JPH088875A - Device for compensating interference between cross polarization and radio receiver - Google Patents

Abstract

PURPOSE:To compensate interference between cross polarization even while adopting a set standby system. CONSTITUTION:The devices 14-1, 14-2 and 24 for compensating the interference between the cross polatization respectively provided in active system receivers 1-1 and 1-2 and a standby system receiver 2 selectively fetch one of the demodulated output of respective demodulators provided in the two receivers different from the belonging receiver by interference wave selection switches 14b-1, 14b-2 and 24b, use it as interference wave signals and compensate the interference between the cross polarization of signals received in the attached receiver.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio receiving apparatus having a ratio of one working system to two working systems and a cross polarization interference compensating device applied to this radio receiving apparatus.

[0002]

2. Description of the Related Art In a communication system requiring reliability such as a digital microwave radio communication system, in order to remedy a decrease in transmission quality or a line disconnection caused by fading in a transmission line or a device failure, To prevent the loss of communication when performing line maintenance,
It is common practice to have a working / standby redundant configuration.

In the case of adopting such a redundant structure, a system spare system has been conventionally adopted. FIG. 3 is a diagram showing a configuration example of a digital microwave radio communication system adopting a system standby system. When the system standby system is adopted as shown in this figure, a large number (five in this case) of active transmitters 32 (32-1 to 32-
For 5), one standby transmitter 33 is provided. The active transmitters 32-1 to 32-5 have SYS1 to SYS5.
5 signals are input. Further, any one of the five signals SYS1 to SYS5 is selectively input to the standby transmitter 33. And the active transmitter
32-1 and the standby system transmitter 33 input the signal to the frequency f ₁ , the active system transmitter 32-2 and the active system transmitter 32-3 transmit the input signal to the frequency f ₂ , and the active system transmission The machine 32-4 and the active transmitter 32-5 respectively modulate the input signal to the frequency f ₃ . Further, the modulated outputs of the active system transmitter 32-2, the active system transmitter 32-4, and the standby system transmitter 33 are radiated from the transmission antenna 34 in the vertical polarization (V polarization). The modulated outputs of the active system transmitter 32-1, the active system transmitter 32-3, and the active system transmitter 32-5 are radiated from the transmitting antenna 34 as horizontal polarized waves (H polarized waves).

On the other hand, the receiver 31 includes an active transmitter 32.
-1 to 32-5 corresponding to the five active receivers 35
And (35-1～35-5), and a standby system receiver 36 corresponding to the standby system transmitter 33 is provided, V-polarized wave of frequency f ₁ is in the standby system receiver 36, a frequency f ₁ The H polarized wave is the working system receiver 35-1, and the V polarized wave of frequency f ₂ is the working system receiver 35-2.
The H-polarized wave of frequency f ₂ is received by the working receiver 35-3, and the frequency f ₃
V polarization of the active receiver 35-4, and H of frequency f ₃
The polarized waves are respectively received by the active receiver 35-5.

Thus, between the transmitter 30 and the receiver 31, five signals SYS1 to SYS5 are transmitted in the frequency arrangement as shown in FIG. Note that the backup channel (V-polarized wave of frequency f ₁ ) transmits any one of the five signals SYS1 to SYS5 as necessary.

In the digital microwave radio communication system described above, cross polarization is used. However, when cross polarization is performed in this way, cross polarization interference occurs on the transmission line, so that the reception device 31 crosses the cross polarization. Compensation for polarization interference.

FIG. 5 is a diagram showing a configuration for compensating for cross polarization interference in the receiver 31. As shown in the figure, each of the active system receivers 35-1 to 35-5 and the standby system receiver 36 includes a cross polarization interference canceller (XPIC) 35a.
-1 to 35a-5 and 36a are provided. This XPIC 3
Each of 5a-1 to 35a-5 and 36a receives a main wave demodulation signal and an interference wave demodulation signal, and performs processing of compensating for cross polarization interference occurring in the main wave demodulation signal using the interference wave demodulation signal. .

Demodulators 35b-1 to 35b- provided in the receivers to which the XPICs 35a-1 to 35a-5 and 36a belong, respectively.
The demodulated signals output from 5 and 36b are input as the main wave demodulated signals. Also, XPIC 35a-1 to 35a-5,
Demodulators 36a output demodulators 35b-1 to 35b-5, 36b provided in receivers that receive signals of different polarization directions at the same frequency as that of the receivers to which they belong. The signals are input as interference wave demodulation signals. That is, the demodulated signal output from the demodulator 36b provided in the standby receiver 36 is supplied to the XPIC 35a-1, and the demodulator 35b-3 provided to the working receiver 35-3 is supplied to the XPIC 35a-2. The demodulated signal output is the demodulated signal output by the demodulator 35b-2 provided in the working receiver 35-2 to the XPIC 35a-3, and the demodulated signal output to the working receiver 35-5 in the XPIC 35a-4. The demodulated signal output from the demodulator 35b-5 is output as an interference wave demodulated signal to the XPIC 35a-5, and the demodulated signal output from the demodulator 35b-4 provided in the active receiver 35-4 is output to the XPIC 35a-5. It has been entered.

In the digital microwave radio communication system adopting the system standby system as described above, the frequency transmitted and received by each transmitter and each receiver is fixed and fixed, so that a signal to be an interference wave demodulation signal is obtained. Is also fixed. Therefore, the cross polarization interference can be compensated by the configuration shown in FIG.

However, in recent years, there is a tendency that the set spare system is adopted for the purpose of economy and effective use of frequency. FIG. 6 is a diagram showing an example of the configuration of a digital microwave radio communication system which adopts the set spare system. When the system standby system is adopted as shown in this figure, the transmitter 60 has two working transmitters 62 (62-1,
62-2) is provided with one standby transmitter 63. The active transmitters 62-1 and 62-2 and the standby transmitter 63 both modulate the input signal with the frequency f ₁ . The two signals SYS1 and SYS2 are normally input to the active transmitters 62-1 and 62-2 by the line switch 64, respectively. Further, normally, the modulation outputs of the active transmitters 62-1 and 62-2 are selected by the line switch 65 and given to the transmitting antenna 66, and the modulated output of the active transmitter 62-1 is transmitted to the transmitting antenna 66. The V-polarized wave is emitted from 66 and the modulated output of the active transmitter 62-2 is emitted from the transmitting antenna 66 in the H-polarized wave. The line switch 64 is S if necessary.
The YS1 signal or the SYS2 signal is transmitted to the standby system transmitter 63.
Can be entered. At this time, the line switch 65
If the SYS1 signal is input to the standby transmitter 63, the modulated output of the standby transmitter 63 is given to the transmitting antenna 66 to radiate the V polarization, and the SYS2 signal is input to the standby transmitter 63. If so, the modulated output of the transmitter 63 of the standby system is given to the transmitting antenna 66 in order to radiate the H polarized wave.

On the other hand, the receiver 61 includes an active transmitter 62.
-1, 62-2 corresponding to two active receivers 67
(67-1, 67-2) and a standby system receiver 68 corresponding to the standby system transmitter 63 are provided. Then, two of these three receivers are also activated by the line switches 70 and 71 provided corresponding to the line switches 64 and 65 in the same manner as the transmitter 60.

Thus, the signals of SYS1 and SYS2 are transmitted between the transmitter 60 and the receiver 61 in the frequency arrangement shown in FIG. The frequency arrangement does not change even when either the SYS1 signal or the SYS2 signal is transmitted via the standby transmitter 63.

When such a set spare system is adopted, it is either the active system receiver 67-1 or the standby system receiver 68 that receives the V polarization, and the line switch 70,
It changes depending on the selection state at 71. The H-polarized wave is received by either the active receiver 67-2 or the standby receiver 68, which also varies depending on the selected state of the line switching devices 70 and 71. Therefore, the active receivers 67-1, 67
For each of the -2 and the standby system receiver 68, the receiver from which a signal corresponding to the interference wave demodulated signal can be obtained changes depending on the selected states of the line switching devices 70 and 71.
Cross-polarization interference cannot be compensated by the above-mentioned configuration for compensating cross-polarization interference in the case of the system standby system configuration.

[0014]

As described above, the prior art is as follows.
Since the system standby system was adopted, it was possible to easily obtain the interference wave signal for compensating the cross polarization interference on the receiving side, and it was possible to compensate the cross polarization interference. If the method is adopted, there is a problem that the cross polarization interference cannot be compensated accurately.

The present invention has been made in view of such circumstances, and an object thereof is to provide a cross polarization between cross polarizations capable of compensating for cross polarization interference while adopting a set spare system. An object is to provide an interference compensation device and a wireless reception device.

[0016]

In order to achieve the above object, the cross polarization interference compensating device of the present invention is provided corresponding to each of the working system and the standby system, and the interference wave signals input separately. Compensation means for compensating cross-polarization interference of signals of the corresponding system based on, for example, a compensating means such as a cross-polarization interference compensator, and the corresponding systems provided for the working system and the standby system, respectively. Together with a selecting means such as an interference wave selecting switch for selecting one of the signals of the other two systems forming a set and giving the selected signal to the compensating means of the corresponding system as an interference wave signal. Equipped with.

In order to achieve the above-mentioned object, the radio receiving apparatus of the present invention is provided corresponding to each of the working system and the standby system, and the signals of the corresponding system are provided based on the interference wave signals input separately. Each of the compensating means such as a cross-polarization interference compensator for compensating the cross-polarization interference, and the compensating means provided corresponding to each of a pair of two working systems and one standby system Of two outputs indicated by the switching control signal given from the outside, which are provided to correspond to the line switching means, such as a line switch, which activates the two, and the active system and the standby system. Any one of the signals of the other two systems forming a set together with the corresponding system is selected, and the selected signal is given to the compensating means of the corresponding system as an interference wave signal. And a selection means such as a-option switch.

Further, in another radio receiving apparatus of the present invention, the selecting means in the radio receiving apparatus is based on the switching control signal for either one of the signals of the other two systems forming a set together with the corresponding system. I chose it. Further, in another radio receiving apparatus of the present invention, the line switching means in the radio receiving apparatus performs the switching after the selection change of the selection means is completed.

[0019]

By taking such means, compensation of cross-polarization interference of signals of the corresponding system provided on the basis of the interference wave signals provided for the working system and the standby system, respectively, is provided. In the compensating means for carrying out the above, by the selecting means provided corresponding to each of the working system and the standby system, one of the signals of the other two systems forming a pair with the corresponding system is provided. It is selectively given as an interference wave signal.

Therefore, by selecting the signal of the valid system of the other two systems forming a set together with the corresponding system by the selecting means, either of the above two systems becomes valid. However, the interference wave signal can be reliably obtained.

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a functional block diagram showing a main configuration of a digital microwave radio receiver according to this embodiment. The same parts as those in FIG. 6 are designated by the same reference numerals.

This digital microwave radio receiver (hereinafter referred to as a receiver) comprises two active receivers 1.
(1-1, 1-2), the standby system receiver 2, the switch control circuit 3, the receiving antenna 69, and the line switching devices 70, 71, and adopts the set standby system.

That is, the V-polarized signal obtained by receiving the V-polarized radio wave at the receiving antenna 69 is the line switch 70.
Is given to either the active system receiver 1-1 or the standby system receiver 2. The H-polarized wave signal obtained by receiving the H-polarized wave at the receiving antenna 69 is given to either the active receiver 1-2 or the standby receiver 2 by the line switch 70. However, the V polarization signal and the H polarization signal are not simultaneously given to the standby system receiver 2. The line switch 71 selects two of the active receivers 1-1 and 1-2 and the standby receiver 2 in the same manner as the line switch 70, and outputs the signal output by the selected receiver to the SYS1. Signal and S
Output as YS2 signal. The line switch 70,
Reference numeral 71 performs line switching according to a switching control signal SEL given from the outside of the device.

The active system receivers 1-1 and 1-2 and the standby system receiver 2 have the same structure, and the band pass filter 11 is used.
-1, 11-2, 21, amplifier 12-1, 12-2, 22, demodulator 13-
1, 13-2, 23 and cross polarization interference compensator (XPI
C) Consists of 14-1, 14-2 and 24.

The bandpass filters 11-1, 11-2 and 21 respectively extract the components of the frequency band of interest from the signal given through the line switching device 70, and the amplifiers 12-1 and 12 respectively.
-2 and 22 are given respectively.

The amplifiers 12-1, 12-2 and 22 amplify the signals respectively supplied from the bandpass filters 11-1, 11-2 and 21 to a level suitable for demodulation processing and demodulate the signal. -1, 13-2, 23 respectively.

The demodulators 13-1, 13-2 and 23 demodulate the signals respectively supplied from the amplifiers 12-1, 12-2 and 22 and the demodulated outputs are respectively sent to the XPICs 14-1, 14-2 and 24. give.

XPICs 14-1, 14-2 and 24 are respectively subtractors 14a-1, 14a-2 and 24a, and interference wave selection switch 14b-.
1, 14b-2, 24b and transversal filters (TRV FIL) 14c-1, 14c-2, 24c.
The subtractors 14a-1, 14a-2, and 24a are respectively demodulators 13-
1, 13-2, 23 demodulation output and transversal filter 1
The compensation signals output from 4c-1, 14c-2, and 24c are input, and the compensation signal is subtracted from the demodulation signal to obtain a signal in which cross polarization interference is compensated.

In the transversal filter 14c-1, either the demodulation output of the demodulator 13-2 of the active system receiver 1-2 or the demodulation output of the demodulator 23 of the standby system receiver 2 is the interference wave selection switch 14b-. 1 is applied via the interference wave selecting switch 14b-1 to generate a compensation signal having a frequency characteristic equivalent to that of the interference wave component. The interference wave selection switch 14b-1 receives the demodulation output of the demodulator 13-2 of the active receiver 1-2 at one terminal TA and the other terminal T at the other terminal T.
The demodulation output of the demodulator 23 of the standby receiver 2 is input to B, and one of these two signals is selected under the control of the switch control circuit 3.

In the transversal filter 14c-2, one of the demodulation output of the demodulator 13-1 of the active system receiver 1-1 and the demodulation output of the demodulator 23 of the standby system receiver 2 is the interference wave selection switch 14b-. 2 is applied via the interference wave selection switch 14b-2 to generate a compensation signal having a frequency characteristic equivalent to that of the interference wave component. The interference wave selection switch 14b-2 is provided with the demodulation output of the demodulator 13-2 of the active receiver 1-1 at one terminal TA and the other terminal T.
The demodulation output of the demodulator 23 of the standby receiver 2 is input to B, and one of these two signals is selected under the control of the switch control circuit 3.

In the transversal filter 24c, one of the demodulation output of the demodulator 13-1 of the active receiver 1-1 and the demodulation output of the demodulator 13-2 of the active receiver 1-2 is an interference wave selection switch. 24b, and a compensation signal having a frequency characteristic equivalent to that of the interference wave component is generated from the signal supplied via the interference wave selection switch 24b. The interference wave selection switch 24b has one terminal TA for receiving the demodulation output of the demodulator 13-2 of the active receiver 1-2, and the other terminal TB for receiving the demodulator 13-1 of the active receiver 1-1. Of the two signals are selected, and one of these two signals is selected under the control of the switch control circuit 3.

The switch control circuit 3 uses the switching control signal S provided to the line switching devices 70 and 71 from outside the device.
In response to the EL, the line selection states of the line switching units 70 and 71 are judged, and the interference wave selection switch 14b-
1, 14b-2, 24b are controlled respectively.

Next, the operation of the receiving apparatus configured as above will be described. First, the receiving apparatus of this embodiment basically uses the active receivers 1-1 and 1-2 for reception. That is, the V-polarized signal obtained by the receiving antenna 69 is given to the working receiver 1-1 by the line switch 70. The H polarized wave signal obtained by the receiving antenna 69 is given to the active receiver 1-2 by the line switch 70.

Thus, in this basic state, the V-polarized signal is extracted by the bandpass filter 11-1 in the required frequency band and is amplified by the amplifier 12-1 before being demodulated by the demodulator 13.
-1 demodulates. Further, the XPIC 14-1 compensates the cross polarization interference for the demodulated output of the demodulator 13-1. The H-polarized wave signal is extracted by the band-pass filter 11-2 into a desired frequency band, amplified by the amplifier 12-2, and then demodulated by the demodulator 13-2. Further, the demodulation output of the demodulator 13-2 is compensated for cross polarization interference in the XPIC 14-2. The output of XPIC14-1 is the signal of SYS1, and the output of XPIC14-2 is S.
The signal of YS2 is selected and output by the line switch 71.

At this time, the switch control circuit 3 switches the interference wave selection switch 14b-1 to the terminal T as shown in FIG.
It is controlled to select the A side. Therefore, the demodulation output of the demodulator 13-2 is given to the transversal filter 14c-1, and a compensation signal is generated from the demodulation output of the demodulator 13-2. The XPIC 14-1 having the transversal filter 14c-1 compensates for cross polarization interference by V
It is a demodulated signal obtained by demodulating a polarized signal. The H polarized wave signal which is an interference wave signal for this signal is received by the active receiver 1-2, and the demodulated signal is output from the demodulator 13-2. Therefore, the interference wave signal is accurately given to the transversal filter 14c-1, and the XPIC 14-1 normally compensates the cross polarization interference using the correct compensation signal.

Further, in the above basic state, the switch control circuit 3 is, as shown in FIG.
Is controlled to select the terminal TA side. Therefore, the demodulation output of the demodulator 13-1 is applied to the transversal filter 14c-2, and the compensation signal is generated from the demodulation output of the demodulator 13-1. This transversal filter 14c-
It is the demodulated signal obtained by demodulating the H-polarized signal that compensates for the cross polarization interference in the XPIC 14-2 having 2. The V-polarized wave signal which is an interference wave signal for this signal is received by the active receiver 1-1, and the demodulated signal is output from the demodulator 13-1. Therefore, the transversal filter
The interference wave signal is accurately given to 14c-2, and
In C14-2, the cross polarization interference is normally compensated by using the correct compensation signal.

Now, from the above basic state, the working system receiver 1-
When a failure occurs in 2, the V-polarized signal is received by the active receiver 1-1 and the H-polarized signal is received by the standby receiver 2 from a failure monitor (not shown) or a manual line setting switch. A switching control signal SEL for switching the lines to be received is provided.

In response to this, the V-polarized signal obtained at the receiving antenna 69 is sent to the working receiver by the line switch 70.
Given to 1-1. In addition, H obtained by the receiving antenna 69
The polarization signal is given to the standby receiver 2 by the line switch 70.

Thus, in this state, the V-polarized signal is received by the active receiver 1-1 in the same manner as in the basic state. Further, the H-polarized signal has a desired frequency band extracted by the band pass filter 21, amplified by the amplifier 22, and then demodulated by the demodulator 23. Further, the demodulation output of the demodulator 23 is compensated for cross polarization interference in the XPIC 24. Then, the output of the XPIC 14-1 is selected as the signal of SYS1 and the output of the XPIC 24 is selected as the signal of SYS2 by the line switching unit 71 and outputted.

At this time, the switch control circuit 3 switches the interference wave selection switch 14b-1 to the terminal T as shown in FIG.
It is controlled to select the B side. Therefore, the demodulation output of the demodulator 23 is given to the transversal filter 14c-1, and a compensation signal is generated from the demodulation output of the demodulator 23. The XPIC 14-1 having the transversal filter 14c-1 compensates for cross polarization interference by V
It is a demodulated signal obtained by demodulating a polarized signal. The H-polarized wave signal, which is an interference wave signal for this signal, is received by the standby system receiver 2, and the demodulated signal thereof is output from the demodulator 23. Therefore, the interference wave signal is accurately given to the transversal filter 14c-1, and the XPIC 14-1 normally compensates the cross polarization interference using the correct compensation signal.

As shown in FIG. 2, the switch control circuit 3 controls the interference wave selection switch 24b so as to select the terminal TB side. For this reason, the demodulation output of the demodulator 13-1 is given to the transversal filter 24c,
A compensation signal is generated from the demodulation output of the demodulator 13-1. XPIC 24 having this transversal filter 24c
It is the demodulation signal obtained by demodulating the H polarization signal that compensates for the cross polarization interference. The V-polarized wave signal which is an interference wave signal for this signal is received by the active receiver 1-1, and the demodulated signal is output from the demodulator 13-1. Therefore, the interference wave signal is accurately given to the transversal filter 24c, and the XPIC 24 normally compensates the cross polarization interference using the correct compensation signal.

On the other hand, from the basic state, the working system receiver 1-1
When a failure occurs in, for example, a failure monitoring device not shown,
Alternatively, from the manual line setting switch, the V polarization signal is received by the standby system receiver 2, and the H polarization signal is received by the active system receiver 1-2.
At, a switching control signal SEL for switching the line to be received is given.

In response to this, the V-polarized signal obtained by the receiving antenna 69 is given to the standby system receiver 2 by the line switch 70. The H polarized wave signal obtained by the receiving antenna 69 is given to the active receiver 1-2 by the line switch 70.

Thus, in this state, the H polarization signal is received by the active receiver 1-2 in the same manner as in the basic state. Further, the V-polarized signal is subjected to extraction of a desired frequency band by the bandpass filter 21, amplified by the amplifier 22, and then demodulated by the demodulator 23. Further, the demodulation output of the demodulator 23 is compensated for cross polarization interference in the XPIC 24. The output of the XPIC 24 is selected and output by the line switch 71 as the SYS1 signal, and the output of the XPIC 14-2 is selected by the line switch 71.

At this time, the switch control circuit 3 switches the interference wave selection switch 14b-2 to the terminal T as shown in FIG.
It is controlled to select the B side. Therefore, the demodulation output of the demodulator 23 is given to the transversal filter 14c-2, and the compensation signal is generated from the demodulation output of the demodulator 23. The XPIC 14-2 having the transversal filter 14c-2 compensates for cross polarization interference by using H
It is a demodulated signal obtained by demodulating a polarized signal. The V-polarized wave signal, which is an interference wave signal for this signal, is received by the standby receiver 2, and the demodulated signal is output from the demodulator 23. Therefore, the interference wave signal is accurately given to the transversal filter 14c-2, and the XPIC 14-2 normally compensates the cross polarization interference using the correct compensation signal.

As shown in FIG. 2, the switch control circuit 3 controls the interference wave selection switch 24b so as to select the terminal TA side. Therefore, the demodulation output of the demodulator 13-2 is given to the transversal filter 24c,
A compensation signal is generated from the demodulation output of the demodulator 13-2. XPIC 24 having this transversal filter 24c
It is the demodulation signal obtained by demodulating the V polarization signal that compensates for the cross polarization interference. The H polarized wave signal which is an interference wave signal for this signal is received by the active receiver 1-2, and the demodulated signal is output from the demodulator 13-2. Therefore, the interference wave signal is accurately given to the transversal filter 24c, and the XPIC 24 normally compensates the cross polarization interference using the correct compensation signal.

As described above, according to the present embodiment, the effective two of the XPICs 14-1, 14-2, and 24 are normally operated between the cross polarizations in any line setting state while adopting the set spare system. Interference compensation can be performed.

Further, in this embodiment, the interference wave selection switch 14
Since b-1, 14b-2, 24b are controlled based on the state of the switching control signal SEL indicating the line selection state in the line switching devices 70, 71, these interference wave selection switches 14b-1, It is not necessary to separately prepare a control signal for controlling 14b-2 and 24b.

By the way, if the line selectors 70, 71 and the interference wave selection switches 14b-1, 14b-2, 24b are switched in synchronization with the switching control signal SEL, the line selectors 70, 71 and the interference wave selectors are selected. Switches 14b-1, 14b-
2 and 24b are switched at almost the same time.
However, in the receiver, a signal may be fed back from the XPIC to the demodulator, and in this case, it takes time for the operation of the demodulator to stabilize after the interference wave selection switch is switched. Therefore, the line switch 71
The operation of the demodulator was unstable for a while after the
The demodulated output becomes unstable, and this unstable signal may be transmitted to the device at the subsequent stage, so that the device at the subsequent stage may perform error detection. Under such circumstances, the interference wave selection switches 14b-1, 14b-2,
After switching 24b, wait for the operation of the demodulators 13-1, 13-2, 23 to stabilize (for example, with a slight delay)
It is preferable to switch the line switch 71. This can be realized by providing the line switch 71 with a time constant to delay the switching timing with respect to the change timing of the switching control signal SEL, or by giving different control signals with different timings. .

The present invention is not limited to the above embodiment. For example, in the above embodiment, the line switching devices 70 and 7
1 and the interference wave selection switches 14b-1, 14b-2, and 24b are commonly controlled by the switching control signal SEL, but each may be controlled by another control signal.

In the above embodiment, the cross polarization interference canceling apparatus and the radio receiving apparatus according to the present invention are applied to the digital microwave radio communication system. However, other radio communication systems using cross polarization can be used. Can also be applied. In addition, various modifications can be made without departing from the scope of the present invention.

[0052]

According to the present invention, the cross polarization interference of the signals of the corresponding system is compensated on the basis of the interference wave signals which are provided for the working system and the standby system respectively and are separately input. Compensation means is provided corresponding to each of the active system and the standby system, and one of the signals of the other two systems forming a pair with the corresponding system is selected, and the selected signal is selected. Since it is provided with a selecting means for giving as a coherent wave signal to the compensating means of the corresponding system, a cross polarization interference canceling device and a radio capable of compensating cross polarization interference while adopting the set spare method. It becomes a receiver.

Further, according to the present invention, it is further effective 2
Based on a switching control signal given from the outside to specify one system, the selecting means selects either one of the signals of the other two systems forming a set together with the corresponding system. The wireless receiving device does not need to separately control the means.

Further in accordance with the present invention, a set of 2
The line switching means for selecting and validating two of the outputs of the compensating means provided corresponding to each of the working system of the system and the standby system of one system, which are indicated by the switching control signal given from the outside. However, since the switching is performed after the selection change of the selecting means is completed, the radio receiving apparatus can perform the line switching after the operation of each system is stabilized.

[Brief description of drawings]

FIG. 1 is a functional block diagram showing a main configuration of a digital microwave radio receiver according to an embodiment of the present invention.

[FIG. 2] Interference wave selection switches 14b-1, 14b-2,
The figure which shows the correspondence of the state of 24b, and the line selection state in the line switching devices 70 and 71.

FIG. 3 is a diagram showing a configuration example of a digital microwave radio communication system adopting a system standby system.

FIG. 4 is a diagram schematically showing a frequency arrangement of signals transmitted between a transmitting device 30 and a receiving device 31 in FIG.

5 is a diagram showing a configuration for compensating for cross polarization interference in the receiving device 31 in FIG.

FIG. 6 is a diagram showing an example of the configuration of a digital microwave radio communication system that employs a set backup method.

FIG. 7 is a diagram schematically showing a frequency arrangement of signals transmitted between a transmission device 60 and a reception device 61 in FIG.

Claims (4)

[Claims] 1. A ratio of one active system to two active systems, and any two of the two active systems and one standby system forming a set use the same frequency band. It is applied to a radio receiving device that receives signal waves that arrive with different polarization directions from each other, and is for compensating for cross-polarization interference that occurs in a received signal, each of the working system and the standby system. Compensating means for compensating for cross-polarization interference of signals of the corresponding system based on the interference wave signals separately input, and provided for the working system and the standby system, respectively. And selecting means for selecting one of the signals of the other two systems forming a set together with the corresponding system, and providing the selected signal to the compensating means of the corresponding system as an interference wave signal. Equipped Cross polarization interference compensating device comprising and. 2. Any one of two working system demodulating means and one working system demodulating means, which is constituted by a ratio of one working system demodulating means to two working system demodulating means, and which forms a pair.
One is a radio receiving apparatus that performs demodulation of signal waves that arrive with different polarization directions using the same frequency band, and is provided corresponding to each of the working system and the standby system, and is input separately. Compensation means for compensating the cross polarization interference of the signal of the corresponding system based on the interference wave signal, and a pair of two working systems and one standby system provided for each of the above Among the respective outputs of the compensating means, the line switching means for selecting and validating two shown by the switching control signal given from the outside, and the line switching means are provided corresponding to the working system and the standby system, respectively. Selecting means for selecting one of the signals of the other two systems forming a set together with the corresponding system, and providing the selected signal to the compensating means of the corresponding system as an interference wave signal. Radio receiving apparatus characterized by Bei was. 3. The selecting means according to claim 2, wherein either one of the signals of the other two systems forming a set together with the corresponding system is selected based on the switching control signal. Wireless receiver. 4. The line switching means performs switching after the selection change of the selection means is completed.
Alternatively, the wireless reception device according to claim 3.