RU113019U1 - SUPPORT SYSTEM FOR MOBILE RADIO COMMUNICATION ITEMS WITH ULTRA WIDE BAND SIGNALS - Google Patents

Abstract

A system for jamming mobile radio communication points with ultra-wideband signals, containing a receiving antenna connected in series with a receiver, which, in turn, is connected to a delay circuit that is connected to a final amplifier connected to a transmitting antenna, characterized in that a computer is introduced, to the inputs of which the receiver, the receiver of the synchronization line, the receiver of the satellite navigation system are connected, respectively, while the output of the calculator is connected to the delay circuit, all of the above blocks are installed on each of the N carriers, where N is a natural number; on the N + 1 carrier is a clock generator connected to the transmitter of the synchronization line, and the second receiver of the satellite navigation system, also connected to the transmitter of the synchronization line, the transmitter of the synchronization line is connected to the transmitting antenna of the synchronization line.

Description

The technical solution relates to the field of electronic warfare and can be used for radio suppression of radio communications and radars with ultra-wideband signals.

A device is known for creating single interference with pulsed radio means, for example, according to RF patent No. 2358277 published on June 10, 2009, “Radar Trap”, consisting of a transmitting antenna, an amplitude detector, a receiving antenna, a pre-amplifier with a control input, a power amplifier, a voltage combiner, synchronous detector, modulating pulse generator and voltage integrator, pulse generator. Its disadvantage is its low efficiency when interfering with the receiving radio means of broadband signals.

A device for creating targeted interference according to the patent of the Russian Federation No. 2229603 published July 20, 2008, "Device for creating targeted interference to radar stations." The device consists of: a receiving antenna, an input switch, a control and synchronization unit, a high-frequency amplifier, a splitter, band-pass filters, frequency estimation subsystem mixers, an intermediate-frequency amplifier, a digital multi-channel filter, a fast Fourier transform device, a reference generator, a modulating signal generating device, pulse generator, electronic switch, noise generator, balanced modulator, phase locked loop, voltage controlled oscillator , Adder ring PLL low pass filter, divider, pryamotsifrovogo synthesizer reference frequency, the phase detector, the high frequency pre-amplifier, the output of the channel switch, the pulse selector, the output of high frequency amplifier, the transmitting antenna. The disadvantage of this device is its complexity and high cost.

It is also difficult to use the device for creating interference according to the patent of the Russian Federation No. 2103705, published on 01.27.1998, “Automatic response interference station”, consisting of a receiving antenna, an input splitter of microwave signals, a device for short-term reproduction of a carrier frequency, an input microwave amplifier, the first and a second microwave coupler, a microwave switch, an output microwave amplifier, a transmitting antenna, a device for generating response noise interference, a device for recording pulse sounding signals, an amplitude detector, a phase detector a modulator, a logic inhibit element, a shaper of gating and modulating pulses, a control and temporary programming device, a device, logical signal processing, the first and second shapers of low-frequency modulating voltages.

The prototype is a device for relaying interference according to A.I. Paly "Radio electronic warfare." Military publishing house, Moscow 1981 p. 50, as the closest in technical essence. The prototype device contains a receiving and transmitting antenna, a frequency storage circuit, a high frequency amplifier, a terminal amplifier, a receiver, a delay circuit, and a modulator.

The operation of the prototype device is as follows. The signal of the suppressed RES, received by the jamming station, enters simultaneously into the frequency storage circuit and into the receiver. From the output of the receiver, the signal is supplied to the delay circuit, where it is delayed by the time t _s . The modulator generates a series (pack) of pulses that modulate the carrier oscillations in the UHF. After amplification in the UHF and in the terminal amplifier, interference pulses are emitted by the transmitting antenna. In this case, reception and transmission is carried out using weakly directional antennas, ensuring the operation of the device in the required sector of the angles of arrival of signals from the suppressed means.

The disadvantage of the prototype is that the interference is carried out in a wide sector of angles, as a result of which interference of the necessary intensity is created in a spatial region of great length. As a result of this, effective suppression requires significant power of the emitted interference, which is difficult to implement when creating small-sized jamming stations installed on small-sized unmanned aerial vehicles. As a result, due to the low radiation power, the intensity of the generated interference is insufficient.

The technical task to be solved is to increase the efficiency of jamming during group use of jamming stations installed on small-sized unmanned aerial vehicles.

The technical problem to be solved in the jamming system for mobile radio communication points with ultra-wideband signals, comprising a receiving antenna connected in series with a receiver, which in turn is connected to a delay circuit, which is connected to a terminal amplifier connected to a transmitting antenna, is achieved by introducing a computer to the inputs of which a receiver, a synchronization line receiver, a satellite navigation system receiver, respectively, are connected, while the output of the calculator is connected to the rear circuit arms, all of the above blocks are mounted on each of N carriers, where N is a natural number; a N-1 carrier has a clock generator connected to the transmitter of the synchronization line and a second receiver of the satellite navigation system, also connected to the transmitter of the synchronization line, the transmitter of the synchronization line is connected to the transmitting antenna of the synchronization line.

Figure 1 shows the structural diagram of the proposed device to create interference. Figure 2 shows the timing diagrams of the system.

A device for interfering with mobile radio communication points with ultra-wideband signals (Fig. 1) comprises a receiving antenna 1 connected in series with a receiver 2, which in turn is connected to a computer 3, and a synchronization line receiver 4 and a satellite navigation system receiver are connected to the inputs of the computer 3 5 respectively. The output of the calculator is connected to one of the inputs of the delay circuit 6, the receiver 2 is connected to the other input of the delay circuit 6. In turn, the delay circuit 6 is connected to the terminal amplifier 7, the output of which is connected to the transmitting antenna 8. All of the above blocks are mounted on carriers 13 ₁ ÷ 13 _N , where N is a natural number, for example, equal to five. The second receiver of the satellite navigation system 9 and the clock generator 10 are connected to the inputs of the transmitter of the synchronization line 11, respectively, which is connected to the transmitting antenna of the synchronization line 12 mounted on 13 _{N + 1} media. All the blocks included in the jamming system for mobile radio communication points with ultra-wideband signals are standard, their circuits are published in the available literature. As carriers can be used, for example, small unmanned aerial vehicles.

The device according to the claimed technical solution works as follows. Installed on 13 _{N + 1} media, the clock 10 generates a series of pulses with a period T ₀ . These pulses and data from the second receiver of the satellite navigation system 9 are fed to the inputs of the transmitter of the synchronization line 11, emitted by the transmitting antenna of the synchronization line 12, and received by the receiver of the synchronization line 4 mounted on each of 13 _N carriers. Input signals containing data on the current coordinates 13 _{N + 1 of the} medium - (x ₀ , y ₀ , z ₀ ) and the clock period T ₀ are received in the calculator 3. Also in the calculator 3 receives a signal from the receiver of the satellite navigation system 5, containing information about the current coordinates of the ith module is (x _i , y _i , z _i ). In calculator 3, the current distance between the carrier 13 m and the carrier 13 _{N + 1} and the corresponding time delay are determined and also the shift of the received sequence of clock pulses is carried out by the value mТ ₀ -τ _0i , where m = 0,1,2 ...

Calculator 3 works according to the following algorithm: input signals containing data on the current coordinates 13 _{N + 1} , the carrier - (x ₀ , y ₀ , z ₀ ) and the clock period T ₀ enter the calculator 3. The next step is that the calculator 3 a signal is received from the receiver of the satellite navigation system 5, containing information about the current coordinates of the i-th module - x _i , y _i , z _i . The next step is to calculate in the calculator 3 the current distance between the carrier 13 _N and 13 _{N + 1} , according to the formula for calculating the distance between two points with known coordinates, given in the book by P.S. Aleksandrov "Course of Analytical Geometry and Linear Algebra", - M . "Science", 1979, p. 29: The next step is to calculate the time delay using the formula

The next action of the calculator 3 is to shift the received sequence of clock pulses by the value mТ ₀ -τ _0i , where m = 0,1,2 ....

As a result, in calculators 3 of each of the modules, a common time scale for the entire system is formed. The received radiation pulse from the suppressed means is received by the receiving antenna 1 of each of the modules and the corresponding receiver 2, at the output of which pulses are generated, the time delay of which corresponds to the propagation time of the signal from the radiation source to the i-th module: This signal from the output of the receiver 2 is fed to the input of the circuit with a delay by calculator 3. In calculator 3, the time delay r is measured, and a control signal is generated for the delay circuit 6, corresponding to the time delay by the value T ₀ -τ _0i . As a result, the pulse signal at the output of the delay circuit 6 is shifted in time by the value of T ₀ -τ _0i . This signal is amplified to the required value in the terminal amplifier 7 and emitted by the transmitting antenna 8. Thus, each of the carriers re-emits the received signal at the time point T ₀ -τ _0i , while it receives at the moment τ _i .

Therefore, all signals re-emitted by all modules come to a point corresponding to the location of the suppressed radiation source simultaneously with a delay equal to T ₀ . The simultaneous exposure to N re-emitted pulses corresponds to an increase of N times the interference power compared to the case of the nonsynchronous action of N interference sources. Timing diagrams are shown in figure 2.

The device according to the claimed technical solution can be implemented as follows: a clock pulse generator based on digital microcircuits, a second satellite navigation system receiver, and a satellite navigation system receiver, using existing GPS-GLONASS system tools. The transmitting and receiving parts of the synchronization line containing the transmitter, antennas, and receiver can either be made in the form of transceiver devices in the centimeter or millimeter wavelength range based on existing GHz circuits, corresponding to the wavelength range. Or they can be performed in the optical range using known modulators, photodetectors and laser diodes as an element base. Antennas, receivers and module receivers can be made according to traditional schemes based on the existing element base. The calculator and the delay circuit can be implemented on the existing digital element base using microprocessors or programmable logic circuits with sufficient speed. The terminal amplifier can be made on the basis of pulse key circuits based on, for example, powerful field-effect transistors.

Claims (1)

A jamming system for mobile radio communication centers with ultra-wideband signals, comprising a receiving antenna connected in series with a receiver, which, in turn, is connected to a delay circuit, which is connected to a terminal amplifier connected to a transmitting antenna, characterized in that a calculator is introduced to the inputs of which a receiver, a synchronization line receiver, a satellite navigation system receiver, respectively, are connected, while the output of the calculator is connected to a delay circuit, all of the above locks are installed on each of N carriers, where N is a natural number; a clock generator connected to the transmitter of the synchronization line and a second receiver of the satellite navigation system, also connected to the transmitter of the synchronization line, the transmitter of the synchronization line connected to the transmitting antenna of the synchronization line are installed on the N + 1 carrier.