KR20110007481A - Apparatus and method for feedback interference cancellation in a wireless repeater - Google Patents

Abstract

PURPOSE: A wireless repeater with a feedback interference cancelling device and a method thereof are provided to increase quality of a signal by cancelling a feedback interference in a communication system using the same frequency band. CONSTITUTION: A frequency down converter(120) converts a band of an amplified signal into an IF(Intermediate Frequency) band. An ADC(Analog to Digital Converter)(130) converts the down-converted analog signal into a digital signal. A feedback interference cancelling device(140) cancels a feedback interference signal in the digital signal. A DAC(Digital to Analog Converter)(150) converts the feedback interference signal cancelled signal into an analog signal.

Description

Wireless repeater with feedback interference cancellation device and feedback interference cancellation method {Apparatus and method for feedback interference cancellation in a wireless repeater}

The present invention relates to a wireless repeater having a feedback interference cancellation device and a feedback interference cancellation method, and more particularly, a signal transmitted to a transmission antenna in a wireless relay system using the same channel is fed back to a reception antenna to interfere with an original signal. The present invention relates to a radio repeater and a feedback interference cancellation method including a feedback interference cancellation device for removing feedback interference with an adaptive filter.

1 is a reference diagram for explaining a general wireless repeater system. A wireless repeater receives an original signal from a base station using a reception antenna, amplifies the signal, and then transmits the signal to a transmission antenna. Reflected on the path or surrounding environment, it is fed back to the receiving antenna through multipath and acts as an interference to the original signal.

The wireless repeater has the advantages of freely selecting the installation location, easy maintenance and repair, low maintenance cost because there is no line cost, and frequency reuse.

Since the radio repeater uses the same frequency as the received signal and the transmitted signal, the signal radiated from the transmitting antenna is fed back to the receiving antenna and acts as an interference to the original signal, so that the receiving antenna should be sufficiently isolated from the transmitting antenna. Otherwise, the feedback signal is added to the original signal, which degrades the performance of the radio repeater and causes oscillation.

2 shows a feedback signal having a direct path between a transmitting antenna and a receiving antenna and multipaths by various objects.

In order to solve the above problems, a feedback interference cancellation device is used in a wireless repeater. The removal method is to reduce the received signal to an intermediate frequency and convert it to digital to remove the feedback interference signal through digital signal processing using an adaptive filter. As the adaptive filter, many algorithms of the LMS (Least Mean Squares) series, which have a relatively small calculation amount and relatively stable characteristics, are used.

The LMS algorithm updates the filter coefficient value using the step size, and the convergence time and the convergence error show a big difference according to the step size, and the place where the wireless repeater is installed is installed in various environments such as downtown, roadside, suburbs, and indoors. Multipath fading caused by various features, Doppler generated by people, vehicles, etc., changes the channel experienced by the feedback signal rapidly.If the step size is large, the filter coefficient value changes according to the rapidly changing channel, but the convergence error is increased. Larger and smaller step sizes do not follow the rapidly changing channel and diverge.

The channels experienced by the feedback signals do not change together, but the feedback signals change little by fixed objects such as buildings, and the feedback signals by vehicles change rapidly. That is, all the feedback signals have different degrees of channel change. .

Another problem is that the filter coefficient value gradually increases, and all signals used in the wireless repeater have their own bandwidth, and all the energy is concentrated in the band. The filter coefficient value gradually increases, resulting in poor performance.

In order to solve the above problems, the present invention measures the correlation according to the filter tap and applies the independent step size to all the filter taps, thereby increasing the estimation speed and reducing the estimation error, thus making it robust even at high Doppler frequencies. It is an object of the present invention to provide a radio repeater and a feedback interference canceling method including a feedback interference removing device capable of effectively removing feedback signals.

A configuration for achieving the object includes a low noise amplifier for linearly minimizing the noise of the signal received by the reception antenna, a frequency down converter for downconverting the amplified signal from the radio frequency to the intermediate frequency band, and the downconverted An analog / digital converter for converting an analog signal into a digital signal, a feedback interference canceller for removing a feedback interference signal included in the converted digital signal, and a digital converter for converting an original signal from which the feedback interference signal has been removed to an analog signal And an analog converter, a frequency up converter for upgrading the analog signal to a radio frequency band, and a power amplifier for amplifying the signal such that the uplinked signal is transmitted through a transmission antenna.

As a method for achieving the object, a tenth step of linearly amplifying a signal received by a reception antenna with a minimum of noise in a low noise amplifier, and amplifying the signal from a radio frequency to an intermediate frequency band through a frequency down converter A 20th step of converting, a 30th step of converting an analog signal down-converted by an analog / digital converter into a digital signal, and a 40th step of removing the feedback interference signal included in the digital signal in the feedback interference canceller; A fifty step of converting the original signal from which the feedback interference signal has been removed into an analog signal in a digital / analog converter; amplifying the signal in a power amplifier after the analog signal is raised from a frequency upconverter to a radio frequency band; The sixth step of transmitting to.

As described above, the present invention improves the signal quality by eliminating feedback interference in a communication system using the same frequency band, and transmits the signal at a high output from the repeater. There is an effect that the restrictions on the design can be freely selected and the installation can be simplified.

In addition, since signal output is possible, the cell coverage can be easily expanded, and the feedback interference cancellation method is all digital, which is advantageous for miniaturization, and the algorithm can be easily changed and expanded to improve system performance.

3 is a unidirectional link embodiment of a wireless repeater including a feedback interference cancellation apparatus according to the present invention, FIG. 4 is a bidirectional link embodiment of a wireless repeater including a feedback interference cancellation apparatus according to the present invention, and FIG. 6 is a block diagram showing the detailed configuration of the feedback interference cancellation apparatus according to the invention, Figure 6 is a block diagram showing the configuration of the interference cancellation unit of the feedback interference cancellation apparatus according to the present invention, Figure 7 is a feedback interference cancellation apparatus according to the present invention 8 is a flowchart illustrating a feedback interference method of a wireless repeater provided, and FIG. 8 is a view illustrating an abnormality of an adaptive filter when implementing interference cancellation according to the present invention, and FIG. 9 is a photograph of a feedback interference cancellation device according to the present invention. Reference is shown.

Hereinafter, the components will be described with reference to the drawings.

3 is a unidirectional link embodiment of the wireless repeater 100 including the feedback interference cancellation device 140 of the present invention, the wireless repeater 100 is a linear by minimizing the noise of the signal received by the receiving antenna 101 A low noise amplifier 110 for amplifying, a frequency down converter 120 for downconverting the amplified signal from a radio frequency to an intermediate frequency band, and an analog / digital converter 130 for converting the downconverted analog signal into a digital signal ), A feedback interference canceller 140 for removing the feedback interference signal included in the converted digital signal, a digital-to-analog converter 150 for converting the original signal from which the feedback interference signal is removed to an analog signal, A frequency upconverter 160 for upgrading the analog signal to a radio frequency band and a signal such that the uplinked signal is transmitted through a transmission antenna 103 It consists of a power amplifier 170 for amplification.

The frequency downconverter 120 may not be used if the frequency of the original signal is low enough to be digitally processed. The frequency downconverter 120 does not lower the intermediate frequency band from the radio frequency band, but directly the baseband of the frequency downconverter 120. You can also convert the frequency with.

4 is a bi-directional link embodiment of the wireless repeater 100 including the feedback interference canceller 140 of the present invention, and both ends are provided with a transmit / receive antenna 105 to receive a signal received at one end of the transmit / receive antenna 105. Is a duplex 107, a low noise amplifier 110, a frequency down converter 120, an analog / digital converter 130, a feedback interference canceller 140, a digital / analog converter 150, a frequency up converter 160 Then, the power amplifier 170 is transmitted via the duplex 107 and the transmission and reception antenna 105 at the other end.

5 is a block diagram showing a detailed configuration of the feedback interference cancellation device 140, the feedback interference removal device 140 is a band pass filter 141 to cut the frequency band of the original signal to remove interference, Feedback interference is achieved through the digital downconverter 142, which lowers the frequency of the signal to the baseband, and a variable step size Normalized Least Mean Squares (NLMS) filter using the correlation between the baseband inphase / quadrature (I / Q) signals. The feedback interference canceller 143 is removed, and the digital up-converter 144 converts and outputs data of an intermediate frequency band.

Many communication systems use a communication method using multiple frequency assignments (FA). In the present invention, a signal is sampled in an intermediate frequency band, separated by a band pass filter 141 for each FA, and then a digital down converter ( The feedback interference elimination unit 143 removes the feedback interference by lowering the frequency to the baseband, but the frequency is reduced to the baseband by seeing several FAs as one signal without separating each FA, and the feedback interference elimination unit 143 ), The interference is removed in the same manner, and the feedback interference canceller 143 may be configured using only the real signal in the intermediate frequency band without lowering the signal to the baseband and changing to I / Q.

FIG. 6 is a block diagram illustrating a feedback interference canceller 143 of the feedback interference canceller 140. The feedback interference canceller 143 includes a power measurement unit 210, a calculation unit 220, and an adaptive filter. 230, a step size adjustment unit 240, a correlation measurer 250, a low pass filter 260, and a memory unit 270.

The power measuring unit 210 measures the average power of the input signal coming into the feedback interference removing unit 143, and ∥u _i ∥ ² of Equation 1 and Equation 2 below is applied to the adaptive filter 230. The signal is normalized by the mean energy of the input vector.

The operation unit 220 removes the estimated feedback interference signal generated by the adaptive filter 230 from the input signal, removes the interference, and outputs the interference to the low pass filter 260.

The adaptive filter 230 determines a filter coefficient value according to a coefficient update equation of a normalized least mean squares (NLMS) filter by using the step size of the vector form determined by the step size adjusting unit 240, and stores the filter coefficient value in the memory unit 270. The estimated output interference signal is generated by multiplying the previous output signal by the coefficient value.

The step size adjustment unit 240 generates a step size vector to be used in the adaptive filter 230. In general, the adaptive filter 230 updates a coefficient value of the filter using a single step size constant. A step size for updating the coefficients is generated in a vector form in which different step sizes are applied to each filter tap according to the correlation.

The correlation measurer 250 analyzes feedback interference by measuring a correlation between an input signal and stored output signals, and measures a correlation between output signals stored in the memory unit 270. The correlation is sent to the step size adjusting unit 240 and used to determine the step size, and the correlation measuring unit 250 includes the correlation between the input signal and the output signals stored in the memory unit 270 and the current output signal and the memory unit ( The abnormality of the adaptive filter 230 is measured using the correlation with the output signals stored in the 270.

The low pass filter 260 is designed according to the bandwidth of the original signal and passes the signal, where the low pass filter 260 appears in response to the repeated use of the feedback signal in addition to the general role of reducing the noise level outside the pass band. It serves to prevent the problem of noise increase of a specific frequency and the problem that the coefficient value of the adaptive filter 230 gradually increases with time.

The memory unit 270 stores signals from which interference is removed, which is the final output of the feedback interference canceller 143, and the output of the feedback interference canceller 143 is transmitted to the transmission antenna 103 by the digital up-converter 144. The system delays up to, the propagation delay from which the signal is fed back from the transmitting antenna 103 to the receiving antenna 101 through the wireless channel, and the system delay from the receiving antenna 101 to the feedback interference canceller 143. Will be fed back.

In addition, the memory unit 270 may store an output signal having a long time, but in the adaptive filter 230, since an increase in arithmetic amount and accumulation of arithmetic error that occur as the filter tap increases, the memory cannot be ignored. The unit 270 selects a start position of a data window to be used for the adaptive filter 230 according to the result of the minimum delay time and the correlation measurer 250, and a correlation diagram of a specific size or more after the minimum delay time. The position of the data window is set with a slight margin at the position where is shown, and the current output of the feedback interference cancellation unit 143 and the output data in the data window are adaptive filter 230, step size adjustment unit 240, correlation degree. It is transmitted to the measuring unit 250.

7 is a flowchart illustrating a feedback interference method of the wireless repeater 100 having the feedback interference removing device 140 according to the present invention, in which a signal received by the reception antenna 101 minimizes noise in the low noise amplifier 110. A tenth step (S10) of linearly amplifying the signal, a twenty step (S20) of converting the frequency of the amplified signal from a radio frequency into an intermediate frequency band through the frequency down converter 120, and an analog / digital converter ( A 30 th step S30 of converting the down-converted analog signal into a digital signal in step 130; a 40 th step S40 of removing the feedback interference signal included in the digital signal from the feedback interference elimination device 140; A 50th step S50 of converting the original signal from which the feedback interference signal has been removed to an analog signal from the digital / analog converter 150, and converting the analog signal from the frequency up converter 160 to the radio frequency band. After which the up-amplifies the signal to the power amplifier 170 includes a first step 60 (S60) to be transmitted by the transmitting antenna 103.

In step S40, when the signal of the intermediate frequency band enters the feedback interference elimination device 140 as digital data through the analog-to-digital converter 130, the band pass filter 141 as much as the frequency band of the original signal to remove the interference. A 41 th step (S41), a 42 th step (S42) of lowering the frequency of the signal from the digital down-converter 142 to the base band, and an I / Q (Inphase / Quadrature) signal of the base band The feedback interference cancellation unit 143 removes the feedback interference through the variable step size NLMS filter using the correlation, in step 43 (S43), and removes the interference signal from the digital up-converter 144. In step S44, the data is converted into data of an intermediate frequency band and output.

FIG. 8 illustrates the power measurement result of the input and output signals, the input signal and the stored output signal in determining whether the adaptive filter 230 operates normally when implementing the variable step size NLMS algorithm using the correlation according to the present invention. An embodiment of identifying an abnormality when implementing interference cancellation using a correlation between the embodiments.

The power measuring unit 210 measures the average power of the input signal and the output signal, but the method of eliminating feedback interference by the NLMS algorithm uses a correlation function between the autocorrelation function of the stored output signal and the input signal and the stored output signal. By removing a signal having a correlation with the stored output signal from the input signal, the energy of the output signal minus the estimated feedback signal from the input signal is minimized.

If the signal itself is random, the portion of the input signal that is not related to the stored output signal cannot be removed, and as the output signal is smaller, it is determined that the feedback signal is removed from the input signal, so that the adaptive filter 230 converges. If it is, the average power of the output signal should be smaller than the average power of the input signal, and if the output signal is larger, it is determined that the adaptive filter 230 does not converge, and the power measuring unit 210 averages the input signal and the output signal. Accurately measuring the power allows you to measure the power of the feedback signal and monitor the channel.

The correlation measurer 250 obtains a correlation between the input signal and the stored output signal, estimates the magnitude and position of the feedback signal in the input signal with the correlation, and uses the adaptive filter ( 230, the starting position can be determined, and the position having the most correlation within the filter length can be selected as the starting position. In general, the feedback signal experiences a system delay and is located between the transmitting antenna 103 and the receiving antenna 101. The starting position of the filter is fixed because it propagates through the direct path of.

The correlation measurer 250 also obtains a correlation between the current output signal and the stored output signal. The correlation indicates the magnitude and position of the feedback signal that the feedback interference canceller 143 does not remove. Is used by the step size adjustment unit 240 to determine the independent step size for each filter tap, and if the adaptive filter 230 converges, the correlation between the output signal and the stored output signal is greater than the correlation between the input signal and the stored output signal. If the correlation between the current output signal and the stored output signal is very small, but the correlation between the current output signal and the stored output signal is very small, but the correlation between the current output is a little larger, this is an error due to quantization error. If the correlation with the current output is greater, it may be determined that the adaptive filter 230 is not converging there.

9 shows a reference picture of the feedback interference cancellation device 140 according to the present invention.

The feedback signal is also fed back into the direct path between the transmitting antenna 103 and the receiving antenna 101, and has a multipath by a fixed object such as a building, a mountain or the ground, and a moving object such as a person or a vehicle. As it enters the reception antenna 101, the channel experienced by the feedback signal by the direct path and the fixed object is changed slowly, and the channel experienced by the moving object is not only changed rapidly but also the delay time is changed.

In the present invention, in order to solve the above problem, the step size used to update the channel coefficient is independently applied to every filter tap, and the feedback signal is that the transmitted signal undergoes the channel and is added to the original signal. As a small portion of the adaptive filter 230 converges, the feedback signal is removed, thereby lowering the correlation. The portion having a large channel change does not remove all the feedback, so the correlation remains high.

Using this characteristic to measure the correlation, the low correlation filter tap applies a small step size to reduce the step error, and the high correlation filter tap applies a large step size to adapt to the channel. While showing speed, it may have a small convergence error, and is particularly robust in a feedback signal having a high Doppler frequency, which causes oscillation in the interference canceling wireless repeater 100.

Correlation measurement is obtained by using an output signal stored in the memory unit 270 connected to the output of the feedback interference elimination device 140, the residual feedback signal that cannot be removed when the correlation between the current output and the previous output is obtained The amount of can be obtained, and the output unit has a memory unit 270 to store the output signal, and is used as a reference signal to the correlation measurer 250, the step size adjusting unit 240, and the adaptive filter 230, and the feedback interference. The cancellation unit 140 may have only one ADC and one DAC, and digitally configure all interference cancellation.

The variable step size NLMS (Normalized Least Mean Square) using the correlation with the above characteristics is an improvement of the conventional LMS (Least Mean Square), and LMS is an adaptive algorithm using the steepest descent (FIR). It has been widely used in various applications such as an adaptive interference canceller using an impulse response filter, and the LMS has a simple formula and a small amount of computation, which is easy to apply in real time, and shows a relatively simple and stable convergence characteristic.

Equation 1 below is an NLMS filter coefficient update equation in which the convergence characteristic is improved by normalizing the step size μ of the LMS with the signal power.

Where μ is a step size of NLMS and is a constant that determines convergence speed and convergence error.As the value of μ increases, convergence speed increases but convergence error increases, while when μ value decreases, convergence speed decreases but convergence error decreases. If the convergence error is large, the desired interference cancellation performance cannot be obtained. If the convergence speed is low, convergence is diverged in a time-varying channel environment.

In order to compensate for the above problems, the variable step size μ, which converges quickly to a large step size when the channel changes rapidly, and reduces the convergence error to a small step size when the channel changes slowly, is represented by Equation 2 below.

Since the step size used in the LMS is a scalar value, but the coefficients of the filter are in the form of a vector, the coefficients are updated by multiplying all the filter coefficients by the same step size, and thus, an optimal step size cannot be used for each coefficient. In order to improve the convergence speed, the filter coefficient value of the filter is updated by changing the step size into a vector using a correlation between the input signal and the output signal of the adaptive filter 230, and β in Equation 2 is the phase difference and the signal. The vector is determined by the characteristics of.

Therefore, the present invention measures the correlation according to the filter tap and applies the independent step size to all the filter taps to increase the estimation speed, reduce the estimation error, and are robust even at high Doppler frequencies, and effectively remove the feedback signal. It is an object of the present invention to provide a wireless repeater and a feedback interference cancellation method provided with a feedback interference cancellation device.

Although the present invention has been shown and described with respect to specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Anyone who can afford it will know.

1 is a reference diagram for explaining a general wireless repeater system.

2 is a reference diagram for explaining a general feedback interference.

Figure 3 is a one-way link embodiment of a wireless repeater including a feedback interference cancellation apparatus according to the present invention.

Figure 4 is a bidirectional link embodiment of a wireless repeater including a feedback interference cancellation apparatus according to the present invention.

5 is a block diagram showing the detailed configuration of the feedback interference cancellation apparatus according to the present invention.

Figure 6 is a block diagram showing the configuration of the interference cancellation unit of the feedback interference cancellation apparatus according to the present invention.

7 is a flow chart showing a feedback interference method of a wireless repeater equipped with a feedback interference cancellation apparatus according to the present invention.

8 is an embodiment of identifying the abnormality of the adaptive filter when implementing interference cancellation according to the present invention.

Figure 9 is a reference diagram showing a photograph of the feedback interference cancellation apparatus according to the present invention.

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

100: wireless repeater 101: receiving antenna

103: transmit antenna 105: transmit and receive antenna

107: duplex 110: low noise amplifier

120: frequency down converter 130: analog to digital converter

140: feedback interference cancellation device 141: band pass filter

142: digital down converter 143: feedback interference canceller

144: digital up converter 150: digital to analog converter

160: frequency up converter 170: power amplifier

210: power measurement unit 220: calculator

230: adaptive filter 240: step size adjustment unit

250: correlation measurer 260: low pass filter

270: memory section

Claims (6)

In the wireless repeater provided with a feedback interference cancellation device, A low noise amplifier 110 for minimizing the noise of the signal received by the reception antenna 101 and linearly amplifying the signal; A frequency down converter (120) for down-converting the amplified signal from a radio frequency to an intermediate frequency band; An analog / digital converter (130) for converting the down-converted analog signal into a digital signal; A feedback interference canceller (140) for removing a feedback interference signal included in the converted digital signal; A digital / analog converter (150) for converting the original signal from which the feedback interference signal is removed to an analog signal; A frequency upconverter (160) for raising the analog signal to a radio frequency band; And a power amplifier (170) for amplifying the signal so that the raised signal is transmitted through the transmission antenna (103). The method of claim 1, wherein the feedback interference cancellation device 140 A band pass filter 141 which cuts out the frequency band of the original signal to remove the interference; A digital down converter 142 for downgrading the frequency of the signal to the base band; A feedback interference canceller 143 for canceling feedback interference through a variable step size Normalized Least Mean Squares (NLMS) filter using a correlation of a baseband I / Q (Inphase / Quadrature) signal; Wireless repeater is provided with a feedback interference cancellation device, characterized in that consisting of a digital up-converter (144) for converting and outputting the data of the intermediate frequency band. The method of claim 2, wherein the feedback interference cancellation unit 143 A power measuring unit 210 measuring an average power of the input signal entering the feedback interference removing unit 143; An operation unit 220 for subtracting the estimated feedback interference signal generated by the adaptive filter 230 from the input signal to remove the interference and outputting the interference to the low pass filter 260; The filter coefficient value is determined according to the coefficient update equation of the Normalized Least Mean Squares (NLMS) filter by using the step size of the vector form determined by the step size adjusting unit 240, and the previous output signal and the coefficient value are stored in the memory unit 270. An adaptive filter 230 that multiplies and generates an estimated feedback interference signal; A step size adjusting unit 240 for generating a step size vector for use in the adaptive filter 230; A correlation measurer 250 measuring a correlation between the input signal and the stored output signals to analyze the feedback interference; A low pass filter 260 for passing the signal in accordance with the bandwidth of the original signal; The wireless repeater is provided with a feedback interference cancellation device, characterized in that consisting of a memory unit 270 that stores the signal of the interference is removed as the final output. The method of claim 3, wherein The correlation measurer 250 uses the correlation between the input signal and the output signals stored in the memory unit 270 and the correlation between the current output signal and the output signals stored in the memory unit 270. Wireless repeater is provided with a feedback interference cancellation device, characterized in that for measuring the abnormality of 230. In the feedback interference cancellation method of a wireless repeater having a feedback interference cancellation device, A tenth step (S10) in which the signal received by the reception antenna 101 is linearly amplified by minimizing noise in the low noise amplifier 110; A 20th step (S20) in which the amplified signal is down-converted from a radio frequency to an intermediate frequency band through a frequency down converter (120); A thirtieth step (S30) of converting the down-converted analog signal from the analog-to-digital converter 130 into a digital signal; A 40 step S40 of removing the feedback interference signal included in the digital signal in the feedback interference removing device 140; A 50th step (S50) of converting the original signal from which the feedback interference signal is removed to an analog signal by a digital / analog converter (150); And a sixty step S60 of amplifying the analog signal to the radio frequency band from the frequency up converter 160 and amplifying the signal to the power amplifier 170 and transmitting the amplified signal to the transmission antenna 103. Feedback interference cancellation method of a wireless repeater having a feedback interference cancellation device. The method of claim 5, wherein the 40 step (S40) A 41 th step (S41) which cuts out using the band pass filter 141 as the frequency band of the original signal to remove the interference; Step 42 (S42) of lowering the frequency of the signal from the digital down converter 142 to the base band; Step 43 (S43) of removing the feedback interference from the baseband inphase / quadature (I / Q) signal through a variable step size normalized least mean squares (NLMS) filter using correlation in the feedback interference canceller 143; ; Feedback interference cancellation of the wireless repeater is provided with a feedback interference cancellation device characterized in that it comprises a 44 step (S44) is converted into the data of the intermediate frequency band in the digital up-converter 144 is removed Way.

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