RU2755522C2 - Method for information protection of distributed random antennas - Google Patents

Abstract

FIELD: information protection.SUBSTANCE: invention relates to the field of protection of confidential information; it can be used to protect radio engineering systems united by a term “distributed random antennas”. The proposed method for protecting distributed random antennas consists in the fact that it includes placing devices near the distributed random antenna that ensure the absorption of the electromagnetic field power of a confidential information signal, where small-sized resonant receiving antennas with the active load are used as the specified devices.EFFECT: increased efficiency of protecting a distributed random antenna from leakage of confidential information.1 cl, 4 dwg

Description

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

To ensure the protection of CI, it is important to identify and consistently block all technical leakage channels outgoing from the premises to be protected (PPP) into the external environment. Examples of PPPs are premises (office rooms, meeting rooms and booths, conference rooms) designed to work with CI during meetings, negotiations, conferences, etc. Examples of PCA are power supply, grounding, warning, burglar and fire alarm systems; cable lines for external, intra-office and computer communications; pipes for ventilation and central heating systems; metal parts of load-bearing structures in buildings, etc. [1].

The negative features of the channels of CI leakage through the SAR include:

- a complex and often ambiguous (unpredictable in advance) nature of the excitation associated with the transformation of the original signal created by the source of the CI (hereinafter CI signal) into CI signals diverging along the SAR. The sources of CI can be both the main (directly involved in the processing, transmission and reception of CI signals) CI equipment, and auxiliary equipment located in the PZP;

- usually, a fundamentally different nature of the propagation of the CI signal inside the PZP and the KI signals in the SAR, with the help of which the vehicles located in the PZP are connected to external publicly available equipment. As a result, the CI signals with low attenuation can go through the SAR far beyond the PZP and become available to the attacker;

- Difficulties in modeling (mathematical, physical, computer) of both sources of CI and elements of SAR;

- negative dynamics of the ecological and ergonomic characteristics of the bottomhole zone when using most of the known methods and means of eliminating the channels of IC leakage - leading to thermal, noise and electromagnetic pollution of the bottomhole zone, deteriorating the microclimate (increasing humidity and changing the air composition without ventilation), reducing the level of natural geomagnetic background, etc. .NS. Undesirable factors are also the cost, weight and dimensions of equipment for the protection of CI.

The specificity of RSA information protection systems is explained, firstly, by the fact that, in contrast to the main communication channels (through which CI signals are received by the "legal" - authorized CI consumers), thanks to the RSA, secondary channels (CI leakage channels) arise. which CI signals are sent to unauthorized CI consumers - malefactors. When organizing the protection of the main channels, the limitation is the absence of unacceptable interference for legitimate consumers of CI. When protecting PCA, this restriction does not exist, since only attackers can connect to them.

Secondly, reliable and universal methods of passive protection of CI (electromagnetic shielding, grounding, filtering [2-4]) are often inapplicable to protect SAR. Therefore, when organizing the protection of CI from leakage through the SAR beyond the PZP, it is necessary by all means, including new scientific and technical ideas, to increase its versatility and efficiency.

Known methods of active protection of CI, based on the use of signals of a special type (intentional interference), designed by the energy method (for masking noise interference) or by inflicting maximum information damage (for imitating interference) "suppress" CI signals in all available and potentially possible channels leaks to make it harder for an attacker to intercept and process CI [2-3]:

- linear noise, which is realized with the help of a noise generator, which supplies a signal to the elements of the SAR to be protected;

- spatial noise, which means the creation of an electromagnetic field within the BZP with a structure and characteristics that ensure the protection of the IC from interception through the channels of electromagnetic leakage;

- code noise, used when it is impossible to effectively use other types of protection of CI;

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

Variants of active protection of SAR with the use of different types of interference are demonstrated [10-13]. The closest in technical essence is the method of linear noise [5, p. 188, fig. 8.9] (prototype of the present invention), which, in relation to the conditions of the problem being solved, provides for the connection to the PCA through N interface devices of N generators of deliberate interference, which ensure the protection of the CI. Generators designed for linear noise are known from the prior art [6].

The disadvantage of the prototype method is the ability to reduce the effectiveness of information protection of the RSA by using the attacker known methods of increasing the noise immunity of receiving signals of any kind (analog, digital) when processing a mixture of signal and interference [12-13]. To ensure the required protection efficiency of the IC, the interference levels must be sufficiently high, which is associated with the growth of the ecological and ergonomic insecurity of the SAR protection system for the personnel and users of the IC by the electromagnetic factor.

The proposed solution provides for the rejection of active protection of the CI in favor of a protection method similar to [18], which in this case provides for the location near the SAR of M devices in the form of receiving small-sized resonant antennas (MRA) with an active load, ensuring the absorption of the power of the electromagnetic field of the CI signal within PPP.

The technical result of the proposed invention is a decrease in the levels of the electromagnetic field generated by the source of the CI signal in the CZP, which leads to a decrease in the efficiency of excitation of the SAR by the dangerous CI signal and to an increase in the efficiency of the protection of the SAR from the leakage of the CI outside the CZP. An additional result is an increase in the ecological and ergonomic safety of the PCA protection system by the electromagnetic factor due to the refusal to use active interference in the CI protection system.

The essence of the proposed method for protecting distributed random antennas, including placing devices near a distributed random antenna that absorb the power of the electromagnetic field of a confidential information signal, is that small-sized resonant antennas with an active load are used as these devices.

FIG. 1 demonstrates a prototype method for linear noise reduction of a PCA with a complex multi-storey structure, where 1 - PCA in the form of a branched network of heterogeneous connecting lines; 2 - interface device (total number N, marked with dashed lines); 3 - jammer (total number N); 4 - the source of the CI signal.

FIG. 2 illustrates the proposed method of information protection RSA, where 5 is a receiving MPA with an active load 6 (total number M), which provides absorption of the power of the electromagnetic field of the CI signal in the PZP, other designations correspond to FIG. 1.

FIG. 3 shows a diagram of the implementation of the device 4 in the form of a receiving MRA of a capacitor type (C-antenna), which ensures the absorption of the power of the electromagnetic field of the CI signal in the PZP.

FIG. 4 contains the calculated and experimental graphs characterizing the frequency dependence of the matching of the capacitor-type MPA (C-antenna) intended for use in the SAR information protection system.

The known prototype method is carried out as follows.

To the elements of the PCA 1 (see Fig. 1) through N interface devices 2 are connected N generators of intentional interference 3, which provide active protection of the IC by forming a mixture of the IC signal and interference circulating in the PCA. The disadvantage of the prototype method is the ability of an attacker to reduce the effectiveness of information protection of the PCA using known methods of increasing the noise immunity of receiving the CI signal as part of the specified mixture, if its levels are sufficient for the isolation and processing of CI [12-13]. In addition, to ensure the required efficiency of SAR protection, the interference should be sufficiently large in terms of the energy level, which is directly related to the ecological and ergonomic insecurity of the protection system for personnel and users of the CI due to the electromagnetic factor.

In order to eliminate these disadvantages, the proposed invention proposes to abandon active protection of the CI in favor of a protection method similar to [18], which provides for the location of receiving MRAs with an active load near the PCA M, providing absorption of the power of the electromagnetic field of the CI signal in the PZP.

The proposed method is carried out as follows.

In the immediate vicinity of the elements of the SAR 1 and the source KI 4 (see Fig. 2), there are receiving MRA 5 with active loads 6. The equation of the balance of the power of the electromagnetic field [7, p. 52, formula (4.1.1)] has the form P _st = P _p + dW / dt + P _Σ , where P _st is the power of third-party sources (in this case, it is the signal power of the CI source); R _p is the power of losses within the volume of the PZP (this is the power of the CI signal dissipated in active loads 6 connected to the MPA 5); dW / dt is the power that is consumed to change the electromagnetic energy of the CI signal inside the BHZ volume; P _Σ is the power of the CI signal that goes beyond the PZP. It follows that the placement of a set of MRA 5 with active loads 6 in the BZP near the SAR 1 and the source of KI 4, associated with an increase in the power losses P _p , leads to a decrease in dW / dt and P _Σ , since the power of the source KI P _st is a finite value. Accordingly, a decrease in dW / dt and P _Σ leads to a decrease in the excitation efficiency and an increase in the efficiency of information protection of the SAR.

The construction and driving circuit of the capacitor-type MPA (C-antenna) is illustrated in FIG. 3. The elements of the MRA are the unfolded plates of the capacitor C1 and C2, the capacitance between which is equal to C, as well as the inductor L = L1 + L2 with an absorbing load connected to it at points A-A in the form of an active resistance R _H.

The advantages of receiving MRAs as devices that ensure the absorption of the power of the electromagnetic field of the CI signal in the PZP are dimensions of the order of 0.1λ or less, where λ is the operating wavelength, as well as the ability to adjust to the frequency of possible leakage of the CI signal. By changing the ratio between L1 and L2, as well as with the help of additional correcting reactances [11], the MPA can be tuned to the desired frequency band with an appropriate Q-factor adjustment. The unique properties of the MPA make it possible to achieve its matching with the load according to the SWR criterion, which is impossible in short antennas with the same dimensions. The results of the study of the layout of a flat C-antenna made of foil-clad fiberglass with dimensions of 85 × 15 mm ² , designed for a frequency of 97 MHz (relative size 2.75 · 10 ^-2 λ), is shown in Fig. 4 (solid lines - the results of calculating the SWR for different versions of the layout, the dots show the experimental data). A half-wave dipole similar to the model of the C-antenna has a maximum size of about 1.5 m [10].

The proposed method is universal and simple, it is convenient for implementation and automation, it allows to increase the efficiency and ecological and ergonomic safety in terms of the electromagnetic factor of the information protection of the RSA.

LITERATURE

1. Maslov ON Theory of random antennas: the first 10 years of development and application // Antennas. No. 9 (241), 2017. - S. 37-59.

2. Buzov G.A., Kalinin S.V., Kondratyev A.V. Protection against information leakage through technical channels. M .: Hot line - Telecom, 2005 .-- 416 p.

3. Maslov ON Principles of modeling information protection systems against leakage through random antennas // Special equipment. No. 6, 2016. - S. 45-55.

4. Kechiev L.N., Stepanov P.V. EMC and information security in telecommunication systems. M .: Publishing House "Technologies", 2005. - 320 p.

5. Sobolev A.N., Kirillov V.M. Physical foundations of technical means of ensuring information security. M .: Helios ARV, 2004 .-- 224 p.

6. Product P218-1M // http://www.kalugapribor.ru/print/produce/p218_1m.html

7. Volman V.I., Pimenov Yu.V. Technical electrodynamics. Moscow: Svyaz, 1971. - 488 p.

8. Maslov O.N., Ryabushkin A.V., Shashenkov V.F. Small-sized resonant antennas // Infocommunication technologies. Vol.8, No. 2, 2010. - S. 57-67.

9. Maslov O.N. Statistical characteristics of a small-sized resonant antenna // Antennas. No. 9, 2011. - S. 62-71.

10. Maslov O. N., Ryabushkin A. V. Experimental determination of the radiation resistance of a capacitor antenna // Infocommunication technologies. T.9, No. 3, 2011. - S. 90-94.

11. Maslov O. N., Silkin A. A. Frequency characteristics of a small-sized resonant antenna with correcting reactivity // Electrosvyaz. No. 3, 2011. - S. 37-40.

12. Alyshev Yu.V., Maslov O.N., Ryabushkin A.V. Application of MIMO technology for the study of random antennas // Radiotekhnika. No. 3, 2008. - S. 61-65.

13. Alyshev Yu.V., Maslov O.N. Evaluation of the effectiveness of random antennas by the criterion of information damage // Infocommunication technologies. Vol.6, No. 3, 2008. - S. 116-125.

14. Method of information protection of a distributed random antenna // Alyshev Yu.V., Maslov ON, Shashenkov V.F. Patent RU 2470465 from 20.12.2010, publ. 12/20/2012, bull. No. 35.

15. Method of information protection in a distributed random antenna // Maslov ON, Zasedateleva PS. Patent RU 2492581 from 30.11.2011, publ. 10.09.2013, bull. No. 25.

16. Device for information protection of a distributed random antenna // Maslov ON, Shashenkov VF, Borisova IE. Patent RU 2502195 from 02.09.2011, publ. 20.12.2013, bull. No. 35.

17. Method of protecting a distributed random antenna // Maslov ON, Shcherbakova T.A. Patent RU 2503132 from 30.11.2011, publ. 12/27/2013, bull. No. 36.

18. Method of information protection of a distributed random antenna element // Maslov ON, Shashenkov V.F. Patent RU 2707385 dated 07.19.2018, publ. 11/26/2019, bull. No. 33.

Claims (1)

A method for protecting distributed random antennas, including placing devices near a distributed random antenna that absorb the power of the electromagnetic field of a confidential information signal, characterized in that small-sized resonant antennas with an active load are used as these devices.

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