JP2003174392A - Radio repeater - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a radio repeater in which a large number of sneaking waves can be dealt with while eliminating the effect of multipath of a master station transmission signal. <P>SOLUTION: The radio repeater comprises a frequency converter 4 for converting an RF signal of radio frequency band into an IF signal of intermediate frequency band, a section 6 for determining the transmission path characteristics of multipath or sneaking waves included in a received signal (transmission path characteristics of interference signal) using a pilot signal included in the IF signal according to a specified criterion and generating a replica signal of the interferring signal base on the transmission path characteristics and a specified reference signal, a subtractor 7 for eliminating the effect of the interferring signal by subtracting the replica signal from the IF signal, and a converter 9 for converting the IF signal from which interference is removed into an RF signal. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an OFDM (Or signal) transmitted from a master station such as a TV broadcast signal or a communication signal.
thogonal Frequency Division Multiplexing) relates to a wireless relay device that relays a signal, and in particular, the frequency of the input master station transmission signal and the frequency of the relay output signal are the same, and the relay output signal is transmitted to its own receiving antenna. The present invention relates to a wireless relay device capable of removing the influence of the wraparound wave even in the case of wraparound.

[0002]

2. Description of the Related Art A conventional wireless relay device will be described below. Generally, when transmitting a TV broadcast signal, a communication signal, or the like using terrestrial waves, the master station transmission signal sent from the master station is relayed through several stages of wireless relay devices provided on the way. And transmitted. At this time, in the wireless relay device,
The signal output from the master station or the wireless relay device at the preceding stage is received by the receiving antenna, amplified, and then transmitted to the next wireless relay device by the transmitting antenna.

However, the frequency of the relay output signal output from the wireless relay device and the frequency of the master station transmission signal input to the wireless relay device are the same, and there is no radio wave between the transmitting antenna and the receiving antenna of the wireless relay device. If there is such coupling, the relay output signal sent from the transmission antenna may sneak into the reception antenna, and may be amplified by the amplification function of the wireless relay device to cause oscillation.
Further, when performing multi-stage relay, this wraparound wave component may be accumulated and signal deterioration may occur.

Therefore, as a technique for solving the above problems,
For example, Japanese Unexamined Patent Application Publication No. 2001-7750 discloses a technique for removing the influence of a radio wave that wraps around from a transmitting antenna to a receiving antenna (hereinafter referred to as a wraparound wave) in a circuit manner.

The wireless relay device described in the above publication utilizes the characteristic that the signal to be relayed has a strong autocorrelation characteristic. First, the signal transmitted from the wireless relay device is stored in a buffer memory, The transmission line fluctuation value of the wraparound wave is estimated by the correlation processing between the memory signal and the received signal. Then, a replica signal of the wraparound wave is generated based on the estimated value, and the replica signal is subtracted from the received signal to remove the influence of the wraparound wave.

[0006] On the other hand, the propagation environment at the actual installation location of the repeater is that an infinite number of wraparound waves are combined, as shown in the technical report AP2000-136 "Terrestrial digital television broadcast wave relay SFN field experiment". It is reported that it is incident on the receiving antenna.

The technique disclosed in Japanese Patent Laid-Open No. 2001-7750 discloses a technique in which a multi-stage configuration is adopted in order to deal with a large number of wraparound waves, but here, an increase in the device scale due to the multi-stage configuration becomes a problem.

Further, it is described in the method of Japanese Patent Laid-Open No. 2001-7750 that it is possible to remove the influence of the wraparound wave by the correlation processing with the wraparound wave. It is not possible to deal with the existence of multipath.

[0009]

As described above, in the above-mentioned conventional radio relay apparatus, a large number of sneaking waves exist depending on the propagation environment at the actual installation location, and therefore, it is attempted to cope with this. Then, there is a problem that the scale of the device increases. Further, there is a problem that it is possible to deal only with the removal of the influence of the sneak wave and it is impossible to remove the influence when there is a multipath relating to the master station transmission signal.

The present invention has been made in view of the above, and an object of the present invention is to obtain a radio relay apparatus which can cope with a large number of sneaking waves and can remove the influence of multipath of a master station transmission signal. And

[0011]

[Means for Solving the Problems]
In order to achieve the object, a wireless relay device according to the present invention is configured to relay a reception signal from a master station or another device, and an RF signal in a wireless frequency band is transmitted to an IF in an intermediate frequency band.
First frequency conversion means for frequency-converting into a signal;
Using the pilot signal included in the F signal according to a predetermined reference, the transmission path characteristics of the multipath and the sneaking wave included in the reception signal (transmission path characteristics of the interference signal) are obtained, and the transmission path characteristics and the predetermined reference signal are obtained. A replica generation unit that generates a replica signal of the interference signal based on the interference signal, an interference signal removal unit that removes the influence of the interference signal by subtracting the replica signal from the IF signal, and an IF signal after the interference removal. Second frequency conversion means for converting to an RF signal, and the predetermined reference signal for generating a replica signal is used as an output signal of the interference signal removal means.

In the wireless relay device according to the next invention, the received signal from the master station or another device is relayed, and the RF signal in the wireless frequency band is frequency-converted into the IF signal in the intermediate frequency band. Using the frequency conversion unit 1 and the pilot signal included in the IF signal according to a predetermined reference, the transmission path characteristics of the multipath and the sneak wave included in the reception signal (transmission path characteristics of the interference signal) are obtained, and the transmission is performed. Replica generation means for generating a replica signal of the interference signal based on a path characteristic and a predetermined reference signal; and interference signal removal means for removing the influence of the interference signal by subtracting the replica signal from the IF signal. , IF after interference removal
Second frequency conversion means for converting the signal into an RF signal, and the predetermined reference signal for generating a replica signal is subjected to power amplification processing and waveform shaping processing for the interference-removed signal. It is characterized by being a signal.

In a wireless relay device according to the next invention, a quadrature detection means for relaying a received signal from a master station or another device and for converting an RF signal in a radio frequency band into a baseband signal, By using the pilot signal included in the baseband signal according to a predetermined reference, the transmission path characteristics of the multipath and the sneaking wave (interference signal transmission path characteristics) included in the received signal are obtained, and the transmission path characteristic and a predetermined reference Replica generation means for generating a replica signal of the interference signal based on a signal; interference signal removal means for removing the influence of the interference signal by subtracting the replica signal from the baseband signal; A quadrature modulation means for converting a baseband signal into an RF signal, and removing the interference signal from the predetermined reference signal for generating a replica signal. Characterized in that the output signal of the stage.

In the wireless relay device according to the next invention, the received signal from the master station or another device is relayed, and the RF signal in the wireless frequency band is frequency-converted into the IF signal in the intermediate frequency band. No. 1 frequency conversion means, analog / digital conversion means for converting the IF signal (analog signal) into a digital signal, and a pilot signal included in the digital signal according to a predetermined reference Replica generation means for obtaining a transmission line characteristic of a sneak wave or a sneaking wave (transmission line characteristic of an interference signal) and generating a replica signal of the interference signal based on the transmission line characteristic and a predetermined reference signal; and the replica from the digital signal. An interference signal removing means for removing the influence of the interference signal by subtracting the signal, and a digital signal after the interference removal are analogized. Signal (IF signal) and digital / analog conversion means and second frequency conversion means for converting the IF signal to an RF signal, and the predetermined reference signal for generating a replica signal is It is characterized in that it is an output signal of the interference signal removing means.

In the radio relay apparatus according to the next invention, the replica generation means averages the amplitude and phase characteristics on the frequency axis obtained from the pilot signal in the time axis direction.

In the radio relay apparatus according to the next invention, the replica generation means obtains the frequency characteristic of the interference signal by removing the desired signal component from the frequency characteristic of the received signal obtained from the pilot signal. And

In the radio relay apparatus according to the next invention, the replica generating means subtracts the frequency characteristic of the received signal obtained from the pilot signal from the desired signal component to obtain the inverse characteristic of the frequency characteristic of the interference signal. Characterized by seeking.

In the wireless relay device according to the next invention, the replica generation means estimates the transmission path fluctuation amount of the direct wave component of the received signal based on the frequency characteristic obtained from the pilot signal, and uses the estimated value as the estimated value. The power amplification amount of the transmission signal is adjusted based on the above.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a wireless relay device according to the present invention will be described below in detail with reference to the drawings. The present invention is not limited to this embodiment.

Embodiment 1. FIG. 1 is a diagram showing a configuration of a wireless relay device according to a first embodiment of the present invention. Figure 1
1, reference numeral 1 is a directional or omnidirectional receiving antenna for receiving a signal transmitted from a master station, 2 is a receiving amplifier for amplifying a receiving signal received by the receiving antenna 1, and 3 is a receiving filter. , 4, 9 are frequency converters, 5 and 8 are BPFs (band pass filters),
Reference numeral 6 is a replica generator, 7 is a subtractor, 10 is a transmission amplifier, 11 is a transmission filter, and 12 is a transmission filter.
Is a transmitting antenna.

RF relayed in the wireless relay device
The (Radio Frequency) signal is down-converted by the frequency converter 4, frequency-converted from the radio frequency band to the intermediate frequency band, becomes an IF (Intermediate Frequency) signal, and is band-limited by the BPF 5. I after bandwidth limitation
The F signal is processed by the replica generator 6 and the subtractor 7.

The subtracter 7 uses the error signal generated by the replica generator 6 to remove the influence of the interference signal such as the multipath of the master station transmission signal and the sneak wave from the reception signal, and the BPF 8 eliminates the unnecessary band. Remove the signal, and
The frequency converter 9 generates an RF signal from the IF signal by up conversion. Thereafter, this RF signal is power-amplified by the transmission amplifier 10 and further waveform-shaped by the transmission filter 11, and then transmitted from the directional or omnidirectional transmission antenna 12 to the next-stage wireless relay device or receiver. Sent out.

On the other hand, the received signal includes the master station transmission signal from the master station, the multipath component of the master station transmission signal, and the sneak wave from the transmission antenna 12, so during this period, the replica generation unit In 6, a replica of an interference signal such as a multipath of a master station transmission signal or a sneak wave is generated by the following operation. In the replica generation unit 6 shown in FIG. 1, 601 is an A / D converter, 602 is a quadrature detector, 603 is an FFT, 604 is a pilot signal extraction unit, and 606 is an error signal output unit. 607 is an IFFT, 608 is a replica generator, 609 is a quadrature modulator, 610 is a D / A converter (digital / analog converter), 61
1 is an LPF (low pass filter), and 612 is A /
D converter (analog / digital converter),
Reference numeral 613 is a quadrature detector.

In the replica generator 6, the IF signal output from the BPF 5 is sampled by the A / D converter 601 as a digital signal, and the quadrature detector 602 performs quadrature detection to generate a baseband signal. The IF signal output from the BPF 8 is sent to the replica converter 6 at the same time as being sent to the frequency converter 9, and in the replica generator 6, the A / D converter 612 samples the IF signal as a digital signal and the quadrature detector 613. Then, quadrature detection is performed to generate a baseband signal.

The baseband signal output from the quadrature detector 602 is subjected to FFT processing by the FFT 603 and converted from a time domain signal to a frequency domain signal.

In the pilot signal extraction unit 604, the FFT
From the signal in the frequency domain output from 603, a pilot signal having a known amplitude and phase, which is inserted at a predetermined position in the frequency axis direction, is extracted.

Some pilot signals, for example, as shown in FIG. 2, are inserted at a constant period like a pilot signal in digital terrestrial broadcasting. In this case, the pilot signal is extracted according to the regularity. There is also a pilot signal inserted as a preamble at the beginning of a burst, which is used in wireless communication and the like. Also in this case, the pilot signal is extracted according to the format.

The error signal output unit 606 calculates an error signal having frequency characteristics of the multipath and the sneaking wave component of the master station transmission signal based on the extracted pilot signal. FIG. 3 is a diagram showing the configuration of the error signal output unit 606. In FIG. 3, 651 is a frequency characteristic detection unit,
652 is an IFFT (Inverse Fast Fourier Transform),
53 is a master station direct wave fluctuation amount estimation unit, and 654 is an FFT.
(Fast Fourier Transform), and 655 is an error signal calculator.

The operation of the error signal output unit 606 will be described in detail. The frequency characteristic detection unit 651 detects the frequency characteristic over the entire signal band from the pilot signal whose amplitude and phase are known. At this time, in the case of the pilot signal for terrestrial digital broadcasting as shown in FIG. 2, since it is inserted at a constant interval in the time axis direction and the frequency axis direction, if four symbols are used, it is moved in the frequency axis direction. Every other two pilot signals are inserted. In this state, the frequency characteristic obtained from each pilot signal is used to perform interpolation processing in the frequency axis direction to detect the frequency characteristic over the entire signal band.

The error signal calculating section 655 removes the desired wave component from the frequency characteristic obtained by the frequency characteristic detecting section 651 and calculates the frequency characteristic of only the multipath or the sneak wave component of the master station transmission signal as an error signal.

Now, the error signal will be described.
For example, if the frequency characteristic of the master station transmission signal is X (z),
Letting Y (z) be the frequency characteristic of the canceller (which is composed of the replica generator 6, the subtractor 7, and the BPF 8), the transfer function H (z) of the entire canceller system is H
(Z) = Y (z) / X (z).

Since the purpose of the canceller is to acquire the master station transmission signal, it is desirable that the transfer function of the entire canceller system is ideally 1. Therefore, assuming that the frequency characteristic of the received signal of the canceller is Y ′ (z), the transfer function H ′ (z) = Y ′ (z) / X (z) at the receiving point is Er (z) as an error function. = H ′ (z) −1, and based on this, the influence of interference signals such as multipath of the master station transmission signal on the frequency axis and wraparound wave is extracted.

If the direct wave component of the master station is affected by the fluctuation of the transmission path, the value of the fluctuation of the transmission path is F ₀ (z).
Then, the target value of the transfer function H (z) becomes F ₀ (z). Therefore, the error function Er (z) is Er (z) = H
It becomes ′ (z) / F ₀ (z) −1. Note that the calculation of F ₀ (z) is performed by inverse fast Fourier transform (IFFT) of the frequency characteristic when obtaining the error function to obtain the delay profile, and the variation amount f (of the amplitude / phase at the time point t = 0). 0) again to F
It can be obtained by FT. In addition, here, it is assumed that the FFT window timing in FFT is synchronized with the direct wave of the master station. Therefore, t
The signal at the time of = 0 represents the direct wave of the master station.

That is, in the error signal output unit 606, I
The FFT 652 converts the signal output from the frequency characteristic detection unit 651 from the frequency domain signal to the time domain signal, and the master station direct wave fluctuation amount estimation unit 653 extracts the signal at t = 0 from the converted signal. When t ≠ 0, all are set to 0, and the fluctuation amount f
Find (t).

Then, in the error signal output unit 606, the FF
In step T654, F ₀ (z) is obtained by performing FFT processing on the fluctuation amount f (t). When the direct wave of the master station does not change, f (0) = 1 and F ₀ (z) =
It is clear that it will be 1. In addition, since the above-mentioned fluctuation amount is notified to the transmission amplifier 10 as reference information for amplification gain adjustment, relaying is performed while maintaining a constant level of the desired signal from which the multipath component and the sneak wave of the master station are removed. It becomes possible to do.

After that, the error signal obtained by the error signal output unit 606 is converted from the frequency domain signal to the time domain signal in the IFFT 607, and the multipath of the master station transmission signal and the amplitude and phase of the sneak wave and the delay time are obtained. It is sent to the replica generator 608 as a transmission channel estimation value including information.

In the replica generator 608, the IFFT 60
7 and the quadrature detector 613.
From the baseband signal sent from, the multipath of the master station transmission signal and the replica signal of the sneak wave are generated.

FIG. 4 is a diagram showing the configuration of the replica generator 608. In FIG. 4, the signal output from the quadrature detector 613 is input to the shift register unit 102 of the FIR filter 101, and the transmission path estimation value output from the IFFT 607 is the tap coefficient unit 1 of the FIR filter 101.
Sent to 03. The tap coefficient unit 103 sets the transmission path estimation value to the tap coefficient, multiplies the signal output from each stage of the shift register unit 102 by the tap coefficient, and the adder 104 synthesizes the multiplication result and replicates it. Output as a signal.

The replica signal output from the replica generator 608 is converted into an IF signal by the quadrature modulator 609 and converted from a digital signal to an analog signal by the D / A converter 610. Further, the IF signal after D / A conversion is waveform-shaped by the LPF 611 and sent to the subtractor 7 as an output of the replica generation unit 6. Then, the subtractor 7 removes the multipath and the sneak wave component of the master station transmission signal from the reception signal.

As described above, in the present embodiment, attention is paid to the fact that a pilot signal whose amplitude and phase are known is inserted in advance, and error is detected by detecting frequency characteristics over the entire signal band using the pilot signal. Seeking signals, i.e., generating multipath and wraparound wave replica signals of the transmitted signal from the master station or other relay station,
The replica signal is subtracted from the received signal. As a result, even in a propagation environment in which a large number of sneak waves are present or a multipath of a master station transmission signal is present, it is possible to eliminate the effects of both.

In the error signal output unit 606, when the error function is Er (z) = 1-H (z) / F ₀ (z), the error function Er (z) = H shown above. (Z)
/ F ₀ (z) −1, the transmission path having the reverse characteristic is estimated. Therefore, by adding the output signal of the replica generation unit 6 to the received signal, the multipath of the master station transmission signal and the sneak wave component, etc. The interference signal component of is removed. In this case, the subtractor 7 is changed to an adder.

Embodiment 2. FIG. 5 is a diagram showing the configuration of the second embodiment of the wireless relay apparatus according to the present invention. Figure 5
In the figure, 614 is a BPF and 615 is a frequency converter. The same components as those in the first embodiment described above are designated by the same reference numerals and the description thereof is omitted.

In the first embodiment, the signal after the A / D conversion process (A / D 612) and the quadrature detection process (quadrature detector 613) are applied to the output signal of the BPF 8 is sent to the replica generator 608. However, in contrast to this, in the second embodiment, the output of the transmission filter 11 is set to the replica generation unit 6.
Have been sent to. However, since the signal in this case is an RF signal, it is necessary to perform A / D conversion after performing predetermined processing by the frequency converter 615 and the BPF 614.

As described above, in this embodiment, the replica signal is generated based on the RF signal. As a result, the same effect as that of the first embodiment is obtained, and the influence of the transmission amplifier 10 and the transmission filter 11 is added to the reference signal for generating the replica signal. Even if the accuracy is relaxed and nonlinearity occurs, the cancellation process can be performed with high accuracy.

Embodiment 3. FIG. 6 is a diagram showing the configuration of the third embodiment of the wireless relay apparatus according to the present invention. Figure 6
In, 13 and 14 are quadrature detectors. The same components as those in the first and second embodiments described above are designated by the same reference numerals and the description thereof will be omitted.

In the first embodiment, the RF signal is frequency-converted into the IF signal and the subtraction process is performed with the IF signal. In contrast, in the third embodiment, the subtraction process is performed with the baseband signal. I am trying.

That is, in the present embodiment, the received signal, which is the input signal of the subtractor 7, passes through the receiving filter 3 and then
The quadrature detector 13 converts the RF signal into a baseband signal. Then, the output signal of the subtractor 7 is returned to the RF signal by the quadrature modulator 14, while being converted into a digital signal by the A / D converter 612 and sent to the replica generator 608. As a result, similarly to the first embodiment, even in a propagation environment in which a large number of sneak waves are present and a multipath component of the master station transmission signal is present, it is possible to eliminate the effects of both.

Fourth Embodiment FIG. 7 is a diagram showing the configuration of the wireless relay device according to the fourth embodiment of the present invention. The same components as those in the first, second and third embodiments described above are designated by the same reference numerals and the description thereof will be omitted.

In the first to third embodiments, the subtraction process is performed with the analog signal, whereas in the fourth embodiment, the subtraction process is performed with the digital signal.

That is, in the present embodiment, the received signal, which is the input signal of the subtractor 7, passes through the BPF 5 and then the A / D
At 601 an analog signal is converted into a digital signal. The output signal of the subtractor 7 is the D / A 610
Is converted back to an analog signal. Thereby, the same effect as that of the first embodiment can be obtained, and further, the timing of the reception signal and the replica signal by the subtractor 7 can be easily adjusted, and more highly accurate cancel processing can be realized.

Embodiment 5. FIG. 8 is a diagram showing the configuration of the wireless relay device according to the fifth embodiment of the present invention. Figure 8
In the above, 606a is the error signal output unit of the fifth embodiment. 9 is a diagram showing the configuration of the error signal output unit 606a, and 657 is a frequency characteristic averaging unit. The same components as those in the first, second, third, and fourth embodiments described above are designated by the same reference numerals, and the description thereof will be omitted.

In the present embodiment, the frequency characteristic detecting section 65
Frequency characteristic averaging unit 616 that averages the output of 1
Have been added. In the present embodiment, for convenience of description, the error signal output unit 606 of the first embodiment is replaced with an error signal output unit 606a.
Not limited to this, for example, the second to the second embodiments described above
4 is also applicable.

As a result, more accurate frequency characteristics can be detected, and the multipath and sneak wave of the master station transmission signal can be canceled with higher accuracy.

The averaging process by the frequency characteristic averaging unit 657 may be either averaging by FIR filter or averaging by IIR filter. The convergence speed is changed by changing the number of stages of FIR filter or the tap coefficient of IIR filter. it can.

Further, in the above-mentioned first to fifth embodiments,
As an example, the description has been made with a radio relay device for broadcast waves in mind, but the present invention is not limited to this, and can be applied to various radio relay devices that wirelessly transmit various information, and is limited to broadcast waves. is not.

[0056]

As described above, according to the present invention, it is noted that a pilot signal having a known amplitude and phase is inserted in advance, and the frequency characteristic over the entire signal band is detected using the pilot signal. By doing so, an error signal is obtained, that is, a multipath component of a transmission signal from the master station or another relay station and a replica signal of a sneak wave are generated, and the replica signal is subtracted from the reception signal. As a result, even in a propagation environment in which a large number of sneak waves are present or a multipath component of a master station transmission signal is present, it is possible to remove the effects of both.

According to the next invention, the replica signal is generated based on the RF signal. As a result, the effect of the transmission amplifier and the transmission filter is added to the reference signal for generating the replica signal, so that the accuracy required for channel estimation is relaxed, and cancellation processing can be performed with high accuracy even when nonlinearity occurs. The effect is that it can be performed.

According to the next invention, the quadrature detecting means converts the RF signal into a baseband signal, and the output of the interference signal removing means is converted back into the RF signal by the quadrature modulating means, while the analog / digital signal is outputted. It is converted into a digital signal by the conversion means and sent to the replica generation means. As a result, even in a propagation environment in which a large number of sneak waves are present or a multipath component of a master station transmission signal is present, it is possible to remove the effects of both.

According to the next invention, the received signal is converted from the analog signal to the digital signal by the analog / digital converting means, and the output of the interference signal removing means is returned to the analog signal by the digital / analog converting means. As a result, there is an effect that the timing of the digital signal and the replica signal can be easily adjusted by the interference signal removing means, and more accurate cancel processing can be realized.

According to the next invention, the frequency characteristic obtained from the pilot signal is temporally averaged. As a result, it is possible to detect the frequency characteristic with higher accuracy and to cancel the multipath and the sneak wave of the master station transmission signal with higher accuracy.

According to the next invention, since the desired signal component is removed from the frequency characteristic of the received signal obtained from the pilot signal, the frequency characteristic of the interference signal can be obtained with high accuracy. .

According to the next invention, from the desired signal component,
Since the frequency characteristic of the received signal obtained from the pilot signal is subtracted, it is possible to obtain the inverse characteristic of the frequency characteristic of the interference signal with high accuracy.

According to the next invention, the transmission path fluctuation amount of the direct wave component of the received signal is estimated based on the frequency characteristic obtained from the pilot signal, and the power amplification amount of the transmitted signal is calculated based on the estimated value. Since the configuration is adjusted, there is an effect that the relay process can be performed while keeping the level of the master station transmission signal constant.

[Brief description of drawings]

FIG. 1 is a first embodiment of a wireless relay device according to the present invention.
It is a figure which shows the structure of.

FIG. 2 is a diagram showing a pilot signal in digital terrestrial broadcasting.

FIG. 3 is a diagram showing a configuration of an error signal output unit 606.

FIG. 4 is a diagram showing a configuration of a replica generator 608.

FIG. 5 is a second embodiment of the wireless relay device according to the present invention.
It is a figure which shows the structure of.

FIG. 6 is a third embodiment of the wireless relay device according to the present invention.
It is a figure which shows the structure of.

FIG. 7 is a fourth embodiment of the wireless relay device according to the present invention.
It is a figure which shows the structure of.

FIG. 8 is a fifth embodiment of the wireless relay device according to the present invention.
It is a figure which shows the structure of.

FIG. 9 is a diagram showing a configuration of an error signal output unit 606a.

[Explanation of symbols]

1 receiving antenna, 2 receiving amplifier, 3 receiving filter, 4,9,615 frequency converter, 5,8,614 B
PF (band pass filter), 6 replica generation section, 7
Subtractor, 10 transmission amplifier, 11 transmission filter, 1
2 transmission antennas, 13, 14, 602, 613 quadrature detector, 101 FIR filter, 102 shift register section, 103 tap coefficient section, 601, 612 A /
D converter (analog / digital converter), 60
3,654 FFT, 604 pilot signal extraction unit,
606, 606a Error signal output section, 607, 652
IFFT, 608 replica generator, 609 quadrature modulator, 610 D / A converter (digital / analog converter), 611 LPF (low pass filter), 65
1 frequency characteristic detection unit, 653 master station direct wave fluctuation amount estimation unit, 655 error signal calculation unit, 657 frequency characteristic averaging unit.

Continued front page    F term (reference) 5K067 AA02 AA03 EE06 EE10 KK03                 5K072 AA04 BB25 BB27 CC34 DD16                       GG01 GG10 GG14 GG23

Claims (8)

[Claims] 1. In a wireless relay device for relaying a received signal from a master station or another device, first frequency conversion means for frequency-converting an RF signal in a wireless frequency band into an IF signal in an intermediate frequency band; The pilot signal included in the signal is used to determine the transmission path characteristics of the multipath and sneaking waves included in the received signal (interference signal transmission path characteristics), and based on the transmission path characteristics and the specified reference signal. Replica generating means for generating a replica signal of the interference signal, an interference signal removing means for removing the effect of the interference signal by subtracting the replica signal from the IF signal, and an IF signal after interference removal for RF Second frequency conversion means for converting into a signal, and the predetermined reference signal for generating a replica signal,
A wireless relay device, wherein the wireless relay device uses the output signal of the interference signal removing means. 2. A radio relay device for relaying a received signal from a master station or another device, comprising: first frequency conversion means for frequency converting an RF signal in a radio frequency band into an IF signal in an intermediate frequency band; The pilot signal included in the signal is used to determine the transmission path characteristics of the multipath and sneaking waves included in the received signal (interference signal transmission path characteristics), and based on the transmission path characteristics and the specified reference signal. Replica generating means for generating a replica signal of the interference signal, an interference signal removing means for removing the effect of the interference signal by subtracting the replica signal from the IF signal, and an IF signal after interference removal for RF Second frequency conversion means for converting into a signal, and the predetermined reference signal for generating a replica signal,
A radio relay apparatus, wherein the signal after the interference is removed is subjected to power amplification processing and waveform shaping processing. 3. A radio relay device for relaying a received signal from a master station or another device, and quadrature detection means for converting an RF signal in a radio frequency band into a baseband signal, and a predetermined reference for the baseband signal. Using the included pilot signal, obtain the transmission path characteristics of the multipath and sneak wave included in the received signal (transmission path characteristics of the interference signal),
Replica generation means for generating a replica signal of the interference signal based on the transmission line characteristic and a predetermined reference signal, and an interference signal for removing the influence of the interference signal by subtracting the replica signal from the baseband signal And a quadrature modulation means for converting the interference-removed baseband signal into an RF signal, the predetermined reference signal for generating a replica signal,
A wireless relay device, wherein the wireless relay device uses the output signal of the interference signal removing means. 4. In a wireless relay device for relaying a received signal from a master station or another device, first frequency conversion means for frequency-converting an RF signal in a wireless frequency band into an IF signal in an intermediate frequency band; By using analog / digital conversion means for converting a signal (analog signal) into a digital signal and a pilot signal included in the digital signal according to a predetermined reference, transmission path characteristics (interference) of multipaths and sneak waves included in a received signal are obtained. Signal transmission path characteristics), replica generation means for generating a replica signal of the interference signal based on the transmission path characteristic and a predetermined reference signal, and the interference by subtracting the replica signal from the digital signal. Interference signal removing means for removing the influence of the signal, and converting the digital signal after interference removal into an analog signal (IF signal) And Ijitaru / analog conversion means, and the second frequency converting means for converting the IF signal into an RF signal, includes a, the predetermined reference signal for generating the replica signal,
A wireless relay device, wherein the wireless relay device uses the output signal of the interference signal removing means. 5. The replica generation means averages amplitude and phase characteristics on a frequency axis obtained from the pilot signal in a direction on a time axis. The wireless relay device according to. 6. The replica generation means obtains a frequency characteristic of an interference signal by removing a desired signal component from a frequency characteristic of a received signal obtained from the pilot signal. The wireless relay device according to any one of the above. 7. The replica generation means obtains an inverse characteristic of a frequency characteristic of an interference signal by subtracting a frequency characteristic of a received signal obtained from the pilot signal from a desired signal component. The wireless relay device according to any one of 1 to 5. 8. The replica generation means estimates a transmission path fluctuation amount of a direct wave component of a received signal based on a frequency characteristic obtained from the pilot signal, and a power amplification amount of a transmitted signal based on the estimated value. The wireless relay device according to claim 1, wherein the wireless relay device according to claim 1 is adjusted.