RU2745257C1 - Device for blocking radio-controlled unauthorized equipment - Google Patents

Abstract

FIELD: radio jammers.

SUBSTANCE: device for blocking radio-controlled unauthorized equipment contains a receiving antenna, a receiver, two amplifiers, three band-pass filters, four signal delay generators, three signal summers, three two-position switches, each of which is controlled by a corresponding control device, an inverter, a generator of a periodic nonlinearly varying voltage, a generator, voltage controlled (VCG), transmitting radiating antenna, connected in a specific way.

EFFECT: increasing the probability of guaranteed radio jamming, simplifying the device and increasing its reliability.

1 cl, 1 dwg

Description

The invention relates to a means of dealing with mines and other explosive objects having radio fuses and is intended to protect against radio-controlled explosive devices by blocking the unauthorized transmission of information to control radio fuses over a radio channel, can also be used to protect against unauthorized transmission of any information over a radio channel in a wide range of previously unknown radio frequencies.

A device for blocking radio fuses is known, containing several (n) modules of the same type, each of which includes a series-connected frequency former, an amplifier and an antenna, while all modules simultaneously operate in non-overlapping sub-bands of the protected frequency range [1]. This known device allows to emit high power in each frequency sub-band, sufficient to protect against radio-controlled explosive devices. One of the disadvantages of such a device for blocking radio fuses is the integrated radiation power increased by n times, where n is the number of modules used. An increase in the integral power of the jammer is undesirable, both due to a significant increase in power consumption, dimensions and weight.

Known device for blocking radio fuses [2], containing n frequency shapers, a switch, a generator of a pseudo-random sequence of pulses, a matching device connected between a broadband power amplifier and a broadband antenna system, and a characteristic controller.

The operation algorithm of this device allows you to quickly adapt it to changes in the radio frequency environment.

However, the device cannot provide guaranteed protection in the specified frequency range, because requires time-consuming monitoring of the radio situation and is in constant search, decision-making mode and blocking of the values of changing frequencies of operating transmitters.

Known device for protection against radio-controlled explosive devices [3] (prototype), containing a receiving antenna, a receiver, an amplifier, a nonlinear voltage generator and a voltage-controlled generator, a power amplifier and a transmitting antenna, band-pass filters, two signal delay shaping devices, three adders signals. This device, using the built-in algorithm of operation, makes it possible to provide protection against unauthorized transmission of information for controlling radio fuses over a radio channel in a given range of protected radio frequencies.

However, the device cannot provide ever increasing levels of guaranteed protection in a given frequency range due to the constant development of radio engineering and radio technologies. The method of generating an interference signal does not provide guaranteed protection against equipment using, for example, pseudo-random tuning of the operating frequency (PFC).

The objective of the present invention is to increase the reliability of protection against unauthorized transmission of information to control radio fuses over a radio channel in a given range of protected radio frequencies without increasing the integral output power of the device, its power consumption, dimensions and weight.

The technical result of the proposed device for protection against radio-controlled explosive devices is to increase the probability of guaranteed radio suppression at the same energy density of the interference signal in the protected range, simplify the device and increase its reliability.

The technical result is achieved due to the fact that a device for blocking radio-controlled unauthorized equipment containing a receiving antenna, a receiver, an amplifier, a nonlinear voltage generator and a voltage-controlled generator, a power amplifier and a transmitting antenna, a first bandpass filter, a second bandpass filter, a first device signal delay forming, second signal delay forming device, first, second, third signal adders, amplifier output is connected to the input of the first bandpass filter, the first bandpass filter output is connected to the inputs of the second bandpass filter and the first delay forming device, outputs of the second bandpass filter and the first device delay generators are connected to the inputs of the first signal adder, the output of which is connected to the input of the second delay generation device and to the first signal input of the second signal adder, the output of the second delay generation device is connected connected to the second signal input of the second signal adder, the output of the second bandpass filter is connected to the first signal input of the first signal adder, the output of which is connected to the first signal input of the second signal adder, the second signal input of the second signal adder is connected to the output of the second delay shaping device, the second signal input the third signal adder is connected to the output of the voltage-controlled generator, the input of which is connected to the output of the nonlinearly varying voltage generator, the output of the third signal adder is connected to the input of the third band-pass filter, the output of which is connected to the input of the power amplifier, the output of which is connected to the input of the transmitting antenna, the first , second and third DIP switches, first, second and third DIP switch control devices, third and fourth signal delay generators and an inverter, the output of the first signal adder and the output of the second adder and the signals are connected respectively to the first and second signal inputs of the first two-position switch, the output of which is connected to the second signal input of the third two-position switch, the output of the first signal combiner is connected to the input of the signal inverter, the output of which is connected to the input of the third signal delay generating device, the output of which is connected to the first signal input of the second two-position switch, the second signal input of the second two-position switch is connected to the output of the third signal delay shaping device, the input of the third signal delay shaping device is connected to the output of the first signal adder, the output of the third two-position switch is connected to the first signal input of the third signal adder, while the first, second and third DIP switches are controlled by the first, second and third DIP switch control devices, respectively, long The delay lines of the signal of the first, second, third and fourth signal delay generating devices are not equal to each other, the switching frequency of the first and second two-position switches is higher than the switching frequency of the third two-position switch, and the frequency range of the voltage-controlled generator is in the range of the frequencies protected by the device.

New features that ensure the achievement of the technical result are the additionally introduced first, second and third on-off switches, the first, second and third control devices for the two-position switches, the third and fourth signal delay generators and the inverter, the output of the first signal adder and the output of the second signal adder are connected, respectively. to the first and second signal inputs of the first two-position switch, the output of which is connected to the second signal input of the third two-position switch, the output of the first signal adder is connected to the input of the signal inverter, the output of which is connected to the input of the third signal delay shaping device, the output of which is connected to the first signal input of the second two-position switch, the second signal input of the second two-position switch is connected to the output of the third signal delay generating device, the input of the third device forms signal delay is connected to the output of the first signal adder, the output of the third on / off switch is connected to the first signal input of the third signal adder, while the first, second and third on / off switches are controlled by the first, second and third on / off switch control devices, respectively, the duration of the signal delay of the first, of the second, third and fourth signal delay generating devices are not equal to each other, the switching frequency of the first and second on-off switches is higher than the switching frequency of the third on-off switch, and the frequency range of the voltage-controlled generator is in the range of the frequencies protected by the device.

Such a technical solution, combined with new features and new connections between its elements and blocks, provides: increasing the reliability of radio suppression,

universality of suppression of all types of modulation, since the structure of the jamming signal corresponds to the structure of the jammed signal,

reducing the size, weight and power consumption of the device to achieve the specified reliability of protection, without increasing the integral power,

an increase in the probability of guaranteed radio suppression at the same energy density of the interference signal.

This technical solution is aimed at increasing the probability of guaranteed radio suppression in the protected range due to the destruction of the information part of the signal / signals while maintaining the structure of the suppressed signals, and the destruction of the information part of the signal / signals upon destruction of individual fragments of the structure of these signal / signals, with the same energy density as in prototype in the protected range.

Thus, the destruction of the information part of the signal / signals, the destruction of individual fragments of the signal / signals structure, together with the amplitude excess, makes it possible to increase the probability of radio suppression.

The use of the method of fragmentary substitution, destructuring and deformation of signals increases the probability of suppressing functioning transmitters, which has been confirmed experimentally.

FIG. 1 shows a block diagram of the inventive device.

The device contains a receiving antenna 1, a receiver 2, a first amplifier 3, a first bandpass filter 4, a first signal delay shaping device 5, a second bandpass filter 6, a first signal adder 7, a second signal delay shaping device 8, a second signal adder 9, a first two-position switch 10 controlled by the DIP switch control device 11 10, the third signal delay generator 12, the inverter 13 and the fourth signal delay generator 14, the second DIP switch 15 controlled by the DIP switch control device 16 15, the third DIP switch 17 controlled by the DIP switch 18 a switch 17, a third signal adder 19, a generator of a periodic nonlinearly varying voltage 20, a voltage controlled generator (VCO) 21, a third bandpass filter 22, a second amplifier 23 of the power of the interference signal and a transmitting radiating antenna 24.

The operation of the claimed protection device is carried out as follows.

Signals are received by antenna 1, processed by receiver 2 and amplified by the first amplifier 3. From the output of the first amplifier 3, the signal is fed to the band-pass filter 4 of the protected frequency range from the lower frequency fn to the upper frequency fb. The output signal from the bandpass filter 4 passes through the delay device 5 (can be made in the form of a delay line) and in parallel through the bandpass filter 6 of the protected frequency range. The signals from the output of the bandpass filter 6 and the delay device 5 are summed by the first signal adder 7, and the result of the summation from the output of the first signal adder 7 is fed to the first signal input of the second signal adder 9, and the signal from the delay device output is sent to the second signal input of the second signal adder 9 8, the input of which is the output of the first signal adder 7 (FIG. 1).

The output signal of the first signal adder 7 and the output signal of the second signal adder 8 come to the first and second signal inputs of the first on / off switch 10 controlled by the on / off switch 10 control device 11.

The output signal of the first signal adder 7 is sequentially fed to the input of the signal delay generating device 12 and the inverter 13. The output signal of the inverter 13 is fed to the input of the signal delay device 14, the output signal of which and the output signal of the signal delay generating device 12 arrive at the signal inputs of the second dip switch 15 controlled by a control device 16 with a two-position switch 15.

The output of the first DIP switch 10 and the output of the second DIP switch 15 are fed to the signal inputs of the third DIP switch 17 controlled by the DIP switch 17 control device 18.

The output of the third two-position signal switch 17 and the output of the generator 21, controlled by the voltage from the linear (or non-linear in general) voltage generator 20, are connected to the inputs of the third signal adder 19, the output of the third signal adder 19 is connected to the bandpass filter 22, the output of which is connected to the input power amplifier 23, the output of which is connected to the input of the transmitting radiating antenna 24.

The delay times of the first, second, third and fourth signal delay generating devices (5, 8, 12 and 14, respectively) are not equal to each other, the switching frequency of the first 10 and second 15 two-position switch is higher than the switching frequency of the third two-position switch 17, and the frequency range of the generator, controlled by voltage, is in the range of frequencies protected by the device from the lower frequency fn to the upper frequency fv.

Bandpass filters 4, 6 and 22 are tuned for the range of protected frequencies from the lower frequency fn to the upper frequency fb. The generator 21, controlled by a voltage (VCO), excited by the generator of a periodic nonlinearly varying voltage 20, also provides the generation of harmonic signals in the range of protected frequencies from the lower frequency fn to the upper frequency fn

The generator 21, controlled by voltage, generates a signal, the frequency of which f continuously changes over a period of time T according to the law determined by the generator 20 of the periodic varying voltage. In this case, the receiving and transmitting antennas have sufficient isolation.

Adding the original signal with its time-shifted copy allows you to preserve the structure of the signal and change its information part. Since the inventive device performs this operation twice: at the adder 7, and then at the adder 9, the output signal of the adder 9 is a practically undetectable mixture with the structure of the original signals. In addition to this mixture, creeping noise from the VCO 21 is mixed in the same frequency range, disrupting or deforming the structure and information part of the fragments of the input signal.

Filtered to the boundaries of the range of protected frequencies from the lower frequency fn to the upper frequency fb, the signal with excess power after the amplifier 23 is fed to the transmitting antenna 24.

The operation of the claimed device for blocking radio-controlled unauthorized equipment is as follows.

Signals are received by antenna 1, processed by receiver 2. From the output of receiver 2, the signal is fed to the input of the first amplifier 3. From the output of the first amplifier 3, the signal passes through the band-pass filter 4 and in parallel through the delay device 5. The signals from the outputs of the band-pass filter 4 and the delay device 5 are summed the first adder 7 signals.

Thus, at the output of the first signal adder 7, a mixture of signals is formed, consisting of the sums of fragments of the received signals, which has a similar structure with the distorted information part due to transformations and shifts.

The result of the summation from the output of the first signal adder 7 is fed to the first input of the second signal adder 9, and the signal from the output of the delay device 8 is fed to the second input of the second signal adder 9, the input of which is the output of the first adder 7.

Thus, at the output of the second signal adder 9, an additionally changed mixture of signals is formed, consisting of the sums of the changed fragments of the received signals, which has a similar structure with the distorted information part due to transformations and shifts.

The two-position switch 10 alternately connects the outputs of the first signal adder 7 and the second signal adder 9, with the frequency and duty cycle set by the on-off switch 10 control device 11.

The two-position switch 10 sequentially in time outputs signal fragments from the output of the first signal adder 7 and the second signal adder 9. The ratio of the durations of the signal fragments from the output of the first signal adder 7 and the second signal adder 9 is proportional to the duty cycle of the signal from the output of the opening control device 11 by the two-position switch 10.

Thus, at the output of the first two-position switch 10 signals, a mixture of signals is formed, consisting of the sums of fragments of an already distorted signal, which has a similar structure, but with an additionally deformed (distorted) information part.

The output signal of the first signal adder 7 is fed to the input of the signal delay generating device 12 and, in series, the inverter 13 and the signal delay generating device 13. The output signal of the signal delay generating device 12 and the output signal of the signal delay generating device 13 are fed to the signal inputs of the second on / off switch 15 controlled by the on / off switch 15 control device 16.

Thus, at the output of the second two-position switch 15 signals, a mixture of signals is formed, consisting of the sums of fragments of an already distorted signal from the first adder 7, but with an additionally deformed (distorted) information part and an additionally phase-shifted inverted signal from the output of the first adder 7.

Thus, at the output of the second two-position switch 15 signals, a mixture of signals is formed, consisting of the sums of fragments of an already distorted signal from the first two-position switch 9 of signals, which has a similar structure, but with an additionally deformed (distorted) information part and an additionally shifted and then inverted signal from the output of the first adder 7.

The ratio of the durations of the signal fragments from the outputs of the signal delay generating device 12 and the output signal of the signal delay generating device 13 are proportional to the duty cycle of the signal from the output of the opening control device 16 by the two-position switch 15.

The output of the first DIP switch 10 and the output of the second DIP switch 15 are fed to the signal inputs of the third DIP switch 17 controlled by the DIP switch 17 control device 18.

The duration of the connection of the outputs of the first 10 and second 15 two-position switches to the first signal input of the third adder 19 is determined by the duty cycle of the output signal of the control device 18.

The output of the third two-position signal switch 17 and the output of the voltage controlled generator 21 are connected to the signal inputs of the third signal adder 19.

Thus, at the output of the third signal adder 19, a signal mixture is formed, consisting of the sums of fragments of multiply distorted signals, which has a similar structure with the input signals and a highly distorted information part and, additionally, a sliding noise from the voltage controlled generator 21 in the same frequency range, deforming both the structure and the information part of the fragments of the input signal.

The output of the third signal adder 19 is connected to a bandpass filter 22, the output of which is connected to the input of the second power amplifier 23, the output of which is connected to the input of the transmitting antenna 24.

Bandpass filters 4, 6, 22 and receiver 2 are tuned to the range of protected frequencies from the lower frequency fн to the upper frequency fb. The generator 21, controlled by voltage, excited by the generator 20 of a periodic nonlinearly varying voltage, provides the generation of harmonic signals in the same range of protected frequencies "running" from the lower frequency fn to the upper frequency fv.

The generator 21, controlled by voltage, generates a signal, the frequency of which f continuously changes over a period of time T according to the law determined by the generator 20 of the periodic varying voltage. Receiving 1 and transmitting 24 antennas thus have sufficient isolation.

Adding the original signal with its time-shifted copy allows you to preserve the structure of the signal, but change its information part to the point of impossibility of detection. Since the inventive device performs this operation twice: at the adder 7, and then at the adder 9, additionally interleaves the signal fragments with the first 10, the second 15 and the third 17 on-off switches of signals, the output signal of the third on-off switch 17 of signals is an undetectable mixture with the structure of the original signals.

In addition to this mixture, creeping noise from the generator 21 controlled by voltage in the same frequency range is mixed in, deforming both the structure and the information part of the fragments of the input signal. After such transformations, while maintaining the similarity of the structure of the original signal, the detection of the output signal becomes impossible or will require significant time resources.

Filtered to the boundaries of the range of protected frequencies from the lower frequency fn to the upper frequency fb, the signal with excess power after the amplifier 23 is fed to the transmitting antenna 24.

The choice of the values of the switching frequency of the two-position switches is due to the maximum changes in the information part of the received signals precisely at these values and the simplicity of the implementation of the concept.

Thus, the change in the information part of the signal / signals, destruction, deformation and substitution of individual fragments of the signal / signal structure, together with the amplitude excess, makes it possible to increase the probability of radio suppression, and due to the new set of features and the interaction algorithm of the nodes corresponding to the declared features, it provides an increase in the effectiveness of radio suppression. ...

Sources of information

1. Petrenko E.G., Linok A.A., Yakubchik A.Yu. Device for blocking radio fuses, patent N 2100752 from 22.11.96, MKI F41H 11/12, publ. BI N36, h. 11, 1997, p. 391.

2. Battalov A.M., Gordon O.I., Konoplev V.A., One-fingered I.A. Device for blocking radio fuses. Patent N 2131645 from 1998-05-26, MKI F41N 11/12, N04K 3/00

3. Semenyuk T. A. Device for protection against radio-controlled explosive devices // Patent RU on application No. 2019114224 (027 319) dated 07.05.2019 Decision to issue a patent on 17.12.2019

Claims (3)

A device for blocking radio-controlled unauthorized equipment, containing a receiving antenna, a receiver, an amplifier, a nonlinear voltage driver and a voltage-controlled generator, a power amplifier and a transmitting antenna, a first bandpass filter, a second bandpass filter, a first signal delay shaping device, a second signal delay shaping device , the first, second, third signal adders, the amplifier output is connected to the input of the first bandpass filter, the output of the first bandpass filter is connected to the inputs of the second bandpass filter and the first delay shaping device, the outputs of the second bandpass filter and the first delay shaping device are connected to the inputs of the first signal adder, the output of which is connected to the input of the second delay generating device and to the first signal input of the second signal adder, the output of the second delay generating device is connected to the second signal input of the second adder signals, the output of the second bandpass filter is connected to the first signal input of the first signal adder, the output of which is connected to the first signal input of the second signal adder, the second signal input of the second signal adder is connected to the output of the second delay generating device, the second signal input of the third signal adder is connected to the output of the voltage-controlled generator, the input of which is connected to the output of the nonlinearly varying voltage generator, the output of the third signal adder is connected to the input of the third band-pass filter, the output of which is connected to the input of the power amplifier, the output of which is connected to the input of the transmitting antenna , characterized in that the first, second and third two-position switches are introduced into it, the first, second and third control devices for the two-position switches, the third and fourth signal delay generating devices and the inverter, the output of the first signal adder and the output of the second signal adder are connected to the first and second, respectively signal inputs of the first two-position switch, the output of which is connected to the second signal input of the third two-position switch, the output of the first signal combiner is connected to the input of the signal inverter, the output of which is connected to the input of the third signal delay shaping device, the output of which is connected to the first signal input of the second two-position switch, the second the signal input of the second two-position switch is connected to the output of the third signal delay generating device, the input of the third signal delay generating device is connected to the output of the first signal adder alov, the output of the third two-position switch is connected to the first signal input of the third signal adder, while the first, second and third two-position switches are controlled by the first, second and third devices for controlling the two-position switches, respectively, the delay duration of the signal of the first, second, third and fourth delay generating devices signals are not equal to each other, the switching frequency of the first and second DIP switches is higher than the switching frequency of the third DIP switch, and the frequency range of the voltage-controlled generator is in the range of the frequencies protected by the device.

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