JPH09284195A - Radio relay booster - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain the radio relay booster that cancels a sneak path interference signal with high accuracy by repeating the update operation of a canceller control variable in a decreasing direction of a residual interference signal obtained through a very small fluctuation of the canceller control variable consisting of attenuation characteristic information and phase rotation information. SOLUTION: A controller 12 at first detects a level of a residual interference signal from a complex correlation device 14 as correlation information and decides attenuation characteristic information to an attenuator and phase rotation information to a phase shifter 9 based on the correlation information and provides an output of values obtained by fluctuating minutely the decided attenuation characteristic information and phase rotation information in both increasing and decreasing directions to the phase shifter 9 and the attenuator 10 as canceller control variables. Furthermore, the controller 12 updates sequentially the canceller control variable in a direction of decreasing the residual interference signal level from the complex correlation device 14 based on the canceller control variable fluctuated minutely. Thus, the attenuation characteristic information and the phase rotation information are optimized and the sneak path interference signal is cancelled with high accuracy.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless relay booster used for relaying a base station transmission signal, and particularly when an output signal of the wireless relay booster wraps around a receiving antenna of the wireless relay booster. The present invention relates to a wireless relay booster capable of removing an interference signal with high accuracy.

[0002]

2. Description of the Related Art In general, a radio relay booster relays a base station transmission signal by receiving a transmission signal sent from a base station by a receiving antenna, amplifying it and transmitting it from the transmitting antenna. At this time, if there is a coupling between the transmitting antenna and the receiving antenna of the wireless relay booster, the transmission output signal from the wireless relay booster wraps around to the receiving antenna, causing a problem of oscillation.

[0003] As one method of solving this problem,
There is a method of preventing the sneak interference signal of the output signal from the wireless relay booster from entering the receiving antenna by taking measures such as providing a sufficient distance between the transmitting antenna and the receiving antenna of the wireless relay booster.

However, it is difficult to secure the installation position of the wireless relay booster in the central area of the city, and it is difficult to secure a sufficient distance between the transmitting and receiving antennas due to the restriction of the location conditions. Is the current situation.

Therefore, a wireless relay booster having a wraparound interference canceller function capable of canceling a wraparound interference signal of a transmission output signal while keeping the distance between the transmitting and receiving antennas short has a problem of a space for installing the wireless relay booster in the center of the city. It has great merit in solving it.

Therefore, a conventional radio relay booster having a loop interference canceller function will be described with reference to FIG. FIG. 4 is a configuration block diagram of a conventional wireless relay booster. As shown in FIG. 4, the conventional wireless relay booster includes a directional receiving antenna 1, an amplifier 2, and a coupler 3.
, Quadrature detector 4, demodulator 5, waveform generator 6, quadrature modulator 7, amplifier 8, phase shifter 9, and attenuator 10.
And a controller 12, a directional transmission antenna 13, and a complex correlator 14.

Next, each part of the conventional wireless relay booster will be specifically described. The directional receiving antenna 1 is an antenna having directivity in the direction of the base station and originally receives a signal transmitted from the base station (hereinafter referred to as a base station transmission signal).

However, at the same time when the base station transmission signal is received,
The wraparound interference signal of the booster output signal output from the directional transmission antenna 13 described later is mixed with the reception signal. Here, the wraparound interference signal is a signal in which the booster output signal from the directional transmission antenna 13 is attenuated by the decoupling amount due to the directional characteristics of the directional reception antenna 1 and the directional transmission antenna 13.

The amplifier 2 amplifies a signal received by the directional receiving antenna 1 (hereinafter referred to as a received signal). The combiner 3 combines the reception signal amplified by the amplifier 2 and the cancel signal output from the phase shifter 9 described later, and outputs a canceller output signal.

The quadrature detector 4 quadrature-detects the canceller output signal from the coupler 3 and outputs quadrature I and Q signals (hereinafter referred to as reception quadrature signals). Demodulator 5
It demodulates the quadrature signal received from the quadrature detector 4 and outputs digital demodulated data.

The waveform generator 6 reproduces the quadrature I and Q signals based on the demodulated data from the demodulator 5 and outputs the reproduced quadrature signals. The quadrature modulator 7 quadrature modulates the reproduced quadrature signal from the waveform generator 6 and outputs a quadrature modulation signal. The amplifier 8 amplifies and outputs the quadrature modulation signal from the quadrature modulator 7. The directional transmission antenna 13 outputs the amplified quadrature modulation signal from the amplifier 8 as a relay amplification signal (hereinafter, booster output signal).

The attenuator 10 attenuates the quadrature modulation signal amplified by the amplifier 8 and outputs the attenuated quadrature modulation signal according to the attenuation characteristic information from the controller 12, which will be described later. The phase shifter 9 uses the attenuator 1 according to the phase rotation information from the controller 12 described later.
The phase of the quadrature modulated signal attenuated by 0 is changed and output as a cancel signal.

The complex correlator 14 takes the complex correlation between the received quadrature signal from the quadrature detector 4 and the reproduced quadrature signal from the waveform generator 6 and outputs it. Here, the received quadrature signal is a signal including a wraparound interference signal, and the reproduced quadrature signal is a signal that is a source of the sneak-in interference signal. Therefore, the complex correlation between the two signals is a wraparound interference signal remaining in the canceller output signal. The interference signal (hereinafter referred to as the residual interference signal) will be extracted.

The controller 12 receives the residual interference signal (I, Q) from the complex correlator 14, detects the level of the residual interference signal by the operation of I ² + Q ² and sets it as correlation value information, and the correlation value information. Based on the attenuation characteristic information to the attenuator 10,
The phase rotation information to the phase shifter 9 is output as a canceller control value.

Next, the operation of the conventional wireless relay booster will be described with reference to FIG. In the conventional wireless relay booster, at the beginning of receiving the base station transmission signal from the base station,
The base station transmission signal is received by the directional receiving antenna 1, amplified by the amplifier 2, combined with the cancel signal from the phase shifter 9 by the coupler 3, and output as a canceller output signal. However, since the cancel signal should not be output at the beginning of reception, the received signal is output as it is as the canceller output signal.

The canceller output signal is quadrature-detected by the quadrature detector 4 and output as a reception quadrature signal, demodulated by the demodulator 5, and the quadrature I and Q signals are regenerated by the waveform generator 6 to be regenerated quadrature signal. The quadrature modulator 7 outputs the quadrature-modulated signal, which is quadrature-modulated by the quadrature modulator 7. Here, in the quadrature modulation signal output from the quadrature modulator 7, noise and wraparound interference signals are not so large, and if there is no demodulation error, the wraparound interference signal mixed in the received signal by the remodulation operation and on the propagation path. It is possible to reproduce the reception signal in which the mixed noise and the like are cleared, that is, the base station transmission signal.

The noise-free quadrature modulation signal output from the quadrature modulator 7 is amplified by the amplifier 8 and transmitted from the directional transmission antenna 13 as a booster output signal.

At this time, the reception quadrature signal output from the quadrature detector 4 and the reproduced quadrature signal output from the waveform generator 6 are branched and input to the complex correlator 14, which then Complex correlation is performed and the residual interference signal is output to the controller 12.

Then, the controller 12 detects the level of the residual interference signal and uses it as the correlation value information, and based on the correlation value information, the attenuation characteristic information which is the canceller control value and the phase rotation so as to remove the residual interference signal. The information is set, the attenuation characteristic information is output to the attenuator 10, and the phase rotation information is output to the phase shifter 9.

The quadrature modulation signal output from the amplifier 8 is branched and taken into the attenuator 10, attenuated in the attenuator 10 according to the attenuation characteristic information from the controller 12, and then in the phase shifter 9. The phase is changed according to the phase rotation information from the controller 12, and is output to the coupler 3 as a cancel signal.

When the booster output signal is output from the directional transmitting antenna 13, the wraparound interference signal attenuated by the decoupling amount due to the directional characteristics of the directional receiving antenna 1 and the directional transmitting antenna 13 is directional. The sum signal received from the reception antenna 1 and the base station transmission signal is output to the amplifier 2 as a reception signal.

After that, when sequentially processed as described above, in the complex correlator 14, the quadrature I and Q signals (the signals including the wraparound interference signal) output from the quadrature detector 4 and the waveform generator are generated. The residual interference signal remaining in the canceller output signal from the phase shifter 9 can be extracted by performing a complex correlation with the quadrature I and Q signals (the signals that are the basis of the wraparound interference signal) that are the outputs of No. 6. it can.

Therefore, the controller 12 monitors the residual interference signal output from the complex correlator 14 and adjusts the phase shifter 9 and the attenuator 10 so as to remove the interference signal. That is, since the residual interference signal can be extracted as the quadrature I and Q signals, the residual interference signal is used as the error information of the canceller control value for updating the control values of the phase shifter 9 and the attenuator 10. The cancellation was realized.

[0024]

However, in the above-mentioned conventional wireless relay booster, although it is possible in principle,
If implemented in hardware, especially in the RF band, the controller 12
Since there is an error between the attenuation characteristic information and the phase rotation information given by, there is a problem that the cancel operation cannot be performed with high accuracy.

As an example, by changing the attenuation value in the attenuator 10 according to the attenuation characteristic information from the controller 12, the delay amount due to passage through the attenuator changes, resulting in the problem that the phase rotates. The solution is
It is necessary to take measures such as using a correction table for the phase value for each attenuation value, and a huge amount of tables is required. Moreover, since the correction table has variations due to individual differences of analog elements, temperature characteristics, or changes over time, it is virtually impossible to create a highly accurate correction table.

On the other hand, the wraparound interference level is not so large as compared with the desired signal (base station transmission signal) (for example,
If the desired signal-to-interference signal ratio is about 0 dB), the phase amplitude accuracy is not so high (for example, the phase accuracy is about 20 degrees), but the sneak interference level is considerably larger than the desired signal (for example, the desired signal). Signal-to-interference signal ratio is −
In a situation such as 40 to -50 dB), high phase amplitude accuracy is required (phase accuracy of 0.1 degrees or less, amplitude accuracy of desired signal to interference signal ratio of about -10 dB or more).

Therefore, even if the control value can be set with high precision by the controller 12, there is an error in the actually set value.
There is a drawback in that it is not possible to obtain high precision control (high cancellation characteristics) of the actual canceller.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a wireless relay booster capable of canceling a sneak interference signal with high accuracy.

[0029]

The invention according to claim 1 for solving the problems of the conventional example is a wireless relay booster used for relaying a base station transmission signal, and the output of the wireless relay booster. In a wireless relay booster that cancels a sneak interference signal that a signal sneak into a receiving antenna of the wireless relay booster, a control value for canceling is slightly changed, and the level of a sneak interference signal remaining in the fluctuation range is small. It is characterized in that the operation of updating as a control value for canceling the value is repeated, and the control value can be changed experimentally, and an appropriate control value can be selected from the actually measured values.

According to a second aspect of the present invention for solving the problems of the conventional example, in the wireless relay booster according to the first aspect, the control value for canceling consists of attenuation characteristic information and phase rotation information. A canceller control value is indicated, the canceller control value is slightly changed, the level of the remaining interference signal is detected, and the operation of updating the canceller control value in the direction of decreasing the level is repeated. By appropriately varying the attenuation characteristic information and the phase rotation information, which are control values, it is possible to select an appropriate control value from the actual measurement value of the level of the remaining interference signal which is the result.

According to a third aspect of the present invention for solving the above-mentioned problems of the conventional example, in the radio relay booster according to the second aspect, the phase rotation information in the canceller control value is changed by a small amount, and the remaining interference signal is generated. Level is detected, the canceller control value is updated in the direction in which the level decreases, the attenuation characteristic information in the canceller control value is changed by a small amount, and the level of the remaining interference signal is detected, and the level decreases. It is characterized by repeating the operation of updating the canceller control value in the direction, experimentally varying the attenuation characteristic information and the phase rotation information respectively, and the appropriate attenuation from the measured value of the residual interference signal level resulting from the experiment. It is possible to select the characteristic information and the phase rotation information.

According to a fourth aspect of the present invention for solving the problems of the conventional example, in a radio relay booster used for relaying a base station transmission signal, a directivity having directivity in the arrival direction of the base station transmission signal. A receiving antenna, a directional transmitting antenna arranged so as not to have directivity of booster output in the receiving antenna direction, a first amplifier for amplifying a received signal received by the receiving antenna, and the first amplifier A combiner for outputting a canceller output signal by synthesizing an output from the input signal and an input cancel signal, a quadrature detector for quadrature detecting the canceller output signal and converting it into a reception quadrature signal, and demodulating the reception quadrature signal And a demodulator that outputs demodulated data, a waveform generator that reproduces an orthogonal signal based on the demodulated data and outputs a reproduced orthogonal signal, and an orthogonal transformer that orthogonally modulates the reproduced orthogonal signal. , A second amplifier for amplifying the quadrature-modulated signal to output a booster output signal, a complex function of the received quadrature signal from the quadrature detector and the reproduced quadrature signal from the waveform generator, A complex correlator that outputs a residual interference signal, an attenuator that attenuates the booster output signal from the second amplifier according to attenuation characteristic information that is input, and a phase that outputs the output from the attenuator according to phase rotation information that is input. A phase shifter that performs an operation and outputs a cancellation signal, and a controller that gives attenuation characteristic information to the attenuator from correlation value information that is the level of the residual interference signal and gives phase rotation information to the phase shifter. The controller has a small amount of variation in the attenuation characteristic information and the phase rotation information before and after the value, detects correlation value information at the time of variation, and reduces the correlation value information within the variation range. It is characterized in that it is a controller that repeats the operation of updating the attenuation characteristic information and the phase rotation information in a direction, the controller empirically fluctuates the attenuation characteristic information and the phase rotation information which are control values, It is possible to select an appropriate control value from the measured value of the correlation value information which is the result.

According to a fifth aspect of the present invention for solving the problems of the conventional example, in the wireless relay booster according to the fourth aspect, the correlation value information indicates the level of the residual interference signal, and the controller. Is a controller that repeats the operation of detecting the level of the residual interference signal and updating the attenuation characteristic information and the phase rotation information in the direction in which the level decreases, and the controller experimentally sets the control value. It is possible to vary the attenuation characteristic information and the phase rotation information, and select an appropriate control value from the actual measurement value of the residual interference signal that is the result.

According to a sixth aspect of the present invention for solving the problems of the conventional example, in the wireless relay booster according to the fourth aspect, the controller varies the set value of the phase rotation information in the phase shifter by ± Δ1. Then, the level of each residual interference signal at the set value of the phase rotation information and the variation point of ± Δ1 is detected, and the value of the phase rotation information of the minimum level among the levels of the detected residual interference signals is calculated. Update the setting value of the new phase rotation information and change the setting value of the attenuation characteristic information in the attenuator by ± Δ2,
An operation of detecting the level of each residual interference signal at the variation point of Δ2 and updating the value of the attenuation characteristic information of the minimum level among the detected levels of the residual interference signal to the new set value of the attenuation characteristic information. It is characterized in that it is a controller that repeats, and the controller experimentally fluctuates the attenuation characteristic information and the phase rotation information, which are control values, and obtains an appropriate control value from the measured value of the residual interference signal that is the result. You can choose.

[0035]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the claimed invention will be described with reference to the drawings. The wireless relay booster according to the present invention slightly changes the current set value of the canceller control value consisting of the attenuation characteristic information and the phase rotation information, detects the level of the residual interference signal each time, and reduces the residual interference signal. By repeating the operation of updating the set value of the canceller control value in such a direction, the residual interference signal approaches the canceller convergence point where the residual interference signal becomes 0, so that it is possible to finally cancel the sneak interference signal with high accuracy. is there.

Radio relay booster according to the present invention (this device)
The configuration of is basically the same as the conventional wireless relay booster shown in FIG. 3, and includes a directional receiving antenna 1, an amplifier 2,
The combiner 3, the quadrature detector 4, the demodulator 5, the waveform generator 6, the quadrature modulator 7, the amplifier 8, the phase shifter 9, the attenuator 10, the controller 12, and the directivity. A transmitting antenna 13,
However, the control method of the canceller control value in the controller 12 is different from the conventional method.

Since the respective parts of the apparatus except the controller 12 are the same as those of the conventional wireless relay booster, the description thereof is omitted here, and the controller 12 which is a characteristic part of the present invention will be specifically described. To do. The controller 12 first detects the level of the residual interference signal from the complex correlator 14 to obtain correlation value information, and based on the correlation value information, the attenuation characteristic information to the attenuator 10 and the phase shifter 9 to the phase shifter 9. Phase rotation information (both are combined to be a canceller setting value) is determined. Then, the phase shifter 9 and the attenuator 1 are used as the canceller control value, which is a value obtained by slightly changing the determined information in both positive and negative directions.
Output to 0.

As a result, the canceller output value output from the phase shifter 9 changes due to the slightly changed canceller control value, and the canceller output signal output from the combiner 3 also changes. The level of the residual interference signal (residual interference level) is detected from the residual interference signal output from the complex correlator 14 at the canceller control value, and the canceller control value is updated to a value that reduces the residual interference level. ing.

A method of controlling the canceller control value in the controller 12 of the wireless relay booster of the present invention will be specifically described with reference to FIG. FIG. 1 is a flowchart showing a control flow of a canceller setting value in the controller 12 of the wireless relay booster according to the present invention. In the control flow of the canceller set value of the present invention, first, the canceller set value (phase rotation information X and attenuation characteristic information Y) is determined based on the correlation value information from the complex correlator 14 (100). The canceller setting value at the start of control may be another value.

Then, the value obtained by adding + Δ1 to the phase rotation information X is output to the phase shifter 9 (110), the level A1 of the residual interference signal from the complex correlator 14 is detected (111), and the phase rotation information is then detected. The value obtained by subtracting -Δ1 from X is output to the phase shifter 9 (11
2), the level A2 of the residual interference signal from the complex correlator 14
Is detected (113).

Then, the residual interference signal level A1 (hereinafter simply referred to as A1) and the residual interference signal level A2 (hereinafter simply referred to as A2) are compared (114). If A1 is larger than A2, the phase rotation is performed. The value obtained by subtracting the information X from -Δ1 is set as the phase rotation information X (115), and when A1 is smaller than A2, the value obtained by adding + Δ1 to the phase rotation information X is set as the phase rotation information X (116), and when A1 and A2 are equal to each other. , The phase rotation information X remains unchanged (117). Note that the processing 117 when A1 and A2 are the same is the processing 115 or the processing 11.
The flow may be included in any one of the six.

Then, a value obtained by adding + Δ2 to the attenuation characteristic information Y is output to the attenuator 10 (120), and the complex correlator 14
Detect the level B1 of the residual interference signal from (121),
Next, a value obtained by subtracting the attenuation characteristic information Y by-? 2 is output to the attenuator 10 (122), and the level B2 of the residual interference signal from the complex correlator 14 is detected (123).

Then, the level B1 of the residual interference signal (hereinafter simply referred to as B1) is compared with the level B2 of the residual interference signal (hereinafter simply referred to as B2) (124). If B1 is larger than B2, the attenuation characteristic is obtained. A value obtained by subtracting the information Y from -Δ2 is set as the attenuation characteristic information Y (125), and when B1 is smaller than B2, a value obtained by adding + Δ2 to the attenuation characteristic information Y is set as the attenuation characteristic information Y (126), and B1 and B2 are equal. Keeps the attenuation characteristic information Y unchanged (127), returns to step 110, and repeats the processing. The process 127 when B1 and B2 are equal may be a flow included in either process 125 or process 126.

In FIG. 1, the phase rotation information is first changed to update the set value of the phase rotation information, and then the attenuation characteristic information is changed to update the set value of the attenuation characteristic information. However, conversely, the attenuation characteristic information may be changed.

Next, how the canceller control value converges in the wireless relay booster of the present invention will be described with reference to FIGS. 2 and 3. FIG. 2 is an explanatory diagram showing the quantization accuracy of the canceller control value in the wireless relay booster of the present invention, and FIG. 3 is a state of update control of the canceller control value using the residual interference signal in the wireless relay booster of the present invention. FIG.

FIG. 2 shows the phase rotation information and the attenuation characteristic information for producing the cancel signal, which are converted from the phase and the amplitude and are shown as vectors on the orthogonal I and Q planes.
That is, in FIG. 2, the circumference represents an equal amplitude value and the radiation represents an equal phase value.

Since the amplitude value, which is the attenuation characteristic information, and the phase value, which is the phase rotation information, have discontinuous values due to quantization in hardware, the canceller control values (attenuation characteristic information and phase rotation information) are actually set. The possible values are only the intersections of the circumference and the lattice that can be represented by radiation, and the distance between the canceller control value (point on the lattice) on the hardware configuration and the true canceller convergence point becomes the residual interference signal. The radiation interval is Δ1 described in FIG. 1, and the circumferential interval is equivalent to Δ2 described in FIG.

The lattice spacing is the quantization accuracy of the hardware, and by taking the spacing fine, it is possible to obtain a canceller control value close to the true canceller convergence point (residual interference signal is 0). Further, since the distance between the point on the grid and the true convergence point of the canceller becomes the residual interference signal, it is necessary to set the grid interval (quantization accuracy) to be sufficiently smaller than the received base station transmission signal.

FIG. 3 shows the residual interference level in contour lines in the direction perpendicular to the plane of the paper on the I and Q planes shown in FIG. 2, and the canceller convergence point is the lowest. Phases and amplitudes are set at adjacent grid points (corresponding to minute movements) with respect to the currently set canceller control value, and the residual interference signal level is measured. By moving the canceller control value in the (lower inclination direction), it is possible to gradually approach the canceller convergence point.

According to the wireless relay booster of the present invention, the canceller control value (attenuation characteristic information and phase rotation information) for the controller 12 to generate the cancel signal is experimentally changed by a small amount in both positive and negative directions, The residual interference signal output from the complex correlator 14 is measured each time, and the canceller control value is sequentially updated in the direction in which the residual interference signal level decreases. There is an effect that the problem of control error can be solved and the canceller control value can be drawn to the optimum convergence point within the range of the quantization accuracy only by the relative positional relationship with the current control value.

[0051]

According to the first aspect of the present invention, the control value for canceling the wraparound interference signal is changed by a small amount, and the value at which the level of the wraparound interference signal remaining in the fluctuation range is reduced is canceled. Because it is a wireless relay booster that repeats the operation of updating as a control value for changing the control value, it is possible to cancel it by changing the control value experimentally and selecting an appropriate control value from the actual measured value. The control value can be optimized, and the sneak interference signal can be canceled with high accuracy.

According to the second aspect of the present invention, the control value for canceling is a canceller control value consisting of attenuation characteristic information and phase rotation information, and the canceller control value is slightly changed and remains. The wireless relay booster according to claim 1, wherein the operation of detecting the level of the interference signal and updating the canceller control value in the direction of decreasing the level is repeated. Therefore, the attenuation characteristic information and the phase rotation information which are the control values are experimentally set. By changing the and, and selecting an appropriate control value from the actual measurement value of the residual interference signal level as a result, the canceller control value can be optimized and the sneak interference signal can be highly accurately determined. There is an effect that can be canceled.

According to the third aspect of the invention, the phase rotation information of the canceller control value is slightly changed to detect the level of the remaining interference signal, and the canceller control value is updated in the direction of decreasing the level. 3. The wireless relay booster according to claim 2, wherein the operation of slightly changing the attenuation characteristic information of the canceller control value, detecting the level of the remaining interference signal, and updating the canceller control value in the direction of decreasing the level is repeated. Therefore, by varying the attenuation characteristic information and the phase rotation information experimentally, and selecting appropriate attenuation characteristic information and phase rotation information from the actual measurement value of the level of the residual interference signal that is the result, The canceller control value can be optimized, and the sneak interference signal can be canceled with high accuracy.

According to the invention described in claim 4, the controller comprises:
Based on the correlation value information detected from the residual interference signal, the attenuation characteristic information is given to the attenuator that attenuates the booster output signal,
The phase shift information is output to the phase shifter that outputs the cancel signal by performing the phase operation on the output from the attenuator. Since it is a wireless relay booster that repeats the operation of detecting the correlation value information and updating the attenuation characteristic information and the phase rotation information in the direction in which the correlation value information decreases within the fluctuation range, the controller experimentally sets the control value. It is possible to optimize the damping characteristic information and the phase rotation information by changing the certain damping characteristic information and the phase rotation information and selecting an appropriate control value from the measured value of the correlation value information which is the result. There is an effect that the sneak interference signal can be canceled with high accuracy.

According to the fifth aspect of the present invention, the correlation value information is the level of the residual interference signal, and the controller detects the level of the residual interference signal and the attenuation characteristic information in the direction of decreasing the level. Since the wireless relay booster according to claim 4 repeats the operation of updating the phase rotation information, the controller experimentally fluctuates the attenuation characteristic information and the phase rotation information, which are control values, and the correlation value information as a result thereof. By selecting an appropriate control value from the actually measured value, the attenuation characteristic information and the phase rotation information can be optimized, and the wraparound interference signal can be canceled with high accuracy.

According to the invention described in claim 6, the controller comprises:
By changing the set value of the phase rotation information in the phase shifter by ± Δ1 and detecting the level of each residual interference signal at the set value of the phase rotation information and the fluctuation point of ± Δ1, The value of the minimum phase rotation information is updated to the new setting value of the phase rotation information, and the setting value of the attenuation characteristic information in the attenuator is changed by ± Δ2, and the setting value of the attenuation characteristic information and ± Δ2 of Repeating the operation of detecting the level of each residual interference signal at the changing point and updating the value of the attenuation characteristic information of the level that is the minimum among the levels of the detected residual interference signals to the new set value of the attenuation characteristic information. Since the wireless relay booster described in Item 4 is used, the controller experimentally fluctuates the attenuation characteristic information and the phase rotation information, which are control values, and selects an appropriate control value from the measured value of the correlation value information that is the result. This It makes it possible to optimize the damping characteristic information and phase rotation information, there is an effect of canceling the sneak interference signal with high accuracy.

[Brief description of drawings]

FIG. 1 is a flowchart showing a control flow of a canceller setting value in a controller of a wireless relay booster according to the present invention.

FIG. 2 is an explanatory diagram showing quantization accuracy of a canceller control value in the wireless relay booster of the present invention.

FIG. 3 is an explanatory diagram showing a state of update control of a canceller control value using a residual interference signal in the wireless relay booster of the present invention.

FIG. 4 is a configuration block diagram of a conventional wireless relay booster.

[Explanation of symbols]

1 ... Directional receiving antenna, 2, 8 ... Amplifier, 3 ... Combiner, 4 ... Quadrature detector, 5 ... Demodulator, 6 ... Waveform generator, 7 ... Quadrature modulator, 9 ... Phase shifter, 10 ... Attenuation Vessel, 12 ... controller, 13 ... directional transmission antenna,
14 ... Complex correlator

 ─────────────────────────────────────────────────── ─── Continued Front Page (72) Inventor Hiroshi Suzuki 2-10-1 Toranomon, Minato-ku, Tokyo NTT Mobile Communication Network Co., Ltd.

Claims (6)

[Claims] 1. A wireless relay booster used for relaying a base station transmission signal, wherein the output signal of the wireless relay booster cancels a sneak interference signal sneaking around a receiving antenna of the wireless relay booster. , A slight change in the control value for cancellation,
A wireless relay booster characterized by repeating an operation of updating as a control value for canceling a value at which the level of a wraparound interference signal remaining in the fluctuation range becomes small. 2. The control value for canceling indicates a canceller control value consisting of attenuation characteristic information and phase rotation information, and the canceller control value is changed by a small amount to detect the level of a residual interference signal, The wireless relay booster according to claim 1, wherein the operation of updating the canceller control value is repeated in the direction in which the level decreases. 3. The phase rotation information in the canceller control value is slightly changed to detect the level of the remaining interference signal, the canceller control value is updated in the direction in which the level decreases, and the attenuation characteristic in the canceller control value is set. The wireless relay booster according to claim 2, wherein the operation of slightly changing the information, detecting the level of the remaining interference signal, and updating the canceller control value in the direction of decreasing the level is repeated. 4. A wireless relay booster used for relaying a base station transmission signal, wherein a directional receiving antenna having directivity in the arrival direction of the base station transmission signal and no booster output directivity in the receiving antenna direction. A directional transmission antenna arranged as described above, a first amplifier for amplifying a reception signal received by the reception antenna, and a canceller output signal by combining an output from the first amplifier and a cancellation signal input , A quadrature detector that quadrature-detects the canceller output signal and converts it into a reception quadrature signal, a demodulator that demodulates the reception quadrature signal and outputs demodulation data, and based on the demodulation data A waveform generator that reproduces a quadrature signal and outputs a reproduction quadrature signal, a quadrature modulator that quadrature-modulates the reproduction quadrature signal, and amplifies the quadrature-modulated signal to output a booster output signal. And a second correlator that takes a complex function of the received quadrature signal from the quadrature detector and the reproduced quadrature signal from the waveform generator and outputs the residual function as a residual interference signal, and the second amplifier An attenuator that attenuates the booster output signal from the attenuator according to the input attenuation characteristic information, a phase shifter that performs a phase operation according to the input phase rotation information to output a cancel signal, and the residual A controller for giving attenuation characteristic information to the attenuator from the correlation value information which is the level of the interference signal, and for giving phase rotation information to the phase shifter, wherein the controller has the attenuation characteristic information and the phase rotation. A small amount of information is fluctuated back and forth from the value, correlation value information at the time of fluctuation is detected, and the attenuation characteristic information and the phase rotation information are updated in a direction in which the correlation value information decreases within the fluctuation range. Radio relay booster, characterized in that the controller to repeat the work. 5. The correlation value information indicates the level of the residual interference signal, and the controller detects the level of the residual interference signal and outputs attenuation characteristic information and phase rotation information in the direction in which the level decreases. The wireless relay booster according to claim 4, wherein the wireless relay booster is a controller that repeats an updating operation. 6. The controller varies the set value of the phase rotation information in the phase shifter by ± Δ1 to detect the set value of the phase rotation information and the level of each residual interference signal at the variation point of ± Δ1. , The value of the phase rotation information of the minimum level among the levels of the detected residual interference signals is updated to the new setting value of the phase rotation information, and the setting value of the attenuation characteristic information in the attenuator is changed by ± Δ2. , The level of each residual interference signal at the set value of the attenuation characteristic information and the variation point of ± Δ2 is detected, and the value of the attenuation characteristic information of the minimum level among the detected levels of the residual interference signal is newly added. The wireless relay booster according to claim 4, wherein the controller is a controller that repeats an operation of updating the set value of the attenuation characteristic information.