JPS59103433A - Compensating device of interference wave - Google Patents

Abstract

PURPOSE:To reduce the interferring radio wave returned to a receiving antenna from a transmission antenna via space by transmitting a pilot signal from the receiving antenna. CONSTITUTION:A signal received on the receiving antenna 1 is a synthesis wave between a signal by a normal incoming radio wave and an interference signal gone round the space after the irradiation from the transmission antenna 2. Since the input signal of a relay amplifier 3 is added with a feedback signal via a feedback loop 4, the interference wave is reduced by cancelling the interference signal and the feedback signal. That is, when the pilot signal of a single frequency is transmitted from the receiving antenna 1, it is extracted by a pilot signal detecting filter 11a, and the amplitude and phase of the feedback loop signal are controlled by detecting the cancelling residual component of the feedback loop signal and the interference signal, allowing to form automatically the optimum compensating condition.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a device for reducing interference radio waves that go around from a transmitting antenna to a receiving antenna through space.

In the wireless relay method, in which a radio signal is received by a receiving antenna, and then retransmitted at the same frequency from a transmitting antenna after being amplified, a part of the signal emitted from the transmitting antenna is transmitted to the receiving antenna as a wraparound radio wave through space. It may be re-received at some point.

In such a case, at the receiving antenna, the signal due to the regular incoming radio wave and the interference signal due to the detouring radio wave are added, which may become a factor that inhibits the function of the relay device. Conventionally, as a method of compensating for this interference signal, as shown in Figure 1, a feedback circuit that can adjust the amplitude and phase is installed between the transmitting end and the receiving end of the repeater, and the feedback signal is sent to the interfering signal with the opposite phase and equal amplitude. There is a configuration that cancels out the interference signal. In the figure, numeral 1 is a receiving antenna, 2 is a transmitting antenna, 3 is a relay amplifier, 5 is a semi-fixed phase shifter, 6 is a semi-fixed attenuator, and 4 is a feedback loop for interference compensation. The conditions of opposite phase and equal amplitude under which the feedback signal from the feedback loop 4 cancels out the interference signal are set by adjusting the semi-fixed phase shifter 5 and the semi-fixed attenuator 6. This adjustment is usually done manually using a measuring instrument, which is very inconvenient. In addition, even if the adjustment is made well, the cancellation state between the interference signal and the feedback signal deteriorates due to variations in the amplifier characteristics and the propagation path characteristics between the transmitting and receiving antennas, so there is a drawback that compensation characteristics cannot be consistently obtained. .

In order to solve these drawbacks, the present invention transmits a pilot signal from a receiving antenna, and detects the residual component of the pilot signal that cancels out the feedback loop signal and the interference signal, thereby determining the amplitude and phase of the feedback loop signal. The present invention provides an interference wave compensator that automatically realizes optimal compensation conditions through control and transmits a pilot signal from a receiving antenna to reduce the influence of pilot signals on transmitted signals.

The present invention will be explained in detail below with reference to the drawings.

FIG. 2 shows an embodiment of the present invention, in which 1 is a receiving antenna;
2 is a transmitting antenna, 3 is a relay amplifier, 4 is a feedback loop,
7 is equal amplitude 2-phase (0°, 90°) distributor, 8 is equal amplitude 4
Phase (0°, 90°, 180°, 270°) distributor, 9 is a pilot signal generator, 10 is a pilot signal removal wave generator, lla and llb are pilot signal detection F wave generators, 12
and 13 are signal band-pass F wave filters, 14 is an amplifier for level adjustment, 15a and 15b are synchronous detectors, and 16a and 16
b is a voltage adder, 17 is a rectifier, 18 is an electrical variable attenuator, and 19a and 19b are variable delay lines.

The signal received by the receiving antenna 1 is a combination of a signal due to a regular arriving radio wave (hereinafter referred to as a regular signal) and an interference signal that is emitted from the transmitting antenna 2 and then circulates through space. A feedback signal via a feedback loop 4 is further added to the input signal of the relay amplifier 30. Now, the present invention automatically realizes the conditions for canceling the interference signal and the feedback signal, and its operation is as follows. Now, consider a situation where a single frequency signal is being transmitted from the receiving antenna 1. At this time, the signal detection p
The output signal of the wave transmitter 11a is a composite signal of the interference wave path signal propagated through the interference signal propagation path and the feedback signal, which is
It is shown in the vector diagram - in the figure. Here, e, + e in the same figure
c represent the interference wavepath signal and the feedback signal, respectively. If this extracted pilot signal 5s is synchronously detected by the synchronous detectors 15a and 15b using the in-phase and quadrature components of the signal branched from the pilot signal generator 9 as a reference, the in-phase and quadrature components ex+ ey of the vector 6 become DC. Can be detected as voltage. Therefore, the vector obtained by inverting the sign of this ez rey. If eBK is further added to .zeta., the output of the F wave detector 11b disappears, and the condition for canceling the interference signal and the feedback signal can be realized. Specifically, this is achieved as follows. 1. Synchronous detector 15a,
The in-phase component e Drive the modulator. Here, diode 1
7 selects the polarity of the X-axis and Y-axis of the vector modulator according to the polarity of the output voltage of the voltage adders 16a and 16b; for example, if the loss is positive, the π-phase signal path becomes conductive; The signal level is determined by the magnitude of the detection voltage, for example 1e.
It is set by the electrical variable attenuator 18 so that it becomes X1. In this way, it is possible to put the vector modulator in a negative feedback state for the voltages detected by the synchronous detectors 15a and 15b. For example, as shown in the vector diagram in Figure 3, e
If y is detected, the vector modulator changes the output signal of the feedback loop to the output signal ec at 1 in addition to -exi-e
yj (where 1+j are the unit vectors of the X-axis and Y-axis, respectively, in FIG. 3), that is, the signal is an added signal of -1. Therefore, by this control, suppression of the pilot signal during the signal period received by the transmitting antenna 2 is realized.

Now, both the propagation path and the feedback loop of the interference signal transmitted from the transmitting antenna 2 and received by the receiving antenna 1 are reversible, and the conditions for suppressing the pilot signal described above depend on the actual signal transmitted from the transmitting antenna 2. Since the interference signal satisfies the condition that it is canceled by the feedback signal, the present invention can be applied to an automatic compensation device for inter-antenna interference. At this time, the pilot signal removal transducer 10 removes the pilot signal component in the main signal path, and as a result, residual pilot components appear on the output side and interfere with the pilot signal received from the transmitting antenna 2 through space. prevent this from happening. It should be noted that it is desirable that the approximation of the added control cloth to -68 of the pressure be better because convergence will be faster, but even if the approximation is not good, the control will converge due to negative feedback, and the interference signal will be suppressed. is possible. Also, a synchronous detector 15a.

The phase synchronization between the reference signal 15b and the input signal and the output signal of the vector modulator is achieved through variable delay lines 19a, respectively.
, 19b is adjusted, and the pilot removal F-wave converter 10 is a pilot signal bandpass F-wave converter]2
It is not necessary if it can be sufficiently removed by

As explained above, by using the present invention, it is possible to automatically reduce the interference wave signal in the antenna reception signal regardless of the characteristic fluctuations of the antenna transmission/reception propagation path and the relay amplifier. It is possible to compensate for interference signals between the transmitting and receiving antennas in a radio relay system in which the transmitting and receiving antennas are the same, and it is possible to allocate more than the coupling attenuation between the transmitting and receiving antennas (the value when no interference compensation is used) as the amplification gain of the relay device. In addition, since the pilot signal is sent out from the receiving antenna, the level of the pilot signal mixed into the transmitted signal is extremely low. This has the advantage of preventing adverse effects from occurring.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an example of a conventional interference compensation device,
FIG. 2 is a block diagram showing an embodiment of the present invention, and FIG. 3 is a vector diagram of received pilot signals. 1...Receiving antenna, 2...Transmitting antenna, 3...
・Relay amplifier, 4... Feedback loop, 5... Semi-fixed phase shifter, 6... Semi-fixed attenuator, 7... Equal amplitude 2-phase divider, 8... Equal amplitude 4-phase distribution 9...Pilot signal generator, 10...Pilot signal removal F-wave device,]
1... Pilot signal detection P wave device, 12, 13...
・Signal bandpass transducer, 14...Amplifier, 15a
, 15b...Synchronous detector, 16a, 16b...
・Voltage adder, 17...diode, 18...
Electrical variable attenuator, 19a, 19b... Variable delay line, 20... Extracted pilot signal vector, 21... Interference signal vector, 22... Feedback signal vector, 23... Pilot signal vector. Inverse vector, 24...X component (in-phase component) of the pilot signal vector, 25...5 Y component (orthogonal component) of the t signal vector, 26a, 26b... circulator. 9- Figure 1

Claims (1)

[Claims] In a radio relay device that receives a radio signal with a receiving antenna, amplifies the received signal with an amplifier, and retransmits it as a transmitting signal from a transmitting antenna at the same frequency as the received signal, wherein a pilot signal of a specific frequency is transmitted from the receiving antenna. means for transmitting a signal; means for extracting the pilot signal from the transmitting antenna; and means for removing the pilot signal from the received signal and applying the received signal to the amplifier. means for branching the pilot signal and a part of the transmission signal and applying it to a vector modulator for adjusting the amplitude and phase; means for returning to the path of the pylon and the transmission signal, means for detecting an in-phase component and a quadrature component of the pylon-to-signal extracted from the transmitting antenna, An interference wave compensating device comprising: means for controlling a vector modulator, and configured to reduce interference signals that return from the transmitting antenna to the receiving antenna via space.