UA17265U - Direction finder for detecting sources of active interferences - Google Patents

Abstract

The proposed direction finder for detecting sources of active interferences contains two signal reception channels, a gated element, two subtractors, four threshold unit, two AND logic circuits, and additionally, a control unit, a switching unit, a band-pass filter, a rejection filter, an adder, a logarithmic intermediate-frequency signal amplifier, and an amplitude detector in the main channel of the direction finder. Each signal reception channel contains a signal receiver and a signal detector. The output of the amplifier is connected to the input of the amplitude detector. The inputs of the adder are connected to the corresponding outputs of the switching unit via the band-pass filter and the rejection filter, which are connected in series. The signal input of the switching unit is connected to the output of the amplifier, and the control input is connected to the output of the control unit. The output of the main channel of the direction finder is connected to the input of the first threshold unit via the gated element. The inputs of the first subtractor are connected to the outputs of the signal receivers in the corresponding channels of the direction finder, and the output is connected to the input of the second threshold unit. The inputs of the second subtractor are connected to the second outputs of the signal detectors in the corresponding channels of the direction finder, and the output is connected to the first input of the second AND logic circuit via the third threshold element. The second input of the second AND logic circuit is connected to the second input of the main channel of the direction finder via the fourth threshold element. The output of the second AND logic circuit is used as the output of the direction finder.

Description

Description of the invention

The useful model belongs to the area of radar and can be used in direction-finding channels of radar 2 to determine the direction (bearings) of active jammers.

As you know, in the case of determining the bearings on the PAZ, a useful signal for the direction finder is the jamming signal of one of the M jammers, which is currently located in the main lobe of the radar antenna's directional diagram. Signals of other (M-1) PAZs, received on the side lobes of the antenna directional pattern (DSA), are interferences subject to compensation. In the general case, the bearing problem 70 is solved when 1(y)2C, where 1(y) is the likelihood ratio or function of the input signal monotonically related to it, and C is the threshold with which the value of the likelihood ratio or monotonically is compared of the function of the input signal associated with it. The direction finder operating according to this algorithm has two channels: one - for calculating the value of 1(y), and the other, the so-called auxiliary or compensatory one, for calculating the threshold value C. 12 The known direction finder of sources of active disturbances | see Radar devices. Under the editorship V.V. Grigorina-Ryabova.

M. 1970), in which a high throughput is achieved with a simultaneous increase in resolution.

For this purpose, a subtraction circuit connected to the output of a non-directional antenna, the output of which is connected to the mixer input, and the second input is connected to the output of an additionally introduced series-connected circuit containing directional splitter, attenuator and phase shifter, while the input of the directional splitter is connected to the main antenna. In the well-known direction finder, two serially connected circuits containing a quadratic detector, an integrator, a differentiating circuit, and a comparator are additionally introduced. In addition, the direction finder contains an expansion circuit and a three-input I circuit. Due to the additional introduced three circuits, as well as an expansion circuit and a logic circuit I, in the described direction finder, instead of one, three signs stand out: the maximum signal, the minimum signal and the pulse of the expansion circuit. This makes it possible to increase the throughput and increase the accuracy in the bearing of the PAZ.

However, the drawback of the described technical solution is the complexity of practical implementation and a high level of false bearings caused by the reflection of probing radar signals from passive interference, local objects and hydrometeors. at

The closest technical solution is a two-threshold direction-finding device containing a non-directional antenna and an auxiliary receiving channel connected in series, as well as a separation circuit connected to the outputs of the receiving channels, the output of which is connected through the first threshold device to the first input of the matching circuit, the second input of which is connected through the second threshold device to the output of the main channel, and the output of the comparison circuit is the output of the direction finder | see O.N. Naguedy apa M.S. UMUosa Yuevidpe itog Zideyubre Viapkipd Zuziet. Yeeeee. Ipiegpayopa! Kadag Sopiegepse (IVS-80) Apipdiop, 1980 1. --

In this direction-finding device, the ratio of the amplitudes of the signals received by the directional and non-directional antenna is compared with the first threshold (compensation threshold) and the amplitude of the signal received by the directional antenna with the second threshold (detection threshold). When two thresholds are exceeded at the same time, a decision is made about the presence of a target in the main beam of the directional antenna. The introduction of the threshold of detection Z allows to reduce losses in the bandwidth of the direction-finding device. The disadvantage of the described technical solution is a high level of false bearings caused by the reflection of the radar sounding signal from

From" passive obstacles, local objects and hydrometeors, as well as the narrow specialization of the direction finder.

The useful model is based on the task of eliminating false bearings caused by the re-imaging of radar probing signals from passive interference, as well as expanding the direction finder's functionality.

The task is solved by the fact that the locator of sources of active interference, which contains a series-connected directional antenna and the main reception channel, a series-connected directional antenna and the auxiliary -I reception channel, as well as the first and second threshold devices connected to by the inputs of the matching circuit, the output of which is the output of the direction finder, while each of the channels contains a mixer with a local oscillator common to both channels, an intermediate frequency amplifier (IFA), an amplitude detector and an integrator, additionally introduced into the main channel

Gee! 20 control device, switch, band-pass and rejection filters and series-connected adder and logarithmic

The PFC, the output of which is connected to the amplitude detector, and the inputs of the adder through the bandpass and rejection filters sl are connected to the outputs of the switch, the signal input of which is connected to the PFC, and the control input is connected to the output of the control device, the auxiliary channel additionally contains a bandpass filter and a logarithmic PPU , included between

PFC Its amplitude detector, in addition, the direction finder additionally contains a valve, the first and second subtracting 29 devices, the third and fourth threshold devices and the second matching circuit, the output of which is the second output of the direction finder, and the output of the main channel through the valve is connected to the input of the first threshold device, the inputs of the first subtracting device are connected to the outputs of the receiving channels, and the output is connected to the input of the second threshold device, the inputs of the second subtracting device are connected to the second outputs of the amplitude detectors of the channels, the output through the third threshold device is connected to the first input of the second matching circuit, the second input of which Through the fourth 60 threshold device is connected to the second output of the amplitude detector of the main channel.

The causal relationship between the set of features of a useful model and the technical result is as follows. Due to the fact that the control device, switch, band-pass and rejection filters are introduced and the adder and the logarithmic PFC are connected in series, the output of which is connected to the amplitude detector, and the inputs of the adder through the band-pass and rejection filters are connected to the outputs of the switch, the signal input which is connected to bo PpPpchCh, and the control input - to the output of the control device, the auxiliary channel additionally contains a band-pass filter and a logarithmic PFC, included between the PFC and the detector, and the direction finder additionally includes a valve, the first and second subtracting devices, the third and fourth threshold devices and the second matching circuit, the output of which is the second output of the direction finder, and the output of the main channel is connected through the valve to the input of the first threshold device, the inputs of the first subtracting device are connected to the outputs of the receiving channels, and the output is to the input of the second threshold device, the inputs of the second subtracting device are connected to of the second outputs of channel detectors, the output through the third threshold device is connected to the per with the input of the second matching circuit, the second input of which is connected through the fourth threshold device to the second output of the detector of the main channel - false bearings are eliminated, as well as expanded functionality of the direction finder. 70 The essence of the useful model is explained by the drawing, which shows the structural electrical diagram of the proposed device (Fig. 1).

The proposed device contains a directional antenna 1, a non-directional antenna 2, the main C and auxiliary 4 receiving channels, consisting of a series-connected mixer 5, to the second input of which is connected a local oscillator 6 common to both channels, a modulator 7, a logarithmic modulator 8, an amplitude detector 9 and integrator 10, /5 Valve 11, the first 12 and the second 13 subtracting devices, the first 14, the second 15, the third 16 and the fourth 17 threshold devices, the first 18 and the second 19 matching circuits, moreover, the main channel includes a control device 20, switch 21, bandpass 22 and rejection 23 filters and adder 24, and the auxiliary channel includes bandpass filter 25.

The proposed device as part of the radar works in the following way. During operation, antennas 1 and 2 receive 2o echo signals and signals generated by PAZ. These signals are received at the inputs of the main C and auxiliary 4 reception channels, where they are converted under the influence of the common local oscillator 6 in the mixers 5 into intermediate frequency signals, are amplified in the PFC 7 and are fed to the input of the bandpass filter 25 in the auxiliary 4 and to the input of the switch 21 in the main channel reception 3.

In the working area of the distance (expansion of the circular view indicator) after the emission of the probing signal, during the time interval when the radar uses the information contained in the reflected signals, the control device 20 using the switch 21 connects the output signal of the PRC 7 to the input of the band-pass filter 22 After quasi-optimal filtering of pulse signals in band-pass filters 22 and 25, the signals are sent (in the main channel through the adder 24) to the logarithmic amplifiers 8, where they are compressed in the dynamic range and then sent to the amplitude detectors 9. After detection, the signals of the main and secondary channels reception are received at the inputs of the second subtracting device 13, the output signal of which, taking into account the logarithm of the signals in the channels, is proportional to the ratio of the amplitudes of the signals in the x, reception channels. The signal from the output of the amplitude detector 9 of the main channel C and the output signal of the subtracting device c 13 are received, respectively, at the inputs of the fourth and third threshold devices 17 and 16. In the fourth threshold device 17, the amplitude of the signal received by the directional antenna 1 is compared with the detection threshold. In the third threshold device 16, the ratio of the signal amplitudes (taking into account the logarithmization of the signals in blocks 8) received by the directional 1 and non-directional 2 antennas is compared. If the signal level in the main channel Z exceeds the detection threshold and if, at the same time, there is an excess of the signals of the auxiliary channel 4 over the signals of the main channel Z (that is, the signal is received on the side lobes of the DSA), then the binary signal BLANK PBP is formed at the output of the matching circuit 19. The PBP BLANK signal is used in the radar echo signal processing channel to blank the information coming to the indicator, with the aim of suppressing the pulse interference received on the side lobes of DSAT1. Valve 11 in the working area of the distance is closed and the signal to the output of the matching scheme 18 does not pass. ;" In the non-working section of the distance (the interval within which the radar does not use the information contained in the reflected echo signals), the control device 20 opens the valve 11 and, using the switch 21, connects the output signal of the PFR 7 to the input of the rejection filter 23. The filter 23 rejects the frequency spectrum , in which the energy of the echo signals is concentrated, i.e., in the main channel Z, signals reflected from passive interference, local objects, and hydrometeors are silenced. In the presence of active noise interference, the spectrum width

Sh- which significantly exceeds the width of the spectrum of echo signals, the signal through the rejection filter 23 and the adder 24 in the main channel C and through the bandpass filter 25 in the auxiliary channel enters the input of the logarithmic amplifiers 8. From the outputs of the logarithmic amplifiers 8, the signal passes through the amplitude detectors 9 and integrators 10

Me. enters the inputs of the first subtracting device 12, the output signal of which, taking into account the logarithm of the signals in the channels, is proportional to the ratio of the amplitudes in the receiving channels. The signal of the main channel C through the valve 11 and the output signal of the subtracting device 12 are received, respectively, at the inputs of the first and second threshold devices 14 and 15. In the first threshold device 14, the average value of the amplitude of the noise signal received by the directional antenna 1 is compared with the detection threshold. In the second threshold device 15, the ratio of the average values of the signal amplitudes received by the directional 1 and non-directional 2 antennas is compared. If the signal level in the main channel C exceeds the detection threshold and if, at the same time, there is an excess of the signal of the main channel C over the signal of the auxiliary channel 4, then a binary signal DIRECTION is formed at the output of the matching circuit 18. The appearance of the DIRECTION signal at the output of the direction finder indicates the presence of an active noise interference detector in the main beam of the DSA.

A feature of the direction finder is the formation of an amplitude contrast between the echo signals received by the main and auxiliary reception channels. This is realized due to the use of a cut-off filter in the main channel and a band-pass filter in the auxiliary channel during direction finding. At the same time, even if the echo signals are received from the direction of the main DSA beam, due to their rejection in the main channel at the output of 65 receiving channels, the auxiliary channel signal received by the non-directional antenna will prevail. Thus, the use of amplitude contrast makes it possible to exclude false bearings due to passive obstacles, local objects and hydrometeors. Under the influence of active interference, the spectrum of which is evenly distributed in the passband of the rejection and bandpass filters, the amplitude contrast is not formed (because the effective passbands of the bandpass and rejection filters are chosen to be the same, taking into account the transmission coefficients) and the probability of correct bearing does not decrease.

The use of a bandpass filter at the input of the logarithmic IF in the main and auxiliary channels (the logarithmic IF is a non-linear device) makes it possible to realize the high sensitivity of the proposed device in the mode of suppressing impulse disturbances acting on the side lobes of the directional diagram.

The proposed device allows you to realize two tasks, namely: direction finding of active 7/0 noise jammers and the task of suppressing impulse jamming acting on the side lobes of the DSA with the help of one device.

Claims (1)

The formula of the invention y y ' y U y Finder of sources of active interference, which contains a series-connected directional antenna and the main reception channel, a series-connected non-directional antenna and an auxiliary reception channel, as well as the first and second threshold devices connected to the inputs comparison circuit, the output of which is the output of the direction finder, while each of the channels contains a mixer with a local oscillator common to both channels, an intermediate frequency amplifier (IFA), an amplitude detector and an integrator, which is distinguished by the fact that a control device, a switch, is additionally introduced into the main channel of the direction finder , bandpass and rejection filters, and an adder and a logarithmic PFD are connected in series, the output of which is connected to the amplitude detector, and the inputs of the adder through the bandpass and rejection filters are connected to the outputs of the switch, the signal input of which is connected to the PFD, and the control input - to the output of the control device, the auxiliary channel additionally contains a bandpass filter and a logarithmic PPU included between the PPC and the detector, and the ngator additionally includes a valve, first and second subtracting devices, third and fourth threshold devices and a second matching circuit, the output of which is the second output of the direction finder, and the output of the main channel is connected through the valve to the input of the first threshold device, the inputs of the first subtracting device are connected to of the outputs of the receiving channels, and the output is to the input of the second threshold device, the inputs of the second subtraction device are connected to the second outputs of the channel detectors, the output through the third threshold device is connected to the first input of the second matching circuit, the second input of which is through the fourth threshold device connected to the second output of the main channel detector. ise) s u yo - and? - -and name) (o) sl 60 b5