RU2282309C1 - Device for masking electromagnetic channels of leakage of speech signals of sound amplification equipment - Google Patents

Abstract

FIELD: technology for creating artificial interference for masking speech information in industrial network of alternating current.

SUBSTANCE: device (dwg. 1) contains rectifier 2 and, connected serially, noise signal generator 4, noise signal power amplifier 5 and emitter 6, in noise signal amplifier 5, mode B or AB is implemented, between rectifier 2 and power chain of noise signal generator 4 and power amplifier of noise signal, impulse automatic-compensation voltage stabilizer 8 is inserted, at output of which upper frequency filter is mounted, lower cut frequency of which is higher than upper frequency of audible spectrum, but lower than clock frequency of impulse automatic-compensation voltage stabilizer 8.

EFFECT: increased protection of sound amplification equipment from possible electromagnetic leakage of sound information along power chains.

2 dwg

Description

The field of technology.

The invention relates to the field of creating artificial interference to mask voice information in an industrial AC network.

The prior art.

It is known that the value of economic, political, scientific and technical information is many times greater than the value of material objects. Therefore, means of protection against unauthorized leakage of information of state, defense, scientific, technical and business content are extremely relevant.

In addition to organizational measures that prescribe certain rules of conduct for personnel, sophisticated technical tools are used to protect meaningful information. In particular, to reduce the leakage of information on acoustic and radio channels, on the telephone network, on the power circuits of the equipment used, etc. apply special schemes for masking information signals, reducing the possibility of their unauthorized listening. For example, "Device for countering the unauthorized operation of wired portable devices and informative hindrances in the LGSh-220 power supply network" (passport TU-6379-005-31056649-2002, PPSh laboratories, certificate of the State Technical Commission of the Russian Federation No. 742 dated April 7, 2003); Rotkevich V. and Rotkevich P. "Measurement technique for radio reception", M .: Communication, 1969, pp. 374-381.

In the work of Khorev A.A. "Methods and means of searching for electronic devices for intercepting information", Moscow: Ministry of Defense of the Russian Federation, p. 24 presents examples of network bookmarks that are installed in electrical outlets, in extension cords, in equipment powered by AC power, or directly into a power line. Bookmarks are designed to remove voice information. Voice amplification equipment should be protected through the leakage channel through the power supply network. Without taking protective measures, the amplification equipment makes a reaction to the network in accordance with the amplified signals, which makes it possible to isolate them from the network, i.e. the possibility of information leakage. The use of network filters and network equivalents in this frequency range almost does not weaken the electrical signals. Network filters for sound frequencies are very bulky and provide a fairly low attenuation (of the order of 5-10 dB) in the range of 100-10000 Hz, which is clearly not enough.

Another area of information protection by technical means is the creation of artificial interference - masking signal generators whose power is many times greater than the power of information leakage signals. This significantly reduces the ability to detect and receive information.

The present invention is an improvement in this direction. The usual block diagram of a camouflage device is given, for example, in the book of Rotkevich V. Rotkevich P. "Measurement technique for radio reception", M .: Communication. 1969 (p. 458-461, Fig. 5.21. It contains a noise generator, the output signal of which (if necessary, with amplification) is supplied to the load, which is usually a radiating antenna. In this case, both the generator and amplifier, if used, are powered by AC mains through a rectifier with a smoothing low-pass filter.It is usually performed on multi-link CLC elements.In addition, between the output of the generator and the load, a line filter is included to prevent spurious leakage of information signals from the load to the power network and in reverse The direction.

The described device is closest to the claimed by most essential features, therefore, selected as a prototype.

The apparatus voice masking device comprises a noise signal generator, the output of which through an amplifier is connected to an antenna, the generator being connected to an industrial AC network via a low-frequency LC filter.

The prototype device operates as follows. After connecting the rectifier to the industrial AC network, its voltage is supplied to the input of the rectifier, rectified by the rectifier, fed to the power filter - a low-pass filter, it is filtered, then fed to the generator, which starts to generate a noise signal. This signal, amplified by an amplifier, also connected to the power supply filter of the rectifier, enters the load (antenna), which emits a powerful electromagnetic noise signal on the air, masking the spurious, unwanted radiation of sound amplification equipment, the inventive device is intended for noise reduction. The device works effectively in cases where masked equipment is powered by autonomous power sources. It prevents or substantially reduces the leakage of information over the air.

However, when powered by masked equipment from a common industrial AC network, information leakage is possible not only over the air, but also through the indicated common industrial AC networks.

The mechanism of formation of these leakage channels can be as follows.

The change in the current consumption of especially powerful amplifiers in accordance with the speech information causes a corresponding change in the AC network. Naturally, the specified voice information can be isolated from the AC network (outside the protected room) for unauthorized eavesdropping.

The prototype device in this case does not mask the signals of information leakage generated, for example, in the above manner, through an industrial power supply network. The signals of the noise generator emitted into the air mask only the electromagnetic leakage channel.

The most obvious two ways to address this shortcoming:

a) to supply equipment protected from leaks only from autonomous power sources, i.e. without using a public industrial network. But this is not always possible and quite expensive.

b) introduce into the power circuit of each protected equipment a line filter that suppresses the speech signal, which requires significant additional costs (see, for example, page 8, Fig. 11c, d and f in the book by V.G. Kostikov and E.M. Parfenov . and Shakhnova VA "Sources of power supply of electronic means. System engineering and design". Textbook for universities, 2nd ed., Moscow, Hot line - Telecom, 2001). Network filters for suppressing the speech range should have large inductances, so in practice they attenuate it by no more than 10 dB, which is clearly not enough to prevent information leakage. In particular, the surge protector contained in the prototype circuit is practically useless in the audio range.

Objectives of the invention.

The objective of the invention is to increase the protection of sound amplification equipment from the possibility of electromagnetic leakage of sound information through power circuits from an industrial AC network.

The solution of the problem.

The problem is solved in that in the known device for masking the electromagnetic channels of the leakage of speech signals of sound-reproducing equipment powered by an industrial AC network, comprising a rectifier and series-connected noise signal generator, noise signal power amplifier and emitter, and the generator and amplifier power circuits connected to the rectifier , significant changes have been made, namely: mode B or AB is applied in the noise power amplifier, between the rectifier and the generator power circuit and a power amplifier noise pulse introduced Autocompensation voltage stabilizer, wherein the stabilizer is mounted on the output high-pass filter whose cutoff frequency above the upper audible frequency range, but below the clock frequency of the switching regulator.

To increase the effectiveness of camouflage, it is better not to shield the pulse self-compensation stabilizer.

The inventive task - the introduction of a powerful noise component of the current into the industrial AC network - was solved by two inextricably linked technical findings: the creation of a powerful current source in shape similar to the generated noise signal, and the proposal of a simple way of introducing it into the industrial AC network.

The essence of the first solution is to apply mode B to the amplifier. In this mode, the instantaneous amplitude of the current passing through the amplifier is almost directly proportional to the instantaneous amplitude of the signal it amplifies. Thus, in our case, when amplifying a noise signal, a current identical to the amplified noise signal will pass through the amplifier power circuit. Naturally, in the AB mode, this dependence of the passing current on the amplified signal is somewhat smoothed out. Incidentally, in mode A it is generally absent.

The second solution is to connect a noise signal power amplifier to an industrial AC network via a pulse self-compensating voltage stabilizer. As you know, such a voltage regulator consumes current from an industrial network, the instantaneous values of which are proportional to the instantaneous values of the current of its load. In our case (amplification of a noise signal), when a noise signal amplifier is powered through a pulse self-compensating voltage stabilizer, the latter will consume a current from the industrial network that corresponds in shape to the current of the amplified noise signal.

To eliminate the short circuit of this current through the stabilizer filter, a high-pass filter is applied, the lower cutoff frequency of which is higher than the upper frequency of the audible spectrum, but lower than the clock frequency of the pulse stabilizer.

Thus, the proposed changes in the device for masking speech signals made it possible by very simple means to introduce a powerful noise signal into the industrial AC network, the frequency composition of which is close to the composition of the generated noise signal. The latter, as you know, masks the signals of the entire audible spectrum.

Disclosure of the invention.

The invention is illustrated by two figures, which show examples of structural diagrams of a device for masking a speech signal (Fig. 1) and a pulse self-compensating voltage regulator for the noise generator and the noise power amplifier (Fig. 2).

The following notation is used in the figures:

1 - industrial AC network, 2 - mains voltage rectifier, 3 - low-pass filter, 4 - noise signal generator, 5 - noise amplifier, 6 - noise emitter (e.g. antenna), 7 - amplification equipment, 8 - pulse self-compensating supply voltage stabilizer, 9 - key stage, 10 - pulse transformer, 11 - output rectifier, 12 - high-pass filter, 13 - reference voltage source, 14 - comparator, 15 - pulse-width modulator, 16 - PWM signal amplifier, 17 - master sawmill generator signal,

The masking device (figure 1) works as follows. When it is turned on, the voltage of the industrial AC network 1 is supplied to the rectifier 2, which rectifies it, the obtained rectified voltage is supplied to the pulse self-compensation stabilizer 8. The voltage stabilized by unit 8 supplies the noise signal generator 4 and the noise signal power amplifier 5. The generator 4 is excited, it starts to generate a noise signal, which, after amplification by the amplifier 5, emits an emitter 6. The emitted noise signal (electromagnetic field generated in the ether) has a power that is many times higher than the power of possible electromagnetic radiation of masked equipment 7, which is powered from AC network 1 through rectifier 2 and low-pass filter 3.

As for masking the signals in the power circuit, this is due to the special mode of the noise signal power amplifier and the introduction of a pulse self-compensation voltage stabilizer between the rectifier and the power amplifier. This is explained in more detail below.

Pulse self-compensation stabilizer 8 voltage operates as follows. The voltage of the industrial AC network 1 through the rectifier 2 is supplied to the input of the key stage 9, the second control input of which receives the opening pulses supplied from the output of the amplifier 16 of the PWM signal. Upon receipt of each unlocking pulse, the key stage 9 is unlocked and through it the primary winding of the pulse transformer 10 (connected in series in the key stage 9) flows a current pulse that creates a pulse voltage in the secondary winding of the transformer 10 with a frequency of the master oscillator 17, which continuously generates sawtooth pulses with a frequency 20-30 kHz. The duration of the current and voltage pulses of the pulse transformer 10 is automatically regulated by the feedback circuit. This feedback circuit removes the pulse output voltage from the output of the pulse transformer 10 and compares it in the comparator 14 with a predetermined constant reference voltage created by a separate low-power rectifier or battery 13. The comparator 14 generates at its output a periodic sequence of sawtooth voltages, the rise rate of each of which is proportional the amplitude difference of each pulse of the pulse transformer 10 and the reference voltage 13. This sequence of sawtooth pulses cos input to pulse width modulator 15 (PWM modulator), which converts this sequence of sawtooth pulses in corresponding sequence of rectangular pulses whose width is proportional to the instantaneous amplitude of the consumed current. The resulting PWM signal through a power amplifier 16 PWM signal is fed to the control input of the key stage 9, unlocking it for the duration of each pulse. The output pulse voltage of the key stage 9 through a pulse transformer 10 is supplied to the output rectifier 11 and the high-pass filter 12, the output of which is the output of the pulse stabilizer 8, which feeds the power amplifier 5 of the noise generator 4.

Since the mode B (or AB) of the operation of the power amplifier 5 of the noise signal is selected, the instantaneous values of the current consumed by it are proportional to the amplified noise signal. Those. opening and locking of the key stage 9, connected directly to the rectifier 2 of the industrial AC network, will also repeat the instantaneous values of the noise signal. Note that the high-pass filter has a lower cutoff frequency above the upper frequency of the audible spectrum - so as not to distort the shape of the masking current in the AC network, but lower than the clock frequency of the pulse stabilizer - to smooth out the ripple of the rectified voltage.

In other words, a current flows in the industrial AC network 1, the spectral shape of which repeats the spectral shape of the generated noise signal.

Naturally, the flow of a current of this form in the industrial AC network 1 has the same masking effect on the signals of a possible leakage of information through it, which produces the signals emitted by the antenna on the electromagnetic signals of information leakage over the air.

Thus, the application of class B or AB mode in the power amplifier of a noise generator and its power supply from an industrial AC network through a pulse self-compensation stabilizer with a high-pass filter at the output made it possible to introduce a powerful masking signal into an industrial AC network in an extremely simple and cheap way.

Industrial applicability.

The claimed device is easily marketable by well-known and long-mastered by industry circuitry and structural means. Rectifiers, filters, generators and amplifiers are performed traditionally. A pulse self-compensation stabilizer can be performed, for example, in accordance with the recommendations of the Guidelines "Power supply for radio devices", St. Petersburg State Academy of Aerospace Instrumentation, St. Petersburg, 1995, pp. 27-32.

The applicant manufactured and tested the claimed device. The test results showed that the protection of the equipment from unauthorized leakage of sound information along the power supply circuit is increased by a factor of 2–3, depending on the power of the speech signal amplified by masked sound amplifying equipment.

At the same time, the cost of changes and additional funds turned out to be incomparably lower in comparison with the known solutions to this problem, and the efficiency was much higher.

Thus, in our opinion, the claimed device meets all the criteria of the invention - it is new, non-obvious and industrially applicable.

Claims (1)

A device for masking the electromagnetic channels of the leakage of speech signals of sound amplification equipment powered by an industrial AC network, comprising a rectifier and series-connected noise signal generator, noise signal power amplifier and emitter, characterized in that the B or AB mode is used in the noise signal power amplifier between the rectifier and the power circuit of the noise generator and the noise amplifier is a pulse self-compensating voltage regulator, during which a high-pass filter is installed, the lower cutoff frequency of which is higher than the upper frequency of the audible spectrum, but lower than the clock frequency of the pulse self-compensation voltage stabilizer.

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