RU126147U1 - INTERFERENCE STATION PROTECTED FROM ANTI-RADAR ROCKETS - Google Patents

Abstract

1. The jamming station with anti-radar protection, containing a series-connected receiving antenna, a reconnaissance receiver and a frequency storage circuit, a series-connected noise generator, a first switch, a modulator and a power amplifier, as well as a control circuit, the first output of which is connected to the second input of the first switch, and the second - with the second input of the power amplifier, a microwave generator, the output of which is connected to the second input of the modulator, and a transmitting antenna, characterized in that, in order to increase the efficiency to protect the jamming station from weapons homing to the radio emission, an additional receiving antenna, a receiving and direction finding device, a multi-channel switch and a panoramic receiver are connected in series; connected to the output of the frequency storage circuit, the second in the code of the amplitudes of the signals generated in the channels of the receiving-direction-finding device, with (n + 1) output at a multi-direction finding device, and the third in the code of the frequency difference between the carrier frequency of the interference and the frequency of the local oscillator signal of the homing of the PRR homing device with the output of the panoramic receiver, and the first digital-to-analog converter, the output of which is connected to the input of the microwave generator, the output of which is also connected to ) the input of the receiving-direction finding device and the second input of the panoramic receiver, a second digital-to-analog converter, the input of which is connected to the third output of the counting-resolving device according to the code for prohibiting radiation from interference,

Description

The utility model relates to radio countermeasures, specifically to jamming stations with protection against anti-radar missiles.

Known jamming stations / 1 ÷ 17 / with protection against anti-radar missiles, containing a series-connected receiver of signals of the airborne radar station (radar) means of aerospace attack (SIC), a meter of received signal parameters and an interference generator.

A disadvantage of the known stations is the relatively low efficiency of protecting the defended objects and the jamming station itself from being hit by missiles homing on the radar’s radio emission.

Of the known jamming stations, the closest to technical implementation, the prototype of the utility model, is a jamming station / 16 / with anti-radar missile protection (RPR), containing a series-connected receiving antenna, a reconnaissance receiver and a frequency storage circuit, series-connected noise generator, a first switch, a modulator and a power amplifier, as well as a control circuit, the first output of which is connected to the second input of the first switch, and the second to the second input of the power amplifier, a microwave generator, the output of which go connected to the second input of the modulator, and the transmitting antenna.

Known prototype station works as follows. The signals of the suppressed airborne radar, received by the receiving antenna (PrA), are amplified in the reconnaissance receiver (RP) and fed to the frequency memory circuit (SZCH). The SZCH controls the block of adjustment of the interference transmitter, with the help of which the microwave generator is tuned to the radar frequency. The monochromatic signal from the output of the microwave generator is fed to the heterodyne input of the Doppler receiver (DP) and to the input of the modulator, where it is modulated periodically by noise fed to the input of the modulator. From the output of the modulator, alternating interference and carrier are fed to the input of the power amplifier (PA). After amplification, the signal enters the transmitter antenna of the transmitting antenna (PerA) and is emitted in the direction of the target. Periodic noise from the output of the noise generator (GS) to the control input of the modulator is carried out by switching the microwave switch with a control signal coming from the output of the control circuit (CS). When a missile is launched by a carrier of a suppressed radar, a continuous signal of an interference station reflected from the missile begins to arrive at the missile launcher. After processing this signal in the DP from its output, the signal enters the control system, where it is converted into a signal to prohibit interference radiation. This signal from the output of the control system is fed to the control input of the PA, which is closed for the time of the prohibition of radiation. At the end of the prohibition signal, the operation of the jamming station (SP) resumes.

Thus, the jamming station allows you to detect objects approaching it with high radial velocities only within its main lobe of the antenna pattern (BOTTOM), and, as a result, to protect against them by stopping the emission of interference.

However, the enemy, planning the use of PRR on radioelectronic means (RES) of air defense (including SP), first of all, counts on the guidance of PRR on the side radiation of SP and RES / 14 /.

Under these conditions, the main disadvantage of the prototype is the relatively low reliability of the protection of the RES it defends against the PRR induced by the side radiation of the SP.

The objective of the utility model is to increase the reliability of protection of defense against homing weapons, including PRR.

The technical result that provides the solution to this problem is to increase the reliability of protection of the jamming station itself from homing weapons in the spatial sector of possible angles of attack.

The achievement of the claimed technical result and, as a result, the solution of the problem is achieved by the fact that the interference station with protection against anti-radar missiles, containing a series-connected receiving antenna, a reconnaissance receiver and a frequency storage circuit, series-connected noise generator, a first switch, a modulator and a power amplifier, as well a control circuit, the first output of which is connected to the second input of the first switch, and the second to the second input of the power amplifier, a microwave generator, the output of which connected to the second input of the modulator, and the transmitting antenna, according to the utility model, an additional receiving antenna, a receiving and direction finding device, a multi-channel switch and a panoramic receiver, series-connected computing device, the first input of which is connected to the output of the frequency storage circuit, are introduced in series, the second - with (n + 1) the output of the receiving-direction finding device, and the third with the output of the panoramic receiver, and the first digital-to-analog converter, the output of which is connected to the input a microwave generator house, the output of which is also connected to the (n + 1) input of the receiving-direction-finding device and the second input of the panoramic receiver, a second digital-to-analog converter, the input of which is connected to the third output of the computing-deciding device, and the output - with the input of the control circuit, the second switch, the output of which is connected to the transmitting antenna, the first input is connected to the output of the power amplifier, and the second input is connected to the first output of the control circuit, as well as the inverter, the third switch and the additional transmit a main antenna, the input of the inverter being connected to the first output of the control circuit, and the second input of the third switch connected to the output of the power amplifier.

In this case, the receiving-and-bearing device contains n receiving channels, each of which consists of a series-connected high-frequency amplifier, a directional coupler, a first mixer, an intermediate-frequency amplifier, a detector, and an analog-to-digital converter, as well as a chain of series-connected reference frequency generators, the second a mixer and a band-pass filter, the output of which is connected to the second inputs of all the first mixers, the second outputs of all directional couplers with the corresponding n input and multi-channel switch, the second input of the second mixer is connected to the output of the microwave generator, and the outputs of all the analog-to-digital converters are connected to the second input of the computing device.

The above set of distinctive features is new, because the well-known literature on the detection of PRR attacks and protection against REP means from them is not given. At the same time, the achieved positive result is an increase in the reliability of protection of the jamming station against PRR and, as a result, an increase in the reliability of protection of objects protected by it is automatically ensured.

Figure 1 shows the structural diagram of the inventive jamming station with protection against PRR, figure 2 is a structural diagram of a receiving-direction finding device.

Figure 3 shows illustrations explaining the sequence of operations for determining frequency resolution elements in which the presence of a local oscillator signal of the homing head (GOS) is predicted.

Figure 4 shows the operational characteristics of an active-passive detector.

The inventive jamming station with protection against PRR (Fig. 1) contains a series-connected receiving antenna (PrA) 1, a reconnaissance receiver (RP) 2, a frequency memory circuit (SZCH) 3, a digital computing device (SRS) 4, a first digital-to-analog converter (DAC) 5 and the microwave generator 6, as well as a series-connected noise generator (GS) 7, the first switch 8, the modulator 9, the power amplifier (PA) 10, the second switch 11 and the transmitting antenna (PerA) 12. To the second input of the first switch 8 the first output of the control circuit (SU) 13 is connected, which is also connected to watts the second input of the second switch 11 and to the input of the circuit, consisting of a series-connected inverter 14, the third switch 15 and an additional transmitting antenna (DPerA) 16. The second output 13 is connected to the second input of the MIND 1O, the output of which is also connected to the second input of the third switch 15. The station also includes a series-connected multi-beam additional receiving antenna (DPrA) 17, a receiving-bearing device (PPU) 18, a multi-channel switch (MK) 19 and a panoramic receiver (PPP) 20, the output of which is connected to a third the input of the switchgear 4, the second output of which is connected to the (n + 1) input of the MK 19, and the third one is connected to the input of the second DAC 21, the output of which is connected to the input 13. (n + 1) the digital output of the control panel 18 is connected to the second input of the switchgear 4 , and (n + 1) input - with the output of the microwave generator 6, which is also connected to the second input of the modulator 9 and the second SPR 20.

The receiving and bearing device 18 (FIG. 2) contains n receiving channels, each of which consists of a series-connected high-frequency amplifier (UHF) 22, a directional coupler (BUT) 23, a first mixer 24, an intermediate frequency amplifier (UPCH) 25, and a detector 26 and ADC 27. The outputs of all ADCs are connected to the second input of the switchgear 4. The second outputs of all HO 23 are connected to the corresponding n inputs of MK19. PPU 18 also contains a series-connected reference frequency generator (RFC) 28, a second mixer 29, to the second input of which the output of the microwave generator 6 is connected, and a band-pass filter (PF) 30, the output of which is connected to the second inputs of all the first mixers 24.

In addition, in the proposed jamming station with protection against PRR, along with active (radar), passive detection of PRR is carried out by means of reconnaissance of spurious radiation of the GSN local oscillator and analysis of its response to the tuning of the interference frequency. Improving the energy conditions of detection in the passive channel also reduces the search time of the local oscillator signal to a value not exceeding the intervals (pauses) in the interference for additional reconnaissance of the signals of the suppressed radar. Joint active-passive detection of PRR attacks allows one to ensure a high probability of detecting PRRs in the range of possible angles of attack, which is much wider than the main lobe of the DN of the SP, and recognizing PRRs among a wide class of aids to navigation, thereby increasing the effectiveness of protection.

The jamming station with protection against PRR can be implemented on a modern element base.

In particular, the panoramic receiver 20 can be implemented as a signal compression receiver that implements a cyclic frequency search algorithm, wherein the addition of the search range is determined by the carrier frequency of the interference. The multi-channel switch 19 may be implemented as a multiplexer or code-controlled switch, i.e. decoder with combined outputs. Microwave switches 11 and 15 can be implemented as switches on p-i-n diodes, which are able to withstand values of incoming power up to several kilowatts at a frequency of ~ 10 GHz. The first 5 and second DAC 21 can be implemented on the basis of the known microchips converters binary parallel digital code into direct current (voltage).

Consider the operation of the claimed jamming station with protection against PRR, carrying out REP of one airborne radar, in a situation when the SP launched the PRR, guided by the near side lobes of the bottom of the bottom of the SP.

The airborne radar signals received by PrA1 are amplified in RP2 and fed to the input of the SZCH 3, which essentially represents a system for determining the carrier frequency of radar signals (for example, a matrix receiver). The carrier frequency code of the onboard radar signal is fed to the first input of the switchgear 4, and if there is no information on the second input of the switchgear 4, it goes to the input of the first DAC 5 without changes. The DAC 5 converts the frequency code into the control voltage of the microwave generator 6, which starts to generate the carrier frequency interference. The noise voltage from the output of the power supply 7 through the open first switch 8 is fed to the first (control) input of the modulator 9, where the amplitude modulation of the carrier frequency of the noise is applied to the second input of the modulator 9 from the output of the microwave generator 6. The generated noise is amplified in the amplifier 10 and through the open the second switch 11 is emitted by the transmitting antenna 12 in the direction of the target. The temporary structure of the interference is formed by the control unit 13. A pulse of positive polarity from the first output of the control unit 13, opening the first switch 8 and the second switch 11 is inverted by the inverter 14 and closes the third switch 15 for the duration of the interference emission. At the end of the pulse of positive polarity, when the first 8 and second 11 switches are closed, the unmodulated carrier frequency of interference ƒ ₀ from the microwave generator 6 through the modulator 9 and the PM 10 through the open third switch 15 is emitted additional PerA 16, covering the region of the near side lobes of the radiation pattern of the joint venture, in the direction of the possible angles of attack of the PRR.

Thus, alternating interference and carrier are emitted respectively through PerA 12 and additional PerA 16.

(фиг 3а, в)When the enemy launches PRR in the spatial sector of possible angles of attack, additional PRA 17 begins to receive the signal of the carrier frequency of interference ƒ _n0 reflected from the PRR with a Doppler shift due to the range of possible radial velocities of the PRR. PPU 18 selects a shift ΔΩ _∂ in the channels and generates codes of signal amplitudes in the channels that are fed to the second input of the switchgear 4. In the switchgear 4, the amplitude codes are compared and the channel is determined in which the reflected signal with the Doppler shift lying within ΔΩ _∂ is maximum . The K-bit code of the channel number with the maximum signal amplitude from the second output of the switchgear 4 is supplied to the controlled (n + 1) input MK 19, which connects the channel of the control panel 18 with the maximum signal amplitude to the first input of the control channel 20. The control channel 20 sequentially searches for the local oscillator signal in frequency band from ƒ ₁ to

(fig 3a, c)

,

,

where ƒ _П0 is the carrier frequency of the interference;

Δƒ _Ï is the width of the interference spectrum;

- максимальное значение промежуточной частоты приемника ГСН.

- the maximum value of the intermediate frequency of the GPS receiver.

(фиг З.е.), который поступает на третий вход СРУ 4. СРУ 4 вырабатывает код несущей частоты помехи со сдвигом Δƒ_П0, превышающим разрешающую способность приемника ГСН по частоте. В результате СП с защитой от ПРР излучает помеху с некоторым частотным сдвигом Δƒ_П0. В следующем цикле разведки сигналов вновь осуществляется обнаружение сигнала и радиоизлучений в пространственном секторе углов атаки ПРР. Если на входе ППР 20 зафиксирован сигнал с частотой

, где

(фиг.3з.), (что свидетельствует о том, что принятый сигнал есть сигнал гетеродина приемника ГСН ПРР, т.к. ГСН осуществляет слежение за несущей частотой помехи), то принимается решение о факте атаки станции помех ПРР. СРУ 4 вырабатывает код запрета излучения, который через второй ЦАП 21 поступает на вход СУ 13, и излучение помехи прекращается на заданное время t, предшествующее падению ПРР.If any signal is detected in the frequency band Δƒ, the SPD 20 automatically generates a code of the frequency difference

(FIG ZE), which is supplied to the third input CPT CPT 4. 4 generates code interference carrier frequency shift Δƒ _P0 exceeding resolving seeker receiver bandwidths. As a result, JV-protected RLP radiates interference with a certain frequency shift Δƒ _P0. In the next signal reconnaissance cycle, the signal and radio emissions are again detected in the spatial sector of the angles of attack of the PRR. If a signal with a frequency

where

(fig.3z.), (which indicates that the received signal is the local oscillator signal of the receiver of the PRR seeker, since the seeker monitors the carrier frequency of the interference), then a decision is made on the fact of the attack of the PRR jamming station. The switchgear 4 generates a radiation prohibition code, which through the second DAC 21 enters the input of the control system 13, and the interference radiation stops for a given time t, preceding the fall of the PRR.

PPU 18 (figure 2) works as follows. Reflected from RLP carrier signal frequency ƒ _P0 enters the interference DEXA 17, amplified in the UHF channel 22 and to the input ND 23. 2 H0 output portion 23 receives the high frequency signal energy to a corresponding input MK19, for passage into the system frequency determination. From the output 1 H0 23, a high-frequency signal with a Doppler shift Ω _∂ , due to the possible range of radial velocities of the PRP, is supplied to the first input of the first mixer 24. Using the frequency converter 28, the second mixer 29, the bandpass filter 30, and the first mixer 24 by double converting the frequency of the received signal the frequency Ω _∂ is transferred to the band of the IFA 25. The bandwidth of the IFA 25 is selected taking into account the a priori value of the range ΔΩ _∂ . Thus, the amplifier 25 transmits and amplifies only those signals that have a frequency shift lying within the range ΔΩ _∂ . All other signals will not pass to the inputs of the detectors 26 due to the limitation by the band of the amplifier 25. The detected signals are fed to the inputs of the ADC 27, where they are compared with the detection threshold and, if it is exceeded, their amplitudes are converted to codes received at the second input of the switchgear 4.

To assess the effectiveness of the claimed jamming station with protection against PRR, we use the most common indicator characterizing the effectiveness of protection - the effectiveness of the jamming station in the conditions of application of it PRR / 1 /

,

,

where E ₁ - the effectiveness of the suppression of the RES station interference;

K _s <1 is a coefficient characterizing a decrease in the effectiveness of suppression when using the protection method (for the case of applying the protection method based on turning off the SP for a while upon detection of an ATO attack, put = 0.9);

- вероятность поражения СП n снарядами,

- the probability of hitting SP n shells,

Obviously, when using a protection method based on turning off a joint venture when establishing the fact of an attack, the effectiveness of E _Pz will depend on the "frequency" of turning off the joint venture, which in turn is determined by the probability of the correct shutdown of P _Pv (only when attacked by a missile with PRGSN), t .e. can write

Moreover, the efficiency E _poises will depend on the probability P vstrelivaniya _Br PRR in the space domain due to lateral radiation SP and substantially defining a sector of possible angles of attack.

Hence

обнаружения ПРР на заданной дальности.As shown above, the probability of an attack by a SP rocket with a PRGSN does not exceed P _a ≤0.44, which will determine the probability P _Pv for the prototype station along with the probability

detection of PRR at a given range.

For the claimed joint venture, the probability P _Pv (in fact recognition of missiles with PRGSN from other means of attack) will be determined by the final probability P _{0 of the} correct end of the search.

отличия в значениях вероятностей правильного и неправильного выключения зависят лишь от априорного распределения вероятностей применения этих ракет по СП. Вероятность правильного выключения Р_Пв для прототипа будет определяться какGiven that in the prototype station no additional features distinguishing a missile with PRGSN from other means of attack are used, then at the same values

the differences in the probabilities of correct and incorrect shutdown depend only on the a priori distribution of the probabilities of using these missiles in the joint venture. The probability of correct shutdown P _Pv for the prototype will be determined as

- вероятность обнаружения ПРР, при условии, что она находится в зоне обнаружения.Where

- the probability of detecting PRR, provided that it is in the detection zone.

/16/. В результате получаем Р_Пв=0,44*0.9=0.4.Since the distance to the PRR in the prototype station is not measured, the detection of PRR in it is searchless, i.e. implemented in one permission element. Let the admissible probability of false detection be given F≤10 ^-2 , which corresponds to the normalized detection threshold U _P = 3. With a distinguishability coefficient (signal-to-noise ratio) of ~ 7 dB, the probability of correct detection by the prototype is

/16/. As a result, we obtain P _Pv = 0.44 * 0.9 = 0.4.

для станции-прототипа даже до величины близкой к единице, не позволит существенно увеличить вероятность Р_Пв, т.к. она, в основном, определяется вероятностью Р_а.The latter indicates that an increase in probability

for the prototype station, even to a value close to unity, it will not significantly increase the probability P _Pv , because it is mainly determined by the probability P _a .

For the claimed SP with protection against PRR, the detection of an PRR attack is carried out in three stages.

At the first stage, active radar detection of the attacking missile and processing of the reflected signal in the Doppler receiver were organized. We set the initial data in order to estimate the width of the directivity pattern of a single PrA ray in the azimuthal and elevation planes. Suppose detection RLP carried on D = 10 km, the EPR target G _q = 0.05 m ^2, the noise factor K _w = 5, the distinguishability coefficient ν = 5 condition detection normal (T = 290 K), the width of the Doppler receiver bandwidth ΔΩ _∂ = 18 kHz. Suppose that the spatial sector of possible angles of attack of the PRR is 55 ° in the azimuthal plane and 6 ° in the elevation plane, and the transmitter power SP R _P = 2 kW. Then the energy potential of the SP R _P · G _P is 1.51 · 10 ⁵ W, and the real sensitivity of the Doppler receiver P _Prmin is in the range 1.8 · 10 ^-15 W. Based on this, the beam width of one partial beam of the DPAA 17 in the azimuthal plane should be 2.3 °, and in the elevation plane 2 °.

The second step in detecting a PRR attack is the passive detection of spurious radiation from the local oscillator of the homing head in a panoramic receiver.

и шириной спектра помехи Δƒ_П, то в первую очередь необходимо обосновать возможные количественные значения величин ΔF_Пр и Δƒ_П.Let us estimate the magnitude of the search zone of the GOS local oscillator signal. The search area can be justified for the following reasons. Since the position of the range ƒ ₁ ... ƒ ₂ (Fig.Z) on the frequency axis is determined by the carrier frequency of the interference ƒ _ON and the average value of the range of possible intermediate frequencies of the PRGSN receiver, and its dimensions - by the range of possible values of the intermediate frequency

and the width of the interference spectrum Δƒ _P , it is first necessary to justify the possible quantitative values of the quantities ΔF _Pr and Δƒ _P.

(для см- диапазона длин волн). Значение ширины спектра помехи, определяемое шириной полосы пропускания приемного устройства подавляемого РЭС, будем полагать равным Δƒ_П=5…6 МГц (при создании прицельных по частоте помех). С учетом того, что частота при преобразовании в приемнике ПРГСН может быть как повышена, так и понижена, диапазон поиска сигнала гетеродина ГСН для рассматриваемого примера должен составлять ΔF=72 МГц (Фиг.3д).It is known that with increasing values of the intermediate frequency ƒ _Pr there is an increase in the noise figure of the receiver K _w which leads to a decrease in its sensitivity. In PRGSN receivers, very strict requirements are imposed on K- _sh , which is due to the need to ensure high threshold sensitivity (-120 ... -130 dB / W). Since PRGSN receivers are usually made without input preselectors and amplifiers, the first stage is, as a rule, a frequency converter. The minimum value of K _W = 10.7 ... 11.2 for such receivers is achieved at ƒ _Ïp = 10 ... 40 MHz. Therefore, we will assume

(for cm - wavelength range). The value of the width of the interference spectrum, determined by the bandwidth of the receiver of the suppressed RES, will be assumed equal to Δƒ _П = 5 ... 6 MHz (when creating interference-frequency interference). Given that the frequency during conversion in the PRGSN receiver can be either increased or decreased, the search range of the GOS local oscillator signal for the considered example should be ΔF = 72 MHz (Fig. 3d).

The third step in detecting a PRR attack (missiles specifically from PRGSN) is to check the presence of a local oscillator signal by tuning the frequency of the interference and analyzing the response of the GOS local oscillator to this tuning.

. Используя подход /17/ для данных показателей получены аналитические выражения, которые из-за их громоздкости в материалах заявки не приводятся.Given that in the inventive jamming station with protection against PRR, the detection of signs inherent only to shells with PRGSN, then P _Pv □ P ₀ . It is customary to evaluate the quality of a three-stage active-passive PRR attack detector by the final search probability p ₀ and the average time until the search ends correctly

. Using the approach / 17 / for these indicators, analytical expressions are obtained, which, due to their bulkiness, are not given in the application materials.

Figure 4 presents the performance characteristics of a three-stage detector obtained in accordance with these expressions. The graphs are plotted for the case when P ₀ ≥0.9, The number of active channels is 75, passive is 720, the bandwidth of one passive channel resolution element is 100 kHz.

от отношения сигнал/шум q на первом этапе обнаружения, при постоянных значениях q на втором и третьем этапе.On figa presents dependencies

from the signal-to-noise ratio q in the first stage of detection, with constant values of q in the second and third stage.

The analysis of the dependences shows that with the correct choice of parameters (Fig. 4b-d) of the detector (detection thresholds s ₁ , s ₂ , s ₃ , the number of accumulated pulses z ₁ at the first detection stage and correlation elements of the local oscillator signal at the second and third detection stages, respectively ) there is a real possibility of detecting a PRR attack in a time commensurate with the reconnaissance interval at the beginning of each CP suppression cycle with protection against PRR. As can be seen from figa, when the received source data, the average search time is 42 ms. As noted above, for the inventive station p ₀ = p _Pv , and therefore, p _Pv ≥0.9.

Suppose the appearance of an attacking PRR at any point in space is equally probable. Then, given that for the claimed station with protection against RRP, the spatial sector of simultaneous operation (search of RRP) of the RPA 17 is: in the azimuthal plane of 55 °, in the elevation plane - 6 °, and for the prototype station, respectively, 5 ° and 5 °, we obtain vstrelivaniya probability p _Br THC claimed to venture about 13 times more than for the prototype plant.

Based on the above calculations, as a result, we obtain that the protection efficiency for the prototype station is

для n=1

for n = 1

When using the inventive joint venture

для n=1.

for n = 1.

Thus, the gain in the effectiveness of protection of the claimed station interference from homing weapons on radio emission, compared with the prototype station, by increasing the likelihood of the correct shutdown p _Pv , is 2.2 times.

Given the likelihood of firing, this gain is approximately 30 times. Correspondingly, the effectiveness of the defense of the objects it defends also increases.

This utility model has been developed at the level of technical proposal and mathematical modeling of the defense process of radar positions from air defense missile systems.

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17. Volzhin A.N., Sizov Yu.G. Fight against homing missiles. M., Military Publishing, 1983.

Claims (2)

1. The jamming station with anti-radar protection, containing a series-connected receiving antenna, a reconnaissance receiver and a frequency storage circuit, a series-connected noise generator, a first switch, a modulator and a power amplifier, as well as a control circuit, the first output of which is connected to the second input of the first switch, and the second - with the second input of the power amplifier, a microwave generator, the output of which is connected to the second input of the modulator, and a transmitting antenna, characterized in that, in order to increase the efficiency to protect the jamming station from weapons homing to the radio emission, an additional receiving antenna, a receiving and direction finding device, a multi-channel switch and a panoramic receiver are connected in series; connected to the output of the frequency storage circuit, the second in the code of the amplitudes of the signals generated in the channels of the receiving-direction-finding device, with (n + 1) output at a multi-direction finding device, and the third in the code of the frequency difference between the carrier frequency of the interference and the frequency of the local oscillator signal of the homing of the PRR homing device with the output of the panoramic receiver, and the first digital-to-analog converter, the output of which is connected to the input of the microwave generator, the output of which is also connected to ) the input of the receiving-direction finding device and the second input of the panoramic receiver, a second digital-to-analog converter, the input of which is connected to the third output of the counting-resolving device according to the code for prohibiting radiation from interference, the second output of which, according to the channel number code of the receiving and direction finding device with the maximum signal amplitude, is connected to the (n + 1) input of the multi-channel switch, and the output of the second digital-to-analog converter is connected to the input of the control circuit, the first input is connected to the output of the power amplifier, and the second input to the first output of the control circuit, as well as a series-connected inverter, a third switch and an additional transmitting antenna, the input of the inverter being connected to the first output of the control circuit, and the second input being third its switch is connected to the output of a power amplifier. 2. The jamming station with protection against PRR according to claim 1, characterized in that the receiving-direction-finding device contains p receiving channels, each of which consists of a series-connected high-frequency amplifier, a directional coupler, a first mixer, an intermediate-frequency amplifier, a detector and analog -digital converter, as well as a chain of series-connected reference frequency generator, a second mixer and a bandpass filter, the output of which is connected to the second inputs of all first mixers, and the second outputs to all directional couplers with the corresponding n inputs of the multi-channel switch, the second input of the second mixer is connected to the output of the microwave generator, and the outputs of all analog-to-digital converters are connected to the second input of the calculating device.

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