RU2234107C1 - Method for simulation of target and its simulator in pulse-doppler radar (modifications) - Google Patents

Abstract

FIELD: radar engineering, applicable in monitoring facilities of pulse-Doppler radars.

SUBSTANCE: the method consists in the fact that at simulation of a target initial attenuation of signals of the simulated target occurs in the network of successive transduction of signals of intermediate and heterodyne frequencies of the master oscillator to the carrier frequency of the outgoing pulses and simulated target; they are attenuated at the input of the network or in the points of gating of target signals to the limits providing their subsequent external attenuation without any influence of parasitic permeation to the radar receiver of pulses of the simulated target at the carrier frequency. An auxiliary IF oscillator is introduced in the target simulator at the input of the network of successive transduction for control of the output signal and its frequency, use is also made of a mode-of-operation switch and an OR gate. Modifications of the target simulator are available with regulators of initial attenuation in the points of gating of simulated target signals and alternation of the mode-of-operation switch.

EFFECT: enhanced decoupling (electric leak-proofness) of the simulated target in the target radar master oscillator to a level preventing its parasitic permeation to the radar receiver without an additional screening of the master oscillator construction.

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Description

The invention relates to the field of radar technology, to methods and devices for integrated monitoring of radar stations, and more specifically to methods of simulating targets using built-in monitoring tools (VSK) and to target simulators in a pulse-Doppler radar.

The invention can be used mainly in airborne radars having severe restrictions on weight and dimensions with high requirements for the reliability of the VSK.

Known methods for simulating targets in pulsed radars, based on the use of probe pulses of the transmitter, which delay in time to the echo reception zone open in the receiver, attenuate them in terms of power to the limits of the dynamic range of the receiver signals and feed attenuated probe pulses directly or through the radar antenna, after which they use a simulated target for integrated radar control in the conditions of its maintenance and operation [1], [2].

Despite the simplicity of implementation, these methods are mainly applicable to incoherent pulsed radar.

For coherent pulse-Doppler radars, a method for simulating a target using a VSC in a radar is known and applicable, based on the use of the properties of its common master oscillator (ZG), which ensures the coherence of the signals of the probe pulses of the transmitter, the simulated target and the local oscillator signals of the radar receiver. This method is the closest analogue of the claimed and follows from the description of the action of the design of MH in the sources [3], [4]. A radar with one (common) MH is described in [5].

A known method of simulating a target in a pulsed-Doppler radar is that the GG common to the transmitter and receiver of the radar is excited by target gating pulses in the intervals between the probe pulses of the radar, which form in the chain the serial conversion of signals of intermediate and heterodyne frequencies of the GG to the carrier frequency of the probing radar pulses and simulated targets, where, in addition to converting them, they are amplified, side frequencies are filtered out, phase manipulation is carried out, pulse gating is performed the converted signals, attenuate at the output of the chain, imitate the Doppler frequency shift of the target inside or outside the MH, externally attenuate the generated pulses of the simulated target at the carrier frequency and feed them directly to the input of the radar receiver or through its antenna.

When implementing this method, the same elements and devices are used as for generating radar probe pulses. An additional element is only the built-in tools inside or outside the MH, providing a simulation of the Doppler frequency shift of the target.

The main disadvantage of this method is that its implementation requires increased isolation or shielding (in general terms - electro-tightness) of the design of the exhaust gas when simulating a target. This is necessary to prevent spurious leakage of pulses of the simulated target to the input of the radar receiver. The known method does not contain techniques for bypassing or compensating for the insufficient electro-tightness of the impulse of the simulated target as part of the SG without additional screening.

Thus, the solved problem of the proposed method is the introduction of techniques that provide a bypass or compensation for insufficient electro-tightness of the impulse of the simulated target as part of the SG without additional screening.

The problem is achieved in that the method of simulating the target, based on the properties of the general GB and described above, is supplemented by the method by which the signals of the simulated target are initially attenuated in a chain of sequential conversion of signals of intermediate and heterodyne frequencies of the SG into the carrier frequency of the probe pulses and the simulated target moreover, they weaken at the input of the chain and / or at the gating points of the target signals to the extent that they provide their subsequent external attenuation without the influence of the parasite Nogo leakage in the pulse radar receiver to the simulated target carrier frequency.

Implementation of the proposed method is possible in simulators of the target (IC) of pulse-Doppler radar as part of their ZG.

ICs in the composition of the airborne defense radar are known [3], [4]. Analogs mainly differ in the number of intermediate (IF) and heterodyne frequencies used in the MH for the formation of probe pulses and ICs at the carrier frequency. In 3G blocks using 2 IFs, phase-shift signals for radar mode with intrapulse phase shift keying are more widely used [6]. The principle of the formation of IC pulses in analogues is based on the well-known method of simulating a target described above.

The design of the well-known ZG airborne radars contains two main functional-forming blocks: a block for the formation of continuous (intermediate and heterodyne) signals and a block for the generation of probe pulses or a simulated target (at the carrier frequency). The heterodyne signals of the 1st block used for the radar receiver, together with the IF signal (usually the 2nd IF) are input into the 2nd block, where they are sequentially converted to the 1st IF and the carrier frequency for signals alternately gated by triggering pulses (gating ) radar transmitter or simulated target, thereby ensuring the alternate formation of probing pulses or ICs.

The main drawback of the known ICs is the difficulty of decoupling them from parasitic leakage of IC pulses at the carrier frequency to the input of the radar receiver, given that the common ZG and receiver are usually located in one monoblock of the onboard radar and additional screening is difficult to implement.

The closest analogue of the inventive simulator is the IC as part of the ZG radar, a description of which is given in the sources [3], [4].

The prototype contains a block for the formation of continuous (intermediate and heterodyne) signals (Fig. 1 in [3] or Fig. 1 in [4]), including a series-connected reference frequency generator (VHF), a frequency synthesizer, and a signal conditioner of the first receiver local oscillator. The input of the signal shaper of the 2nd receiver local oscillator is connected to the 2nd output of the OGF. The input of the signal generator of the 2nd IF is connected to the 3rd output of the OGF. The second output of the frequency synthesizer is connected to the 2nd input of the signal shaper of the 1st receiver local oscillator, and the second inputs of the frequency synthesizer and the second IF shaper are respectively the block and 3G inputs for connecting to the input buses for controlling the frequency tuning and frequency modulation (FM). The fourth output of the OGF is the output of the block and the ZG for connecting to the output bus of the reference frequency used in other radar units (in the synchronizer and the 3rd receiver local oscillator). The outputs of this block for the signals of the 2nd and 1st local oscillators of the receiver are the output buses of the block and the ZG, providing its communication with the radar receiver. The outputs for the signals of the 2nd IF, as well as the outputs for the signals of the 2nd and 1st local oscillators of the receiver are connected to the inputs of the same name of the probe pulse generation unit or the simulated target (at the carrier frequency).

The block for generating probe pulses or a simulated target contains (Fig. 2 in [3]) connected to the input for signals of the 2nd IF in series: the 1st mixer, the 2nd input of which is connected to the input for signals of the 2nd receiver local oscillator ( for conversion to the 1st IF), amplifier, 1st side-frequency filter, phase manipulator, the control input of which serves as the input of the unit for connecting to the input phase manipulation control bus, 1st strobe key, 2nd mixer, 2nd the input of which is connected to the input for the signals of the 1st receiver local oscillator (for conversion to the carrier frequency), 2nd amplifier, 2nd side-frequency filter, 2nd gating key, the control input of which is connected to the control input of the 1st strobing key and the input of the block and 3G, used to connect the gating pulses to the input bus (transmitter or IC), and the output device with the 1st and 2nd outputs, which are the outputs of the block and ЗГ, respectively, for communication with the terminal amplifier of the transmitter and the input of the receiver at the carrier frequency of the radar. The control input of the output device, through which its power is regulated, is the input of the unit and the ЗГ for connecting to the input bus for controlling the work-simulation modes, which also provides external switching (in the synchronizer) of the transmitter gating pulses (work) or IC (simulation). In simulation mode, the communication between the output device and the terminal amplifier of the transmitter is blocked and an external modulator is turned on to simulate the Doppler frequency shift of the target.

Providing a partial decoupling of IC signals due to external simulation of the Doppler frequency shift of the target and overlapping of the coupling of the ZG with the terminal amplifier of the transmitter, the prototype, however, does not provide the required electrical tightness in other cases (phase-shifted and unmodulated IC signals) without additional screening of the ZG design.

Thus, the solvable task of the proposed IC is to increase the electrical tightness of the PG without additional screening based on the proposed method of simulating a target.

The solution of this problem is achieved by the fact that in the IC of the pulse-Doppler radar as part of its MSS containing a continuous signal generation unit, the first input of which is connected to the input frequency tuning control bus, the second input is connected to the frequency modulation input control bus, its The 1st output is connected to the output bus of the reference frequency, and the 2nd, 3rd and 4th outputs, respectively, for the signals of the 2nd IF, 2nd and 1st local oscillator of the receiver are connected to the same inputs of the probe pulse generating unit and simulated target containing Ice-connected 1st mixer, the 1st input of which is used to input signals of the 2nd IF, and the 2nd input is connected to the input for signals of the 2nd receiver local oscillator, amplifier, 1st side frequency filter, phase manipulator, control the input of which is the 4th input of the block, which is connected to the input bus for phase shift control, the 1st gating key, the 2nd mixer, the 2nd input of which is connected to the input for signals of the 1st receiver local oscillator, 2nd side filter frequencies, 2nd gating key and output device with 1st and 2nd outputs, which are block outputs, respectively, for communication with the terminal amplifier of the transmitter and the input of the receiver, with the 1st and 2nd inputs, the 1st, 3rd and 4th outputs of the block for generating continuous signals, 4th input, 1st and The 2nd outputs of the probe pulse generation block and the simulated target are respectively the inputs and outputs of the ЗГ, which also contains inputs for connecting to the input gates of the strobe pulses to the transmitters and control the work-simulation modes, an auxiliary generator of the 2nd is introduced into the probe pulse generation block and the simulated targetH with the possibility of changing it and the output signal regulator, an OR element, and a work-simulator mode switch, while the input for the reference frequency of the auxiliary generator of the 2nd IF is connected to the 1st output of the continuous signal generation unit, the output of the work-simulator mode switch The 1st input of the 1st mixer, the 1st and 2nd information inputs of the switch are connected respectively to the input of the unit for input of the 2nd IF and the output of the auxiliary generator of the 2nd IF, the control input of the switch is connected to the input bus ota-simulation, the control inputs of the 1st and 2nd keys gate connected to the output of the OR gate, the 1st and the 2nd inputs of which are respectively inputs for connection to transmitter input bus and strobe pulses to the pulse input bus storbirovaniya purpose.

According to the 2nd option, the IC differs in that between the input of the unit for connecting the target strobe pulses to the input bus and the 2nd input of the OR element, the target strobe pulse level controller is turned on.

According to the 3rd option, the IC is characterized in that in parallel with the 1st gating key, the control input of which is connected to the input gate of the transmitter gating pulses, a target signal level controller is connected, made in the form of a series-connected attenuator and the 3rd gating key, whose control input is connected to the input of the block for the input bus of the strobe pulses of the target.

According to the 4th option, the IC differs in that the work-simulation mode switch is performed on the 1st and 2nd gating keys of the opposite on-off sign, the information inputs of which are respectively connected to the input of the block for inputting the 2nd IF and the output of the auxiliary generator 2nd IF, the outputs of these keys are connected to the 1st input of the 1st mixer, and the control inputs of these keys are connected to the input of the unit for connecting to the input bus of the strobe pulses of the target, which also serves as a work-simulator switching bus tion.

Figure 1 shows a block diagram of the declared IC as part of the ZG radar, figure 2, 3, 4 - diagrams of options, figure 5 - plot signals explaining the operation of the IC, where:

1 - a block for generating continuous signals, 2 - the 1st input of block 1 for connecting to the input bus for controlling the frequency tuning Δf ₀ , 3 - the 2nd input of block 1 for connecting to the input bus for controlling the frequency modulation Δf _hm , 4 - 1st the output of block 1 for connecting to the output bus of the reference frequency f _op , 5 - the 2nd output of block 1 and the input of block 8 for signals f _pc2 of the 2nd IF, 6 - the third output of block 1, the output bus and the input of block 8 for signals f _g2 of the 2nd receiver local oscillator, 7 - 4th output of block 1, the output bus and input of block 8 for signals f _g1 of the 1st local oscillator of the receiver;

8 - a block for generating probing pulses and a simulated target, 9 - the 1st mixer, 10 - amplifier, 11 - 1st filter of the side frequencies, 12 - phase manipulator, 13 - 4th input of block 8 for connecting to the input manipulation control bus phases (Ex. MF), 14 - 1st gate key, 15 - 2nd mixer, 16 - 2nd side-pass filter, 17 - 2nd gate key, 18 - output device, 19 - 1st output device 18 for communication with the transmitter final amplifier, 20 - 2nd exit device 18 for communication with the receiver input, 21 - entrance for power off command unit 8 (F ₀ O) at the output 19 device Steps 18, 22 — input of block 8 for connecting to the input bus of the strobe pulses of the transmitter (ICP), 23 — input of block 8 for connecting to the input bus of pulses of strobe of the target (ISC), 24 - input of block 8 for connecting to the input bus of operating mode control -imitation (Exercise K);

25 - auxiliary generator of the 2nd IF, 26 - generator output signal regulator 25, 27 - generator frequency regulator 25, 28 - OR element, 29 - work-simulator mode switch, 30 - target strobe pulse level regulator, 31 - signal level regulator targets, 32 - the 3rd gate key, 33 - the 1st gate key of the switch 29, 34 - the 2nd gate key of the switch 29;

35 - transmitter gating pulses (ICP), 36 - target gating pulses (CSC), 37 - changing ΔISC 'at the input of keys 14 and 17, 38 - signals f _pc2 at the output of the switch 29, 39 - signals ΔU and f' _pc2 at the output the switch 29, 40 - pulses f ₀ and f ₀ + F _d at the outputs of the device 18, 41 - the control input of the generator 25 for electronic frequency control.

The proposed method of simulating a target and its simulator in the composition of the ZG radar are implemented and work as follows (figure 1).

Block 1 forming continuous signals controlled via the inputs 2 and 3 signals Δf ₀ and Δf _FM coming from the input buses tuning of frequency and frequency modulation generates signals f _pch2, f _r2 and f _r1 which via outputs respectively 5, 6, 7 arrive at the inputs of the same name (5, 6, 7) of block 8 of the formation of probing pulses and a simulated target. The signals f _g2 and f _g1 , from outputs 6 and 7, in addition, also go to the radar receiver (not shown) on the same buses for its 2nd and 1st local oscillators.

In block 8 _pch2 signals f, f f _r1 and _r2 are used in the chain of serial conversion to the 1st IF (f _pch1 and f _'pch1) and carrier frequency (f ₀₎ probing radar pulse and simulated targets (f _0). This chain, consisting of elements and devices 29, 9-12, 14-18, works as follows.

Using the switch 29, controlled through the input 24 by the command Ctrl K, the signal f _pc2 (operation) or signal f _pc2 (imitation) from the auxiliary generator 25 of the 2nd inverter with the regulator 26 of its output signal is connected to the 1st input of the 1st mixer 9.

In the mixer 9, the 2nd input 6 which receives the signal f _r2, f _pch2 input signals or f _'pch2 converted into the 1st IF (f _pch1). Next, the signal f _{pch1 is} amplified in the amplifier 10, the side frequencies are filtered out in the filter 11, the phase is manipulated in the manipulator 12, to the 2nd input 13 of which signals from the input phase manipulation control bus (MFR) are supplied. To excite and form the probe pulses at f _pc1 and f ₀ , ICP gating pulses are used.

Similarly, using the ISC operating in the intervals between ICPs, a series conversion chain is excited in the IC mode. In this case, the ISC through the element 28 OR enter the control input of the 1st gate key 14, open it, providing the signals f ′ _{pc1 of the} simulated target to the first input of the mixer 15, the second input of which receives signals f _g1 , providing its conversion to the carrier frequency f ₀ '. Next, in the 2nd filter 16, the side conversion frequencies are filtered out and repeated gating is performed with the 2nd key 17. Then, the pulse signals f ₀ 'are supplied to the output device 18 with outputs 19 (operation) and 20 (simulation). The device 18 contains an amplifier that provides the necessary power at its output 19 for excitation in the operating mode of the terminal amplifier of the radar transmitter (not shown). In the simulation mode, by the command P ₀ out, coming through the input 21 of block 8, the signal power at the output 19 of the device 18 can be significantly reduced for a deeper isolation of the IC from the input of the radar receiver.

(In the mode, the operation of the command Ctrl K, P ₀ out and ISC to the inputs 24, 21, 23 of block 8 are not received). The Doppler frequency shift of the target, f ' ₀ + F' _d, is _imitated inside the PG by changing the frequency f ′ _{be2 of the} auxiliary generator 25 of the 2nd IF, which is set by the frequency controller 27, or through its control input 41 for Δf'FM, based on of the fact that F _d = f ' _pc2 -f _pc2 , and Δf' _hm = Δf _hm at the input 3 of block 1.

The initial attenuation of the IC signals at the input of the series conversion circuit is performed by the controller 26 of the output signal of the auxiliary generator 25 of the 2nd IF. The signal f _{pc2 is} reduced to the extent that the external subsequent attenuation of the IC signals is reduced without the influence of spurious leakage of these signals to the radar receiver at the carrier frequency f ' ₀ or f' ₀ + F ' _d .

The initial attenuation of the signals f ' _pc2 ensures the electrical _{tightness of the} IC as part of the MH also in cases when it is required to use only phase-shifted signals without simulating F _d (F _d = 0, if f' _pc2 = f _pch2 ) or if F _{d is} carried out outside the MH (f ' ₀ ± F _d ).

For the implementation of the initial attenuation of the signal of the simulated target according to the diagram in figure 2, the regulator 30 of the MSC, included in the circuit between the input 23 of block 8 and the input of the element 28 OR, provides a change in the level UΔ of the MSC 'and f' _pch1 pulses of the IC, the gentle part of the characteristics of the gating keys 14 and 17, without affecting the signal level of the probe pulses gated by the ICP through another input of the OR element 28 from the input 22 of block 8 (see paragraphs 35-40 in Fig. 5).

For the embodiment of the initial attenuation of the signal of the simulated target according to the scheme in Fig. 3, the signal level of the IC is changed through the regulator 31 of the signal level of the target (f ' _pc1 ) and the 3rd _gate key 32, which are connected in series and connected in parallel to the 1st gate key 14 . In this case, a smoother control of the target signal level at the gating point is provided, which also does not affect the signal level f _{pc1 of the} probe pulses (see paragraphs 39, 40 in FIG. 5),

To implement the variant of IC according to the scheme in Fig. 4, the switch 29 modes work-simulation provides the connection of the signal f ' _be2 (imitation) when the keys 33 and 34 of the information center are received from the input 23 of block 8 connected to the input bus of the strobe pulses of the target serving at the same time, the work-imitation mode switching bus (see p. 38-40 in Fig. 5).

Thus, the initial attenuation of IC signals, excluding their spurious leakage at the carrier frequency, is performed at the input of the serial conversion chain and / or at the gating points of IC signals. Options are selected depending on the operating mode of the radar and the design of the ZG.

The claimed device can be made by a specialist on the materials of the present description, the attached drawings and the given sources of information.

Block 1 of the formation of continuous signals can have many options for execution (p. 151 in [7]), which do not significantly affect the solution of the tasks, but provide the formation and delivery of the necessary signals in the SG, common to the radar receiver and transmitter. In addition to the option described above, block 1 can be performed using information sources [7] and [8].

Block 8 of the formation of the probe pulses and the simulated target is performed according to the diagrams in Figs. 1-4 of this description, the main elements of which: switch, mixers, filters, amplifiers, keys, phase manipulator are described in the general technical literature, in particular in sources [9], [10], [11] and [14].

The auxiliary generator 25 of the 2nd inverter with the possibility of changing it can be performed by analogy with the generator of the 2nd inverter in block 1, where the reference frequency f _{op is used} , which is multiplied or divided to the required value f ' _pc2 . The change in the frequency f ' _{be2 is} carried out by changing the coefficient of multiplication or division of the reference frequency f _op [12]. The regulator 27 of the frequency f ' _{pc2 of the} auxiliary generator 25 of the 2nd IF can be its control input 41 for electronic frequency control, for example, voltage, including for the FM mode by analogy with the FM in block 1 for the 2nd IF (f' _be2 ) [12].

The regulator 30 level ISC can be performed, for example, in the form of a variable resistor [14].

The target signal level controller 31 is executed, for example, in the form of an attenuator capable of attenuating a signal at a frequency f ' _pts2 [14].

The gating key 32 is performed by analogy with the keys 14 or 17, usually performed on the pulse high-frequency diodes for the respective frequencies.

The OR element 28 is performed on diodes capable of transmitting the gating pulses of ICP and ISC [13].

The switch 29 modes of work-imitation in the key version is performed on the keys 33 and 34 of the opposite sign on-off, calculated to operate at frequencies f _pc2 (f ' _pc2 ).

Using the invention allows to solve the following tasks:

1. By simple reception and minimal means, it is possible to increase the level of isolation (electro-tightness) of the IC signals in the MG to the limits limited by its electric tightness in the intervals (pauses) between the radar probe pulses, practically without increasing the mass and dimensions of the MG.

2. To provide a deeper suppression of the lateral frequencies of the IC pulses in all modes of operation of the IC with the key option of switching the work-simulation modes and to separate the simulation of the Doppler frequency shift of the target from superimposing this shift on the frequency of the radar probe pulses.

3. To increase the operational manufacturability of the radar through the use of ICs as part of its ZG, which in its electrical parameters, in particular in electrical leakage and suppression of side frequencies, approaches the parameters of external special measuring instruments.

Sources of information

1. Latin O.M. et al. Theory and practice of operating radar systems. M., Soviet Radio, 1970, pp. 120, 133-140.

2. RF patent No. 2103706 with a priority of 07/11/96 on "Method for calibrating the radar and radar", MKI G 01 s 7/40. Applicant: Murom Institute of VSTU. Authors: Bulkin VV, Falin VV and etc.

3. Application No. 2000116217/09 dated 06/23/2000 for the "Simulator of the target of a pulse-Doppler radar." Bulletin of inventions No. 19 dated July 10, 2002. Applicant: OJSC Fazotron-NIIR Corporation. Authors: Surzhikov L.Ya., Matyushin AS, Goldenberg V.A.

4. Product FK03 (Airborne radar "Spear-21I"). Manual for technical operation of USTI.416.131.007 RE 4. Part 5. Section 112.17.02. Block FK03-22 - master oscillator (damn. RBKY 434.857.009). Description and work, M., 1996, JSC "Research Institute of Radio Engineering", pp. 1-5.

5. Radar devices. (Theory and practice of construction). Ed. V.V. Grigorina-Ryabova. M., Soviet Radio, 1970, § 13.3. Coherent pulse radar. Block diagram of a radar with one master oscillator. Fig. 13.13, pp. 344, 355.

6. Ibid. §14.3. Radar with intrapulse phase shift keying. The scheme of the device FM signals. Fig. 14.8, p. 390.

7. Handbook of radar. Ed. M. Skolnik. Volume 3. Radar devices. M., Soviet Radio, 1979, § 2.5 heterodyne. Heterodyne according to the frequency multiplication scheme, p.151.

8. Ibid. § 2.5. Frequency synthesizer Fig. 11 ,, p. 152.

9. Ibid. § 2.4. HF receiver head. Mixer Fig. 3, p. 141, 146.

10. Ibid. § 2.4. Microwave amplifier, Fig. 6, pp. 146, 147.

11. Ibid. § 4.6. Receivers IF amplifier, p. 251.

12. Ibid. § 8.3. Linear frequency modulation. Voltage controlled oscillator. Fig. 13, p. 414.

13. W. Titze, C. Schenck. Semiconductor circuitry. Moscow, Mir, 1982. Section 9.1. Scheme OR, Fig. 25.

14.R.A. Valitov, V.N. Sretensky. Radio engineering measurements. Measurement methods and techniques ranging from long to optical waves. M., Soviet Radio, 1970 (§ 2.7 Attenuators, p.62).

Claims (5)

1. A method of simulating a target in a pulse-Doppler radar station (radar), which consists in the fact that the master oscillator (ZG), common to the transmitter and receiver of the radar, is excited by pulses of strobe of the target in the intervals between the probe pulses of the radar, which form in the sequence conversion chain signals, intermediate and heterodyne frequencies of the SH to the carrier frequency of the probe pulses and the simulated target, where, in addition to conversion, they are amplified, side frequencies are filtered out, phase manipulation is performed s, they perform pulsed gating of the converted signals, imitate the Doppler frequency shift of the target inside or outside the MH, externally attenuate the generated pulses of the simulated target at the carrier frequency and feed them to the radar receiver input directly or through its antenna, characterized in that they produce the initial attenuation of signals of a simulated target in a chain of sequential conversion of signals of intermediate and heterodyne frequencies of a 3G to a carrier frequency, and this is attenuated at the input of the chain and / or Sampling points outside the target signals to ensure their subsequent attenuation without external influence of parasitic infiltration in the pulse radar receiver to the simulated target carrier frequency. 2. A target simulator of a pulsed-Doppler radar as part of its ZG containing a block for generating continuous signals, the first input of which is connected to the input bus for controlling the frequency tuning, the second input is connected to the input bus for controlling the frequency modulation, its first output is connected to the output bus of the reference frequency, and the second, third and fourth outputs, respectively, for signals of the second intermediate frequency (IF), the second and first local oscillators of the receiver are connected to the same inputs of the block generating probing pulses and they a target containing a first mixer in series, the first input of which is used to input signals of the second IF, and the second input is connected to the input for signals of the second local oscillator of the receiver, an amplifier, a first side-frequency filter, a phase manipulator, the control input of which is the fourth input of the unit, which connected to the input phase shift control bus, the first gating key, the second mixer, the second input of which is connected to the input for signals of the first receiver local oscillator, the second side filter x frequencies, a second gating key and an output device with first and second outputs, which are the outputs of the block, respectively, for communication with the terminal amplifier of the transmitter and the input of the receiver, while the first and second inputs, the first, third and fourth outputs of the continuous signal generating unit, fourth input, the first and second outputs of the probe pulse generation unit and the simulated target are respectively the inputs and outputs of the ЗГ, which also contains inputs for connecting to the input buses of the strobe pulses of the transmitter and control modes of work-imitation, characterized in that the auxiliary frequency generator of the second IF with the possibility of changing it and the output signal regulator, the OR element and the work-simulation mode switch, an input for the reference frequency of the auxiliary generator of the second The inverter is connected to the first output of the continuous signal generation unit, the output of the work-simulation mode switch is connected to the first input of the first mixer, the first and second information inputs The operation-simulation mode switch s are connected respectively to the input for inputting the signals of the second inverter of the probe pulse generation unit and the simulated target and the output of the auxiliary generator of the second inverter with the possibility of changing it and the output signal regulator, the control-mode operation input of the operation-simulator switch is connected to the input mode control bus work-simulation, the control inputs of the first and second gating keys are connected to the output of the OR element, the first and second inputs of which are respectively inputs for connecting to the input bus of the strobe pulses of the transmitter and to the input bus of the strobe pulses of the target. 3. The simulator according to claim 2, characterized in that between the input for connecting to the input bus of the strobe pulses of the target of the probe pulse generation unit and the simulated target and the second input of the OR element, the target strobe pulse level controller is turned on. 4. The simulator according to claim 2 or 3, characterized in that the operation-simulation mode switch is executed on the first and second gating keys of the opposite on-off sign, the information inputs of which are respectively connected to the input for inputting signals of the second IF of the probe pulse generation unit and simulated the purpose and output of the auxiliary generator of the second frequency converter with the possibility of changing it and the output signal regulator, the outputs of these keys are connected to the first input of the first mixer, and the control inputs of these the keys are connected to the input of the probe pulse generation unit and the simulated target for connecting to the input gate of the strobe pulses of the target, which also serves as a work-simulation mode switching bus. 5. A target simulator of a pulse-Doppler radar as a part of its ZG containing a block for generating continuous signals, the first input of which is connected to the input bus for controlling the frequency tuning, the second input is connected to the input bus for controlling the frequency modulation, its first output is connected to the output bus of the reference frequency, and the second, third and fourth outputs, respectively, for the signals of the second intermediate frequency (IF), the second and first local oscillators of the receiver are connected to the same inputs of the probe pulse generating unit and imitates a target containing serially connected first mixer, the first input of which is intended for input of the second IF signals, and the second input is connected to the input for signals of the second receiver local oscillator, an amplifier, a first side-frequency filter, a phase manipulator, the control input of which is the fourth input of the unit, which connected to the input phase shift control bus, the first gating key, the second mixer, the second input of which is connected to the input for signals of the first receiver local oscillator, the second side filter frequencies, a second gating key and an output device with first and second outputs, which are the outputs of the block, respectively, for communication with the terminal amplifier of the transmitter and the input of the receiver, while the first and second inputs, the first, third and fourth outputs of the continuous signal generating unit, the fourth input, the first and the second outputs of the probe pulse generation unit and the simulated target are respectively the inputs and outputs of the ЗГ, which also contains inputs for connecting to the input bus pulses of the transmitter gating pulses and control modes of work-imitation, characterized in that in the block for generating probing pulses and simulated targets introduced an auxiliary generator of the second IF with the ability to change it and the output signal regulator, an OR element and a mode switch work-imitation, while the input for the reference frequency of the auxiliary generator of the second The inverter is connected to the first output of the continuous signal generation unit, the output of the operating mode switch -imitation is connected to the first input of the first mixer, the first and second information inputs the work-simulator mode switch is connected respectively to the input for inputting the signals of the second inverter of the probe pulse generation unit and the simulated target and the output of the auxiliary generator of the second inverter with the possibility of changing it and the output signal regulator, the control input of the work-simulator mode switch is connected to the work mode control input bus -imitation, the control input of the first strobe key is connected to the input bus of the strobe pulses of the transmitter, the control input of the second strobe key It is connected to the output of the OR element, the first and second inputs of which respectively are inputs for connecting to the input gate of the transmitter gating pulses and to the input bus of the strobe gates of the target, and in parallel with the first strobe key, the target signal level regulator is connected, made in the form of a series-connected attenuator and a third key gating, the control input of which is connected to the input bus of the strobe pulses of the target.

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