RU2755489C1 - Radio-controlled apparatus blocker - Google Patents

Abstract

FIELD: radio equipment.

SUBSTANCE: invention relates to means of combating explosive objects equipped with radio fuzes by blocking unsanctioned transmission of control information by radio fuzes over a radio channel, and can also be used for protection against unsanctioned transmission of any information over a radio channel in a wide range of previously unknown radio frequencies. The apparatus comprises a first 1, a second 2, a third 3 and a fourth 4 non-linearly changing periodic voltage generators, wherein each generator provides a specific amplitude range, a first 5, a second 6, a third 7 two-input controlled switches, a voltage-controlled oscillator 8 (VCO), a bandpass filter 9, a power amplifier 10 and a transmitting emitting antenna 11, a control apparatus 12, an inverter 13, a binary counter 14, a bandpass filter and apparatus 15 for synchronisation of linearly changing voltage generators, the output of the apparatus 15 for synchronisation of linearly changing voltage generators is connected to the synchronisation inputs of the linearly changing voltage generators 1, 2, 3 and 4.

EFFECT: technical result is the increased probability of guaranteed radio suppression.

1 cl, 6 dwg

Description

The invention relates to a means of dealing with mines and other explosive objects with radio fuses. and is designed to protect against radio-controlled explosive devices by blocking unauthorized transmission of information to control radio fuses over a radio channel, and 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.

Known protection devices that can be used to prevent the triggering of radio fuses, for example [1], containing a series-connected frequency shaper, a broadband power amplifier and a broadband antenna system, creating a barrage in a wide frequency band in the form of amplified "white" noise. In this and similar devices, the radiated interference power at each particular suppressed frequency is small, since the integral transmitter power is "smeared" over the entire wide spectrum of frequencies, as a result of which only very low-power unauthorized information transmitters can be suppressed.

Known device for blocking radio fuses, containing several (n) of the same type of modules, each of which includes a series-connected frequency former, amplifier and antenna, while all modules simultaneously operate in non-overlapping sub-bands of the protected frequency range [2]. 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 n times increased integral radiation power, 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.

A device for blocking radio fuses [3] (prototype) is known, containing n frequency shapers, a switch, a pseudo-random pulse train generator, 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.

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 wide 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 means for blocking radio fuses is to increase the probability of guaranteed radio suppression at the same energy density of the interference signal in the protected range.

The technical result is achieved due to the fact that the device for blocking radio fuses, containing the first generator of nonlinearly varying voltage and a voltage-controlled generator, a power amplifier and an antenna, are introduced

second, third and fourth nonlinear voltage drivers, three two-input controlled switches, control device, inverter, binary counter, bandpass filter, synchronization device for nonlinear voltage drivers,

the outputs of the first and second nonlinear voltage shapers are connected to the first and second signal inputs of the first two-input switch, the outputs of the third and fourth nonlinear voltage shapers are connected to the first and second signal inputs of the second two-input switch, the outputs of the first and second two-input switch are connected to the first and second signal the inputs of the third two-input switch, the output of the third two-input switch is connected to the input of a voltage-controlled generator, the output of which is connected to the input of the band-pass filter, the output of which is connected to the input of the power amplifier, the output of which is loaded onto the transmitting antenna, the output of the control device is connected to the control input of the second two-input controlled switch and with the input of the inverter, the output of which is connected to the control input of the first two-input controlled switch and to the input of the binary counter, the output of the binary count The switch is connected to the control input of the third two-input controlled switch, while the switching frequency of the first and second two-input controlled switch of the key is 3-122 kHz, and the conversion factor of the binary counter is two.

New features that ensure the achievement of a technical result are additionally introduced

second, third and fourth nonlinear voltage drivers, three two-input controlled switches, control device, inverter, binary counter, bandpass filter, synchronization device for nonlinear voltage drivers,

the outputs of the first and second nonlinear voltage generators are connected to the first and second signal inputs of the first two-input switch, the outputs of the third and fourth nonlinear voltage generators are connected to the first and second signal inputs of the second two-input switch, the outputs of the first and second two-input switches are connected to the first and second signal the inputs of the third two-input switch, the output of the third two-input switch is connected to the input of a voltage-controlled generator, the output of which is connected to the input of the band-pass filter, the output of which is connected to the input of the power amplifier, the output of which is loaded onto the transmitting antenna, the output of the control device is connected to the control input of the second two-input controlled switch and with the input of the inverter, the output of which is connected to the control input of the first two-input controlled switch and to the input of the binary counter, the output of the binary counter The sensor is connected to the control input of the third two-input controlled switch.

This technical solution, together with new features, provides:

universality of suppression of signals with all types of modulation,

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.

The device uses a well-known frequency sweep method that allows high power to be emitted at each frequency or near frequencies sequentially in time. In this case, at a certain frequency f (t), a signal of the required power sufficient for reliable protection is generated and emitted, and this frequency itself, for a time interval depending on the number n of frequency shapers and the time T of the frequency sweep by one frequency shaper, changes over the entire range of protected frequencies , "running through" all values from bottom to top.

This technical solution is aimed at increasing the probability of guaranteed radio suppression in the protected range by interleaving the frequency ranges of the interference signal with its equal energy density, increasing the speed of the interference harmonic along the frequency sweep and increasing the energy impact on a greater number of nearby frequencies of adjacent bands.

FIG. 1 shows a block diagram of the proposed device,

in fig. 2 shows the division into two sub-bands of the range of protected frequencies,

in fig. 3 shows the division into four sub-bands of the frequency range to be protected,

in fig. 4 - a sequence of generated radiated frequencies in an arbitrary time interval (conditionally),

in fig. 5 is a sequence of generated radiated frequencies in the next after an arbitrary time interval in FIG. 4 (conditionally),

in fig. 6 - dependence of the output voltage of the formers of a periodic varying voltage in an arbitrarily taken time interval (conventionally).

The device contains the first 1, second 2, third 3 and fourth 4 generators of nonlinearly varying periodic voltage (Fig. 1), each of which provides its own amplitude range (Fig. 6), the first 5, second 6, third 7 two-input controlled switches (Fig. . 1), generator 8, voltage controlled (VCO), bandpass filter 9 for the entire range of protected frequencies from the lower frequency fn to the upper frequency fw, power amplifier 10 and transmitting radiating antenna 11, control device 12, inverter 13, binary counter 14, a band-pass filter, and a device 15 for synchronizing the nonlinearly varying voltage drivers, the output of the device 15 for synchronizing the nonlinearly varying voltage drivers is connected to the synchronization inputs of the nonlinearly varying voltage drivers 1, 2, 3 and 4.

The outputs of the first 1 and second 2 nonlinear voltage generators are connected to the first and second signal inputs of the first 5 two-input switch, the outputs of the third 3 and fourth 4 nonlinear voltage generators are connected to the first and second signal inputs of the second 6 two-input switch, the outputs of the first 5 and second 6 two-input switches are connected to the first and second signal inputs of the third two-input switch 7, the output of the third two-input switch 7 is connected to the input of a voltage-controlled oscillator 8, the output of which is connected to the input of the band-pass filter 9, the output of which is connected to the input of the power amplifier 10, the output of which is loaded on transmitting antenna 11.

The output of the control device 12 is connected to the control input of the second two-input controlled switch 6 and to the input of the inverter 13, the output of which is connected to the control input of the first two-input controlled switch 5 and to the input of the binary counter 14 with a conversion factor equal to two, the output of the binary counter 14 is connected to the control input third two-input controllable switch 7.

The output of the device 15 synchronization of the non-linearly varying voltage shapers is connected to the synchronization inputs of the shapers 1, 2, 3 and 4 of the linearly varying voltage.

The switching frequency of the first and second two-input controlled switch of the key is 3-122 kHz, and the conversion factor of the binary counter is two.

The operation of the claimed device for blocking radio fuses is carried out as follows.

Ramp drivers 1, 2, 3, and 4 generate periodic signals as shown in FIG. 6.

The first 5, the second 6, the third 7 two-input controlled switches sequentially in time transmit fragments of the output signals from the voltage shapers 1, 2, 3 and 4.

A voltage controlled generator (VCO) 8 generates a signal whose frequency f is continuously changing over a time interval T according to the law determined by the periodic voltage generator 1, 2, 3 and 4 of FIG. 5.

The signal from the output of the VCO 8 is fed to the input of the band-pass filter 9. The band-pass filter 9 of the protected frequency range from the lower frequency fn to the upper frequency fb filters out high-order harmonics arising from switching the switches. The output signal from the bandpass filter 9 goes to the power amplifier 10, where it is amplified and arrives at the transmitting antenna 11.

The switching frequency of key 6 is 3-122 kHz, and the duty cycle of the switching signal of key 6 is 1/2. The choice of the key switching frequency values is due to the width of the suppressed communication channels and is sufficient to ensure significant deformations or violations of the information part of the suppressed communication signals.

This solution is equivalent to the presence of two signals in different segments, one of which is in the lower part of the protected range, and the other - in the upper one. In this case, the amplifier always works in optimal mode without compression.

All other things being equal, the device has a higher travel speed of the interference harmonic signal over the protected range and a higher specific fragment density of the suppressed signal in the entire protected range, and a higher spectral density of the interference harmonic signal.

This improves the effectiveness of radio jamming.

Thus, the proposed tool, due to a new set of features and a new algorithm of operation, provides a higher efficiency of radio suppression.

Sources of information

1. Ivliev S., Maistrenko N. et al. Search and disposal of explosive devices. - M .: Fund "For Economic Security", 1996.

2. Petrenko E.S., Linok A.A., Yakubchik A.Yu. Device for blocking radio fuses, patent N 2100752 dated 11/22/96, MKI F41H 11/12, publ. BI N 36, h. 11, 1997, p. 391.

3. Battalov A.M., Gordon O.I., Konoplev V.A., Odnopalov I.A. Device for blocking radio fuses patent N 2131645 dated 1998-05-26, MKI F41H 11/12, H04K 3/00.

Claims (1)

A device for blocking radio fuses, containing a first nonlinear voltage generator and a voltage controlled generator, a power amplifier and an antenna, characterized in that the second, third and fourth nonlinear voltage generators are introduced into it, three two-input controlled switches, a control device, an inverter, a binary counter, bandpass filter, synchronization device for nonlinearly varying voltage shapers, outputs of the first and second nonlinearly varying voltage shapers are connected to the first and second signal inputs of the first two-input switch, outputs of the third and fourth nonlinearly varying voltage shapers are connected to the first and second signal inputs of the second two-input switch, the outputs of the first and second two-input switch are connected to the first and second signal inputs of the third two-input switch, the output of the third two-input switch is connected to the input of the voltage controlled generator, the output of which is connected to the input of the bandpass filter, the output of which is connected to the input of the power amplifier, the output of which is loaded onto the transmitting antenna, the output of the control device is connected to the control input of the second two-input controlled switch and to the input of the inverter, the output of which is connected with the control input of the first two-input controlled switch and with the input of the binary counter, the output of the binary counter is connected to the control input of the third two-input controlled switch, the output of the synchronization device for the nonlinearly varying voltage generators is connected to the synchronization inputs of the first, second, third and fourth nonlinearly varying voltage generators, while the switching frequency of the first and second two-input controlled switch of the key is 3-122 kHz, and the conversion factor of the binary counter is two.

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