by the analog converter 50 and outputs the same to the service antenna 70.

The service antenna 70 receives a signal from the transmitter 60 and transmits the signal to the terminal.

Since the adaptive filter algorithm used in the conventional wireless interference canceling repeater as described above finds an optimal solution while continuously accumulating past values to estimate the coefficient of the interference channel, a constant convergence is needed to estimate an accurate interference channel. I need time.

However, if a very large interference signal is input within the convergence time for estimating the correct interference channel, the interference cancellation repeater may oscillate without estimating the interference channel coefficient, and if the interference channel changes faster than the algorithm convergence time, radio interference may occur. The signal-rejection repeater may oscillate without estimating the interference signal.

In addition, the adaptive filter algorithm has a limitation in the performance of the radio interference elimination repeater because it is impossible to estimate the interference channel coefficients even after the convergence time, since the adaptive filter algorithm has a constant error.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a wireless interference signal removing repeater which can reduce oscillation possibility.

In order to achieve this object, in one aspect of the present invention, a wireless interference signal removing repeater includes: a receiving unit for receiving a signal; An interference signal removing unit for removing the interference signal from the signal received by the receiving unit; And a transmitter for transmitting a signal from which the interference signal has been removed from the interference signal remover. The interference signal canceller may include estimating an interference channel from the received signal and generating a virtual interference signal using the estimated interference channel and the signal output from the interference signal remover to remove the interference signal. It features.

The interference signal canceller may include: an interference channel estimator estimating an interference channel from an input signal; A filter tap generator configured to configure a filter tap for estimating an interference signal based on the interference channel estimated by the interference channel estimator; An interference signal generator configured to generate a virtual interference signal using the filter tap configured in the filter tap generator; And an interference signal canceller for generating an antiphase signal of the interference signal from the virtual interference signal generated by the interference signal generator to remove the interference signal. Characterized in that it comprises a.

In this case, the interference channel estimator may include synchronization means for obtaining synchronization of an input signal; Interference channel analysis means for analyzing an interference channel in an input signal; And multipath selection means for estimating an interference channel by extracting a component having high reliability from the interference channel component analyzed by the interference channel analysis means. Characterized in that it comprises a.

In addition, in order to achieve the above object, in one aspect of the present invention, a method for implementing a wireless interference signal removing repeater includes: a receiving step of receiving a signal; An interference channel estimating step of estimating an interference channel in the received signal; A filter tap generating step of generating a filter tap necessary for estimating an interference signal based on the interference channel estimated in the interference channel estimating step; An interference signal generation step of generating a virtual interference signal using the filter tap configured in the filter tap configuration step; An interference signal removing step of removing the interference signal by using an inverse phase of the interference signal generated in the interference signal generation step; And transmitting a signal from which the interference signal has been removed through the interference signal removing step. Characterized in that it comprises a.

The interference signal estimating step may include: a synchronization step of obtaining synchronization of an input signal; An interference channel analysis step of analyzing an interference channel in an input signal; And a multipath selecting step of estimating an interference channel by extracting a component having high reliability from the interference channel component analyzed in the interference channel analysis step. Characterized in that it comprises a.

As described above, according to the present invention, it is possible to minimize the possibility of oscillation of the wireless interference signal elimination repeater by estimating the interference channel from the input signal at once, and to reduce the error of the interference channel estimation. There is an effect that can be improved.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

<Description of Configuration>

Figure 2 shows a block diagram of a wireless interference signal cancellation repeater 100 according to an embodiment of the present invention, Figure 3 shows a block diagram of the interference channel estimator 148 of the present invention, the present invention The wireless interference signal removing repeater 100 may include a donor antenna 110, a receiver 120, a digital converter 130, an interference signal remover 140, an analog converter 150, a transmitter 160, and a service antenna. It consists of 170.

The donor antenna 110 receives the RF signal from the base station side and outputs the RF signal to the receiver 120.

The receiver 120 receives a signal received from the donor antenna 110, amplifies, down-converts, and filters the output signal to the service antenna 170.

The digital converter 130 converts the analog signal output from the receiver 120 into a digital signal and outputs the digital signal.

The interference signal removing unit 140 removes the interference signal by adding the inverse phase of the interference signal and the digital signal converted by the digital converter 130, and the interference channel estimator 148, the filter tap generator 146, and the interference signal generator 142 and the interference signal canceller 142.

The interference channel estimator 148 inputs the digital signal converted by the digital converter 130 to estimate the interference channel, and performs the synchronization means 148a, the interference channel analysis means 148b, and the multipath selection means 148c. It is configured to include.

The synchronization means 148a receives a digital signal converted by the digital conversion unit 130 to obtain synchronization of the input signal.

The interference channel analyzing unit 148b analyzes the size, phase and delay time of the interference channel using a pilot channel included in the signal input through the synchronization unit 148a.

The multipath selecting unit 148c inputs the signal analyzed by the interference channel analyzing unit 148b, extracts a high reliability component among the interference channel components of the input signal, and estimates the interference channel.

The filter tap generator 144 generates a filter tap to be used for interference signal estimation based on the interference channel estimated by the interference channel estimator 148.

The interference signal generator 142 is fed back with a signal output from the interference signal remover 140, and performs FIR filtering on the input reference signal using the filter tap generated by the filter tap generator 144. Next, a virtual interference signal is generated. In this case, when the generated virtual interference signal is ideal, it is the same as the signal input through the actual interference channel.

The interference signal remover 142 inputs a virtual interference signal generated by the interference signal generator 142 to generate an antiphase signal of the interference signal, and generates the antiphase signal and the signal input through the digital converter 130. Add to remove the interference signal.

That is, the signal output from the digital converter 130 obtains the signal synchronization, accurately estimates the interference channel using a pilot channel, etc., analyzes the estimated interference channel information, generates a filter tap, and generates the generated filter tap. Estimate the interference signal using. Therefore, when the interference channel is directly estimated as described above, there is an advantage that the possibility of oscillation of the wireless interference signal removing repeater 100 can be reduced and the performance can be improved.

The analog converter 150 converts the signal from which interference is removed through the interference signal remover 140 and outputs the analog signal.

The transmitter 160 up-converts, filters, and amplifies the analog signal converted by the analog converter 150 and outputs the same to the service antenna 170.

The service antenna 170 receives a signal from the transmitter 160 and transmits the signal to the terminal.

<Description of the method>

In order to explain the method for implementing the wireless interference signal elimination repeater 100 of the present invention, it will be described with reference to the flowchart shown in FIG.

1) Receive step <S401>

The RF signal received by the donor antenna 110 is input to the receiver 120, amplified and downconverted into an IF signal, and then filtered and output to the service antenna 170.

2) Digital conversion step <S402>

The analog signal having passed through step S401 is input to the digital conversion unit 130, converted into a digital signal, and output.

3) Synchronization stage <S403a>

The signal converted into the digital signal through step S402 is input to the synchronization means 148a of the interference channel estimator 148. At this time, the synchronization means 148a acquires synchronization of the input signal.

4) Interference channel analysis step <S403b>

As the signal passed through step S403a, the pilot channel included in the signal is used in the interference channel analyzing unit 148b, and the size, phase, delay time, and the like of the interference channel are analyzed.

5) Multipath selection step <S403c>

The signal analyzed in step S403b is input to multipath selection means 148c. At this time, the multipath selecting means 148c extracts a component having high reliability from the interference channel components of the input signal and estimates the interference channel.

In the above, steps S403a to S403c are steps performed by the interference channel estimator 148.

6) Filter tab creation step <S404>

The signal passed through step S403c is input to the filter tap generator 144. At this time, the filter tap generator 144 generates a filter tap to be used for the interference signal estimation based on the interference channel estimated in step S403c from the input signal.

7) Interference signal generation step <S405>

Two signals are input to the interference signal generator 142, and a signal through which the signal output from the digital converter 130 and the signal output through the interference signal remover 142 is fed back is input. The FIR filter is generated using the filter tap generated through the step S404 using the feedback signal passed through the interference signal remover 142 as a reference signal to generate a virtual interference signal. In this case, when the generated virtual interference signal is ideal, it is the same as the signal input through the actual interference channel.

8) Step of removing interference signal <S406>

The virtual interference signal generated in step S405 is input to the interference signal canceller 142, and an antiphase signal is generated, and the interference signal is generated from the signal passed through step S402 by combining the generated antiphase signal with the signal that passed through step S402. Removed.

In the above, steps S403a to S406 are steps performed by the interference signal removing unit 140.

9) Analog conversion step <S407>

The digital signal from which the interference signal is removed during step S406 is converted into an analog signal and output.

10) Transmission step <S408>

The analog signal having passed through step S407 is up-converted, filtered, and amplified and output to the terminal through the service antenna 170.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

1 is a block diagram of a conventional radio interference canceling repeater.

2 is a block diagram of a wireless interference signal removing repeater according to an embodiment of the present invention.

3 is a block diagram of an interference signal estimator of the present invention.

4 is a flowchart illustrating a method for implementing a radio interference cancellation relay of the present invention.

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

100: wireless interference canceling repeater

110: donor antenna 120: receiver

130: digital conversion unit

140: interference signal removing unit

142: interference signal canceller 144: interference signal generator

146: Filter Tab Generator

148: interference channel estimator

148a: synchronization means 148b: interference channel analysis means

148c: multipath selection means

150: analog converter

160: transmitter 170: service antenna

Claims (5)

Receiving unit for receiving a signal; An interference signal removing unit for removing the interference signal from the signal received by the receiving unit; And A transmitter for transmitting a signal from which the interference signal is removed from the interference signal remover; Including, The interference signal removing unit, And estimating an interference channel from the input signal, generating a virtual interference signal using the estimated interference channel and the signal output from the interference signal canceller, and removing the interference signal. The method of claim 1, The interference signal removing unit, An interference channel estimator for estimating an interference channel from an input signal; A filter tap generator configured to configure a filter tap for estimating an interference signal based on the interference channel estimated by the interference channel estimator; An interference signal generator configured to generate a virtual interference signal using the filter tap configured in the filter tap generator; And An interference signal canceller for generating an inverse phase signal of the interference signal from the virtual interference signal generated by the interference signal generator to remove the interference signal; Wireless interference signal removal repeater comprising a. The method of claim 2, The interference channel estimator, Synchronization means for obtaining synchronization of an input signal; Interference channel analysis means for analyzing an interference channel in an input signal; And Multipath selection means for estimating an interference channel using the interference channel component analyzed by the interference channel analysis means; Wireless interference elimination repeater comprising a. A receiving step of receiving a signal; An interference channel estimating step of estimating an interference channel in the received signal; A filter tap generating step of generating a filter tap necessary for estimating an interference signal based on the interference channel estimated in the interference channel estimating step; An interference signal generation step of generating a virtual interference signal using the filter tap configured in the filter tap configuration step; An interference signal removing step of removing the interference signal by using an inverse phase of the interference signal generated in the interference signal generation step; And A transmitting step of transmitting a signal from which the interference signal has been removed through the interference signal removing step; Wireless interfering signal removing repeater implementation method comprising a. 5. The method of claim 4, The interference signal estimating step, A synchronization step of obtaining synchronization of an input signal; An interference channel analysis step of analyzing an interference channel in an input signal; And A multipath selection step of estimating an interference channel using the interference channel component analyzed in the interference channel analysis step; Wireless interfering signal removing repeater implementation method comprising a.

Images