RU145014U1 - DEVICE FOR PROTECTION OF A RADAR STATION FROM DAMAGE TO SELF-GUIDED WEAPON RADIATION - Google Patents

Abstract

A device for protecting a radar station from being hit by radiation-homing weapons, comprising a receiving device, the first input of which is connected to the first output of the master oscillator, the second to the first output of the synchronizer, and the third to the output of the transmitting and receiving antenna of the radar station, serially connected by the second output of the master a generator, the second output of the synchronizer, the first output of which is connected to the first input of the power amplifier, and the third to the third input of the first additional power amplifier and with the first input of the second additional power amplifier, the first output of the pulse modulator, the second output of which is connected to the input of the first shaper of the pulse pulses and to the input of the second delay line, the first delay line, the power amplifier and the transmitting and receiving antenna device of the radar station, and connected in series with the first shaper of the false pulses, the first additional power amplifier, the first additional antenna device, characterized in that a second frequency multiplier, the input of which is connected to the output of the master oscillator, and a switch connected by the first input to the output of the first frequency multiplier, the second input to the output of the second frequency multiplier, the third input to the second output of the pulse modulator, and the fourth input to the output of the second line delays, and the first output of the switch is connected to the input of the second shaper of false pulses, and the second output is connected to the third input of the second additional power amplifier.

Description

The proposed utility model relates to the field of radar and can be used in specialized multifunctional radar stations for reconnaissance of air targets and weapon control, namely to protect the radar from being hit by radiation-homing weapons.

Known protective measures for specialized radar stations (radars) from hitting radiation-homing weapons * based on the use of methods to reduce information about the emitting object and shift the pointing point. However, the implementation of these methods of protection causes a contradiction between the need for continuous operation of the radar for radiation in conditions of high intensity of hostilities and at the same time minimizing the working time of the radar in order to protect against reconnaissance and destruction of radiation-homing weapons. This is a significant drawback of the above protection methods.

The closest technical solution to the proposed utility model is a radar having the functions of active electronic protection against the effects of reconnaissance and strike systems through the use of built-in additional radiation channels that provide spatio-temporal decorrelation of their background radiation in the region of the side lobes [1, 2]. This device by spatio-temporal decorrelation of the background radar radiation in the region of the side lobes creates systematic errors in determining the coordinates of the emitting means by the radio reconnaissance and reconnaissance systems. The block diagram of this device is shown in FIG. one.

A known device - a radar with the function of electronic protection from reconnaissance and strike systems contains a receiving device 1, a master oscillator 2, a synchronizer 3, a pulse modulator 4, a first delay line 5, a power amplifier 6, a transmitting and receiving antenna device radar 7, a frequency multiplier 8, the first shaper of false pulses 9, the first additional power amplifier 10, the first additional antenna device 11, the second delay line 12, the second shaper of false pulses 13, the second additional power amplifier 14, Thoroe additional antenna device 15.

Elements of the known device of electronic defense of the radar from reconnaissance and strike systems are connected as follows.

The first output of the master oscillator 2 is connected to the first input of the receiving device 1. The second output of the master oscillator 2 is connected to the input of the synchronizer 3. The third output of the master oscillator 2 is connected to the input of the frequency multiplier 8, the output of which is the third input of the power amplifier 6, the first input of the first additional power amplifier 10 and the second input of the second additional power amplifier 14. The first output of the synchronizer 3 is connected to the second input of the receiving device 1 and the first input of the power amplifier 6. The third output synchronizer 3 is connected to the third input of the first additional power amplifier 10 and to the first input of the second additional power amplifier 14. The second output of the synchronizer 3 is connected to the input of the pulse modulator 4. The first output of the pulse modulator 4 is connected to the input of the first delay line 5, the output of which is connected to the second the input of the power amplifier 6. The output of the power amplifier 6 is connected to the input of the transceiver antenna device 7, the output of which is connected to the third input of the receiving device 1. The second output of the pulses a different modulator 4 is connected to the input of the first shaper of false pulses 9 and to the input of the second delay line 12, the output of which is connected to the input of the second shaper of pulses 13. The output of the first shaper of false pulses 9 is connected to the second input of the first additional power amplifier 10, the output of which is the input of the first additional antenna device 11. The output of the second shaper of false pulses 13 is connected to the third input of the second additional power amplifier 14, the output of which is connected to the input second additional antenna device 15.

The operation of the radar with the function of active electronic defense against reconnaissance and strike systems is as follows.

The receiving device 1, the master oscillator 2, the synchronizer 3, the pulse modulator 4, the power amplifier, the transceiver 7 and the frequency multiplier 8 are the main path of the radar. The first shaper of false pulses 9, the first additional power amplifier 10 and the first additional antenna device 11 represent the first auxiliary (additional) antenna path of the radar. The second delay line 12, the second shaper of false pulses 13, the second additional power amplifier 14 and the second additional antenna device 15 represent the second auxiliary antenna path of the radar. The master oscillator 2 is the primary source of high-frequency oscillations and provides high stability of the oscillation frequency. In the frequency multiplier 8, the oscillation frequency rises to the desired operating value. The operation of the transmitter devices is synchronized in time by the synchronizer 3. From the synchronizer 3 to the radio transmitting device, a transmitter start pulse (IPS) is supplied. Under the influence of the ISP, the modulator 4 generates a modulating pulse, during which the power amplifier 6 amplifies the microwave oscillations coming from the frequency multiplier 8 to the desired operating value. This modulating pulse is delayed in the first delay line 5 for a time τ _lz1 . High-frequency modulated oscillations are transmitted to the transceiver antenna device 7 and radiated into space. The modulating pulses of the modulator 4 are fed to the input of the first shaper of false pulses 9 and through the second delay line 12, with a delay of a time of τ _ls2 , to the input of the second shaper of false pulses 13, and in this case are the triggering pulses of the shapers of false pulses 9 and 13. Formed false pulses control the operation of the first additional power amplifier 10 and the second additional power amplifier 14 which during these pulses amplify microwave oscillations coming from the frequency multiplier 8 to the desired working value. These oscillations are transmitted through space through additional antenna devices 11 and 13. The first and second auxiliary antenna paths form additional (false) signals identical to the main radar signal. The identity of the structure of the main and additional signals is achieved by using, when generating additional signals, the signal of the main path of the radar. The first delay line 5 in the main path of the radar provides advanced radiation of additional signals relative to the main one, which is necessary to provide them with false information about the location of the radar. In this case, the delay time in the delay line is 5 τ _lz1 = const. The second delay line 12 (τ _lz2 can be both controlled and constant) provides additional time difference signals emitted by the first additional antenna device 11 and the second auxiliary antenna device 15. The maximum delay time τ _lz2 not exceed wherein _lz1 τ (τ _lz2 <τ _lz1 ). Their specific values are chosen so as to ensure constant overlap of the main and additional signals, taking into account their duration (τ _and , τ _d ). The gain of the first additional power amplifier 10 and the second additional power amplifier 14 is selected so as to mask the main signal emitted from the side lobes. The power level of the additional signals should be commensurate with the level of the useful signal emitted from the near side lobes of the radar antenna pattern.

Due to the time shift of the signals of the primary and secondary channels, systematic errors occur in the differential-range measuring system for determining radar coordinates, which ultimately translate into errors in pointing standard means of destruction and target designation [1, 2]. The main disadvantage of the device in question is that the use of guided weapons, in particular anti-radar missiles (PRR), is possible by “crude” target designation with subsequent additional search for the object (radar) and its defeat in the specified area. This determines the need to find ways to solve the problem of protecting the radar from being hit by radiation-homing weapons.

The technical result of the utility model is to increase the survivability (stability of operation) of a known radar device with the function of active electronic protection against reconnaissance and strike systems by giving it a new property - protection against PRR damage.

The claimed technical result is achieved by the fact that in the radar with active electronic protection from reconnaissance and strike systems based on the spatio-temporal decorrelation of their background radiation in the region of the side lobes, the following are additionally introduced: a second frequency multiplier 16 and switch 17 (see Fig. 2), moreover, the input of the frequency multiplier 16 is connected to the output of the master oscillator 2, and the output is connected to the second input of the switch 17, the output of the first frequency multiplier 8 is connected to the first input of the switch 17, to the third input of the switch 17 under for prison second output pulse modulator 4, and a fourth input connected to the output of the second delay line 12, the first output of the switch 17 is connected to the input of the second shaper 13 false signals, and a second output connected to the third input of the second additional power amplifier 14.

A comparative analysis with the prototype showed that the inclusion of an additional frequency multiplier and a switch in the circuit gives the radar with the active REZ function from RTR RUS a new property - the ability to actively protect the radar from the damage of the radar, which can increase the stability of the protected radar in typical applications without stopping the operation of the radar radiation, and therefore, the claimed device meets the criteria of "novelty" and "inventive step".

The proposed scheme of the device for active electronic protection of the radar from the RUS and the defeat of the PRR is shown in FIG. 2.

The device of active electronic protection of the radar from the RUS and the defeat of the PRR contains a receiving device 1, a master oscillator 2, a synchronizer 3, a pulse modulator 4, a first delay line 5, a power amplifier 6, a transmitting and receiving antenna device of the radar 7, the first frequency multiplier 8, the second multiplier frequency 16, the first driver of false pulses 9, the first additional power amplifier 10, the first additional antenna device 11, the second delay line 12, switch 17, the second driver of false pulses 13, the second additional power amplifier 14, second auxiliary antenna device 15.

The elements of the device of active electronic protection of the radar from the RUS and the defeat of the PRR are connected as follows.

The first output of the master oscillator 2 is connected to the first input of the receiving device 1. The second output of the master oscillator 2 is connected to the second input of the synchronizer 3. The third output of the master oscillator 2 is connected to the input of the first frequency multiplier 8 and to the input of the second frequency multiplier 16. The output of the first frequency multiplier 8 is the third input of the power amplifier 6, the first input of the first additional power amplifier 10 and the first input of the switch 17. The output of the second frequency multiplier 16 is the second input of the switch 17. The first output One synchronizer 3 is connected to the second input of the receiving device 1 and the first input of the power amplifier 6. The third output of the synchronizer 3 is connected to the third input of the first additional power amplifier 10 and to the first input of the second additional power amplifier 14. The second output of the synchronizer 3 is connected to the input of the pulse modulator 4 The first output of the pulse modulator 4 is connected to the input of the first delay line 5, the output of which is connected to the second input of the power amplifier 6. The output of the power amplifier 6 is connected to the input of the receiver a transmitting antenna device 7, the output of which is connected to the third input of the receiving device 1. The second output of the pulse modulator 4 is connected to the input of the first shaper 9, to the third input of the switch 17 and to the input of the second delay line 12, the output of which is connected to the fourth input of the switch 17. The first output of the switch is connected to the input of the second shaper of false pulses 13, and the second output of the switch 17 is connected to the third input of the second additional power amplifier 14. The output of the first shaper is false x pulses 9 are connected to the second input of the first additional power amplifier 10, the output of which is the input of the first additional antenna device 11. The output of the second shaper of pulse pulses 13 is connected to the second input of the second additional power amplifier 14, the output of which is connected to the input of the second additional antenna device 15.

The operation of the device of active electronic protection of the radar from the RUS and the defeat of the PRR is as follows.

The receiving device 1, the master oscillator 2, the synchronizer 3, the pulse modulator 4, the power amplifier, the transceiver 7 and the frequency multiplier 8 are the main path of the radar. The first shaper of false pulses 9, the first additional power amplifier 10 and the first additional antenna device 11 represent the first auxiliary (additional) antenna path of the radar. The second frequency multiplier 16, the second delay line 12, the switch 17, the second shaper of impulses 13, the second additional power amplifier 14 and the second additional antenna device 15 represent the second auxiliary antenna path of the radar. The master oscillator 2 is the primary source of high-frequency oscillations and provides high stability of the oscillation frequency. In the frequency multiplier 8, the oscillation frequency rises to the desired operating value f ₀ . In the second frequency multiplier 16, the oscillation frequency of the master oscillator 2 rises to the value f ₁ = f ₀ ± ΔF. AF lies in the range 0.04f _pr ... 0.07f _pr (f _pr is the intermediate frequency of the receiver of the passive radar homing of the attacking PRR). The operation of the transmitter devices is synchronized in time by the synchronizer 3. From the synchronizer 3 to the radio transmitting device, a transmitter start pulse is supplied. Under the influence of the ISP, the modulator 4 generates a modulating pulse, during which the power amplifier 6 amplifies the microwave oscillations coming from the frequency multiplier 8 to the desired operating value. This modulating pulse is delayed in the first delay line 5 for a time τ _lz1 (see Fig. 3).

High-frequency modulated oscillations are transmitted to the transceiver antenna device 7 and radiated into space. The modulating pulses of the modulator 4 are fed to the input of the first shaper of false pulses 9, as well as to the input of the switch 17 without delay and through the second delay line 12 with a delay of TL 32. Τ _lz2 maximum values of the delay time does not exceed wherein _lz1 τ (τ _lz2 <τ _lz1) · Their specific values are selected so as to provide a constant overlap of the main and additional signals in accordance with their duration (τ _and, τ _d). For operation of the device for the purpose of protection against damage to RRS, the modulator pulse 4 of the modulator 4 is switched to the input of the second spurious pulse generator 13 without a time delay, and for the operation of the radar with active electronic protection from electronic intelligence means RUS, the modulator pulse of the modulator is switched to the input of the second spurious pulse generator 13 4 delayed in the second delay line 12 for a time τ _lz2 . The operation of the active REZ radar device from RTR RUS is illustrated by the signal voltage diagrams shown in FIG. 3, and the operation of the radar active protection device against PRR damage is illustrated by the diagrams of the signal voltages shown in FIG. 4. The pulses of the modulator 4 are, in this case, the triggering pulses of the shapers of false pulses 9 and 13. The generated false pulses control the operation of the first additional power amplifier 10 and the second additional power amplifier 14 which during these pulses amplify microwave oscillations to the desired operating value. These microwave oscillations are fed to the first additional power amplifier 10 s, the first frequency multiplier 8, and to the second additional amplifier 14 from the output of the switch 17, moreover, to operate the device in the protection mode against damage, the microwave oscillations are switched from the second frequency multiplier 16, and for operation devices in the active REZ mode from RTR RUS to the second additional power amplifier 14, microwave oscillations coming from the first frequency multiplier 8 are switched on. After amplification, these oscillations are through additional antenna devices 11 and 15 are emitted into space. The gain of the first additional power amplifier 10 and the second additional power amplifier 14 is selected so as to mask the main signal emitted from the side lobes. The power level of the additional signals should be commensurate with the level of the useful signal emitted from the near side lobes of the radar antenna pattern.

When the device is operating in the protection mode of the radar from damage by PRR, the first additional channel generates a signal identical to the signal of the main channel of the radar. The identity of the structure of the main signal and the additional signal in the first additional channel is achieved by using, when generating the additional signal, the signal of the main radar path. In the second additional channel, an additional signal is generated from microwave oscillations coming from the second frequency multiplier 16 without a time delay. Thus, additional antenna devices 11 and 15 radiate into space simultaneously two signals of the same structure, but spaced in frequency by an amount equal to ΔF.

The proposed radar protection device against PRR takes into account the specifics of building information processing equipment in advanced missile homing systems, which is manifested in the following. Receivers of passive homing heads (GOS) of modern and promising missiles are superheterodyne, which is done in the interest of increasing their sensitivity and frequency selectivity [3]. Directional seeker seekers are typically monopulse to eliminate angular errors due to amplitude modulation of the received signal. In this case, the most probable is the use of phase direction finding methods, which have a number of advantages over amplitude ones [4]. The most likely application of phase-phase and phase total-difference direction finding methods.

The possibility of disabling PRR guidance when using a frequency-diversity signal radar is based on the manifestation of one of the following effects:

The two-frequency signal, which is combinational in nature, after converting in the mixer a passive GOS gives the combinational component of the intermediate frequency. The presence in the receiver of protection schemes against receiving signals at combination and mirror frequencies can lead to the prohibition of capture and rejection of the subsequent tracking of a signal of this type in frequency. In this case, it is also impossible to track the signal in angular coordinates and, consequently, there will be a breakdown in the guidance of the PRR to the radar emitting a frequency-spaced signal.

In the absence of protection schemes against combinational components and the capture of the frequency of a two-frequency signal, its angular tracking is violated due to distortions in the direction-finding characteristics of the direction finder [5].

The calculations show that the probability of tracking failure along the angular coordinate of the passive GOS will be maximum when the ratio of the power of the additional channels is ρ≈1 (see Fig. 5). With increasing detuning in the frequency of the second additional signal relative to the frequency of the first additional signal, the probability of disruption initially increases, and then decreases (see Fig. 6). The greatest probability of failure, as can be seen from FIG. 6, corresponds to a relative mismatch lying in the range of 0.03 ... 0.07f, _etc.

Thus, the effect of the frequency-spaced signal on the passive GOS of homing missiles leads to disruption of tracking along the angular coordinate with a probability of 0.5 ... 0.7, which confirms the possibility of organizing sufficiently effective radar protection from damage by PRS by using the device described above. At the same time, an important feature of the proposed radar protection device against PRR damage is that the radar does not stop emitting, thereby ensuring the possibility of its functioning for its intended purpose over the entire time interval of military operations.

Used Books

1. Kulakov M.A. and others. Copyright certificate No. 257758 of 1.07.88

2. Kulakov M.A., Kerkov V.G. Methods of active electronic protection of radio electronic systems from reconnaissance and strike complexes of the PLSS type based on the spatio-temporal decorrelation of their side radiation. - Military radio electronics, No. 1 - 1988.

3. Maximov M.V., Gorgonov G.I. Radio engineering homing systems. - M .: Radio and communications, 1982. - 304 p.

4. Leonov A.I., Fomichev K.I. Monopulse radar. - M .: Radio and communications, 1984. - 312 p.

5. Zatonsky V.I., Karkotsky V.L. The use of special multi-frequency signals to protect electronic equipment from damage by missiles homing on radiation. - Military radio electronics, No. 1 - 1988.

Claims (1)

A device for protecting a radar station from being hit by radiation-homing weapons, comprising a receiving device, the first input of which is connected to the first output of the master oscillator, the second to the first output of the synchronizer, and the third to the output of the transmitting and receiving antenna of the radar station, serially connected by the second output of the master a generator, the second output of the synchronizer, the first output of which is connected to the first input of the power amplifier, and the third to the third input of the first additional power amplifier and with the first input of the second additional power amplifier, the first output of the pulse modulator, the second output of which is connected to the input of the first shaper of the pulse pulses and to the input of the second delay line, the first delay line, the power amplifier and the transmitting and receiving antenna device of the radar station, and connected in series with the first shaper of the false pulses, the first additional power amplifier, the first additional antenna device, characterized in that a second frequency multiplier, the input of which is connected to the output of the master oscillator, and a switch connected by the first input to the output of the first frequency multiplier, the second input to the output of the second frequency multiplier, the third input to the second output of the pulse modulator, and the fourth input to the output of the second line delays, and the first output of the switch is connected to the input of the second shaper of false pulses, and the second output is connected to the third input of the second additional power amplifier.