RU101845U1 - DEVICE FOR SUPPRESSING BROADBAND ACTIVE NOISE INTERFERENCE - Google Patents

Abstract

 Device for suppressing broadband active noise interference, consisting of a main antenna and a compensation channel antenna, two low-noise high-frequency amplifiers, a voltage divider, three limiters, phase shifters, adjustable attenuators, two converters, the second input of which is connected to the local oscillator, two intermediate frequency amplifiers, an adder and a subtracting device (hereinafter referred to as the subtracting adder), while the antenna outputs are connected to low-noise amplifiers, the output of the low-noise antenna amplifier is compensated The channel is connected to the first input of the converter, the output of which is connected to a voltage divider, each of the outputs of which is connected to a phase shifter and connected in series with it, a corresponding attenuator, while the output of the subtracting adder is the output of the entire device, characterized in that three phase a manipulator, a second voltage divider, two phase detectors, two analog-to-digital converters, two DC component subtraction schemes, two intermediate frequency amplifiers s and two integrators, a converter is connected to the output of a low-noise amplifier in the main channel, the output of which is through a series-connected phase shifter with zero shift, a fully open attenuator, a phase manipulator with a constant zero phase value and an intermediate frequency amplifier connected to one of the inputs of the subtracting adder, the outputs of the attenuators in-phase and quadrature components of the compensation channel are each connected to their series-connected phase manipulators and intermediate amplifiers

Description

The utility model relates to radar and is intended to protect the radar from broadband active noise interference (ACP), acting on the side lobes of the antenna radiation pattern.

ACP suppressors are auto-compensators (AK). The creation of analog AKs for operation in a wide frequency band presents significant difficulties. To increase the broadband, analog AKs are constructed on the basis of attenuators in combination with switches and phase shifters. Designing an AK for operation at an intermediate frequency (IF) causes additional difficulties associated with the narrowband of the main components of the AK, such as a π / 2 phase shifter.

In the journal "Radio Engineering", No. 12 for 1984 (p.10, 11), and in the article White B.et al. Intern. Conf. on sat. Commun. Syst. Technology (1975) describes a high frequency (RF) interference canceller. In this equalizer, low-noise amplifiers are connected to the antenna outputs. Next, in the main path, a directional coupler is included, which performs the functions of a subtractor, to the second input of which a compensating signal is started from the automatic balance adjustment unit (ARV). In this block, 4 copies are formed from the input signal: in-phase with it, in-phase, and two, differing in phase by ± 90 °. Attenuators are included in each of these four branches. The outputs of the attenuators are connected to the adder, the output of which is the output of the ARV unit. Control voltages to the attenuators are supplied using control circuits (CA). The signals supplied to the CA are formed as a result of the correlation of the signals of the primary and secondary channels.

The disadvantage of this device is the low stability of the device in a large dynamic range of changes in interfering vibrations due to fluctuations in the weight coefficients during transients at high interference intensities.

To increase the resistance to self-excitation in a large dynamic range of interference oscillations, i.e. The technical solution described in RF patent No. 2139627, application 98119406/09 dated 10.29.1998, published on 10.10.1999, the patent holder - Center for Technical, allows to increase the stability of the side lobe suppression device and to ensure a high coefficient of suppression of interference when exposed to high intensity interference. cooperation of the electronic complex. "

The device contains the main and additional antennas connected in series with low-noise amplifiers, a divider by 4, phase shifters by zero, 90, 180 and 270 degrees, controlled attenuators, an adder, a subtractor, signal mixers, a local oscillator, amplifiers of the intermediate frequency of the main and additional channels, a limiter intermediate frequency signal, intermediate frequency filter, phase shifter 90 degrees intermediate frequency, in-phase and quadrature control units.

In this scheme, in the subtractor at a high frequency, coherent compensation of the interference received by the main antenna is carried out, which makes it possible to obtain significant suppression of interference in a large dynamic range of interference oscillations at a high frequency, but coherent interference compensation on the IF in this circuit cannot be achieved without alterations. This AK is taken as a prototype.

The proposed technical solution, a device for suppressing broadband ACP (analog-to-digital auto-compensator), allows one to obtain a significant suppression of active noise at an intermediate frequency in a large dynamic range of interference oscillations.

The technical result is achieved in that a device for suppressing broadband active noise interference, which is an analog-to-digital quadrature auto-compensator with digital control, uses phase shifters on surface acoustic waves (SAW), patent for utility model “Phaser on SAW” No. 95926, application No. 2010106578/22 from 02.24.2010; patent holder - JSC FNPC “NNIIRT.” In the used phase shifter between the output channels, a stable phase shift of π / 2 is provided in the entire signal band.

The structural diagram of the proposed device is shown in the figure. The following notation is used in the diagram:

1, 3 - antennas of the main and compensation channels A _ok , A _kk ;

2 - local oscillator;

4, 7 - low-noise amplifiers of the main and compensation channels LNA 1, LNA 2;

5 - the first voltage divider D 1;

6, 8 - converters of the compensation and main channels Pr 1, Pr 2;

9 - the first phase shifter F 1;

10 - phase shifter of the main channel f;

11, 13 - attenuators of the compensation channel Att 1, Att 2;

12 - the first intermediate frequency amplifier UPCH 1;

14 - attenuator of the main channel Att;

15, 19 - phase manipulators of the compensation channel FM 1, FM 2;

16, 18- digital integrators Int 1, Int 2;

17 - the first limiter Ogre 1;

20 - phase manipulator of the main channel FM;

21, 23 - the second and third limiters Ogre 2, Ogre 3;

22 - the second voltage divider D 2;

24 - amplifier of the intermediate frequency of the main channel UPCH;

25. 29 - second and third amplifiers of intermediate frequency UPCH 2, UPCH 3;

26. 28 - scheme for subtracting the constant component of the UPU 1, UPU 2;

27 - the second phase shifter F 2;

30, 33 - analog-to-digital converters ADC 1, ADC 2;

31, 32 - phase detectors PD 1, PD 2;

34 is a subtracting adder ∑.

The device for suppressing broadband ACPs is a quadrature analog-to-digital auto-compensator based on surfactant phase shifters controlled by weight coefficients in the form of a digital code of attenuators and phase manipulators having two phase values - zero and π. The auto-compensator has two subchannels - in-phase and quadrature, which are formed using a voltage divider into two and a phase shifter on the surfactant.

The proposed device comprises an antenna of the main channel 1 and an antenna of the compensation channel 2. To the outputs of the antennas are respectively connected in series low-noise high-frequency amplifiers 4, 7 and converters 6, 8, the second input of which is connected to the output of the local oscillator 2.

In the main channel to the output of the Converter 8 are connected in series to the phase shifter 10, the attenuator 14, the phase manipulator 20 and the intermediate frequency amplifier 24, the output of which is connected to one of the inputs of the subtracting adder 34.

In the compensation channel, the output of converter 6 is connected to the input of the first voltage divider 5 and the input of the first intermediate frequency amplifier 12. The outputs of the first voltage divider 5 are connected to the corresponding inputs of the first phase shifter 9. Using the divider 5 and the phase shifter 9, two quadratures of the compensation channel are formed.

Two identical circuits are connected to the outputs of the first phase shifter 9, consisting, respectively, of a series-connected attenuator of the compensation channel 11 (13), a phase manipulator of the compensation channel 15 (19), and a second (third) intermediate frequency amplifier 25 (29), the outputs of which are respectively connected with inputs 2 and 3 of the subtracting adder 34.

To generate digital codes, the output of the first intermediate frequency amplifier 12 is connected to series-connected: the first limiter 17, the second voltage divider 22 and the second phase shifter 27. Identical circuits forming in-phase and quadrature feedback channels are connected to the outputs of the second phase shifter 27. The circuits consist of series-connected phase detectors 31 (32), ADC 30 (33), a circuit for subtracting the DC component 26, (28), the second and third limiters 21 (23), and digital integrators 16 (18). Digital integrators produce weighting factors in the form of a digital code, the sign of which controls the phase of the phase shifters, and the absolute value controls the attenuation of the attenuators of the compensation channel. The outputs of the digital integrators 16 (18) are connected to the control inputs of the attenuators of the compensation channel 11 (13) and phase manipulators 15 (19). Namely, the first outputs of the digital integrators 16 (18) are connected to the second inputs of the attenuators of the compensation channel 11 (13), and their second outputs are connected to the second inputs of the phase manipulators 15 (19). The output of the subtracting adder 34 is the output of the entire device and, in addition, is connected to the second input of the phase detectors 31 and 32.

A device for suppressing broadband active noise interference works as follows.

The useful signal and interference are received by the antenna of the main channel 1, amplified by a low-noise amplifier of the main channel 4, converted by means of a local oscillator 2 in the converter 8 to an intermediate frequency and fed through the phase shifter of the main channel 10 (without phase shift), open fully attenuator of the main channel 14, phase manipulator of the main channel 20 with a constant zero phase value and an intermediate frequency amplifier of the main channel 24 to the first input of the subtracting adder 34. Phaser, attenu The ator and phase manipulator are included to ensure the identity of the main and compensation channels.

The interference received by the antenna of the compensation channel 3, amplified by a low-noise amplifier of the compensation channel 7 and converted by means of a local oscillator 2 into an intermediate frequency by the converter of the compensation channel 6, is fed to the first voltage divider 5, which, together with the first phase shifter 9 connected in series, form two squares of the compensation channel.

From the outputs of the first phase shifter 9, the noise signals of the compensation channel (in-phase and quadrature components) are supplied, respectively, to the attenuators of the compensation channel 11 and 13, the attenuation of which is controlled by digital codes. By changing the attenuation of the attenuators of the compensation channel 11, 13, it is possible to smoothly rotate the phase of the noise vector of the signal of the compensation channel in the range from zero to π / 2. From the outputs of the attenuators of the compensation channel 11, 13, the noise signals respectively arrive at the phase manipulators of the compensation channel 15 and 19, which, when the sign of the digital control code is changed, ensure that the phase of the noise signal rotates to zero or π. The attenuators of the compensation channel 11 and 13, together with the phase manipulators of the compensation channel 15 and 19, provide rotation of the common vector of the noise signal of the compensation channel in the range of angles from zero to 2π. After the phase manipulators of the compensation channels 15, 19, noise signals amplified by the second and third intermediate frequency amplifiers 25 and 29 are supplied to the second and third inputs of the subtracting adder 34, in which, when added to the noise signal of the main channel, they provide its compensation.

To create digital control codes, the signal received by the compensation antenna 3 from the converter of the compensation channel 6 through the first intermediate frequency amplifier 12, the first limiter 17 and the second voltage divider 22 is supplied to the second phase shifter 27, from the outputs of which the signals of two quadrature signals are respectively supplied to the first phase input detectors 31, 32. at the second input of which a feedback signal is supplied from the output of the subtracting adder 34. The polarity of the signals at the output of the phase detectors 31 and 32 depends on the phase difference MOV signals supplied from the second phase shifter 27, and feedback signals from the output of the subtracting adder 34, and the amplitude from the degree of correlation of these signals.

After digitization in the analog-to-digital converters 30, 33 and passing through the subtraction circuits of the constant component 26, 28, the signals through the second and third limiters 21, 23, having a logarithmic characteristic, are fed to digital integrators 16 and 18, in which control digital codes are generated, the sign of which controls the phase manipulators, and the absolute value - the attenuators.

The device is configured in a strobe located outside the working area of the radar. The control signals of the adjustable digital attenuators 11, 13 generated in the strobe are stored and stored during active operation of the radar at a working distance. The adjustment of the constant component subtraction circuits 26, 28 is carried out in the gate located in front of the gate in which the control signal is generated, with the main channel turned off.

The use in the inventive device of phase shifters for surfactants having a high identity of the amplitude-frequency characteristics and a fixed phase shift of π / 2 in a wide relative passband with an error of 1-2 degrees in phase, provide the autocompensator with high noise suppression at an intermediate frequency.

The use of digital processing greatly simplifies the scheme for generating weight coefficients and their control system.

The use of limiters with a logarithmic characteristic having an initial linear section allows us to stabilize the total dynamic time constant of the auto-compensator.

The use of the proposed device in the product being developed made it possible to obtain a noise suppression coefficient of more than 20 dB in the 20 MHz band at a central frequency of about 80 MHz.

Claims (1)

Device for suppressing broadband active noise interference, consisting of a main antenna and a compensation channel antenna, two low-noise high-frequency amplifiers, a voltage divider, three limiters, phase shifters, adjustable attenuators, two converters, the second input of which is connected to the local oscillator, two intermediate frequency amplifiers, an adder and a subtracting device (hereinafter referred to as the subtracting adder), while the antenna outputs are connected to low-noise amplifiers, the output of the low-noise antenna amplifier is compensated The channel is connected to the first input of the converter, the output of which is connected to a voltage divider, each of the outputs of which is connected to a phase shifter and connected in series with it, a corresponding attenuator, while the output of the subtracting adder is the output of the entire device, characterized in that three phase a manipulator, a second voltage divider, two phase detectors, two analog-to-digital converters, two DC component subtraction schemes, two intermediate frequency amplifiers s and two integrators, a converter is connected to the output of a low-noise amplifier in the main channel, the output of which is through a series-connected phase shifter with zero offset, a fully open attenuator, a phase manipulator with a constant zero phase value and an intermediate frequency amplifier connected to one of the inputs of the subtracting adder, the outputs of the attenuators in-phase and quadrature components of the compensation channel are each connected to their series-connected phase manipulators and amplifiers intermediate frequency, the outputs of which are connected to the corresponding inputs of the subtracting adder, in addition, the output of the compensation channel converter is connected to the intermediate frequency amplifier, a limiter, a second voltage divider and a phase shifter, the outputs of which are connected to the first input of the phase detectors, the second input of which is connected to the output subtracting adder, and the output with the corresponding series-connected analog-to-digital converters, constant subtraction circuits luminaire, limiters and integrators, the first output of which is connected to the second input of the corresponding attenuator of the compensation channel, and the second to the second input of the phase manipulator, in this case, limiters with a logarithmic characteristic are used, and phase shifters for surfactants are used as phase shifters.