RU2152051C1 - Method for protection of radar station against anti-radar missile and device which implements said method - Google Patents

Abstract

FIELD: radar equipment. SUBSTANCE: method involves emission of sounding signals by radar to be protected, emission of simulation pulses at same frequency as sounding signals, transmission and reception of codes of parameters of radar sounding signals, generation of masking pulses, which are delayed with respect to received sounding signals by repetition rate of sounding signals minus sum of advance interval and time interval for which sounding pulses pass known distance from radar to location of reception and emission of masking and simulation pulses, from location of reception and emission of masking and simulation pulses to remote passive emission source, and from remote passive emission source to radar. Then, method involves generation of masking pulses, which duration with respect to received sounding pulse is equal to sum of advance, duration of sounding pulse and double interval, which is required for passing known distance from radar to remote passive emission source. Then, method involves amplification of masking and simulation pulses, and their emission towards remote passive emission source, and re-emission of masking and simulation signals by passive emission source within known spatial angle. Respective device has receiving and transmitting antennas, channel for transmission of codes of parameters of radar sounding pulses, device for generation of modulation signals, carrier frequency generator, modulator, microwave amplifier, and remote passive emission source. EFFECT: increased efficiency of radar station protection. 4 cl, 3 dwg

Description

 The present invention relates to the field of radar and radio countermeasures and can be used to protect radars with pulse-to-pulse parameters of a signal from damage from anti-radar missiles homing onto radio emission.

Known methods for the protection of radar stations (radar) from anti-radar missiles, based on the emission of signals from false sources, including:
1. Methods based on the emission by one or more false transmitters through the antenna of pulses unsynchronized with the protected radar (RF Patent N 2099734), pulses offset from the probing signal, and each pulse of the false transmitter is ahead of the pulse of the protected radar (German Patent N 3341070), pulses overlapping radar pulses (US Patent N 4,990,919) or coherent pulses (US Patent N 4,646,098);
2. Methods based on the introduction of an additional device for detecting anti-radar missiles and false transmitters with antennas, moreover, the radar when it detects anti-radar missiles is turned off, and the false transmitters turn on and emit signals in the direction of anti-radar missiles (German Patent No. 3341069, Japanese Application 2-40193) ;
3. Methods based on the termination of radar radiation towards an anti-radar missile upon detection of the latter and emission of a false source signal through an additional antenna connected to the radar cable or directly from a reflector mounted on the ground (German Patent No. 4229509) or in the air (Application Japan 4-351984).

 A common drawback of almost all of these methods is the use of radar protection for false transmitters emitting their signals through the antenna in the direction of anti-radar missiles. This leads to the fact that when the energy of these signals is sufficient to protect the radar, the anti-radar missile re-targets the false transmitter and hits it with a probability close to unity. As a result, with a simultaneous attack on the radar with several anti-radar missiles (the standard method of conducting military operations) after the first missile is hit by a false transmitter, subsequent missiles confidently hit the protected radar. In addition, a number of methods provide for the sewerage of microwave energy from the protected radar to false transmitters via microwave cables or waveguides, which are also vulnerable to the damaging factors of the warhead of anti-radar missiles (shock wave or fragments), which significantly reduces the effectiveness of radar protection from anti-radar missiles. In the methods of the second and third groups, it is planned to turn off the radar radiation when anti-radar missiles are detected by an additional detector and turn on the false transmitter. At the same time, the radar’s combat work is completely disrupted and the tracking of targets is stopped.

 Thus, a common drawback of the described methods is the insufficient effectiveness of radar protection from anti-radar missiles, which is a consequence of the high likelihood of anti-radar missiles hitting false transmitters and microwave cables connecting the radar with a false transmitter.

 Closest to the proposed invention is a method of protecting a radar station from anti-radar missiles (UK Patent N 2252464), comprising receiving radiation from an antenna of a protected radar and emitting a simulated signal by an auxiliary transmitter at a signal frequency of a protected radar.

 This method is implemented by a device adopted as a prototype (see ibid.) And containing a protected radar with a transmitting antenna and an auxiliary transmitter remote from it, designed to interfere with an anti-radar missile and having a receiving antenna, attenuator, microwave amplifier and transmitting antenna. Using the directional receiving antenna, the auxiliary transmitter receives radiation from the transmitting radar antenna along the side lobes of its radiation pattern. The received signal is limited by the attenuator, amplified in the microwave amplifier and emitted by a weakly directed transmitting antenna in a wide solid angle. The transmitting antenna of the auxiliary transmitter is oriented in the direction of the vertical axis to overlap the sector of the most likely approach of the anti-radar missile. According to the author of the aforementioned patent, when pointing at such a radar system, an anti-radar missile should be aimed at the energy center of two radiation sources located at a sufficient distance from the protected radar and the auxiliary transmitter.

 As you know, modern anti-radar missiles are equipped with temporary selection devices that provide guidance on one of the pulses of the probing and imitating signals in a given period of their movement, as well as angular selection devices that separate one object from the composition of a group target at the end of the flight, when the angular mismatch between the objects group goal reaches several degrees.

 When protecting pulsed radars by the methods and device described above, the homing missile head receives separately the radar pulses and the pulses of the auxiliary transmitter. The difference in the time the radar pulses and the auxiliary transmitter arrive at the homing head is due to the distance between them. For example, when the distance between the radar and the auxiliary transmitter is 150 m, the time interval between the leading edges of their pulses is in the direction of the remote transmitter - 1 μs radar. The pulse duration of a pulsed radar is (0.2 - 0.5) μs. In this case, the angular selection device provides guidance of the anti-radar missile either by the pulses of the radar being protected or by the pulses of the auxiliary transmitter, which leads to the defeat of one or another object. Moreover, when approaching a distance of (0.5 - 1) km, one of the targets (radar or auxiliary transmitter) begins to resolve in angular coordinates. In this case, the selected target does not affect the guidance of the anti-radar missile.

 Thus, the known method and device for protecting the radar from anti-radar missiles, selected as a prototype, do not have sufficient protection against it. The probability of hitting both objects of the radar system with two anti-radar missiles is close to one.

 The present invention is based on the task of developing a method for protecting a radar station from anti-radar missiles and a system for its implementation, providing a false point of aiming anti-radar missiles, remote from the protected radar station by a distance exceeding the effective radius of destruction of the warhead of the anti-radar missile.

 The problem is solved in that in a method for protecting a radar station from an anti-radar missile, comprising receiving radiation from the probing signals of the protected radar station and emitting simulating pulses at the frequency of the probing signals from the protected radar station, according to the invention, an external passive radiation source is used, and the transmissions generated in the protected radar station are transmitted codes of the parameters of its sounding signals with their subsequent reception, forming masking pulses, the delay time of which relative to the received sounding signals is determined as the repetition period of the sounding signals, reduced by the sum of the lead time and the time spent by the sounding signals on passing at known speeds from the protected radar station to the place of reception and emission of masking and imitating pulses, from the place of reception and emission of masking and imitating pulses to a remote passive radiation source and from a remote passive the radiation source to the protected radar station, the formation of the duration of the masking pulses relative to the received sounding signal, equal to the sum of the lead time, the duration of the sounding signal and the doubled time spent by the signal on passing a known distance from the protected radar station to the remote passive radiation source, amplification of masking and simulating pulses and their radiation in the direction of the remote passive radiation source and luchenie masking and simulating pulses rendered passive radiation source in a predetermined solid angle space.

 Advance reception of codes of probing signal parameters provides the possibility of timely calculation of the delay time of the emitted masking signal relative to the received one to ensure that the leading edge of the masking pulse is ahead of the leading edge of the sounding signal for any direction of approach of the anti-radar missile and the corresponding formation of a masking signal. Advance at the location of the anti-radar rocket of the leading edge of the masking pulse provides triggering of the selection of the homing head of the anti-radar rocket along the leading edge and guiding it only by the masking signal. The duration of the masking signal is set based on the condition of the overlapping of the probing signal. This allows, in the case of an algorithmic failure of the anti-radar missile from selection along the leading edge of the pulse, to preserve the interference effect and to ensure that the anti-radar missile is guided to the energy center of the twin source - radar - an external passive radiation source. The additional formation of simulating signals at adjacent frequencies makes it difficult to capture the true radar signal by the homing missile at the stage of searching and capturing a ground target.

 To ensure the invulnerability of radar protection equipment in the claimed method provides for the masking and simulating pulses in the direction of the anti-radar missile not directly from the antenna, as in the prototype, but through a remote passive radiation source. This is due to the fact that the antennas are subject to the damaging factors of the warhead of the anti-radar missile and are easily affected by both high-explosive and fragmentation components of the warhead when it is undermined even at a distance of up to two to three tens of meters. In addition, they basically can not be carried far from the transmitter serving them, which leads to the simultaneous defeat of the transceiver equipment, which generates masking and imitating pulses. When pointing the anti-radar missile to a remote passive radiation source, as provided by the present invention, full security of the proposed system is achieved, since a remote passive radiation source can be located at a distance of up to 100 meters from the transceiver equipment. The security of the most remote passive radiation source is achieved due to its constructive implementation.

 A passive source can be, for example, an angular reflector having a pronounced radiation pattern with its main lobe oriented in the direction of the intended sector of the anti-radar missile attack, or a sphere with a uniform circular radiation pattern (D. Barton. "Radar systems". Transl. From English. P Gorokhova et al., Moscow, Military Publishing House, 1967, p. 82-86). When a passive radiation source is made of armored elements, for example, steel or duralumin of sufficient thickness (approximately from 3 to 10 mm), these elements are not pierced by fragments, and due to their considerable weight with small linear dimensions (up to 1.5-2 m) the impact of a high-explosive component arising from the explosion of an anti-radar missile.

 Thus, the formation of a masking pulse ahead of and blocking the probing signal of the protected radar, as well as the use of a masked and simulating pulses in the direction of an anti-radar missile with an external passive radiation source, significantly increase the effectiveness of radar protection from damage from anti-radar missiles in comparison with known methods.

 The problem is also solved by the fact that the system for protecting a radar station from an anti-radar missile, comprising a receiving antenna, a microwave amplifier and a transmitting antenna, according to the invention further comprises a preselector connected to the receiving antenna, an external passive radiation source, and a channel for transmitting the codes of the parameters of the probing signals of the radar stations associated with a radar station, a modulating signal generating device, one of the inputs of which is connected to the channel output transmitting the parameters of the probing signals of the radar station, and its other input to the output of the preselector, a carrier frequency forming device connected by its input to the preselector output, a modulator, one group of inputs of which is connected to the outputs of the carrier frequency forming device, and the other group of its inputs to the outputs devices for generating modulating signals, while the output of the modulator is connected to the input of a microwave amplifier connected to a transmitting antenna oriented by the maximum radiation pattern n imposed passive radiation source remote from the perimeter of the radar and transmitting antenna by a distance greater than the radius of the warhead defeat anti-radar missiles, wherein the angular dimension of the radiation source rendered passive by placing the point of the transmitting antenna is the angular size of the main lobe of the radiation pattern of the transmitting antenna.

 Advance transmission of the codes of the protected radar is carried out by the channel for transmitting the codes of the parameters of the probing signals of the protected radar associated with the radar. For transmission, codes of signal parameters are used, which are used in any radar when generating a probing signal in a radar transmitter. The resulting codes are used in a modulating signal generating apparatus to generate an appropriate sequence of modulating pulses.

 The radar probe signal received by the receiving antenna of the proposed system is amplified in the preselector and used in the carrier frequency generating device to generate continuous signals at a frequency that coincides with the frequency of the radar probe signal and the adjacent frequency of this frequency range. These signals are modulated in a modulator, while a masking pulse that advances and overlaps in time the radar probe signal for any direction of approach of an anti-radar missile is generated at a frequency that matches the frequency of the radar signal, and a simulating pulse at an adjacent frequency of this frequency range. These pulses are amplified and emitted in the direction of the remote passive radiation source. Such work of the inventive system provides the formation of masking and simulating pulses, redirecting the anti-radar missile to a remote passive radiation source.

 Thus, the claimed system completely performs operations according to the claimed method, which provides effective protection of the radar from damage by an anti-radar missile.

It is advisable that the channel for transmitting the parameters codes of the probing signals of the radar station would contain a series-connected transmitter of the codes for the parameters of the probing signals of the radar station, the communication line and the receiver of the codes for the parameters of the probing signals of the radar station, the device for generating modulating signals would contain a series-connected differentiating circuit, an analog-to-digital converter, and microprocessor, while one of the inputs of the device for generating modulating signal would be the input of the differentiating circuit, which would be connected to the output of the preselector, and its other input would be one of the inputs of the microprocessor, connected to the output of the receiver of the codes of the parameters of the probing signals of the radar station, the device for forming the carrier frequencies would contain a frequency detector, an analog-to-digital converter , a microprocessor and two controlled generators, while one input of the frequency detector, which is the input of the carrier frequency forming device, would be connected to the output of the preselector , the output of the frequency detector through an analog-to-digital converter would be connected to a microprocessor, the control outputs of which would be connected respectively to the control inputs of controlled generators, while the output of one controlled generator would be connected to another input of the frequency detector, and the outputs of controlled generators would be outputs carrier frequency shaping devices, in addition, the modulator would contain two microwave keys and an adder, moreover, one of the microwave key inputs would be connected respectively to the outputs controlled generators, the control inputs of the microwave keys would be connected to the microprocessor outputs of the modulating signal generating device, and the outputs of the microwave keys would be combined by an adder, the output of which would be the output of the modulator
Preferably, the remote passive radiation source would be a conductive hemisphere, the thickness and material of which would be selected from the condition that its high-explosive and fragmentation components would not be damaged if the warhead of an anti-radar missile explodes.

 Use for transmitting codes of signal parameters of a protected radar station of a transmitter of signal parameters, a communication line and a receiver of codes of signal parameters, for receiving the probing radar signal of a receiving antenna and a selector, for generating masking and imitating signals of two controlled generators, two microprocessors, a frequency detector, and a differentiating circuit , two microwave keys, an adder and a microwave amplifier, for emitting them in the direction to a remote passive radiation source of a highly directional ayuschey antennas for re-radiation into the upper hemisphere rendered passive radiation source in the form of a conductive hemisphere enables most efficiently implement the inventive method.

In the future, the invention is illustrated by a specific example of its implementation and the accompanying drawings, in which:
FIG. 1 shows time diagrams of sounding and masking signals at the points of placement of the protected radar station, preselector and remote passive radiation source;
figure 2 is a block diagram of a system for protecting a radar station from anti-radar missiles;
FIG. 3 is a structural diagram of a radar protection system against anti-radar missiles.

 The proposed method of protecting a radar station from anti-radar missiles is as follows.

 The transmission of the parameter codes of the probing signals of the protected radar is made in order to synchronize masking and imitating pulses with the probing radar signals. The parameter codes of the probing signals are generated in the radar equipment and are used to control its mode. In time, the formation of parameter codes always precedes the formation of sounding signals. Parameter codes are transmitted in real time on a communication line, the type of which (wired, radio, optical) is not of fundamental importance. A fundamental limitation on the length of the communication line is the size of the time interval between the moment of transmission of the code and the formation of the probing signals: it must exceed the propagation time of the code along the communication line between the transmitter and receiver of the codes.

 The parameter codes of the probing radar signals are received at the place of reception and emission of masking and imitating pulses.

 The received signal is used to restore the carrier frequency of the probing signals. Recovery methods - reduction of the frequencies of a continuous signal of a controlled generator in a self-tuning system of frequencies or a signal recirculation device.

The formation of the delay time of the masking pulses relative to the received sounding signals, corresponding to the repetition period, reduced by the sum of the lead time and the time spent by the signals on traveling at a speed of light of known distances from the protected radar to the place of reception and emission of masking and imitating pulses, from the place of reception and emission of masking and simulating pulses to the remote passive radiation source and to the protected radar, provides advance masking pulse probing Radar signals throughout the hemisphere. The delay time is calculated by the formula
T _ass = T _rep - (g ₁ + g ₂ + g ₃ ) / s + T _op , (1)
where g ₁ , g ₂ , g ₃ are the distances between the protected radar and the place of reception and emission of masking and imitating pulses, between the place of reception and radiation of masking and imitating pulses and a remote passive radiation source, between the remote passive radiation source and the protected radar, respectively;
T _op - pre-selected and recorded in the microprocessor memory value of the lead time;
c is the speed of light.

The formation of the duration of the masking pulses relative to the received sounding signals, equal to the sum of the lead time, the pulse duration and the doubled time spent by the signals on passing a known distance from the protected radar to the remote passive radiation source at the speed of light, ensures that the masking pulse covers the probe signals in the entire hemisphere of space. Duration is calculated by the formula
τ ₁ = 2r ₃ / c + T _op + τ ₂ (2)
where τ ₁ is the pulse duration of the masking signal;
τ ₂ - the pulse duration of the signal of the protected radar.

Figure 1 presents the timing diagrams of probing and masking signals:
a) a sounding signal at the radar location point;
b) a probe signal in the place of reception and emission of masking and imitating pulses;
c) a masking impulse at the place of reception and emission of masking and imitating impulses;
d) a masking pulse at the point of placement of the remote passive radiation source;
d) a masking pulse at the radar placement point;
f) a sounding signal at the location of the remote passive radiation source.

 From FIG. 1 it follows that in two critical directions: a remote passive radiation source - radar and radar - a remote passive radiation source, the masking pulse blocks and advances the probing radar signals.

 The calculated values of the delay time and duration of the masking pulse are used to pulse modulate a continuous signal at the carrier frequency of the radar probe signals.

 To make it difficult for a passive radar to capture a radar homing signal at the search and capture stage, a simulated pulse is generated. A simulating pulse is generated at a frequency that does not coincide with the frequency of the radar probe signals by introducing an additional frequency stand to the reconstructed carrier frequency of the radar probe signal. A continuous signal at a frequency of a simulating pulse is subjected to pulse modulation with a pulse duration and a repetition period corresponding to the received codes of the corresponding parameters of the radar probe signals.

 Masking and simulating pulses are amplified and radiated in the direction of the remote passive radiation source. To reduce the radiation level in minor directions that do not coincide with the direction to the remote source, shielding and absorbing devices are used.

 An external passive radiation source re-emits masking and imitating pulses in a given solid angle of space. As a passive source, rotation ellipsoids, corner reflectors, dipole reflectors, etc. can be used.

 A system for protecting a radar station from anti-radar missiles comprises a channel 1 (Fig. 1) for transmitting the parameters of the radar probe signals, the input of which is connected to the output of the radar clock of the protected radar (not shown), a modulating signal generating device 2, one of whose inputs is connected to the output of channel 1, and its other input, to the output of the preselector 3, connected to the receiving antenna 4, for example, a horn antenna (see Korbansky I.N. "Antennas". Moscow, Energia, 1973, p.197-214). The system also contains a carrier frequency generating device 5 connected to the output of the preselector 3 by its input, a modulator 6, one group of inputs 7 and 8 of which is connected to the outputs of the device 5, and the other group of its inputs 9 and 10 to the outputs of the device 2, while the output modulator 6 is connected to the input of the microwave amplifier 11 connected to the transmitting antenna 12, oriented by the maximum radiation pattern to a remote passive radiation source 13, remote from the protected radar and transmitting antenna 12 by a distance exceeding the pore radius of the warhead of the anti-radar missile, and the angular size of the transmitted passive radiation source 13 from the location of the transmitting antenna 12 is equal to the angular size of the main lobe of the radiation pattern of the transmitting antenna 12, made, for example, in the form of a mirror or lens antenna with an irradiator (see I. Korbansky Antennas. Moscow, Energy, 1973, p. 214-286).

 Channel 1 (figure 2) contains a series-connected transmitter 14 of the parameters of the radar sounding signals, a communication line 15 and a receiver 16 of codes of the parameters of the radar sounding signals, the output of which is the output of channel 1. Channel 1 is a standard transmission channel used to transmit discrete messages (see, for example, NI Kalashnikov et al. "Radio communication systems. Moscow, Radio and communications, 1988, p.5-9). Technical performance of the elements of channel 1 transmission, i.e. the use of wired communication or communication in the radio or optical wavelength range, the types of modulation used, may be different. The use of wireless is preferred.

 The modulating signal generating device 2 comprises a differentiating circuit 17, an analog-to-digital converter 18, and a microprocessor 19 connected in series. The input of the differentiating circuit 17, which is the input of the device 2, is connected to the output of the preselector 3 connected to the receiving antenna 4. The output of the receiver 16 is connected to the input 20 a microprocessor 19, the input 21 of which is connected to the output of an analog-to-digital converter 18. The differentiating circuit 17 can be performed on operational amplifiers, for example, according to the schemes given in books e (Tetelbaum IM, Schneider Yu.R. "Practice of analog modeling of dynamic systems". Reference manual, Moscow, Energoatomizdat, 1987, p. 88-94). Preselector 3 can be made, in particular, according to the scheme described in (Radio receivers. / Ed. By A.P. Zhukovsky, Moscow, Higher School, 1989, pp. 8-10, 32-56), including input circuits, low noise amplifier and radio frequency amplifier.

 The carrier frequency generating device 5 comprises a frequency detector 22, an analog-to-digital converter 23, a microprocessor 24, and controlled oscillators 25 and 26. The input 27 of the frequency detector 22, which is the input of the device 5, is connected to the output of the preselector 3, the output of the frequency detector 22 through an analog-digital the converter 23 is connected to the microprocessor 24, the control outputs 28 and 29 of which are connected respectively to the control inputs of the controlled oscillators 25 and 26. The output of the controlled generator 25 is connected to the input 30 of the frequency detector a 22. The frequency detector 22 can be performed, in particular, according to schemes with amplitude conversion of frequency modulation (see "Radio receivers" ./ Edited by A.P. Zhukovsky, Moscow, Higher School, 1989, pp. 146-148 ) Analog-to-digital converters 18 and 23 can be performed on standard integrated circuits (see "Designing radio transmitting devices using computers." / Edited by OV Alekseev, Moscow, Radio and Communications, 1987, p. 328-332; "Guide to radar." / Edited by M. Skolnik, trans. From English, vol. 3, Moscow, Soviet Radio, 1979, pp. 189-195). Controlled generators 25 and 26 are performed, for example, on solid-state elements, in particular, using varactors or YIG resonators (L. Gassanov et al. “Solid-state microwave devices in communication technology.” Moscow, Radio and Communications, 1988, p. 237). Microprocessors 19 and 24 are built and programmed on the basis of standard circuit solutions described, for example, in R. Tokheim's book "Microprocessors", trans. from English under the editorship of V.I. Grasevich. Moscow, Energoatomizdat, 1988, p. 81-195).

 The modulator 6 contains microwave keys 31 and 32 and an adder 33, and the inputs 34, 35 of the microwave keys 31, 32 are connected respectively to the outputs of the controlled generators 25 and 26, the control inputs 36, 37 of the microwave keys 31 and 32 are connected to the outputs of the microprocessor 19 device 2 forming modulating signals. The outputs of the microwave keys 31 and 32 are combined by an adder 33, the output of which is the output of the modulator 6 and connected to the input of the microwave amplifier 11. The microwave keys 31 and 32 are based on switching diodes according to the schemes described in the book by L. Gassanov. and others. "Solid-state microwave devices in communication technology." Moscow, Radio and Communications, 1988, p. 135-140). The adder 33 can be performed on connected strip lines or double waveguide tees according to the schemes presented in the book "Design of radio transmitting devices using computers." / Ed. O. V. Alekseeva, Moscow, Radio and Communications, 1987, p. 196-203. Microwave amplifier 11 is performed, for example, on the basis of solid-state active microwave elements (see L. Gassanov and others. "Solid-state microwave devices in communication technology. Moscow, Radio and communication, 1988, p. 156 - 168).

 The remote passive radiation source 13 is a conducting, for example metal, hemisphere, providing uniform radiation in all directions, i.e. all-round radar protection against anti-radar missiles. Matching the size of the hemisphere with the linear size of the radiation pattern of the transmitting antenna 12 ensures minimal energy loss during re-radiation. The thickness of the material (steel or duralumin) is selected from the condition that its high-explosive and fragmentation components that occur during the explosion of the warhead of a radar missile are not affected, and is 3-10 mm.

 The proposed device to protect the radar from anti-radar missiles works as follows.

The system equipment for protecting the radar from being hit by an anti-radar missile (with the exception of the transmitter 14 and the remote passive radiation source 13) is located at a distance of r ₁ = (100-200) m from the protected radar. Remote passive radiation source 13 is installed at a distance of r ₂ = (60 -100) m from the complex of electronic protection and at a distance of g ₃ = (150-250) from the protected radar. The distance between the protected radar, the complex of electronic protection and the remote radiation source 13 is measured and entered into the memory of the microprocessor 19.

 The transmitter 14, located on the radar of the protected radar, before each sounding signal transmits the code of the repetition period implemented in this radar cycle and the duration code of the next signal. Codes of these parameters are generated in each radar to control their own transmitter. Codes on the communication line 15 are sent to the receiver 16, and then to the input 20 of the microprocessor 19. The type of the communication line 15 — wired, radio, or in the optical range — is not critical.

 Probing radar signals are emitted from the main lobe, side lobes and the background of the antenna pattern. The preselector 3 provides for the frequency selection of the probing signals of the protected radar, which is received through the receiving antenna 4, and their amplification. The amplified signals are fed to the input 27 of the frequency detector 22 and in parallel to the differentiating circuit. 17. The frequency detector 22 generates a voltage proportional to the magnitude of the frequency detuning between the frequencies of the signals of the controlled oscillator 25 and the received sounding signals. The error signal from the output of the frequency detector 22 is converted into the corresponding digital code by an analog-to-digital converter 23 and is fed to the input of the microprocessor 24.

 According to the adopted code, the microprocessor 24 at its output 28 generates control signals of the microwave generator 25, corresponding to the frequency mismatch between it and the probing signals. Thus, the frequency detector 22, the converter 23, the microprocessor 24, and the controlled microwave generator 25 form an automatic frequency control system. The auto-frequency control system performs the function of restoring the carrier frequency specified in the operations of the method.

From the output 29 of the microprocessor 24, the control signal is input to a controlled microwave generator 26. The control signal tunes the microwave generator 26 to one of the pre-selected frequency letters of the protected radar by introducing a predetermined frequency detuning into it relative to the radar signal of the protected radar
The differentiating circuit 17 highlights the leading edge of the received sounding signals. The output signal of the differentiating circuit 17 is supplied to the converter 18, where it is converted to a digital code, which is fed to the input 21 of the microprocessor 19. The microprocessor 19 calculates the required delay of the masking pulses with respect to the time of arrival of the radar-sensing signals of the leading edge of the radar probe complex using the received repetition period and duration codes. and the duration of the masking pulse according to the formulas
T _ass = T _rep - (g ₁ + g ₂ + g ₃ ) / s + T _op , (1)
where r ₁ , g ₂ , g ₃ are the distances between the protected radar and the preselector 3, between the preselector 3 and the remote passive radiation source 13, between the remote passive radiation source 13 and the protected radar, respectively;
T _op - pre-selected and recorded in the memory of the microprocessor 19 value of the lead time;
c is the speed of light
τ ₁ = 2r ₃ / c + T _op + τ ₂ (2)
where τ ₁ is the duration of the masking pulse;
τ ₂ - the pulse duration of the signal of the protected radar.

The microprocessor 19 generates the video control pulses of the microwave keys 31 and 32. To control the microwave key 31 used to generate the masking pulse, the delay time of the leading edge of the control video pulse (the opening time of the microwave key 31) relative to the time of arrival of the leading edge of the pulse is set to T _ass , and the duration of the video control pulse is equal to τ ₁ .
To control the microwave key 32, used to form a simulating pulse, the delay time of the leading edge of the control video pulse (the moment the microwave key 32 is opened) relative to the time of arrival of the leading edge of the pulse is set to a value previously set and recorded in the microprocessor 19, and the duration is equal to τ ₂ .
The signals from the output of the microwave keys 31 and 32 are fed to the inputs of the adder 33, the output signal of which, which is an additive mixture of masking and imitating pulses, is amplified by the microwave amplifier 11 and radiated through the transmitting antenna 12 in the direction of the remote passive radiation source 13.

 Remote passive radiation source 13 is a metal armored hemisphere. The radiation pattern of the secondary radiation of the hemisphere is also a hemisphere. The coordination of the linear dimensions of the source 13 and the main lobe of the radiation pattern of the transmitting antenna 12 minimizes the loss of signal power due to re-emission. According to experimental data, the loss does not exceed 3-5 dB.

 Thus, a masking and imitating pulse with a power equal to the transmitter power, reduced by a loss factor (3 - 5) dB, is re-emitted into space.

Claims (4)

 1. A method of protecting a radar station from an anti-radar missile, which provides for receiving radiation from the probing signals of the protected radar station and emitting imitating pulses at the frequency of the probing signals from the protected radar station, characterized in that they use an external passive radiation source, transmitting its parameter codes generated in the protected radar station sounding signals with their subsequent reception, the formation of masking pulses, the backside Arms of which relative to the received sounding signals are defined as the repetition period of the sounding signals, reduced by the sum of the lead time and the time spent by the sounding signals on traveling at a speed of light of known distances from the protected radar station to the place of reception and emission of masking and imitating pulses, from the place of reception and radiation masking and simulating pulses to a remote passive radiation source and from a remote passive radiation source to a protected the radar station, the formation of the duration of the masking pulses relative to the received sounding signal, equal to the sum of the lead time, the duration of the sounding signal and the doubled time spent by the signal on passing a known distance from the protected radar station to the remote passive radiation source, amplification of masking and simulating pulses and their radiation towards a remote passive radiation source and re-radiation of masking and imitating imp lsov rendered passive source of radiation in a given solid angle space.  2. A system for protecting a radar station from an anti-radar missile, comprising a receiving antenna, a microwave amplifier and a transmitting antenna, characterized in that it further comprises a preselector connected to the receiving antenna, a remote passive radiation source, a channel for transmitting the parameters codes of the probing signals of the radar station, connected with a protected radar station, a modulating signal generating device, one of the inputs of which is connected to the output of the probing parameters transmission channel x signals of the radar station, and its other input is to the output of the preselector, a carrier frequency forming device connected by its input to the output of the preselector, a modulator, one group of inputs of which is connected to the outputs of the carrier frequency forming device, and another group of its inputs to the outputs of the forming device modulating signals. wherein the output of the modulator is connected to the input of a microwave amplifier connected to a transmitting antenna oriented by the maximum radiation pattern to a remote passive radiation source, remote from the protected radar station and the transmitting antenna by a distance exceeding the radius of destruction of the warhead of the anti-radar missile, and the angular size of the passive the radiation source from the location of the transmitting antenna is equal to the angular size of the main lobe of the radiation pattern of the transmitting antenna.  3. The system according to claim 2, characterized in that the channel for transmitting the parameter codes of the probing signals of the radar station comprises a transmitter of codes for the parameters of the probing signals of the radar station, a communication line and a receiver for the parameter codes of the probing signals of the radar station, the device for generating modulating signals contains a series-differentiating circuit, analog-to-digital converter and microprocessor, while one of the inputs of the forming device is modulating their signal is the input of the differentiating circuit, which is connected to the output of the preselector, and its other input is one of the inputs of the microprocessor, connected to the output of the receiver of the codes of the parameters of the probing signals of the radar station, the device for generating carrier frequencies contains a frequency detector, an analog-to-digital converter, a microprocessor and two controlled by the generator, while one input of the frequency detector, which is the input of the carrier frequency forming device, is connected to the output of the preselector, the output is hour of the detector through an analog-to-digital converter is connected to a microprocessor, the control outputs of which are connected respectively to the control inputs of the controlled generators, while the output of one controlled generator is connected to the other input of the frequency detector, and the outputs of the controlled generators are outputs of the carrier frequency generating device, in addition, the modulator contains two microwave keys and an adder, and one of the inputs of the microwave keys are connected respectively to the outputs of the controlled generators, the control inputs RF-keys are connected to the outputs of the microprocessor forming apparatus, modulating signals, and the outputs of microwave-keys are combined by the adder, whose output is the output of the modulator.  4. The system according to p. 3, characterized in that the remote passive radiation source is a conductive hemisphere, the thickness and material of which are selected from the condition that its high-explosive and fragmentation components will not be damaged when the warhead of an anti-radar missile explodes.

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