RU96101435A - METHOD FOR COMPENSATING IN-CHANNEL ADDITIVE RADIO INTERFERENCE IN AMPLITUDE-MODULATED RECEIVERS, FREQUENCY PHASOMANIPULATED RADIO SIGNALS AND DEVICE FOR ITS IMPLEMENTATION - Google Patents

Claims (3)

1. A method of compensating for in-channel additive radio interference in receivers of amplitude-modulated, frequency and phase-shifted radio signals, consisting in receiving an additive mixture of a useful signal and an interference signal and subtracting from the received mixture a useful signal and an interference signal of a compensating interference signal, characterized in that the compensation signal is extracted the interference signal from the received mixture of the useful signal and the interference signal, in which instant samples of the interference signal are generated at zero times the field signal in the received additive mixture of the useful signal and the interference signal and restore from them the analog interference signal that matches the shape of the interference signal in the received additive mixture of the useful signal and the interference signal, and then the subtracted reconstructed interference signal, which is a compensating signal of interference, is subtracted from the received mixtures of the useful signal and the interference signal, the aforementioned allocation of the compensating interference signal is carried out separately in the lower and inverted upper side bands x the received mixture of the useful signal and the interference signal, while previously the spectrum of the upper sideband signal is mirror-inverted to the spectral region of the lower sideband, and after subtracting the useful signal and the interference signal of the compensating interference signal from the mixture of the inverted upper sideband, they re-mirror the inversion of the spectrum of the inverted upper sideband to its original position, after which the obtained spectra of the upper and lower sidebands are taken together forward the desired signal.  2. A device for compensating in-channel additive radio noise in receivers of amplitude-modulated, frequency and phase-shifted radio signals, comprising an antenna, a frequency converter consisting of a mixer and a local oscillator, an amplification amplifier and an algebraic adder, with an antenna connected to the first input of the mixer, and a local oscillator connected to the second input of the mixer and the mixer output is connected to the input of the amplifier, characterized in that the first and second isolators of the compensating interference signal are introduced into it within the lower and inverted the side band, respectively, the first and second delay blocks, an additional algebraic adder, the first and second additional mixers, the first and second band filters of the lower and upper side bands, respectively, the adder and the master oscillator, and the input of the first delay block, the output of which is connected connected to the summing input of the algebraic adder, the input of the first isolator of the compensating interference signal, the output of which is connected to the subtracting input of the algebraic adder, and the first input is not of the first additional mixer, the output of the second delay unit, the output of which is connected to the summing input of the additional algebraic adder, and the input of the second isolator of the compensating interference signal, the output of the algebraic adder through the first bandpass filter of the lower sideband is connected to the first input of the adder which is connected to the subtracting input of the additional algebraic adder, the output of the additional algebraic adder through The second auxiliary mixer and the second bandpass filter of the upper sideband are connected separately to the second input of the adder, the output of which is the output of the device, and the output of the master oscillator is connected to the second inputs of the first and second additional mixers.  3. The device according to claim 2, characterized in that each isolator of the compensating interference signal consists of a sampling unit, a synchronization unit and an interference signal recovery unit, while the inputs of the sampling unit and the synchronization unit are combined and are the input of the isolator, and the output of the synchronization unit is connected to the control input of the discretization unit, the output of which is connected to the input of the interference signal recovery unit, the output of which is the output of the isolator.