RU2295197C1 - Method for electromagnetic protection of premises - Google Patents

Abstract

FIELD: radio engineering; protection of premises against unwanted access to secret information.

SUBSTANCE: electromagnetic protection of premises is provided by means of shielding chamber whose walls are made in the form of three-layer metal-insulator-metal structure inserted between metal layers; insulator is divided into cavities isolated from one another by walls covered with double-ended radio-absorbing coating, electromagnetic radiation interference being provided within each cavity. In addition, similar radiation intensity of secret-information containing signal is afforded and masking interference acting in case of poor shielding of premises is ensured.

EFFECT: enhanced reliability of secret information active protection.

1 cl, 4 dwg

Description

The invention relates to radio engineering and can be used to protect premises from unauthorized access to confidential information (CI) by means of electromagnetic radiation (EMP) created by equipment designed to transmit, receive and process CI during its operation.

Known are active methods of protecting KI by creating EMR interference in the environment [1] and passive methods of protecting KI associated with shielding by EMR of individual units and devices, equipment complexes, communication lines, as well as rooms in which equipment designed for transmission is installed, reception and processing of CI [2-3].

The closest in technical essence is a method of protecting electromagnetic radiation from electronic reconnaissance [4] (prototype of the invention), which involves the use of a shielding chamber with walls made of a three-layer metal-insulator-metal structure, and the creation of an electromagnetic field masking interference in the volume of the dielectric enclosed between conductive layers. When the camera is in good condition, the prototype provides passive protection of electromagnetic radiation by means of EMI shielding; if the camera malfunctions (micro-slots and holes appear in its walls), active protection is implemented because simultaneously with the electromagnetic radiation of the signal containing the electromagnetic radiation, masking interference emits outside the camera.

The disadvantage of the prototype is the lack of reliability of the active protection of KI, due to the uneven nature of the excitation of random micro-slots (holes) in the walls of the camera with a signal source containing KI, and a source of masking interference. The spatial structure of the EMP in the volume of the dielectric between the conducting layers corresponds to the standing wave regime, since the boundary conditions must be satisfied on the metal surface [5]. The bundles (nodes) of the conduction currents on the metal walls of the chamber corresponding to the signal containing the CI and masking noise at the same frequencies within the used frequency band may not coincide, therefore the same micro-slots (holes) will emit in surrounding space with different intensities. As a result, the ratio between the EMR levels generated by the signal containing the CI and the masking interference may not be sufficient to provide reliable protection for the CI. To avoid this, it is necessary to increase the power of the source of masking interference (in order to ensure the protection of IC in the worst case), which leads to an increase in the total level of electromagnetic radiation and environmental degradation in the environment.

The solution to the problem is to ensure a more uniform (and, as a result, more uniform) nature of the distribution of conduction currents, exciting random micro-slots (holes) in the chamber walls, for a signal containing KI and masking interference. To this end, in the proposed method, the volume of the dielectric between the conductive layers is proposed to be divided into a number of cavities (for example, corresponding to six chamber walls), isolated from each other by walls with a two-sided radar absorbing coating, and to create an EMR masking interference inside each cavity.

The technical result of the invention is to increase the reliability of active protection of CI by providing the same radiation intensity of a signal containing CI and masking interference in case of a malfunction of the shielding chamber (violation of the screening of the room). At the same time, an improvement in the ecological cleanliness of the premises by the EMR factor is achieved, since there is no need to use the EMR of masking interference with a level that provides reliable protection for the KI in the worst case.

The essence of the invention lies in the fact that the electromagnetic protection of the room is carried out by using a shielding chamber with walls in the form of a three-layer metal-dielectric-metal structure and creating electromagnetic radiation of interference in the volume of the dielectric enclosed between the metal layers, a distinctive feature is the implementation of the chamber walls in in the form of cavities isolated from each other by walls with a two-sided radar absorbing coating, and the creation of electromagnetic radiation interference inside zhdoy cavity.

Figure 1 in a schematic view shows the design of the cavity, which is an integral part of the shielding chamber, made in accordance with the proposed method of protecting the premises.

Figure 2 shows the structure of the EMP in a cavity with conductive (solid line) and radar absorbing (dashed line) walls.

Figure 3 illustrates the unequal random nature of the excitation of a microcit in the standing wave mode by a signal containing KI and masking interference in the General case.

Figure 4 illustrates the nature of the excitation of the micro-slit signal containing KI, and masking interference in the case of using the present invention.

The implementation of the proposed method of electromagnetic protection involves the installation of a shielding chamber in the room, the walls of which are cavities (see Figure 1) with metal upper 1 and lower 2 walls, left 3, rear 4, right 5 and front 6 side walls made of radar absorbing material, with the device 7 create inside the cavity of the EMP masking interference.

The method is as follows.

If all the elements of the shielding chamber are in good condition (joints, inputs, technological openings, doors), passive protection of the CI is carried out by shielding by the EMR of the room in which the equipment is installed, which is used to transmit, receive and process CI. In case of violation of the shielding and depressurization of the chamber by EMR (due to corrosion, accidental mechanical ruptures of the shielding surfaces, deliberate damage) in the places of occurrence of microcracks (holes), an EMR signal containing KI and masking interference simultaneously occurs. At a given frequency, the ratio between their levels in the environment depends on the ratio between the amplitudes of the conduction currents perpendicular to the microgaps, which determine the amplitudes of the bias currents within it (conduction currents flow along metal surfaces bordering an insulator in a three-layer chamber - similar to a metal waveguide [5] ) In the prototype, the ratio between the indicated amplitudes of the bias currents corresponds to the structure of standing waves and is random, since the methods of excitation of the microgap with a signal containing CI (by passing through the screen or through the communication holes [5]) and masking noise (using a special excitation unit [4 ]) differ from each other. Therefore, a situation is not ruled out when the ratio between the EMP levels of the signal containing the CI and the masking interference is insufficient for reliable protection (the energy criterion for assessing the reliability of the CI protection is, for example, the magnitude of the “interference / signal” ratio by the EMF power flux density in the environment) .

In the proposed method, the volume of the dielectric between the conductive surfaces in the shielding chamber of a three-layer metal-dielectric-metal structure is divided into cavities (in a room with rectangular cavity surfaces, they may have the shape of parallelepipeds shown in FIG. 1, their total number may be six - by the number rectangular surfaces). The upper 1 and lower 2 walls of the cavity are metal, left 3, rear 4, right 5 and front 6 side walls are made of radar absorbing material - thus, all cavities are separated from each other by surfaces with a two-way radar absorbing coating. Inside the cavity there is an excitation unit 7 EMP masking interference.

Figure 2 shows the diagrams of the distribution of the amplitude of the vector of the electric field E at a frequency where the size of the shielding chamber along the y axis corresponds to 1.5 wavelengths for the prototype (solid line 7) and the proposed method (dashed line 2). It should be emphasized that regardless of the constructive implementation of the prototype (when dividing the internal volume into cavities, installing reflective or radiolucent partitions, filling with a solid dielectric, etc.), the nature of the EMP distribution within the internal volume of the shielding chamber will remain uneven. Uniform along the y axis, the nature of the distribution of the amplitude of the vector E in the proposed method (see FIG. 2) is achieved by eliminating waves reflected from the side (left 3 and right 5 in FIG. 1) walls of the shielding chamber.

3 shows a diagram of the conduction current J _s, corresponding to the signal containing KI, and a current J _n corresponding masking interference, in the worst case, when on the surface of the shielding chamber S in the place of occurrence of microcracks S _u occur antinode current J _c and the current node J _p In accordance with the above, in this case, the level of the EMP signal containing the CI will significantly exceed the level of the EMP masking interference, since the last microslip S _u does not emit at all. It should be emphasized that the situation illustrated by Figure 3 is random in place, time and frequency, and in this sense, any "adjustment" is not amenable to.

In contrast to it, in the proposed method (see Figure 4), the diagrams of the currents J _c and J _p , due to the elimination of reflected waves when using radar absorbing coatings, are almost uniform, therefore, when a microgap S _u occurs in any place, it will be excited with the same intensity as a signal containing KI, and masking noise. This leads to the required "interference / signal" ratio, regardless of the random circumstances leading to the formation of micro-slots (holes) in the walls of the shielding chamber.

Thus, the proposed method improves the reliability of the active protection of CI in case of a malfunction of the shielding chamber (violation of the shielding of the room). Improving the environmental cleanliness of the premises by the factor of EMR is achieved due to the fact that there is no need to use the EMR of masking interference with a level that provides reliable protection of IC in the worst case, shown in Fig.3.

LITERATURE

1. Tsvetkov VV et al. Electronic warfare: radio intelligence and radio countermeasures. M .: Publishing. MAI, 1998 .-- S.99.

2. Grodnev I.I. Electromagnetic shielding in a wide range of frequencies. M .: Communication, 1972. - P.76.

3. Petrakov A.V., Lagutin B.C. Leak and protection of information in telephone channels. M .: Energoatomizdat, 1997. - P.186; 207-208.

4. RF patent for the invention No. 2190303 "Method for the protection of electromagnetic radiation from electronic intelligence". Etc. from 02/05/2001, issue 09/27/2002.

5. Volman V.I., Pimenov Yu.V. Technical electrodynamics. M .: Communication. - S. 273.

6. Eisenberg G.Z., Yampolsky V.G., Tereshin O.N. VHF antennas. Part 2. M .: Communication, 1977. - P.177.

Claims (1)

A method of electromagnetic protection of a room, including the use of a shielding chamber with walls in the form of a three-layer metal-dielectric-metal structure and the creation of electromagnetic interference radiation in the volume of the dielectric enclosed between the metal layers, characterized in that the dielectric volume is divided into cavities isolated from each other walls with a double-sided radar absorbing coating, and electromagnetic interference radiation is created inside each cavity.

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