RU2790273C1 - Method and device for information protection of an aperture random antenna - Google Patents

Abstract

FIELD: protection of confidential information.

SUBSTANCE: invention relates to the protection of confidential information and can be used to protect radio engineering systems covered by the term "random antennas". The essence of the claimed group of inventions lies in the fact that a device is placed in the aperture of a random antenna in the form of a semiconductor panel rotated by a rotary device, which is capable of deflecting the radiation of an information signal of an aperture random antenna protected by a low-energy interference generated by the panel, which reduces the level of the information signal and increases the "interference/signal" ratio at the place of the intended location of technical means of interception the information signal of the aperture random antenna. In this case, the device includes a modulating noise signal generator and a nonlinear re-emitting surface in the form of a set of modulated diode elements located at fixed distances from each other and interconnected by metal solid or lattice plates, and the modulated diode elements forming a nonlinear re-emitting surface, on the one hand, are galvanically connected to an aperture random antenna, which is made of in the form of a metal window grating, on the other hand – to two metal solid or lattice plates parallel to the surface of the aperture random antenna, which are made in the form of two triangles oriented towards each other with their sharp vertices, and the output of the modulating noise signal generator is connected to two sharp vertices of metal solid or lattice plates, while metal plates and the aperture random antenna are located close to each other so that to ensure maximum electromagnetic coupling between them.

EFFECT: present invention enables to increase the efficiency of the protection of the aperture of a random antenna by reducing the level of strength of the EC (t) field of the confidential information signal and increasing the "noise/signal" ratio in the area of the intended placement of the hacker's intercepting equipment.

3 cl, 8 dwg

Description

The invention relates to the field of confidential information protection (CI) and can be used to protect radio engineering systems, united by the term "random aperture antennas".

To ensure the protection of CI, it is important to identify and consistently block all technical leakage channels: through open space and through connecting lines extending from protected premises (PZP) into the external environment. Examples of PZP are premises (office offices, meeting rooms and booths, conference rooms) designed to work with CI during meetings, negotiations, etc. Examples of connecting lines are power, ground, burglar and fire alarm wire systems; cable lines of external and internal communication; pipes of ventilation and central heating systems; metal parts of load-bearing structures in buildings, etc.

In accordance with the classification of random antennas [1-2], examples of aperture random antennas (ASA) can be “leakage apertures” of CI in the form of windows, doorways, ventilation and technological openings, gaps, slots, etc. [3], which are sources of an electromagnetic field (EMF) in the environment surrounding the PZP and carrying CI to the intended locations of the attacker's technical means of interception (TSM). Since many reliable and universal methods of passive protection of CI (“sealed” electromagnetic shielding, grounding, filtering of CI signals [4-5]) are not applicable to protect ASA, the main and most promising means in this case is active protection of CI using various kinds of intentional interference (barrage noise, imitation aiming [8-9]). The following methods of active protection of CI are known, based on the use of deliberate interference, designed to “suppress” CI signals by energy means (for noise interference) or by causing maximum information damage (for imitation interference)U _WITH (t) in all available and potentially possible channels of leakage, in order to make it difficult for an attacker to intercept and process CI using the TSP he has [1-2, 4, 6]:

- linear noise , which is implemented using a noise generator that sends a signalU _P (t) to all interconnecting lines to be protected;

- spatial noise , which means the creation of an EMF with a field strength levelE _P (t) correspondingU _P (t), with a structure and characteristics that ensure the protection of the CI signalU _WITH (t) with field strengthE _WITH (t) from interception through leakage channels;

- code noise – used when it is impossible to use other types of active protection related to EMF;

- self-noise , which is a specific type of computer noise, computers that have ever stood next to each other work in such a way that the EMF of their CI signals distort each other, or one computer operates in a multiprogram mode, when processing an intercepted CI signal in order to extract CI by an attacker is difficult.

The closest in technical essence is an effective and versatile method of spatial noise [6, p. 188, fig. 8.9] (prototype of the proposed invention), which, in relation to the conditions of the problem being solved, provides for the placement of N emitters of intentional interference (IPP) in the PZP, providing information protection of the PZP, including ASA.

However, the main disadvantage of the prototype method is the ability to reduce the effectiveness of ASA protection by using known methods by an attacker to increase the noise immunity of receiving signals of any particular type (analog, digital) when processing an additive mixture of signal and interferenceE _WITH (t) +E _P (t) [7]. To ensure effective protection of CI levelsE _P (t) should be large enough, which is associated with the deterioration of the electromagnetic compatibility of the radio equipment used and the increase in the environmental hazard to the environment (personnel, CT users, the population) due to the EMF factor. This is largely determined by the fact that "leakage apertures" emit CI signals.E _WITH (t) quasi-uniformly in all directions, including in the area of the alleged locations of the attacker's TSP, to ensure the necessary "interference / signal" ratio, within which it is necessary to increaseE _P (t).

The technical result of the invention is to increase the effectiveness of ASA protection by reducing the level of field strengthE _WITH (t) an information CI signal and an increase in the "interference / signal" ratio in the area of the proposed location of the attacker's TSP. An additional result is the improvement of the electromagnetic compatibility of the radio equipment used and the reduction of the environmental hazard to the environment (personnel, CT users, the public) in terms of the EMF factor of the ASA protection system by reducing the field strength levelsE _P (t) IPP while providing a fixed "interference/signal" ratio.

The technical essence of the proposed method for protecting an aperture random antenna using a system of deliberate interference emitters is different in that a device in the form of a semiconductor panel rotated by a rotary device is placed in the aperture of the random antenna, which is capable of rejecting the radiation of the information signal of the aperture random antenna, protected by the low-energy noise generated by the panel, which provides a decrease in the level of the information signal and an increase in the "interference / signal" ratio at the location of the intended location of the technical means for intercepting the information signal of the aperture random antenna.

Fig. 1 illustrates a prototype method used to secure an ACA.

Fig. 2 illustrates the proposed ACA protection method.

Fig. 5 illustrates the scheme of practical application of the considered methods of ASA information protection.

The known prototype method is carried out as follows.

Fig. 1 shows ACA as a rectangle S _A on a surface S ₀ in a rectangular primary x coordinate system; y ; z the information protection of which is carried out using the IPP system (for simplicity, it is shown as a single IPP with a round blackened aperture S _P ). Dimensions of ACA to be protected 2 X _m ×2 Y _m ; dimensions of the zone S _Z of the alleged location of the attacker's TSP 2 X _Z ×2 Y _Z in a rectangular system of secondary coordinates x _z ; yz _; z _z at a distance z ₀ from the SA at an arbitrary point z _S . The ASA aperture is excited by a CI signal with a field strength E _C (the passage of the CI signal into the ASA aperture is shown as a solid thickened arrow); the field strength of the CI signal at the point z _S is equal to E _C1 (the passage of the CI signal to the point z _S is shown as a set of solid thin arrows). This reflects the fact that, in reality, the ASA is excited by a signal with a rather complex composition and structure (out of phase, multipath, coming from different directions, etc.), so its designation with a single arrow is conditional. The field strength of the IPP at the point z _S is equal to E _P1 (interference radiation is shown as a set of dashed thickened arrows). With the exception of these designations, the description of the known method and TSP [1-2 6-8] does not need additional explanation.

The proposed method is carried out as follows.

Unlike the prototype method, the proposed method of protection involves placing in the aperture of the ACA device in the form of a semiconductor panel rotated by a rotary device, which is capable of rejecting the radiation of the information signal of the aperture random antenna, protected by the low-energy noise generated by the panel, which ensures a decrease in the level of the information signal and an increase in the ratio " interference/signal" at the location of the intended location of technical means for intercepting the information signal of the aperture random antenna.

Fig. 3 illustrates the scheme of application of the proposed method of protecting ASA using the IPP system (for simplicity, one IPP is shown in the diagram), where the attacker’s TSP highlighted by a dashed line represents N receivers of the CI signal PR-1 ... PR- N and a computer circuit for processing the CI signal KS , forming, together with the receivers, a system of N -fold diversity reception; the field strength levels of the CI signal and the IPP are denoted as E _C ( t ) and E _P ( t ), respectively. The proposed method is universal and simple, it allows you to increase the efficiency and environmental friendliness of the ASA information protection.

From the prior art methods and means of low-energy protection of random antennas are known, including ASA [9-13]; options for the implementation and use of nonlinear semiconductor surfaces in order to organize covert communication [5-6], as well as rotary devices [14-16] for mechanical and electromechanical remote control [17-20], which cannot be directly applied to achieve technical result of the proposed method. Therefore, for its implementation, a device for ASA information protection is proposed.

Device for information protection of aperture random antenna

Fig. 4 illustrates the operation of the prototype device in ACA protection.

Fig. 5 illustrates the principle of operation of the proposed device in the formation of low-energy interference.

Fig. 6 shows the first variant of the proposed device for ASA information security.

Fig. 7 shows the second variant of the proposed device for ASA information protection.

Fig. 8 demonstrates the principle of operation of the rotary device as part of the proposed device for ASA information protection.

Diagram Fig. 4 illustrates a known method of protecting a random antenna 1 using a system of jamming emitters (IPI) - for simplicity, one IPP 2 is shown here; and also 3 – N CI signal receivers; 4 - computer circuit (CS) for processing the CI signal, which, together with the receivers, forms a system of N -fold diversity reception, highlighted by a dashed line as a single TSP; 5 - M repeaters of the CI signal connected through M amplitude and (or) angle modulators 6 to jamming generators 7 . The device that implements this method is the prototype of the present invention [8].

According to FIG. 4, the information protection of a random antenna 1 is carried out by the SMPS 2 system, which acts as a source of deliberate interference, as a result of which a mixture of the CI signal and interference is formed, which arrives at M radio repeaters 5 under the influence of MP U _MP ( t ) created by amplitude and (or) angular modulators 6 under the influence of noise interference generators 7 . In this case, stochastic AM is carried out by changing the active components R _MT ( t ), and stochastic AM - by changing the reactive components X _MT ( t ) of complex resistances Z _MT ( t ) = R _MT ( t ) + j X _MT ( t ) introduced by the repeaters 5 into the radio paths of the CI leakage channels.

The disadvantage of the prototype is the impossibility of its use for information protection of the ASA in the form of a metal window grill and a fragment of a reinforced concrete wall (floor, ceiling) of the PZP, since it is not advisable to place CI signal repeaters between the ASA and the attacker's TSP both inside the PZP and outside it in this case. . Firstly, this is due to the fact that a metal window grill and a fragment of a reinforced concrete wall (floor, ceiling) are located on the border of the PZP, beyond which the external environment begins - where to ensure effective masking, safety and covert monitoring of the performance of CI signal repeaters, as well as any other elements of the ASA information security system is impossible. Secondly, when CI signal repeaters are placed inside the PZP, their operation will negatively affect the electromagnetic safety of workplaces of CI users. Thirdly, the interference generated during the placement of repeaters of the CI signal inside the PZP will pass through the ASA to the external environment with inevitable additional attenuation over the air at the “Repeaters - ASA” section. Fourthly, considering a fragment of a reinforced concrete wall (floor, ceiling) of the BFZ as an ASA is due to the possibility of ultra-wideband CI signals penetrating through such obstacles: for example, from a computer at frequencies from 10 Hz or less to 4 GHz or more.

The technical result of the invention is to increase the efficiency of information protection of the ASA in the form of a metal window grill and a fragment of a reinforced concrete wall (floor, ceiling) of the PZP due to their combination with noise interference generators and CI signal modulators implemented in the form of NPP, when placed in close proximity from the ASA surface and providing maximum (electromagnetic, capacitive) coupling between them.

The technical essence of the first embodiment of the information protection device for an aperture random antenna using a modulating noise signal generator and a non-linear re-radiating surface in the form of a set of modulated diode elements located at fixed distances from each other and interconnected by means of metal solid or lattice plates is that that the modulated diode elements forming a non-linear re-radiating surface are, on the one hand, galvanically connected to an aperture random antenna, which is made in the form of a metal window lattice, on the other hand, to two metal solid or lattice plates parallel to the surface of the aperture random antenna, which are made in in the form of two triangles oriented towards each other with their sharp vertices, and the output of the modulating noise signal generator is connected to two sharp vertices of metal solid or lattice plates, while met Allic plates and aperture random antenna are located close to each other in such a way that maximum electromagnetic coupling takes place between them.

The technical essence of the second embodiment of the information protection device for an aperture random antenna using a modulating noise signal generator and a non-linear re-radiating surface in the form of a set of modulated diode elements located at fixed distances from each other and interconnected by means of metal solid or lattice plates is that that the modulated diode elements and the output of the modulating noise signal generator are galvanically connected to two metal solid or lattice plates made in the form of two strips parallel to each other and an aperture random antenna, which is made in the form of a fragment of a reinforced concrete wall (floor, ceiling) of the room to be protected , while the metal plates and the aperture random antenna are located close to each other in such a way that the maximum capacitive and electromagnetic coupling takes place between them.

The interaction diagram of the noise noise generator 7 , the CI signal and noise modulator 6 implemented in the form of NPP, and the ACA 1, shown in Fig. 5 is extremely simple to implement - since all of the listed elements are structurally combined and represent a single device for information protection of the ASA.

The proposed device operates as follows.

The first embodiment of the proposed ASA information security device in the form of a metal window grill, shown in the diagram of Fig. 6, in addition to ASA 1 and a noise interference generator 7 , it includes modulated diode elements 6 that form NPP, as well as two triangular metal plates 8 , with diode elements 6 on one side galvanically connected to ASA 1 , on the other hand - to plates 8 . On the re-emitting system as part of ASA 1 ; diode modulators 6 and triangular plates 8 are affected by the electromagnetic field of the CI signal, the sources of which are inside the PZP. Generator 7 , connected to two sharp tops of triangular plates 8 , supplies a modulating signal U _MP ( t ) to the specified system of elements, due to which stochastic modulation of the CI signal is carried out: AM due to a change in the active components R _MP ( t ) and stochastic PA - due to a change reactive components X _MP ( t ) of complex resistances Z _MP ( t ) = R _MP ( t ) + j X _MP ( t ) introduced by diode elements 6 into the radio path of the CI leakage channel. The method of connecting diode elements 6 to ACA 1 and metal plates 8 can also be inductive or capacitive, which does not play a special role - it is only important that, firstly, the electromagnetic connection of elements 1 be as high as possible; 6-8 in the diagram of FIG. 6, and secondly, their re-radiating ability - which are determined by the electrical dimensions and the degree of mutual proximity of the ACA 1 and metal plates 8 ; the number and parameters of the diode elements 6 , as well as the level of the modulating signal U _MP ( t ).

Analysis shows [7; 9; 16] that the proposed device provides low-energy information protection of the ASA - since for given indicators of the effectiveness of protecting the CI outside the PZP, the level of the total electromagnetic field inside the PZP is significantly less than with spatial noise. At the same time, unlike the prototype method, the proposed device is specifically designed for information protection of a typical ASA in the form of a metal window grille.

ASA protection device in the form of a fragment of a reinforced concrete wall (floor, ceiling) PZP, shown in the diagram of Fig. 7 differs from the considered first variant in that the metal plates 8 are made in the form of two parallel strips parallel to the ASA 1 and placed in close proximity to it - in this case, there is a capacitive coupling between the indicated elements of the re-radiating system, since the plates 8 are galvanically attached to metal reinforcement ACA 1 in this case is not possible. The second embodiment of the proposed device has no other differences. A typical implementation of a rotary device [19] is illustrated in Fig. 8.

LITERATURE

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17. Patent RU 171448U1. Device for automatic orientation of the solar battery, from 2016-05-20.

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19. Patent E05D15/5.2 Tilt and turn fittings for opening both vertically and horizontally. Appl. 2003-11-27, publ. 07/20/2008.

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Claims (3)

1. A method for information protection of an aperture random antenna using a system of emitters of deliberate interference, characterized in that a device in the form of a semiconductor panel rotated by a rotary device is placed in the aperture of the random antenna, which is capable of rejecting the radiation of the information signal of the aperture random antenna, protected by the low-energy noise generated by the panel, which provides a decrease in the level of the information signal and an increase in the "interference / signal" ratio at the location of the intended location of the technical means for intercepting the information signal of the aperture random antenna. 2. A device for implementing a method for information protection of an aperture random antenna according to claim 1, including a modulating noise signal generator and a nonlinear re-radiating surface in the form of a set of modulated diode elements located at fixed distances from each other and interconnected by means of metal solid or lattice plates , characterized in that the modulated diode elements forming a non-linear re-radiating surface are, on the one hand, galvanically connected to an aperture random antenna, which is made in the form of a metal window lattice, on the other hand, to two metal solid or lattice plates parallel to the surface of the aperture random antenna, which are made in the form of two triangles oriented towards each other with their sharp vertices, and the output of the modulating noise signal generator is connected to two sharp vertices of metal solid or lattice plates, while the metal the plates and the aperture random antenna are located close to each other in such a way that the maximum electromagnetic coupling takes place between them. 3. The device according to claim 2, characterized in that the modulated diode elements and the output of the modulating noise signal generator are galvanically connected to two metal solid or lattice plates made in the form of two strips parallel to each other and an aperture random antenna, which is made in the form of a fragment reinforced concrete wall, or floor, or ceiling of the room to be protected, while the metal plates and the aperture random antenna are located close to each other in such a way that maximum capacitive and electromagnetic coupling takes place between them.

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