JP2000183781A - Broad band interference wave elimination device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To eliminate an interference wave from the same frequency or frequencies close to each other over a wide frequency range in a radio communication system where a transmission antenna and a reception antenna are separately installed. SOLUTION: In a broad band interference wave elimination device 10, a directional coupler 6 separates part of an output signal of a transmitter 1 as a cancellation signal, which is given to a compensation circuit 11 via a variable attenuator 7 and a variable phase shifter 8. The compensation circuit 11 has a transmission response characteristic to compensate a phase frequency characteristic of an interference wave cancellation loop consisting of the variable attenuator 7 and the variable phase shifter 8. The signal compensated by the compensation circuit 11 is given to a directional coupler 9 as a interference wave cancellation signal to cancel the interference wave of a frequency F1 from a transmission antenna 3 entering the reception antenna 4.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a broadband interference wave removing apparatus for removing interference waves having the same or close frequencies in a wide band.

[0002]

2. Description of the Related Art Conventionally, in a radio communication system in which a transmitting antenna and a receiving antenna are separately installed, when a transmitting frequency and a receiving frequency are close to each other, a radio wave coming from the transmitter to the receiver is received. It causes interference such as sensitivity suppression and transmitter noise.

In order to remove such an interference wave, an interference wave removing device shown in FIG. 9 is conventionally used. In FIG. 9, reference numeral 1 denotes a transmitter (Tx) whose transmission frequency is set to F1. A receiver 2 has a frequency close to the transmission frequency F1, for example, a frequency F which is an adjacent channel.
2 is received. As described above, when the transmission frequency and the reception frequency are close to each other, the interference wave removing device 5 is installed between the transmitter 1 and the transmission antenna 3 and between the receiver 2 and the reception antenna 4.

The interference wave removing device 5 comprises a directional coupler 6, a variable attenuator 7, a variable phase shifter 8, and a directional coupler 9, and a directional coupler is provided between the transmitter 1 and the transmitting antenna 3. The directional coupler 9 is connected between the receiver 2 and the receiving antenna 4. The directional coupler 6 separates a part of the transmission output and inputs it to the directional coupler 9 via the variable attenuator 7 and the variable phase shifter 8.

In the above configuration, the output signal of the transmitter 1 is sent to the transmitting antenna 3 via the directional coupler 6,
The signal is transmitted from the transmitting antenna 3 to the outside. Radio waves transmitted from the outside are received by the receiving antenna 4 and input to the receiver 2 via the directional coupler 9. Receiver 2
Is a frequency close to the transmission frequency F1 as described above,
For example, a radio wave of the frequency F2 which is an adjacent channel is received. At this time, a part of the radio wave transmitted from the transmission antenna 3 goes around to the reception antenna 4 and becomes an interference wave for the reception wave of the frequency F2.

On the other hand, the interference wave removing device 5 separates a part of the output signal of the transmitter 1, for example, a signal of about 1/100 by the directional coupler 6, and switches the variable attenuator 7 and the variable phase shifter 8. The signal is input to the directional coupler 9 on the receiver side. That is, the interfering wave removing device 5 is connected to the transmitting antenna 3 and the receiving antenna 4
The variable attenuator 7 and the variable phase shifter 8 create a signal having the same signal level and a phase difference of 180 ° with respect to the interfering wave which enters the directional coupler 5, and input the signal to the directional coupler 5 to cancel the interfering wave. Works like that.

[0007]

The above-described conventional interference wave removing apparatus 5 can efficiently remove an interference wave when the frequency band of the interference wave is narrow, but when the frequency band of the interference wave becomes wide, There is a problem that the efficiency of the interference wave is reduced.

The following two factors can be considered as factors that hinder the band for removing the interference wave.

(1) It depends on the frequency transmission (amplitude response) characteristics and phase / frequency characteristics of the variable attenuator 7, the variable phase shifter 8, the directional couplers 6, 9, and the antenna. Usually, among these factors, the influence of the frequency characteristics of the variable attenuator 7 and the variable phase shifter 8 is the largest. The directional couplers 6, 9 and the antenna have a sufficiently wide frequency band, and do not pose any particular problem. (2) phase and frequency characteristics of the connection cable between the directional coupler 6 and the transmitting antenna 3, the propagation distance between the antennas 3 and 4,
The phase and frequency characteristics of the connection cable between the receiving antenna 4 and the directional coupler 9 also have a strong influence.

FIG. 10 shows the frequency characteristics of the variable attenuator 7 of the voltage control type. FIG. 10A shows the frequency-amplitude response characteristics, and FIG.
Is a frequency-phase response characteristic (center frequency: standardized by λ / 4). Ideally, it is desirable that the gradient be constant with respect to a change in frequency near the center frequency regardless of the control voltage. However, the following characteristics are actually obtained.

In the amplitude response characteristic shown in (a), the slope (minus) of attenuation increases as the control voltage increases. In the phase response characteristic shown in (b), the slope (minus) of the phase change decreases as the control voltage increases.

FIGS. 11A and 11B show frequency characteristics of the voltage-controlled variable phase shifter 8, wherein FIG. 11A shows a frequency-amplitude response characteristic, and FIG.
Is a frequency-phase response characteristic (center frequency: standardized by λ / 4). In the variable phase shifter 8 as well, ideally, it is desirable that the slope be constant with respect to a change in the frequency near the center frequency irrespective of the control voltage, similarly to the variable attenuator 7. Has the following characteristics.

In the amplitude response characteristic shown in (a), the slope (minus) of the attenuation decreases as the control voltage increases. In the phase response characteristic shown in (b), the slope (minus) of the phase change increases as the control voltage increases. As described above, in the conventional interference wave removing device, since the attenuation and the phase characteristics change depending on the frequency, it is difficult to satisfy the favorable conditions for canceling the interference wave over a wide frequency range.

Next, the effect of the cable (coaxial feed line) will be described. The phase shift φe of the frequency component shifted from the center frequency by the cable by Δf is obtained by the following equation.

Φe = (L / Δλg) × 360 ° where Δλg = c / Δf For example, there is a 33.5 m cable (shortening rate 0.67), and the phase shift φe of the frequency component shifted by 1 MHz from the center frequency is , (0.67) ^-1 × (33.5 / 3 × 10 ² ) × 360 °
= 60 °. That is, the frequency component shifted by 1 MHz from the center frequency is delayed by as much as 60 °, and the effect of canceling out the interference wave is almost lost.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problem. In a wireless communication system in which a transmitting antenna and a receiving antenna are separately installed, an interfering wave of the same or close frequency is spread over a wide frequency range. It is an object of the present invention to provide a broadband interference wave elimination device that can surely eliminate the interference.

[0017]

SUMMARY OF THE INVENTION A first aspect of the present invention is a broadband interference wave elimination system for eliminating a sneak wave from a transmission antenna to a reception antenna when the transmission frequency of the transmitter is close to the reception frequency of the receiver. In the apparatus, a signal extracting means for extracting a part of the transmission output of the transmitter as an interference wave canceling signal, a variable attenuator for adjusting a level of the canceling signal extracted by the extracting means, A variable phase shifter for adjusting the phase, a compensating means for compensating for the phase and frequency characteristics of the canceling signal, and a canceling signal compensated by the compensating means coupled to a received signal of the receiving antenna; And a coupling unit for canceling an interfering wave which goes around from the antenna to the receiving antenna.

According to a second aspect of the present invention, the compensating means for compensating the phase and frequency characteristics of the canceling signal is constituted by a parallel resonance circuit including a resonance inductance, a resonance capacitance and a dump resistor.

According to a third aspect of the present invention, as the compensating means for compensating the phase and frequency characteristics of the canceling signal in the first or second aspect, the length of the cable connected to the transmitting antenna and the length of the cable connected to the receiving antenna are adjusted. It is characterized by comprising a compensating cable having a length corresponding to the length of the cable and the equivalent cable length from the transmitting antenna to the receiving antenna.

According to a fourth aspect of the present invention, as a compensating means for compensating the phase and frequency characteristics of the canceling signal according to the first, second or third aspect, a parallel resonance circuit comprising a resonance inductance, a resonance capacitance and a dump resistance is provided. , The length of the cable connected to the transmitting antenna, the length of the cable connected to the receiving antenna, and a compensation cable having a length corresponding to the equivalent cable length from the transmitting antenna to the receiving antenna. And

A fifth aspect of the present invention is characterized in that the compensating means for compensating the phase and frequency characteristics of the canceling signal according to the first aspect of the present invention comprises a surface acoustic wave element.

According to a sixth aspect of the present invention, there is provided a broadband interference wave eliminator for eliminating a sneak interference wave from a transmission antenna to a reception antenna when the transmission frequency of the transmitter and the reception frequency of the receiver are close to each other. Signal extracting means for extracting a part of the transmission output as a signal for canceling an interference wave, a voltage variable attenuator for adjusting the level of the canceling signal extracted by the extracting means, and a voltage for adjusting the phase of the canceling signal. A variable phase shifter, a voltage variable compensation circuit for compensating the phase and frequency characteristics of the cancellation signal, and a cancellation signal compensated by the voltage variable compensation circuit combined with a reception signal of the reception antenna; Coupling means for canceling an interfering wave circling from the receiving antenna to the receiving antenna, and the signal in the signal input to the receiver via the coupling means A monitor receiver for monitoring the interfering interference wave, and an attenuation amount of the variable voltage attenuator, a phase shift amount of the variable voltage phase shifter, and a variable voltage compensation circuit according to the interfering wave monitored by the monitor receiver. A cancellation control unit for controlling a compensation characteristic.

According to a seventh aspect of the present invention, there is provided a broadband interference wave elimination apparatus which comprises a transmitter and a receiver and eliminates external interference waves to the receiver when the transmission antenna and the reception antenna are arranged close to each other. A signal extracting means for extracting a part of the external interference wave received by the transmitting antenna during the pause as a signal for canceling the interference wave, and a variable attenuator for adjusting the level of the canceling signal extracted by the extracting means, A variable phase shifter for adjusting the phase of the canceling signal, compensating means for compensating the phase and frequency characteristics of the canceling signal, and combining the canceling signal compensated by the compensating means with the received signal of the receiving antenna. And coupling means for canceling an external interference wave received by the receiving antenna.

[0024]

Embodiments of the present invention will be described below with reference to the drawings. (First Embodiment) FIG. 1 is a block diagram showing a configuration of a broadband interference wave removing apparatus according to a first embodiment of the present invention.
In FIG. 1, 1 is a transmitter (Tx) whose transmission frequency is F
It is set to 1. A receiver (Rx) 2 receives a radio wave of a frequency close to the transmission frequency F1, for example, a frequency F2 which is an adjacent channel. And the transmitter 1
And a transmitting antenna 3 and between the receiver 2 and the receiving antenna 4.

The broadband interference wave removing apparatus 10 includes a directional coupler 6, a variable attenuator 7, a variable phase shifter 8, and a compensation circuit 1.
1. Consisting of a directional coupler 9, a directional coupler 6 is connected between the transmitter 1 and the transmitting antenna 3, and a directional coupler 9 is connected between the receiver 2 and the receiving antenna 4. I have. The directional coupler 6 separates a part of the transmission output and inputs the directional coupler 9 via the variable attenuator 7, the variable phase shifter 8 and the compensation circuit 11.

As the compensation circuit 11, for example, a parallel resonance circuit including a resonance inductance L, a resonance capacitance C, and a dump resistor R as shown in FIG. 2 is used.

In the above configuration, the output signal of the transmitter 1 is sent to the transmission antenna 3 via the directional coupler 6,
The signal is transmitted from the transmitting antenna 3 to the outside. Radio waves transmitted from the outside are received by the receiving antenna 4 and input to the receiver 2 via the directional coupler 9. Receiver 2
Is a frequency close to the transmission frequency F1 as described above,
For example, a radio wave of the frequency F2 which is an adjacent channel is received. At this time, a part of the radio wave transmitted from the transmission antenna 3 goes around to the reception antenna 4 and becomes an interference wave for the reception wave of the frequency F2.

On the other hand, the broadband interference wave removing apparatus 10 uses the directional coupler 6 to output a part of the output signal of the transmitter 1, for example, 1/1.
The signal of about 00 is separated and input to the compensation circuit 11 via the variable attenuator 7 and the variable phase shifter 8. This compensation circuit 11
Has the transfer response characteristics shown in FIG. 3 and compensates for the characteristic characteristics of the variable attenuator 7 and the variable phase shifter 8. Compensation circuit 11
Has an approximately flat and convex downward characteristic near the center frequency as shown in FIG. 3, and a transfer characteristic in which the phase advances linearly. The response characteristic of the compensation circuit 11 can be variably set by the value of the dump resistor R.

The signal compensated by the compensation circuit 11 is input to the directional coupler 9 as an interference wave canceling signal.
Frequency F that goes from transmitting antenna 3 to receiving antenna 4
Cancel one jammer.

As described above, the broadband interference wave removing apparatus 10
Is the frequency F from the transmitting antenna 3 to the receiving antenna 4
The signal level is the same and the phase is 1
The signals differing by 80 ° are applied to the variable attenuator 7 and the variable phase shifter 8.
, And input to the directional coupler 5 to operate to cancel the wraparound interference wave. At this time, the characteristics of the variable attenuator 7 and the variable phase shifter 8 are compensated by the compensation circuit 11. In this case, the directional coupler 6, the variable attenuator 7,
Since the interference wave canceling loop constituted by the variable phase shifter 8 and the directional coupler 9 has a characteristic that the amplitude response is negative and the phase is delayed around the canceling frequency, the compensation circuit 11 The resistance R adjusts and compensates for the damping response in the negative direction and the phase in the positive direction. By the operation of the compensation circuit 11, the frequency dependence of the interference wave canceling loop can be eliminated, and the interference wave having a frequency close to the reception frequency can be reliably removed over a wide frequency range.

In the first embodiment, a case has been described in which an interference wave of a frequency close to the reception frequency is removed. However, even when the reception wave and the interference wave have the same frequency, the interference wave is similarly removed. Can be removed.

In the first embodiment, the compensation circuit 1
1 has been described after the variable attenuator 7 and the variable phase shifter 8, the above-described embodiment is applicable even if the compensation circuit 11 is inserted before the variable attenuator 7 or before the variable phase shifter 8. The same effect as described above can be obtained.

Further, in the first embodiment, the compensation circuit 1
Although the case where the LCR parallel resonator is used as 1 has been described, a surface wave element may be used instead of the LCR parallel resonator. Since the surface acoustic wave element can set the amplitude characteristic and the phase characteristic independently, it can cope with more complicated characteristics than the LCR parallel resonator.

(Second Embodiment) Next, a second embodiment of the present invention will be described. FIG. 4 is a block diagram showing the configuration of the wideband interference wave removing apparatus according to the second embodiment of the present invention. In the second embodiment, a compensation cable 12 is provided instead of the compensation circuit 11 in the first embodiment to compensate for the characteristics of the variable attenuator 7 and the variable phase shifter 8.

When the factor that hinders broadband erasure is in the phase and frequency characteristics of the cable connecting the transmitting and receiving antennas 3 and 4 and the interference wave removing device, that is, when the connecting cable is as long as several tens to 100 m. , The total extension is Lt. The total extension Lt of the compensation cable 12 is set to Lt = L1 + L2 + L3.

Here, L1 is the cable length from the directional coupler 6 to the transmitting antenna 3, L2 is the equivalent cable length from the transmitting antenna 3 to the receiving antenna 4, and L3 is the cable from the receiving antenna 4 to the directional coupler 9. Long.

As described above, the cable connecting between the transmitting / receiving antennas 3 and 4 and the interference wave removing device is several tens to 100 m.
When the factor that hinders broadband erasure is due to the phase and frequency characteristics of the connection cable, the phase and frequency characteristics are compensated for by using the compensation cable 12 whose total length is Lt, so that the frequency of interference wave removal is reduced. The characteristics can be broadened.

(Third Embodiment) Next, a third embodiment of the present invention will be described. FIG. 5 is a block diagram illustrating a configuration of a wideband interference wave removing apparatus according to a third embodiment of the present invention. In the third embodiment, both the compensation circuit 11 in the first embodiment and the compensation cable 12 in the second embodiment are provided to compensate for the characteristics of the variable attenuator 7 and the variable phase shifter 8 and the characteristics of the connection cable. It is like that.

The phase and frequency characteristics of the cables connecting the transmitting and receiving antennas 3 and 4 and the interfering wave eliminator are obstacles to wideband erasure, and the frequency characteristics can be improved only by the compensation circuit 11 shown in the first embodiment. If not,
As shown in FIG. 5, the compensation cable 12 shown in the second embodiment is provided together with the compensation circuit 11.

As described above, by providing both the compensating circuit 11 and the compensating cable 12 in the broadband interference wave removing device 10 to improve the phase and frequency characteristics, the effect of removing the interference wave can be further enhanced.

(Fourth Embodiment) Next, a fourth embodiment of the present invention will be described. FIG. 6 is a block diagram showing a configuration of a wideband interference wave removing apparatus according to a fourth embodiment of the present invention. In the fourth embodiment, a compensating circuit 21 whose characteristics can be varied by a control voltage is provided instead of the compensating circuit 11 in FIG. 1, and a voltage-controlled variable attenuator 7, a voltage-controlled variable phase shifter 8, and a compensating circuit 21 are provided. Is provided with a cancellation control unit (microprocessor) 22 for controlling the operation of the control unit. The details of the compensation circuit 21 will be described later. Further, a directional coupler 23 is provided between the directional coupler 9 and the receiver 2.

The directional coupler 23 separates a part of the signal input to the receiver 2, for example, a signal of about 1/100, and inputs the separated signal to the monitor receiver 24. This monitor receiver 2
4 monitors the signal of the frequency F1 from among the received signals,
This is input to the cancellation control unit 22. The cancellation control unit 22 controls the frequency F1 input from the monitor receiver 24.
The attenuation control voltage VATT is changed based on the signal of
Then, the phase control voltage Vφ is input to the variable phase shifter 8, and the capacitance control voltage Vc and the resistance control voltage Vr are input to the compensation circuit 21. That is, the cancellation control unit 22 controls the variable attenuator 7 and the variable phase shifter 8 so that the signal of the frequency F1 monitored by the monitor receiver 24 is minimized,
Compensates the phase and frequency characteristics of the interference canceling loop.

The compensation circuit 21 is configured, for example, as shown in FIG. That is, the input terminal t1 and the output terminal t
2 and a choke coil CH is provided between the output side of the resonance inductance L and the ground. Further, the resonance inductance L
, A series circuit of a coupling capacitor C1 and a variable capacitance diode D1 is provided in parallel, and a series circuit of a coupling capacitor C2 and a pin (Pin) diode D2 is provided in parallel. The capacitance control voltage Vc sent from the cancellation control unit 22 is supplied between the coupling capacitor C1 and the variable capacitance diode D1 via the choke coil CH2. During this period, the resistance control voltage Vr sent from the cancellation control unit 22 is supplied via the current limiting resistor Ri and the choke coil CH3.

The compensating circuit 21 constitutes a parallel resonance circuit similarly to the compensating circuit 11 in the first embodiment.
The variable capacitance diode D1 is controlled by the capacitance control voltage Vc.
Is variably set, and the equivalent resistance of the pin diode D2 is variably set by the resistance control voltage Vr. That is, the junction capacitance of the variable capacitance diode D1 changes with the bias voltage based on the capacitance control voltage Vc, and changes the center frequency of the parallel resonance circuit. Further, the equivalent resistance of the pin diode D2 changes with the bias current caused by the resistance control voltage Vr,
Change the amplitude characteristics and phase characteristics of the parallel resonance circuit.

The control voltage Vr of the pin diode D2 and the control voltage Vc of the variable capacitance diode D1 are the control voltage VATT of the variable attenuator 7 and the control voltage Vφ of the variable phase shifter 8.
Is stored in the cancellation control unit 22 as a control table to obtain the best compensation effect with respect to the change (set value), so that the interference wave can be effectively canceled. FIG. 8 shows a pattern example of the control voltages Vr and Vc stored in the cancellation control unit 22.
In FIG. 8, Vri indicates the i-th pin diode control voltage, and Vcj indicates the j-th variable capacitance diode control voltage.

In the above configuration, the output signal of the transmitter 1 is sent to the transmission antenna 3 via the directional coupler 9 of the broadband interference wave canceller 10, and is transmitted from the transmission antenna 3 to the outside. Radio waves transmitted from the outside are received by the receiving antenna 4 and input to the receiver 2 via the directional couplers 9 and 23. The receiver 2 has a transmission frequency F1
, For example, a radio wave of a frequency F2 which is an adjacent channel. At this time, part of the radio wave transmitted from the transmitting antenna 3 goes around the receiving antenna 4,
It becomes an interference wave for the reception wave of the frequency F2.

On the other hand, the wideband interference wave removing apparatus 10 separates a part of the output signal of the transmitter 1 as a canceling signal by the directional coupler 6, and outputs the variable attenuator 7, the variable phase shifter 8 and the compensation circuit 21. Is input to the directional coupler 23 on the receiving side. As a result, the interfering wave of frequency F1 wrapping around from the transmitting antenna 3 to the receiving antenna 4 is canceled by the canceling signal input to the directional coupler 6 from the compensation circuit 21. At this time, the monitor receiver 24 monitors the loop interference wave of the frequency F <b> 1, and when detecting the loop interference wave, inputs the detection signal to the cancellation control unit 22.

The cancellation control section 22 outputs an attenuation control voltage VATT and a phase control voltage Vφ in accordance with the level and phase of the sneaking wave monitored by the monitor receiver 24, and outputs the attenuation amount of the variable attenuator 7 and The phase shift amount of the variable phase shifter 8 is controlled so that the sneak interference signal monitored by the monitor receiver 24 is minimized. Further, the cancellation control unit 22 obtains the best compensation effect according to the control voltages VATT and Vφ output to the variable attenuator 7 and the variable phase shifter 8 with reference to the control table shown in FIG. The resistance control voltage Vr and the capacitance control voltage Vc are output to the compensation circuit 21. For example, in FIG. 8, the control voltage VATT of the variable attenuator 7 is 5 to 6 V, and the control voltage Vφ of the variable phase shifter 8 is 5
Assuming that the voltage is 〜6 V, the control voltage Vr for the pin diode D2 is set to Vr5, and the control voltage Vc for the variable capacitance diode D1 is set to Vc3.

Pin diode D2 in compensation circuit 21
Means that the equivalent resistance changes with a bias current caused by the resistance control voltage Vr, thereby changing the amplitude characteristic and the phase characteristic of the parallel resonance circuit. In addition, the junction capacitance of the variable capacitance diode D1 changes with the bias voltage caused by the capacitance control voltage Vc. Change the center frequency of the parallel resonance circuit. As a result, the phase and frequency characteristics of the interference wave canceling loop are compensated to the best state by the compensation circuit 21, and the interference wave can be removed over a wide frequency range.

In the above embodiment, a case has been described in which both the resistance control voltage Vr and the capacitance control control voltage Vc output from the cancellation control unit 22 to the compensation circuit 21 are variably set. Alternatively, the other control voltage may be set variably.

In each of the above embodiments, a case has been described in which the interference wave from the transmitting antenna 3 to the receiving antenna 4 is removed. A part of the wave is taken out as a signal for canceling the interference wave by the directional coupler,
The signal may be input to the variable attenuator 7 to remove an external interference wave to the receiver 2. Even in the case of removing the external interference wave, by providing the compensating circuit 11, the compensating cable 12, the compensating circuit 21 and the like as in the above embodiments,
The frequency characteristic of the interference wave removal can be broadened.

[0052]

As described above in detail, according to the present invention, in a wireless communication system in which a transmitting antenna and a receiving antenna are separately installed, a part of a transmission signal output from a transmitter is extracted as a cancellation signal. The level and phase are adjusted by a variable attenuator and a variable phase shifter, and the compensating circuit compensates the phase and frequency characteristics to cancel the interference wave from the transmitting antenna to the receiving antenna. Frequency interference can be reliably removed over a wide frequency range. By inserting the compensating circuit as described above, the frequency range of the interference wave removal can be expanded by about 10 times to several tens times.

Further, according to the present invention, a part of an external interference wave received by the transmission antenna while the transmitter is at rest is taken out as an interference wave canceling signal, and a variable attenuator, a variable phase shifter,
By inputting to an interference wave canceling loop composed of a compensation circuit or the like, an external interference wave can also be removed over a wide frequency range.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a broadband interference wave removing apparatus according to a first embodiment of the present invention.

FIG. 2 is a diagram showing a configuration example of a compensation circuit according to the embodiment.

FIG. 3 is a diagram showing a transfer response characteristic of the compensation circuit according to the first embodiment;

FIG. 4 is a block diagram showing a configuration of a wideband interference wave removing apparatus according to a second embodiment of the present invention.

FIG. 5 is a block diagram showing a configuration of a wideband interference wave removing apparatus according to a third embodiment of the present invention.

FIG. 6 is a block diagram showing a configuration of a wideband interference wave removing apparatus according to a fourth embodiment of the present invention.

FIG. 7 is an exemplary view showing a configuration example of a compensation circuit in the embodiment.

FIG. 8 is an exemplary view showing a pattern example of a control voltage stored in a cancellation control unit according to the embodiment.

FIG. 9 is a block diagram showing a configuration of a conventional interference wave removing device.

FIG. 10 is a diagram showing a frequency characteristic of a variable voltage attenuator used in an interference wave removing device.

FIG. 11 is a diagram illustrating frequency characteristics of a variable voltage phase shifter used in the interference wave removing device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Transmitter 2 Receiver 3 Transmitting antenna 4 Receiving antenna 6 Directional coupler 7 Variable attenuator 8 Variable phase shifter 9 Directional coupler 10 Broadband interference wave eliminator 11 Compensation circuit 12 Compensation cable 21 Voltage control type compensation circuit 22 cancellation control unit 23 directional coupler 24 monitor receiver

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Tokoki Oba 4-72 Miyagaya Tower, Omiya City, Saitama Antenna Giken Co., Ltd. F term (reference) 5C021 PA00 PA14 PA17 PA18 PA94 PA95 PA96 PA97 RB04 RC06 XB01 XB05 YA01 5K011 DA01 DA23 DA27 EA02 EA03 JA01 KA05 5K052 AA01 BB07 BB08 DD04 FF01 FF32 GG13 GG19 GG31 GG41 GG57

Claims (7)

[Claims] An apparatus for removing a disturbing wave from a transmitting antenna to a receiving antenna when a transmitting frequency of a transmitter and a receiving frequency of a receiver are close to each other, comprising: A signal extracting means for extracting a part as an interference wave canceling signal, a variable attenuator for adjusting the level of the canceling signal extracted by the extracting means, and a variable phase shifter for adjusting the phase of the canceling signal, A compensating means for compensating the phase and frequency characteristics of the canceling signal; and a coupling for combining the canceling signal compensated by the compensating means with the received signal of the receiving antenna and canceling an interfering wave from the transmitting antenna to the receiving antenna. Means for removing broadband interference waves. 2. The wide-band interference wave according to claim 1, wherein the compensating means for compensating the phase / frequency characteristics of the canceling signal comprises a parallel resonance circuit including a resonance inductance, a resonance capacitance and a dump resistor. Removal device. 3. The compensating means for compensating the phase / frequency characteristics of the canceling signal includes the length of a cable connected to a transmitting antenna, the length of a cable connected to a receiving antenna, and the length of a cable from a transmitting antenna to a receiving antenna. 3. The apparatus according to claim 1, wherein the compensating cable has a length corresponding to an equivalent cable length. 4. A compensating means for compensating the phase / frequency characteristics of the canceling signal includes a parallel resonant circuit including a resonant inductance, a resonant capacitance and a dump resistor, a length of a cable connected to a transmitting antenna, and a receiving antenna. 4. The wideband interference wave elimination apparatus according to claim 1, wherein the compensation cable has a length corresponding to a length of a connected cable and an equivalent cable length from a transmission antenna to a reception antenna. apparatus. 5. The wide-band interference wave removing apparatus according to claim 1, wherein the compensating means for compensating the phase / frequency characteristics of the canceling signal comprises a surface wave element. 6. A wideband interference wave eliminator for removing an interference wave from a transmission antenna to a reception antenna when the transmission frequency of the transmitter is close to the reception frequency of the receiver. Signal extracting means for extracting a part as an interference wave canceling signal, a variable voltage attenuator for adjusting the level of the canceling signal extracted by the extracting means, and a variable voltage phase shifter for adjusting the phase of the canceling signal And a voltage variable compensation circuit for compensating the phase and frequency characteristics of the cancellation signal, and combining the cancellation signal compensated by the voltage variable compensation circuit with the reception signal of the reception antenna, and transmitting from the transmission antenna to the reception antenna. Coupling means for canceling the sneaking interference wave, and the sneaking interference in a signal input to the receiver via the coupling means Monitor, and controls the attenuation of the variable voltage attenuator, the phase shift of the variable voltage phase shifter, and the compensation characteristics of the variable voltage compensator in accordance with the sneaking wave monitored by the monitor receiver. A broadband interference wave removing device, comprising: 7. A broadband interference wave eliminator comprising a transmitter and a receiver and eliminating an external interference wave to the receiver when the transmission antenna and the reception antenna are arranged close to each other, comprising: Signal extraction means for extracting a part of the external interference wave received by the transmission antenna as an interference wave cancellation signal, a variable attenuator for adjusting the level of the cancellation signal extracted by the extraction means, and the cancellation signal A variable phase shifter for adjusting the phase of the signal, compensation means for compensating the phase and frequency characteristics of the canceling signal, and a canceling signal compensated by the compensating means combined with a received signal of the receiving antenna to form a receiving antenna. And a coupling unit for canceling an external interference wave received by the apparatus.