RU1840940C - Nonsynchronous jamming simulator - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: simulator includes an interference generator, two counters, an interference type switch, an interference intensity switch and a gate former. The control input of the first counter is connected to the interference type switch and the output is connected to the interference generator and the complementing input of the second counter, the control input of which is connected to the interference intensity switch, the output of the second counter and the output of the interference generator are connected to the gate former, the output of which is the output of the simulator.

EFFECT: high accuracy of simulation.

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Description

The invention relates to the field of simulators and can be used in simulators of radar stations to simulate an interference environment.

In real conditions, non-synchronous impulse noise (NIPS) from interacting carriers of encoded transponder beacons (RMOs) occurs due to a spread in the launch frequencies of requesting radars. These interferences have the form of the same coded marks as the useful signal, but appear on the radar indicator screen at ranges other than the useful signal range, i.e. They are located, as it were, on segments of spirals converging to the center of the screen or diverging from it, depending on the sign of the frequency difference.

Known simulator of non-synchronous interference, consisting of an independent generator and a shaper of interference (for example, a simulator of non-synchronous interference from RMO "Coordinate" in the simulator radar I-2M). An independent generator generates a voltage close to the start frequency of the simulated radar, and the difference in these frequencies is a simulation of the difference in start frequency of the requesting radar in real conditions.

This simulator has the following significant disadvantages:

- a sufficiently high departure of the NPC frequency relative to the probe pulse;

- the inability to control the type of interference.

A known simulator of non-synchronous interference, consisting of a shaper of interference, two counters, a coincidence device, a switch of the sign of the frequency difference, the sensor of the frequency difference.

This simulator, selected as a prototype, works as follows (see figure 1).

From the radar simulator to the simulator input:

- pulses of a quartz oscillator;

- control pulses with a start frequency of a simulated radar.

Counter 2 counts the pulses of the crystal oscillator, zeroing control pulses. Thus, the formation of the current phase shift noise.

Counter 3 counts the pulses coming from the output of the frequency difference sensor 6, triggered by control pulses. Zeroing the counter 3 is carried out by filling its senior discharge, determined by the maximum range of the simulated radar. Thus, the formation of an instantaneous phase shift of the interference occurs.

Coincidence device 4 performs bitwise comparison of counters 2 and 3 (i.e., compares the current and instantaneous shift of interference) and, if the codes match, it generates a start pulse of the jammer 1, in which the interference signal is generated in the form of a coded set of pulses. The type of interference is set by the frequency difference sign switch 5 and the frequency difference sensor 6.

The frequency difference sign 5 switch determines whether operations are performed in the forward or reverse code:

if in the direct code, then each subsequent match occurs in the higher bits, i.e. the interference appears at a greater range and a diverging spiral is obtained, if in the reverse code, then each subsequent match occurs in the lower digits, and the spiral will converge.

The frequency difference sensor 6 detects the steepness of the spiral. Depending on its installation, a different number of pulses is supplied to the input of counter 3 for each control pulse. The more such impulses, the higher the degree of each subsequent coincidence and the spiral will be steeper.

The disadvantage of the prototype simulator is the inability to simulate interference of varying intensity, i.e. the inability to change the number of interference pulses that appear on the screen of the indicator on each spiral, which takes place in real conditions.

The aim of the present invention is to expand the functionality of the simulator by changing the intensity of the simulated interference.

This goal is achieved by the fact that in the prototype device containing an interference generator, two counters and an interference type switch (combining the functions of a frequency difference sign switch and a frequency difference sensor), the counting input of the first counter connected to the radar simulator, an interference intensity switch and a shaper are introduced the strobe.

In this case, the switch of the type of interference is connected to the control input of the first counter, the output of which is connected to the jammer and the counting input of the second counter, the noise intensity switch is connected to the control input of the last counter, the outputs of the jammer and the second counter are connected to the gate former.

The introduction of these new elements and the change in the connections between the old ones change the principle of the simulator - the jammer is triggered not by coincidence of the current and instantaneous phase shift of the jammer, as in the prototype, but by specially developed frequency pulses not equal to and not a multiple of the launch frequency of the radar simulator.

Due to this, the proposed simulator, while maintaining the positive qualities of the prototype, expands its functionality and allows you to change the intensity of the simulated interference.

Figure 1 shows a block diagram of a prototype device, figure 2 is a block diagram of the proposed simulator of non-synchronous interference.

The non-synchronous interference simulator (Fig. 2) consists of a jammer 1, two counters 2 and 3, a switch of the interference type 7, a noise intensity switch 8, a gate shaper 9. The counting input of the counter 2 is connected to the output of the radar simulator, and the control input is from the switches type of interference 7. The output of the counter 2 is connected to the jammer 1 and the counting input of the counter 3, with the control input of which the commutator of the interference intensity 8 is connected.

The gate driver 9 is connected to the output of the jammer 1 and the counter 3.

During operation, the counter 2 divides the pulses of the crystal oscillator of the radar simulator. The division ratio is set by the switch of the type of interference 7 and is set not equal to and not a multiple of the division coefficient in the pulse shaper of the launch of the radar simulator. So, for example, if the pulse repetition rate of the radar simulator start pulses is 312.5 Hz, then the pulse repetition rate at the output of counter 2 can vary from 311.2 to 313.8 Hz, depending on the installation of the interference type switch 7. These pulses trigger the jammer 1, in which an interference signal is generated in the form of an encoded set of pulses.

If the start frequency of the jammer 1 is lower than the frequency of the start pulses of the radar simulator, the interference mark on the display screen appears each time at a shorter range and a converging spiral is obtained.

If the start frequency of the jammer 1 is higher than the frequency of the start pulses of the radar simulator, the interference mark appears each time at a greater range and the spiral turns out to be diverging.

The steepness of the spiral and, therefore, the number of spirals is determined by the absolute value of the difference in the frequencies of the start of the jammer 1 and the radar simulator.

Thus, the switch 7 completely determines the type of non-synchronous interference.

At the same time, pulses from the output of counter 2 go to the counting input of counter 3. The division coefficient of the counter 3 is determined by the interference intensity switch 8. The pulses from the output of counter 3 start the strobe generator 9, in which a strobe is generated, the duration of which depends on the start frequency (the higher the start frequency, the shorter the strobe duration).

Impulse pulses from the output of the jammer 1 are supplied to the driver of the strobe 9 and, when they coincide in time with the strobe, they are output to the simulator as an interference signal.

Thus, the number of pulses in the interference signal on each spiral can vary depending on the installation of the commutator interference intensity 8.

The proposed simulator of non-synchronous interference makes it possible to simulate non-synchronous interference without increasing the amount of equipment, taking more fully into account the factors characterizing its parameters by changing the intensity of the interference.

The development of the proposed simulator is caused by the need to create an interference environment in radar simulators, including non-synchronous interference, with the maximum approximation of the simulated environment to the real one, which improves the quality of training of radar operators.

State tests of the simulator "Octopus" with its simulator of non-synchronous interference confirmed the positive qualities of the latter.

Claims (1)

A non-synchronous interference simulator comprising an interference generator, two counters and an interference type switch, characterized in that, in order to increase the simulation accuracy by providing a change in the interference intensity, an interference intensity switch and a gate driver are additionally introduced into it, while the control input of the first counter is connected with a switch of the type of interference, and the output with a shaper of interference and a counting input of the second counter, the control input of which is connected to the switch of the interference intensity, the output of the second counter and the output of the driver of interference is connected to the driver of the strobe, the output of which is the output of the simulator.

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