RU2153769C1 - Adaptive interference compensator - Google Patents

Abstract

FIELD: radio engineering, various communication systems whose receiving and transmitting parts are located in close proximity. SUBSTANCE: antenna receives interference signals from transmitter located nearby which go into compensating adder to whose second input signal from same transmitter is fed, for instance, by way of direct feeder coupling controlled by amplitude-phase control circuit made of controlled attenuator and phase inverter so that it is equal in amplitude and opposite in phase to signal coming from receiving antenna. Signal from output of circuit of amplitude-phase control is phase-modulated and is summed with remainder of interference across output of compensator and is detected. After this synchronous detector determines phase of received signal. Integrator whose output is used to control controlled phase inverter is placed across output of synchronous detector. Signal from output of modulator is shifted through 90 degrees, is summed up with remainder of interference across output of capacitor, is detected and after this synchronous detector determines phase of received signal. Integrator whose output is used to control controlled attenuator is placed across output of synchronous detector. EFFECT: elimination of remainder of modulation in output signal. 1 dwg

Description

 The invention relates to radio engineering and can be used in various communication systems, the receiving and transmitting parts of which are located in close proximity to each other and work simultaneously.

Known adaptive interference canceller containing a transmitter and a receiver connected to the transmitting and receiving antennas using transmission and reception lines, the transmission line is connected to the reception line through the first amplitude and phase control device, as well as through a 90 ^o phase shifter and a second amplitude control device and phase, the first synchronous detector, the inputs of which are connected to the transmission and reception line, and the output through the low-pass filter is connected to the first amplitude and phase control device, the second synchronous detector p, whose inputs are connected to the receiving line and the output of the phase shifter 90 ^o, and the output through a low-pass filter connected to the second amplitude and phase control apparatus [1].

 Such an adaptive interference compensator operates in a wide range of frequencies, which is associated with the impossibility of constructing a synchronous detector operating in a wide frequency band, with spurious phase raids in the circuits preceding the synchronous detector.

 It is possible to build a compensator with synchronous detectors operating at an intermediate frequency [2]. Such a circuit leads to a significant complication of the compensator, since two channels of conversion to an intermediate frequency are necessary.

 The above drawbacks are deprived of the interference compensation system with additional modulation, containing a receiving channel for receiving a mixture of useful and interfering signals, a compensation channel that receives only an interfering signal, an amplitude-phase control circuit for changing the amplitude and phase of the interfering signal in accordance with the A + control signals αcos (ωt) and B + αsin (ωt), where A and B change in accordance with the differences in the interference signal in the receiving and compensation channels, α and ω are the amplitude and frequency of the modulating low-frequency (LF) g generator, compensating adder, which receives the signal of the main antenna and the signal from the output of the amplitude-phase control circuit, the output of which forms a signal cleared of interference [3]. Since the interfering signal in the compensation channel is modulated in phase and amplitude with the frequency of the low-frequency generator, the output signal of the compensation adder is also modulated in amplitude with the frequency of the low-frequency generator. The modulation phase determines the differences in the amplitude and phase of the interfering signal in the main and compensation channels. Thus, the system is tuned due to the presence of low-frequency modulation in the output signal.

 This analogue is closest to the proposed invention.

 The disadvantage of the prototype is the presence in the output signal of the remainder of the modulation, which is essential for the operation of the system.

 The present invention solves the problem of eliminating the remainder of the modulation in the output signal.

To achieve this technical result, in an apparatus containing an input from a receiving antenna for receiving a mixture of a useful and interfering signal, an additional input that receives only an interfering signal, an amplitude-phase control circuit consisting of series-connected controlled attenuator and phase shifter, compensating adder, first the input of which is connected to the receiving antenna, the second input is connected to the output of the amplitude-phase control circuit, and the output is the output of the adaptive interference compensator, the first the second and second adders, the first envelope detector, the first and second synchronous detectors, the first and second integrators and the low-frequency generator, an additional second envelope detector, a 90 ^o phase shifter, a phase modulator, the first input of which is connected to the output of the amplitude-phase control circuit, are additionally introduced the second input is connected to the output of the low-frequency generator, and the output is connected to a series-connected first adder, a first envelope detector, a first synchronous detector and a first integrator, and is also connected to series-connected phase shifter 90 ^o, the second adder, a second envelope detector, a second synchronous detector and the second integrator, the second inputs of the first and second adders are connected to the output of the offset adder, second inputs of first and second synchronous detectors are connected to the output of the low-frequency oscillator output of the first integrator is connected with the control input of the controlled phase shifter, and the output of the second integrator is connected to the control input of the controlled attenuator.

Distinctive features of the proposed adaptive interference canceller from the specified prototype is that it is additionally introduced a second envelope detector, a 90 ^o phase shifter, a phase modulator, the first input of which is connected to the output of the amplitude-phase control circuit, the second input is connected to the output of the low-frequency generator, and the output is connected to a series-connected first adder, a first envelope detector, a first synchronous detector and a first integrator, and also connected to a series-connected phase rotation 90 ^o , a second adder, a second envelope detector, a second synchronous detector and a second integrator, the second inputs of the first and second adders connected to the output of the compensating adder, the second inputs of the first and second synchronous detectors connected to the output of the low frequency generator, the output of the first integrator is connected with the control input of the controlled phase shifter, and the output of the second integrator is connected to the control input of the controlled attenuator.

 Thanks to such a compensator device, low-frequency modulation is introduced not into the amplitude-phase control circuit, but into the circuit connected between the input and output of the compensating adder and therefore does not get to the output of the compensating adder.

 The proposed adaptive interference canceller is shown in the drawing.

The device contains an additional input 1, an input from a receiving antenna 2, an amplitude-phase control circuit 3, consisting of a controlled attenuator 4 and a controlled phase shifter 5, a compensating adder 6, a phase 7 modulator, an LF generator 8, a phase shifter 90 ^o 9, adders 10 , 11, envelope detectors 12, 13, synchronous detectors 14, 15, integrators 16, 17.

 The operation of the device is as follows.

 From the antenna input 2, the useful signal and interference from a nearby transmitter are fed to a compensating adder 6, the second input of which receives an interference signal from the same transmitter, for example, by branching part of the power from the transmitter, adjusted by the amplitude-phase control circuit 3 so that it is equal in amplitude and opposite in phase to the interference signal received from the antenna input. The output of the compensating adder 6 is the output of the adaptive interference canceller.

The interference signal from the output of the amplitude-phase control circuit enters the phase modulator 7, after which it is summed in the adder 10 with the remainder of the interference signal from the output of the compensator. The total signal is modulated in amplitude with the frequency of the low-frequency oscillator, and the modulation phase takes two values 0 and π depending on the direction in which it is necessary to change the phase of the controlled phase shifter 5 to suppress interference in the receiving channel. The envelope is extracted by the detector 12 and fed to the synchronous detector 14, which determines its phase, and hence the direction of adjustment of the phase shifter 5. It can be shown that the signal at the output of the synchronous detector 14: S ₁ = AUC ₁ sin (B-φ), where A - attenuator control signal 4, B is the control signal of the phase shifter 5, U is the ratio of the amplitudes of the interfering signal at the first input of the compensating adder 6 and the input of the amplitude-phase control circuit 3, φ is the phase difference of the interfering signal at the first input of the adder 6 and the input of the amplitude-phase circuit control 3, C ₁ is a constant determined by the parameters of the circuit. Thus, in the steady state, S ₁ = 0 and B = φ.
Similarly, the signal from the output of the phase modulator 7, phase shifted by π / 2 by the phase shifter 9 after summing with the remainder of the noise at the output of the compensating adder 6 in the adder 11, is amplitude-modulated with the frequency of the low frequency generator. The modulation phase determines the direction of tuning of the attenuator 4. It can be shown that the signal at the output of the synchronous detector 15 is: S ₂ = AC ₂ {U _cos (B-φ) + A}, where C ₂ is a constant determined by the circuit parameters. Thus, in the steady state with B = φ and S ₂ = 0, we obtain A = U and the interference signals at the inputs of the adder 6 are equal in amplitude and opposite in phase, therefore, the interference signal generated by the interfering transmitter does not pass to the output of the compensator.

Literature
1. Pat. U.S. N 3696429.

 2. Pat. U.S. N 3881177.

 3. Pat. US N 4384366 (prototype).

Claims (1)

An adaptive interference compensator containing an antenna input for receiving a mixture of useful and interfering signals, an additional input for receiving only an interfering signal, an amplitude-phase control circuit, containing serially connected controlled attenuator and phase shifter, compensating adder, the first input of which is connected to the antenna input, the second input - with the output of the amplitude-phase control circuit, and the output is the output of the adaptive interference compensator, the first and second adders, the first envelope detector, the first and second second synchronous detectors, the first and second integrators, and a low-frequency (LF) generator, characterized in that it additionally introduced second envelope detector, phase shifter ^o 90, a phase modulator having a first input connected to the output of the amplitude-phase control circuit, the second input - with the output of the LF generator, and the output is connected to a series-connected first adder, an envelope detector, a synchronous detector and an integrator, and also connected to a 90 ^° phase shifter connected in series, a second adder, a detector bending, synchronous detector, integrator, the second inputs of the first and second adders connected to the output of the compensating adder, the second inputs of the first and second synchronous detector with the output of the low frequency generator, the output of the first integrator connected to the control input of the controlled phase shifter, and the output of the second
integrator - with the control input of the controlled attenuator.