JPH0611125B2 - Same frequency relay system - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a same-frequency relay system, and particularly in a wireless communication line that uses the same carrier frequency for transmission and reception, the line quality of a transmission signal at a relay station interferes with a reception signal. The present invention relates to a same frequency relay system that improves deterioration.

[Conventional example]

2. Description of the Related Art Conventionally, a so-called dual frequency system is used in a microwave band wireless communication line formed via a relay station, and the transmission and reception frequencies of the same station are to prevent interference that occurs between transmission and reception. Different frequencies are used for each. Therefore, in each relay station in the wireless communication line, frequency allocation is performed in such a manner that transmission / reception frequencies are alternated for each relay section. However, recently, from the viewpoint of effective utilization of frequencies used in microwave band wireless communication lines,
Instead of the frequency system, it has been proposed to apply the same frequency wireless communication line that uses the same frequency for transmission and reception in the same station. FIG. 2 is a block diagram showing a main part of a relay system corresponding to one direction of one route of a relay station in the same frequency wireless communication line.
5, a receiver 26, a local oscillator 27 for generating a local oscillation signal for converting the carrier frequency of the received signal into a predetermined intermediate frequency, a demodulator 28, a modulator 29, a carrier generation circuit 30, The transmitter 31 includes a transmitter 31, a local oscillator 32 for generating a local oscillation signal for frequency conversion for generating a carrier frequency of a transmission signal, and a transmission antenna 32.

In FIG. 2, the received signal 105 with the transmitted wave frequency f ₁
Is input to the receiver 26 via the receiving antenna 25. The receiver 26 is provided with a frequency converter, an intermediate frequency amplifier, and the like. The local oscillation signal sent from the local oscillator 27 converts the reception signal 105 into a predetermined intermediate frequency signal, and the intermediate frequency amplifier It is amplified and input to the demodulator 28. The demodulator 28 is configured to use a quadrature phase detection method as a demodulation method in response to the input of, for example, a digital multi-phase phase modulated wave or a digital multi-level quadrature amplitude modulated wave, and to receive a received signal. An equalizing circuit and the like for removing the included amplitude distortion and phase distortion are provided.

The demodulated signal demodulated and output by the demodulator 28 is input to the modulator 29, and the carrier signal sent from the carrier generation circuit 30 is modulated by the demodulated signal. The modulated wave signal output from the modulator 29 is input to the transmitter 31 and converted into a transmission signal having a carrier frequency equal to the carrier frequency f ₁ of the reception signal 105 by the local oscillation signal sent from the local oscillator 32. The power is amplified and transmitted as a transmission signal 106 from the transmission antenna 33 to the opposite station. In this same frequency relay system, since the transmission and reception frequencies are the same, an interference signal is generated at the relay station itself due to leakage of the transmission signal with respect to the reception signal. It is considered that the interference signal is removed by the equalization circuit provided in 28.

[Problems to be solved by the invention]

In the above-mentioned same frequency relay system, since the baseband signal for the received signal and the transmitted signal is the same, the baseband signal between the original received signal and the baseband signal of the interference signal due to leakage of the transmitted signal is Since the cross-correlation becomes large and therefore the original received signal and the interference signal are extremely difficult to discriminate, there is a drawback that the interference signal due to the leakage of the transmission signal into the reception signal cannot be sufficiently removed.

[Means for solving problems]

In order to solve the above-mentioned problems, the same frequency relay system of the present invention provides a reception frequency and transmission for each relay system corresponding to each route in the plurality of routes in a relay station of a plurality of routes of the same frequency wireless communication line. A means for setting the frequency different from the frequency is provided.

〔Example〕

 Hereinafter, the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing a main part of a pair of relay systems according to an embodiment of the present invention. As shown in FIG. 1, the relay system includes receiving antennas 1 and 10.
, Receivers 1 and 11 and local oscillators 3 and 12
, Adder circuits 1 and 14, demodulators 5 and 15,
Modulators 6 and 13 and carrier generation circuits 7 and 16
, Transmitters 8 and 17, and transmitting antennas 9 and 18
And correlation detector 19 and transversal filter
Variable frequency characteristic filter 21 including 20 and correlation detector 2
2 and a variable frequency characteristic filter 24 including a transversal filter 23.

In FIG. 1, received signals 101 and 102 corresponding to two routes having carrier frequencies f ₁ and f ₂ are input to receivers 2 and 11 via receiving antennas 1 and 10, respectively. The receivers 2 and 11 are respectively provided with a frequency converter and an intermediate frequency amplifier, and the received signals 101 and 102 are given intermediate frequency signals by the local oscillation signals sent from the local oscillators 3 and 12, respectively. Are converted into the following, are amplified by the intermediate frequency amplifier, and are input to the corresponding adder circuits 4 and 13, respectively. The addition circuits 4 and 13 add the interference cancellation signals 111 and 112 transmitted from the transversal filters 20 and 23 included in the variable frequency characteristic filters 21 and 24, respectively, and transmit signals leaking into the reception signals. Thus, the interference signal is reduced and input to the demodulators 5 and 14, respectively. The demodulators 5 and 14 are configured by a quadrature phase synchronous detection system as a demodulation system corresponding to the input of, for example, a digital multiphase phase modulation wave or a digital multilevel quadrature amplitude modulation wave. The demodulated signals 105 and 106 output from and 14 are sent to the modulator 6 and the correlation detector 22, and the modulator 15 and the correlation detector 19, respectively. In the modulators 6 and 15, predetermined carrier wave signals input from the carrier wave generating circuits 7 and 16 are modulated using the corresponding demodulated signals as baseband signals, and the respective modulated wave signals 113 and 114 are It is sent to the corresponding transmitters 8 and 17 and also to the transversal filters 23 and 20, respectively. The transmitters 8 and 17 are respectively provided with a frequency converter and a power amplifier,
It is input from the local oscillators 3 and 12, respectively. Via the local oscillation frequency, the carrier frequency of the modulated wave signal is converted to the carrier frequency f ₂ and f ₁ , respectively,
It is amplified to a predetermined power level and transmitted from the transmission antennas 9 and 18 to the opposite station as transmission signals 103 and 104, respectively. Therefore, in the route carrier frequency corresponding to the received signal f _1, the carrier frequency corresponds the transmission signal 103 of f _2, In the route carrier frequency corresponding to the received signal 102 f _2, the carrier frequency Corresponds to the transmission signal 104 of f ₁ , and in the pair of relay systems shown in FIG. 1, the reception frequency and the transmission frequency are set to different frequencies.

In the pair of relay systems in the present embodiment described above, the modulated wave signal 113 in the intermediate frequency band output from the modulator 6 in the route corresponding to the received signal 101 (hereinafter referred to as the A route) is the variable frequency characteristic filter. 24
To the transversal filter 23 included in the. In addition, the route corresponding to the receiving route 102 (hereinafter,
The modulated wave signal 114 in the intermediate frequency band output from the modulator 15 in the B route) is included in the transversal filter 20 included in the variable frequency characteristic filter 21.
Sent to. On the other hand, the error signal 107 output from the demodulator 5 in the A route and the demodulator 1 in the B route
The error signal 108 output from 4 is input to the correlation detectors 19 and 22, respectively. The baseband signal in the A route and the interference signal due to the leakage of the transmission signal in the B route are superimposed on the demodulated signal 105 in the A route, and the demodulated signal 106 in the B route is included in the demodulated signal 106 in the B route. The signal and the interference signal due to the leakage of the transmission signal of the A route are superimposed. Further, the error signals 107 and 10 output from the demodulators 5 and 14
In FIG. 8, an interference signal due to a leak in the transmission signal of the B route and an interference signal due to a leak of the transmission signal of the A route are interposed. Therefore, the correlation detector 19 cross-correlates the demodulated signal 106 and the error signal 107, and detects the interference signal from the B route leaking into the received signal of the A route with the demodulated signal 106 as a reference. , A plurality of control signals 109 used to minimize the interference signal are output and input to the weighting circuits of the corresponding taps of the transversal filter 20. The transversal filter 20 includes a modulator 15
Modulated wave signal in the intermediate frequency band of B route output from
114 has been input, and via the control action on the weighting circuit of each tap by the plurality of control signals 109,
The interference cancellation signal 111 in the intermediate frequency band is output. This interference cancellation signal 111 is input to the adder circuit 4, and the receiver 2
The interference signal which is added to the received signal in the intermediate frequency band of the A route transmitted from the and is superimposed is removed. Similarly, the interference canceling signal 112 input to the adding circuit 13 is operated through the action of the variable frequency characteristic filter 24 including the correlation detector 22 and the transversal filter 23.
Thus, the interference signal superimposed on the received signal in the intermediate frequency band of the B route is removed. In this case, the frequencies f ₁ and f ₂ are separated to the extent that mutual interference does not occur between the pair of relay systems, and there is no interference between transmitted and received signals on the same route, which is not a problem.

〔The invention's effect〕

As described above, the present invention is applied to a plurality of routes of the same frequency wireless communication circuit, eliminates interference due to leakage of a transmission signal in a relay station to a reception signal, and improves the line quality of the same frequency wireless communication line. The effect is that it can be maintained normally.

[Brief description of drawings]

FIG. 1 is a block diagram showing a main part of a relay station in one embodiment of the present invention, and FIG. 2 is a block diagram showing a main part of a relay station in a conventional frequency repeater system. In the figure, 1, 10, 25 ... Receiving antenna, 2, 2
2, 26 ... Receiver, 3, 12, 27, 32 ... Local oscillator, 4, 13 ... Adder circuit, 5, 14, 28 ... Demodulator, 6, 15, 29 ... Modulator, 7, 16, 30 ... Carrier wave generation circuit, 8, 17, 31 ... Transmitter, 9, 18,
33 ... Transmitting antenna, 19, 17, 31 ... Transmitter,
9, 18, 33 ... Transmission antenna, 19, 22 ... Correlation detector, 20, 23 ... Transversal filter,
21, 24 ... Variable frequency characteristic filter.

Claims (1)

[Claims] 1. A relay station for a plurality of routes of the same frequency wireless communication line, comprising means for setting a reception frequency and a transmission frequency to different frequencies for each relay system corresponding to each route of the plurality of routes, and each route is provided. As a part of means for setting the reception frequency and the transmission frequency to different frequencies for each of the relay systems, between the pair of relay systems in which the reception frequency and the transmission frequency are set to the same frequency, the output on the modulator output side of each relay system is The same-frequency relay system characterized by comprising signal waveform modifying means having a variable frequency characteristic for introducing a modulated wave signal into a demodulator input side of a corresponding relay system.