JP4120422B2 - Cross-polarization interference compensator circuit reset method and cross-polarization interference canceller - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a digital microwave communication system using a cross polarization transmission system, and more particularly to a cross polarization interference compensator circuit that removes an interference component between cross polarizations.
[0002]
[Prior art]
In the digital microwave communication method using the cross polarization transmission method, the V polarization and the H polarization that are orthogonal to each other use the same frequency. Signal leakage from the wave to the H polarization or from the H polarization to the V polarization occurs. This leakage is called cross-polarization interference, and adversely affects signal transmission quality.
[0003]
In particular, when both polarization transmission methods and multi-level modulation / demodulation methods such as QAM are used together, the effect is significant. Therefore, interference components are eliminated using a cross polarization interference canceller (XPIC). Is done.
[0004]
Conventionally, when both the self-polarized wave and the cross-polarized wave (defining the target polarized wave in XPIC as the self-polarized wave and the radio wave polarized so as to be orthogonal thereto) are synchronized (carrier) In the state where the signal is normally demodulated), the XPIC circuit is set to the auto state (the XPIC circuit is operating normally) to remove the interference component, and the synchronization is lost (the carrier is lost) When the signal cannot be demodulated normally), the XPIC circuit is reset (the XPIC circuit is stopped) so that interference components are not removed (see, for example, Patent Documents 1 and 2).
[0005]
FIG. 7 is a block diagram showing an example of a demodulation circuit in a digital microwave communication apparatus using a conventional cross polarization interference compensator. In FIG. 7, since the configurations of the V polarization and the H polarization are the same, the following description will be made assuming that the V polarization is an own polarization signal and the H polarization is a different polarization signal.
[0006]
The transmitted polarization signal is input to the terminal 1, frequency-converted by the multiplier 5, and then converted to a digital signal through the low-pass filter 11 and the A / D converter 15. This digital signal and a carrier signal generated by a numerically controlled oscillator (NCO) 21 are input to an infinite phase shifter (EPS) 20 to perform frequency conversion and demodulate the baseband signal. The carrier synchronization controller 22 generates a phase control signal based on the error signal generated by the determination circuit 39, and performs frequency control of the secondary carrier signal generated by the NCO 21. The infinite phase shifter 20, NCO 21, and carrier synchronization controller 22 constitute a demodulator 19.
[0007]
The cross-polarized signal input to the terminal 3 is frequency-converted by the multiplier 6 and then converted to a digital signal through the low-pass filter 12 and the A / D converter 16. This digital signal is input to the infinite phase shifter 28 together with the carrier signal generated by the NCO 21 common to the own polarization side, and is frequency-converted to become an XPIC reference signal. The XPIC reference signal and the tap coefficient of the XPIC generated by the tap coefficient control circuit 30 are input to the transversal filter 29, and a cross-polarized duplicate signal is generated. The infinite phase shifter 28, the transversal filter 29, and the tap coefficient control circuit 30 constitute a cross polarization interference compensator (XPIC) 27.
[0008]
Then, the cross polarization interference is removed by subtracting the duplicate signal of the different polarization interference component from the own polarization baseband signal by the adder 35 and removing it. The OR circuit 43 inputs the synchronous asynchronous information from the own polarization determination circuit 39 and the synchronous asynchronous information from the different polarization determination circuit 40 and controls the XPIC circuit 27.
[0009]
When the own polarization and the different polarization are synchronized, the XPIC circuit 27 is set to the auto state by the output of the OR circuit 43, and the interference removal operation for the different polarization component is performed. On the other hand, when at least one of the own polarization and the different polarization is out of synchronization, the XPIC circuit 27 is reset by the OR output of the synchronous asynchronous information of the determination circuit 39 and the determination circuit 40, and the different polarization component The interference cancellation operation is stopped. That is, the XPIC circuit 27 is reset except when the own polarization and the different polarization are synchronized as shown in FIG.
[0010]
[Patent Document 1]
JP-A-3-147437 [Patent Document 2]
Japanese Patent Laid-Open No. 10-303847
[Problems to be solved by the invention]
FIG. 9 shows the D / U ratio (level ratio between the main wave and interference wave) of the own polarization (for example, H polarization) and the different polarization (for example, V polarization) orthogonal to each other, FIG. 9 is a diagram showing a synchronous pull-in range. In the above-described conventional method, there is a problem that the pull-in characteristic of XPIC becomes as shown by the dotted line in FIG. This is because the XPIC circuit 27 is always in a reset state until synchronous pull-in, and therefore, when the own polarization and the different polarization are leaking from each other, the different polarization component cannot be removed. This is because the synchronization information is not output from.
[0012]
Therefore, in Patent Documents 1 and 2, an intermittent reset signal is transmitted by intermittently canceling the XPIC reset, and the intermittent reset is canceled and the reset signal is transmitted as it is when the own polarization is in a synchronized state. By providing the switching means, it is easy to perform synchronization pull-in when cross-polarization interference is improved, and an early return to the normal operation state is attempted. However, these configurations also have the following problems.
[0013]
In the state where the intermittent reset signal is transmitted by the configuration described in the above patent document, when the own polarization is different from the other polarization and the different polarization leaks into the own polarization, the own polarization is synchronized from the out of synchronization. If the XPIC circuit is reset immediately after the change to, the cross polarization component cannot be removed, and the synchronization may be lost again.
[0014]
When the XPIC circuit is changed to the auto state immediately after the own polarization is synchronized, the own polarization is kept in the synchronized state, but the tap coefficient control circuit of the XPIC circuit operates because the XPIC circuit is in the auto state. Therefore, the tap coefficient of XPIC (the own polarization itself) becomes large. For this reason, at the moment when the XPIC circuit is changed from the auto state to the reset state, the component of the own polarization may be affected, and the own polarization may come off again.
[0015]
In view of the above problems, an object of the present invention is to provide a cross-polarization interference compensator capable of achieving stable synchronization even when there is a large leakage from the own polarization to the different polarization and from the different polarization to the own polarization. It is to provide a circuit reset method.
[0016]
[Means for Solving the Problems]
The cross-polarization interference compensator circuit reset method of the present invention sets the cross-polarization interference compensation circuit (XPIC circuit) to the first intermittent reset state when the self-polarized wave and the different polarization are in an asynchronous state, and the first intermittent reset is performed. When the own polarization changes to a synchronous state in the state, the XPIC circuit is set to a reset state. When the own polarization changes to an asynchronous state again in the reset state, the XPIC circuit is set to a second intermittent reset state. 2 When the own polarization changes to the synchronized state in the intermittent reset state, the XPIC circuit is set to the auto state for a predetermined time from the change time point, and when the different polarization changes to the synchronized state within the predetermined time, the XPIC circuit is The XPIC circuit is switched to the reset state again when the auto polarization state is maintained and the different polarizations are not synchronized within the predetermined time. That.
[0017]
Further, the cross polarization interference canceling apparatus of the present invention includes a demodulator that demodulates the own polarization baseband signal from the transmitted own polarization signal, and a different polarization from the transmitted different polarization signal. A cross-polarization interference compensation circuit (XPIC circuit) that generates a replica signal of the first polarization, an adder that subtracts the replica signal of the different polarization from the self-polarization baseband signal to remove cross-polarization interference, and the addition The determination circuit for determining the synchronous / asynchronous of the own polarization from the output of the detector, and the synchronous / asynchronous determination result from the determination circuit on the own polarization side and the determination circuit on the other polarization side are input, and the XPIC circuit is And an XPIC reset signal generation circuit that controls switching to a state or a reset state, the XPIC reset signal generation circuit has the same determination result on the own polarization side and the different polarization side. At the time of disconnection, the XPIC circuit is controlled to the first intermittent reset state. When the determination result on the polarization side changes to the synchronous state in the first intermittent reset state, the XPIC circuit is controlled to the reset state. When the determination result on the own polarization side changes to the asynchronous state again, the XPIC circuit is controlled to the second intermittent reset state, and the determination result on the own polarization side changes to the synchronous state in the second intermittent reset state. The XPIC circuit is controlled to be in an auto state for a predetermined time from the time of the change, and when the determination result on the different polarization side changes to a synchronous state within the predetermined time, the XPIC circuit is held in the auto state, When the determination result on the different polarization side does not become synchronized within the time, the XPIC circuit is controlled to be switched to the reset state again.
[0018]
In the present invention, when the own polarization and the different polarization are out of synchronization, the XPIC circuit is in an intermittent reset state, and immediately after the own polarization is changed from out of synchronization to synchronization in this state, the XPIC circuit is in a reset state. By alternately repeating the case and the auto state, it becomes easier to draw different polarizations.
[0019]
As a result, the pull-in characteristic of XPIC has been shown as a dotted line in FIG. 9 in the past, but it becomes a solid line in FIG. 9 by the resetting method of the present invention, and self-polarization and cross-polarization leak into each other. Even if it is large, it becomes possible to pull in.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a block diagram of a demodulation circuit in a digital microwave communication apparatus using a cross polarization interference compensator showing an embodiment of the present invention. In FIG. 1, the configuration of the demodulation circuit using the XPIC is the same for each of the V polarization and the H polarization, and therefore the configuration of the V polarization will be described.
[0021]
The transmitted polarization signal is input to the terminal 1, frequency-converted by the multiplier 5, and then converted to a digital signal through the low-pass filter 11 and the A / D converter 15. The digital signal and the carrier signal generated by the numerical operation control oscillator (NCO) 21 are input to an infinite phase shifter (EPS) 20 to perform frequency conversion and demodulate the baseband signal.
[0022]
The carrier synchronization controller 22 generates a phase control signal based on the error signal generated by the determination circuit 39, and performs frequency control of the secondary carrier signal generated by the NCO 21. The cross-polarized signal input to the terminal 3 is frequency-converted by the multiplier 6 and then converted to a digital signal through the low-pass filter 12 and the A / D converter 16. This digital signal is input to the infinite phase shifter 28 together with the carrier signal generated by the NCO 21 common to the own polarization side, and is frequency-converted to become an XPIC reference signal.
[0023]
The XPIC reference signal and the tap coefficient of the XPIC generated by the tap coefficient control circuit 30 are input to the transversal filter 29, and a cross-polarized duplicate signal is generated. Then, the cross polarization interference is removed by subtracting the duplicate signal of the different polarization interference component from the own polarization baseband signal by the adder 35 and removing it. Further, synchronous asynchronous information by the own polarization determination circuit 39 and synchronous asynchronous information by the different polarization determination circuit 40 are input to the XPIC reset signal generation circuit 37 to control the XPIC circuit 27.
[0024]
The circuit shown in FIG. 1 has a configuration when a demodulation method called quasi-synchronous detection is used. Next, the operation of the demodulation circuit in FIG. 1 will be described. Since the configuration and operation of the V-polarization demodulation circuit and the H-polarization demodulation circuit are the same, the operation of the V-polarization demodulation circuit will be mainly described below.
[0025]
The IF signal of the own polarization (V polarization) input from the terminal 1 is frequency-converted by the multiplier 5 using the output of the local oscillator 9, and then the harmonic component is removed by the low-pass filter 11. Further, it is quantized by the A / D converter 15 and converted into a digital signal. This digital signal and the secondary carrier signal generated by the NCO 21 are input to the EPS 20 to perform frequency conversion and demodulate the baseband signal. The carrier synchronization controller 22 generates a phase control signal based on the error signal generated by the determination circuit 39, and performs frequency control of the secondary carrier signal generated by the NCO 21.
[0026]
Further, the IF signal of different polarization (H polarization) input from the terminal 3 is frequency-converted by the multiplier 6 using the output of the local oscillator 9 common to the own polarization, and then the low-pass filter 12. Then, the harmonic component is removed, quantized by the A / D converter 16 and converted into a digital signal. This digital signal is further input to the infinite phase shifter 28 together with the secondary carrier generated by the NCO 21 common to the own polarization side, and the frequency is converted into an XPIC reference signal. The XPIC reference signal and the tap coefficient of the XPIC generated by the tap coefficient control circuit 30 are input to the transversal filter 29, and a duplicate signal of interference components from different polarizations received in space is generated.
[0027]
Then, the cross-polarization interference removal is performed by subtracting the duplicate signal of the different polarization interference component from the own polarization baseband signal by the adder 35 and removing it. The XPIC reset signal generation circuit 37 generates a control signal based on the synchronous asynchronous information generated by the own polarization determination circuit 39 and the synchronous asynchronous information generated by the different polarization determination circuit 40, and the XPIC circuit 27 To control.
[0028]
FIG. 2 shows a control flow of the XPIC reset signal generation circuit 37. When the own polarization and the different polarization are synchronized, the XPIC reset signal generation circuit 37 controls the XPIC circuit 27 to be in the auto state. Is output. In addition, when either one of the own polarization or the different polarization, or both the own polarization and the different polarization are asynchronous (states (1) to (3) in FIG. 2), as described below. In addition, a control signal is output so that the XPIC circuit 27 is in an auto state or a reset state.
[0029]
3 to 6 are time charts and flowcharts showing the reset method of the XPIC circuit in the state of (1) to (3) in FIG. 2, that is, when both the self-polarization and the different polarization are asynchronous or any of them is asynchronous. FIG. Hereinafter, a reset method in the states (1) to (3) of the XPIC circuit of this embodiment will be described.
[0030]
(1) When both the own polarization and the different polarization are asynchronous [0031]
When both the own polarization and the different polarization are out of synchronization, an intermittent reset is applied as shown in part A of FIG. The reset time (T1) in this intermittent reset pulse is the demodulator pull-in time (from the time when input to the demodulator is started until there is no leakage of V polarization and H polarization until synchronization is established. Time) longer.
[0032]
When both the self-polarized wave and the different polarized wave are out of synchronization, the XPIC circuit 27 is not held in the auto state but is in the intermittent reset state because the XPIC generated by the XPIC reference signal and the tap coefficient control circuit 30 is used. This is to prevent the self-polarized wave from becoming difficult to synchronize due to the divergent tap coefficient. On the contrary, the XPIC circuit 27 is not held in the reset state because the XPIC circuit 27 generates a duplicate signal of the different polarization and adds it to the adder 35 when the different polarization leaks into the own polarization. This is because the interference wave is removed and the self-polarized wave is easily drawn.
[0033]
The reason why the reset time in the intermittent reset pulse is longer than the pull-in time is as follows.
[0034]
If the transmission signal of the different polarization is cut off in a state where the own polarization leaks into the different polarization, only the component of the own polarization is input to the XPIC circuit 27 of the demodulation circuit of the own polarization. The At this time, since the signal replicated in the XPIC circuit 27 is the own polarization itself, when this duplicate signal is added to the adder 35, the own polarization is removed, and the own polarization is not in a synchronized state. There is.
[0035]
Therefore, by setting the reset time (T1) of the XPIC circuit 27 longer than the pull-in time of the demodulation circuit, the XPIC circuit 27 is being reset even if the signal duplicated by the XPIC circuit 27 is the same signal as the own polarization. This is so that the self-polarized wave can be synchronized.
[0036]
Next, when the own polarization changes from the out-of-synchronization state to the synchronized state, immediately after the own polarization changes to the synchronized state (the different polarization remains unsynchronized), the XPIC circuit immediately after the synchronization follows the flow of FIG. 3B is maintained in the auto state, and the operation of FIG. 3C for resetting the XPIC circuit immediately after the synchronization is alternately performed.
[0037]
The reason why the XPIC circuit 27 is maintained in the auto state for a while immediately after the self-polarized wave is synchronized as shown in FIG. 3B is as follows.
[0038]
When the XPIC circuit 27 is reset immediately after the self-polarized light is changed into the opposite polarization and the different polarization is leaked into the own polarization, immediately after the own polarization changes from the out-of-synchronization to the synchronization, May not be removed, and synchronization may be lost again. Therefore, the XPIC circuit 27 is kept in the auto state so that the different polarizations can be synchronized while the XPIC circuit 27 is in the auto state.
[0039]
If the different polarizations are synchronized during the auto state, the XPIC circuit 27 can maintain the auto state without entering the reset state, and the own polarization remains synchronized. As a result, it is possible to pull in even if the amount of leakage is larger than when the XPIC circuit is reset immediately after the own polarization is synchronized. The time for keeping the XPIC circuit in the auto state is determined by measuring the pull-in characteristic of the XPIC (FIG. 9).
[0040]
Even if the time is lengthened, the characteristics are hardly improved after a certain time. Therefore, if the time is not drawn within the optimum auto time, the XPIC circuit 27 is reset (usually, when the different polarization is out of synchronization). In the state where the own polarization is leaking into the different polarization, the signal of the different polarization is lost, and the own polarization itself may be input to the XPIC circuit 27. When the wave remains out of synchronization, the XPIC circuit 27 is reset.)
[0041]
The reason why the XPIC circuit 27 is reset immediately after the own polarization is synchronized as shown in FIG. 3C is as follows.
[0042]
If the cross-polarization signal leaks in the state where the self-polarization leaks into the cross-polarization, only the self-polarization component is input to the XPIC circuit 27 of the self-polarization demodulation circuit. At this time, the signal replicated in the XPIC circuit 27 is the own polarization itself. As described above, in such a case, the XPIC circuit 27 is intermittently reset so as to be pulled in during reset.
[0043]
Even if the XPIC circuit 27 is changed to the auto state immediately after the own polarization is synchronized, the own polarization is maintained in the synchronized state. However, since the XPIC circuit 27 is in the auto state, the tap coefficient control circuit 30 of the XPIC circuit 27 operates. However, the tap coefficient of XPIC (the own polarization itself) becomes large. Therefore, at the moment when the XPIC circuit 27 is changed from the auto state to the reset state, the self-polarized component may be affected and the self-polarized wave may come off again. Therefore, it is necessary to reset the XPIC circuit 27 before the tap coefficient of the XPIC circuit 27 becomes large.
[0044]
Since the operations of B and C are contradictory, the state of the XPIC circuit 27 immediately after the self-polarized wave is synchronized so that B and C are alternately repeated so that both cases can be handled. To do.
[0045]
(2) When only the own polarization is asynchronous [0046]
The XPIC circuit 27 performs an intermittent reset as shown in FIG. The reason for intermittent resetting without setting the XPIC circuit 27 in the AUTO state is to prevent the XPIC tap signal generated by the XPIC reference signal and the tap coefficient control circuit 30 from diverging and making it difficult to synchronize its own polarization. It is. The reset pulse width (T2) of the intermittent reset is reset to initialize the tap coefficient, so there is no problem even with a short pulse.
[0047]
(3) When only different polarizations are asynchronous [0048]
The XPIC circuit 27 is reset as shown in FIG. This is because, as described above, when the different polarization is out of synchronization, the own polarization is leaking into the different polarization, the different polarization is broken, and the XPIC circuit 27 Since the own polarization itself may be input, the XPIC circuit 27 is reset.
[0049]
The circuit of the present embodiment has a configuration in the case where a demodulation method called quasi-synchronous detection is used. However, since the present invention does not depend on the DEM demodulation method, it can also be realized by a synchronous DEM.
[0050]
【The invention's effect】
According to the present invention, it is possible to synchronize even if there is a large leakage from the own polarization to the different polarization and from the different polarization to the own polarization.
[0051]
That is, for a while after the own polarization synchronization, the XPIC circuit is set to the auto state to wait for the different polarizations to synchronize while maintaining the own polarization synchronization. Are synchronized, the polarization of the own polarization will not be lost again. As a result, the XPIC circuit can be synchronized even if the leakage of the polarization is large compared to the case where the XPIC circuit is reset immediately after the polarization synchronization.
[Brief description of the drawings]
FIG. 1 is a block diagram of a demodulation circuit in a digital microwave communication apparatus using a cross polarization interference compensator showing an embodiment of the present invention.
FIG. 2 is a diagram showing a control flow of an XPIC reset signal generation circuit in the present embodiment.
FIG. 3 is a time chart showing a method of resetting an XPIC circuit when both the own polarization and the different polarization are asynchronous.
FIG. 4 is a diagram showing an operation flow of the XPIC circuit immediately after the own polarization is synchronized.
FIG. 5 is a time chart showing a method of resetting the XPIC circuit when only the own polarization is asynchronous.
FIG. 6 is a time chart showing a method for resetting an XPIC circuit when only different polarizations are asynchronous.
FIG. 7 is a block diagram showing an example of a demodulation circuit in a digital microwave communication apparatus using a conventional cross polarization interference compensator.
FIG. 8 is a diagram showing a control flow of an XPIC circuit in a conventional example (FIG. 7).
FIG. 9 is a diagram showing the pulling characteristics of XPIC.
[Explanation of symbols]
1 V-polarization own polarization IF signal input terminal 2 H-polarization own polarization IF signal input terminal 3 H-polarization different polarization IF signal input terminal 4 V-polarization different polarization IF signal input terminal 5- 8 Multipliers 9 and 10 Primary carrier oscillator 11-14 Low-pass filter 15-18 A / D converter 19 Demodulator 20 Infinite phase shifter (EPS)
21 Numerical Controlled Oscillator (NCO)
22 Carrier synchronization controller 23 Demodulator 24 Infinite phase shifter (EPS)
25 Numerical Controlled Oscillator (NCO)
26 Carrier Synchronization Controller 27 XPIC Circuit 28 Infinite Phase Shifter (EPS)
29 Transversal filter 30 Tap coefficient control circuit 31 XPIC circuit 32 Infinite phase shifter (EPS)
33 Transversal filter 34 Tap coefficient control circuit 35, 36 Adder 37, 38 XPIC RESET generation circuit 39, 40 Determination circuit 41, 42 Demodulation circuit output terminal 43, 44 OR circuit

Claims (10)

When the own polarization and the different polarization are in an asynchronous state, the cross polarization interference compensation circuit (XPIC circuit) is set to a first intermittent reset state, and the XPIC is changed to a synchronous state in the first intermittent reset state. When the circuit is set in the reset state, and the own polarization is changed to the asynchronous state again in the reset state, the XPIC circuit is changed to the second intermittent reset state, and the own polarization is changed to the synchronous state in the second intermittent reset state. When the XPIC circuit is in an auto state for a predetermined time from the time of the change, and when the different polarization changes to a synchronous state within the predetermined time, the XPIC circuit is held in the auto state and the different polarization within the predetermined time. The cross-polarization interference compensator circuit resetting method is characterized in that the XPIC circuit is switched to the reset state again when is not synchronized. 2. The XPIC circuit according to claim 1, wherein when the XPIC circuit is in a reset state and the own polarization is kept in a synchronized state, the XPIC circuit is kept in a reset state until the different polarization is in a synchronized state. Cross-polarization interference compensator circuit reset method. 3. The XPIC circuit according to claim 1, wherein the XPIC circuit is set to the first intermittent reset state when the self-polarized light changes to the asynchronous state again in a state where the XPIC circuit is switched to the reset state again. The cross-polarization interference compensator circuit reset method as described. The cross-polarized wave interference according to any one of claims 1 to 3, wherein when only the different polarization is in a synchronized state, the XPIC circuit is in a third intermittent reset state until the own polarization is in a synchronized state. Compensator circuit reset method. 5. The cross-polarization interference compensator circuit reset method according to claim 1, wherein a reset time in the first and second intermittent reset states is set longer than a synchronization pull-in time by a demodulator. Each of them includes a demodulator that demodulates the self-polarized baseband signal from the transmitted self-polarized signal, and a cross-polarization interference compensation circuit that generates a cross-polarized replica signal from the transmitted different-polarized signal ( An XPIC circuit), an adder for subtracting the cross-polarization interference by subtracting the cross-polarization replica signal from the self-polarization baseband signal, and determining the synchronous / asynchronous of the self-polarization from the output of the adder An XPIC reset signal generation circuit which inputs a determination circuit and a synchronous / asynchronous determination result from the determination circuit on the own polarization side and the determination circuit on the other polarization side, and controls the XPIC circuit to be switched between an auto state and a reset state. In the cross polarization interference canceller with
The XPIC reset signal generation circuit controls the XPIC circuit to the first intermittent reset state when both the determination results of the own polarization side and the different polarization side are out of synchronization, and in the first intermittent reset state, When the determination result on the side changes to the synchronous state, the XPIC circuit is controlled to the reset state. When the determination result on the polarization side changes again to the asynchronous state in the reset state, the XPIC circuit is reset to the second intermittent reset state. When the determination result on the polarization side changes to the synchronous state in the second intermittent reset state, the XPIC circuit is controlled to be in the auto state for a predetermined time from the time of the change, and the deviation occurs within the predetermined time. When the determination result on the wave side changes to the synchronous state, the XPIC circuit is held in the auto state, and the determination result on the different polarization side does not become the synchronous state within the predetermined time , Cross polarization interference cancellation apparatus and controlling the switching on again reset the XPIC circuit. The XPIC reset signal generation circuit holds the reset state of the XPIC circuit until the determination result on the opposite polarization side is in a synchronized state when the determination result on the own polarization side is held in a synchronized state. The cross polarization interference canceling apparatus according to claim 6. The XPIC reset signal generation circuit sets the XPIC circuit to the first intermittent reset state when the determination result on the polarization side changes to the asynchronous state again in a state where the XPIC circuit is switched to the reset state again. 8. The cross polarization interference canceling apparatus according to claim 6, wherein the cross polarization interference canceling apparatus is controlled. The XPIC reset signal generation circuit controls the XPIC circuit to a third intermittent reset state until only the determination result on the opposite polarization side is in a synchronized state until the determination result on the own polarization side is in a synchronized state. The cross polarization interference canceling apparatus according to any one of claims 6 to 8. 10. The cross polarization interference canceling apparatus according to claim 6, wherein a reset time in the first and second intermittent reset states is set longer than a synchronization pull-in time by the demodulator.

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