RU2760030C1 - Method for blocking cellular communications - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: invention relates to the field of radio engineering, engaged in the creation of artificial interference in radio communications. The claimed method for blocking cellular communication includes amplification of the received broadband signal emitted by the subscriber unit, its re-emission with the introduction of a phase change according to the law of a low-frequency pseudo-random sequence in real time while maintaining the spectrum within the allowed frequencies of the subscriber unit. The phase change in the re-emitted signal is performed at a random value, which is selected from a set of sequence values ranging from 0 to (n-1)*2π/n and spaced from each other with a step of 2 π/n, and a low-frequency pseudo-random sequence determining the value phase shift, takes n integer values in the range from 0 to n-1.

EFFECT: increasing the size of the blocking zone and improving the reliability of the blocking.

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Description

The invention relates to the field of radio engineering, engaged in the creation of artificial interference in radio communications. The invention can be used to block the passage of information flows in radio communication networks and data transmission with a macro and microcellular structure.

The ubiquitous penetration of cellular communications makes it easy to use the appropriate communication channels as channels of information leakage. Therefore, the question of an effective method of blocking cellular communications from allocated premises is acutely raised.

Cellular blocking methods must meet the following technical requirements:

- you cannot make irreversible changes to blocked (subscriber) devices;

- blocking of cellular communication should not affect the functioning of any other electronic systems located both in the control area and outside it.

There is a known method of creating retransmission interference according to the RF patent No. 2123238. This analogue includes: amplification of the received broadband signal, the selection of spectral regions affected by interference and their exclusion from the signal spectrum, storing the received signal, followed by cyclic re-emission and phase manipulation according to the low-frequency binary law pseudo-random sequence. However, in order to block a large number of cellular communication devices located in the monitoring zone, an appropriate number of filtering and storage channels in the blocking device is required, which leads to extremely high complexity, up to the impossibility of real-time implementation of this method, or requires significant hardware and software resources for implementation.

The closest in essence to the claimed is the method of local suppression of mobile communications (Eurasian patent No. 006784). The prototype method includes amplification of the received broadband signal and its re-emission with phase manipulation according to the law of a low-frequency pseudo-random sequence, while phase manipulation is performed with the received and amplified signal in real time, and the spectrum of the re-emitted signal is kept within the allowed frequency band.

The phase of the interference signal changes with a low frequency and either exactly coincides with the phase of the received one, or differs by 180 degrees. Therefore, the prototype method does not allow to reliably block cellular communications in the control zone (blocking zone). As a consequence, the superposition of the interference and main signals on the receiving side differs from the pure signal by a deterministic phase shift with two fixed values, albeit determined randomly at random times.

The pseudo-random sequence that determines the phase jumps is low-frequency, and therefore the introduced errors are of a group nature (tens to hundreds of bits of information). Since the phase shift is the same for the entire group of errors, it is possible to programmatically correct the errors introduced into the useful signal. For example, it is possible to introduce some redundancy into the transmitted signal with additional special sequences and, restoring these sequences, calculate the introduced phase shift and, as a consequence, correct errors. There are other ways to correct errors of this kind. When a deterministic phase interference is introduced, a group of phase shifts (in this case, two phase modifications) remain stable for a long time (depending on the mutual displacements of the receiver and transmitter). This means that the calculated error is applicable for correction for a sufficiently long time (hundreds of milliseconds - tens of seconds).

The objective of this invention is to improve the reliability of blocking cellular communications in a certain area in the absence of influence on subscriber terminals of cellular networks that are outside the blocking zone, as well as on electronic devices in the blocking area that are not subscriber terminals of cellular networks.

This problem is solved by means of a method for blocking cellular communications, including amplification of the received broadband signal emitted by the subscriber unit, its re-emission with the introduction of a phase change according to the law of a low-frequency pseudo-random sequence in real time while maintaining the spectrum within the allowed frequencies of the subscriber unit, characterized in that the phase change in the re-emitted signal is performed on a random value, while the random value is selected from a set of sequence values ranging from 0 to (n-1) * 2p / n and spaced from each other with a step of 2p / n, where n is an integer, and the low-frequency pseudo-random sequence determining the phase shift value takes n values in the range from 0 to n-1.

To change the phase in the re-emitted signal, a controlled multi-position phase switch and a control pseudo-random sequence generator can be used, while the controlled multi-position phase switch can be controlled from the control pseudo-random sequence generator.

In the proposed method of blocking cellular communication, the phase of the generated interference signal is changed not by phase manipulation (as in the prototype, where two values are: 0 degrees and 180 degrees), but by multi-position phase modulation (n phase values with an interval of 2p / n), while The pseudo-random sequence that controls the selection of the phase shift is not binary (two values, 0 or 1), but can take n different values (each value of the pseudo-random sequence can take one of n values from 0 to n-1).

This makes it possible to create an interference signal, the filtering of which on the receiving side is much more complicated both in software and hardware implementation than filtering interference with two values of the phase shift.

In addition, an additional result is that the implementation of the proposed method increases the radius of the blocking zone of cellular communication while maintaining the remaining parameters, since the radius of the blocking zone (for retransmission blockers) is a function of the level of the signal received for re-emission and the number of errors introduced: if at what - if the radius of the blocking zone of the received signal level is no longer enough for blocking using phase shift keying, then the multi-position modulation method (more errors introduced) is effective on a weaker signal, that is, it has a longer blocking range. The increase in the radius of the blocking zone has been confirmed experimentally. As a result, the reliability of the blocking is increased.

The claimed method makes it possible to suppress cellular communications, introducing the maximum number of uncorrectable errors into the blocked signal.

FIG. 1 shows a block diagram of a device for implementing the proposed method.

A device for implementing the method comprises a receiving antenna 1 for receiving a signal, an input band-pass filter 2, a high-frequency amplifier 3, a controlled multi-position phase switch 4, a generator 5 of a control pseudo-random sequence, an output power amplifier 6 and a re-emitting antenna 7. In this case, the output of the receiving antenna 1 is connected to the input of the input band-pass filter 2, the output of which is connected to the input of the high-frequency amplifier 3, the output of which is connected to the high-frequency input of the controlled multi-position phase switch 4. The control input of the controlled multi-position phase switch 4 with the possibility of obtaining a control signal is connected to the generator 5 of the control pseudo-random sequence, the output of the controlled multi-position the phase switch 4 is connected to the output power amplifier 6 and the re-emitting antenna 7 to emit the re-emitted signal.

The difference from the device that implements the prototype method is that the control switch 4 generator 5 is configured to generate a control pseudo-random sequence from a set of sequence values ranging from 0 to (n-1) * 2p / n and spaced from each another with a step of 2p / n, where n is an integer. In this case, the phase switch 4 is multi-position, i.e. is configured to change the phase of the signal to a random value determined by the generator 5 of the pseudo-random control sequence from a plurality of sequence values.

The inventive method is implemented as follows.

Directional receiving antenna 1 (this can also be a group of directional antennas necessary to create complex boundaries of the monitoring zone, i.e., cellular blocking zones) receive the signal of the subscriber terminal emitted from the blocking zone.

The signal received by the antenna 1 from the subscriber terminal passes the necessary band-pass filtering by the input band-pass filter 2 and is amplified by the normalizing high-frequency amplifier 3, after which it is fed to the high-frequency input of the controlled multi-position phase switch 4.

The control input of the phase switch 4 receives a control signal from the generator 5 of the control pseudo-random sequence.

Depending on the value of the control signal acting at the control input of the phase switch 4, at the high-frequency output of the phase switch 4, a signal is generated that is phase-shifted relative to the input by the angle k * 2π / n, where n is the number of possible values of the control pseudo-random sequence, and k is an integer indicating the value of this sequence at the current time.

For example, if the pseudo-random sequence can take one of 12 values (from 0 to 11), then the phase shift of the output signal of the phase switch 4 relative to the signal at the high-frequency input will be determined as k * 30 °. The signal received from the high-frequency output of the multi-position phase switch 4 is amplified by the output power amplifier 6 and is emitted by the re-emitting antenna 7.

Due to the presence of the generator 5 of the multi-position pseudo-random sequence and the switch 4, which controls the phase, it is possible to obtain an interference signal with a variable phase shift value relative to the intrinsic signal of the blocked device, and this value is not binary, but randomly takes one of n values, where n is the number of values of the control pseudo-random sequence.

The base station antenna receives a signal from a blocked subscriber unit and an interference signal from a re-emitting antenna 7 of a device that implements the claimed method. A mixture of blocked and blocking signals is fed for further processing, i.e. for processing, the base station equipment receives a signal "affected" by phase interference. In this case, group errors are inevitable (the number of symbols in a group is determined by the ratio of the cycle duration of the applied pseudo-random sequence to the duration of the information bit), moreover, if with binary phase manipulation the errors can be easily corrected with relatively simple correction algorithms, then with multi-position phase manipulation the correction algorithms become many times more complicated, which significantly increases the likelihood of a disconnection already at the stage of organizing the connection.

The inventive method was tested in a manner similar to testing the method according to the prototype patent.

First, the circuit was assembled as presented in Eurasian patent No. 006784 describing the prototype. The filter was tuned to the 1920-1980 MHz frequency band, i.e. the check was carried out in the UMTS range (uplink). The pseudo-random sequence generator frequency was set to 5 kHz. The power supplied to the re-radiating antenna was 30 dBm (1 W), and the input sensitivity (from the receiving antenna) was minus 60 dBm. The whip band (1920 - 1980 MHz) receiving and re-emitting antennas with a circular directional pattern were used. The receiving antenna was installed in the center of the controlled room (hall for static tests of aircraft structures 90 * 70 m), the re-radiating antenna was on the roof of the hangar. The Huawei P Smart Z smartphone was selected as a test device, forcibly set to the "3G only" mode. Repeated attempts were made to establish a connection both by the activity of the test device and by the activity of the external subscriber (no difference in the results was observed).

The following experimental results were obtained: zone of confident blocking - within a radius of 11 meters from the installed receiving antenna (out of several hundred attempts to establish communication, there were no successful connections); unstable communication zone - radius from 11 to 15 meters (establishing communication is possible, but it is unstable in nature with the possibility of breaking at an arbitrary moment in time); stable communication zone - further 15 meters from the location of the receiving antenna.

Then was assembled a diagram corresponding to the scheme of the proposed method (Fig. 1). The parameters of the amplifiers, filters, antennas, as well as the location of the receiving antenna 1 and the transmitting antenna 7 were set the same as in the first experiment. The only difference was in the modulation scheme. We used a phase switch 4 for 16 phase shift values and a pseudo-random sequence generator 5 with the same generation frequency (5 kHz) with numerical values of k at the output ranging from 0 to 15. The experimental results are as follows: a zone of confident blocking - within a radius of 19 meters from the installation site of the receiving antenna 1; unstable communication zone - within a radius of 19 to 26 meters; stable communication zone - further 26 meters from the location of the receiving antenna.

Thus, along the blocking radius, the proposed method is 1.7 times more effective than the prototype method. The technical result consists in the fact that the method allows to provide more reliable blocking of cellular communication in the protected area, while outside the blocking zone there is no influence on cellular communication. An additional technical result consists in increasing the size of the blocking zone with the same communication parameters, i.e. with the same characteristics and operating conditions of the terminal and the mobile station, amplifiers, filters, antennas, with the same location of the receiving and transmitting antennas.

Claims (4)

1. A method of blocking cellular communication, including amplification of the received broadband signal emitted by the subscriber device, its re-emission with the introduction of a phase change according to the law of a low-frequency pseudo-random sequence in real time while maintaining the spectrum within the allowed frequencies of the subscriber device, characterized in that the phase change in the re-emitted signal is performed on a random value, while the random value is selected from a plurality of sequence values ranging from 0 to (n-1) * 2

/ n and spaced apart from each other with a step of 2

/ n, and the low-frequency pseudo-random sequence determining the phase shift value takes n integer values in the range from 0 to n-1. 2. The method according to claim 1, wherein a controlled multi-position phase switch and a control pseudo-random sequence generator are used to change the phase in the re-emitted signal, wherein the controlled multi-position phase switch is configured to be controlled from the control pseudo-random sequence generator. 3. The method of claim 1, wherein the reception of the ballband signal is performed using a plurality of directional receiving antennas pre-oriented to establish a cellular blocking area. 4. The method of claim 1, wherein the signal re-emission is performed using a plurality of directional re-emitting antennas pre-oriented to establish a cellular blocking area.

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