RU2439707C1 - Device for prevention of false data entry to controlled objects - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: device enables to extend the functionality of known devices for alarm not only about condition of controlled objects, but also the possibility of false data entry of start sequence of the device from the part of active infractor, thereby preventing the device blocking in case of unauthorised action on the line of communication.

EFFECT: increased reliability of control over the protected objects, the line of communication and data exchange between them, on the basis of coding and creating control code in the start mode.

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Description

The invention relates to imitation protection devices of controlled objects and communication lines and can be used to protect controlled objects.

A known system for centralized notification of violation of a guarded object, including object devices installed on objects and connected to the subscriber line using signal relay contacts, a switching and broadcast device installed on the cross of an automatic telephone exchange and containing a distribution and control unit, an amplitude unit selections and linear kits connected to subscriber communication lines using the contacts of linear relays, and a receiving device installed in pu nte of protection (see USSR author's certificate No. 383091, class G08B 25/02).

This system provides security for facilities with individual telephone sets. The system, after taking the object under protection, monitors the subscriber line connecting the protected object with the device for switching and broadcasting to the open and short circuit. If a violation has occurred at the facility, the signal relay contact included in the subscriber line opens and thereby sends an alarm signal to the switching and broadcasting device, which then arrives at the receiving device.

There is another device for signaling the state of monitored objects, containing communication lines, transmission units installed on the objects, each of which consists of a code lock connected to the input of the control and reception unit, a translator containing a linear unit, an amplifier, a selector, a decoder, the first the output of which is connected to the first input of the linear block, a counter, a notification type memory block, an information transmission permission block and a pulse generator, the output of which is connected to a counter containing a print block, a block indications and electric clocks (see USSR author's certificate No. 374646, class G08B 25/02).

The device provides the issuance of security and fire alerts, allows the materially responsible person to automatically arm the object with an electrocode lock and disarm it with an acknowledgment of the performance of these functions both at the object and at the receiving device at the security point.

There is another device for signaling the state of controlled objects, consisting of a transmission unit containing a code lock, a control and reception unit, a high-frequency generator, a signal selection unit, communication lines, a translator containing a clock, a serial binary counter, a decoder, a unit the memory of the type of notices, the block for permitting the transmission of information, an amplifier, a pulse width selector, a comparison unit, an analyzer, a buffer memory unit, a control unit, a transceiver Single linear block control unit, receiving unit information, comprising a printing block, the electric clock, the control unit, the transceiver, the buffer memory unit, memory unit, memory unit, light panel, the block indicating line connection state with the translator

(see USSR author's certificate No. 691906, class G08B 25/02, 1979).

The device provides the issuance of security and fire notices, allows the materially responsible person to automatically arm the object and disarm it with an electrocode lock, acknowledging the performance of these functions both at the object and at the receiving device at the security point, and round-the-clock security of the object telephone connection.

However, these systems do not allow detecting the substitution of the transmission unit when introduced into the communication line between the transmission unit and the translator.

Also known is another device for simulating controlled objects with increased reliability, consisting of a sensor included in the transmission unit, comprising a matching device, modulator, demodulator, block for converting a serial combination into n-bit parallel, a memory block, a starting sequence memory block, a comparison block , second pseudorandom sequence generator (PSP-2 generator), block for converting an n-bit parallel combination into a serial, information processing device included in the translator containing a matching device, modulator, demodulator, block for converting a serial combination into n-bit parallel, a starting sequence memory block, a key generator, a first pseudorandom sequence generator (PSP-1 generator), PSP-2 generator, a control memory block values, a first storage device, a second storage device, a comparison unit, an n-bit parallel to serial combination conversion unit (see copyright certificate RU No. 2310236 C1, G08B 25/04, 2007).

However, this device, protecting the transmission unit from spoofing when introduced into the communication line, between the transmission unit and the translator, does not allow to detect falsification of the start sequence at the time of starting the device, in the conditions of an active intruder using technical means.

The aim of the invention is the development of a device for the protection of monitored objects and a communication line between objects with verification for reliability in the "Start" mode using a control code (authenticator), which allows to expand the functionality of known devices for simulating controlled objects and a communication line between them.

The technical result that can be obtained using the present invention is to increase the reliability of control over protected objects, the communication line and the exchange of data between them, based on the encoding and generation of a control code (authenticator) in the "Start" mode. This device will expand the functionality of known devices for signaling not only about the state of controlled objects, but also the possibility of falsification of the starting sequence of the device from the active intruder, thereby preventing the device from blocking during unauthorized actions on the communication line.

The technical result is achieved using a device for simulating controlled objects, comprising a signal selection unit included in the transmission unit, a signal selection unit included in the translator, a control unit included in the information reception unit, a communication line included in the transmission unit, a sensor comprising a matching device, modulator, demodulator, block for converting a serial combination to n-bit parallel, a memory block, a memory block for the starting sequence, a comparison block, a gene a second pseudo-random sequence generator (PSP-2 generator), a block for converting an n-bit parallel combination to a serial one, an information processing device included in the translator containing a matching device, a modulator, a demodulator, a block for converting a serial combination to n-bit parallel, a start memory block sequences, key generator, first pseudo-random sequence generator (PSP-1 generator), PSP-2 generator, control value memory block, first memory A device, a second storage device, a comparison unit, an n-bit parallel to serial combination conversion unit, the output of the starting sequence memory block included in the sensor connected to the first input of the comparison unit, the first output of the comparison unit connected to the reset input to the initial state of the unit memory and reset input to the initial state of the PSP-2 generator, the second output of the comparison unit is connected to the first input of the PSP-2 generator, the output of the PSP-2 generator is connected to the input of the n-bit conversion unit parallel parallel to serial combination, the output of the n-bit parallel to serial combination conversion unit is connected to the modulator input, the memory block output is connected to the second input of the comparison unit and to the PSP-2 generator start input, the modulator output is connected to the first input of the matching device, the block output converting a serial combination into an n-bit parallel is connected to the input of the memory block, the first output of the matching device is connected to the input of the demodulator, the second output of the matching the device is connected to the first input of the signal selection unit, which is part of the transmission unit, the first output of the signal selection unit, which is part of the transmission unit, is connected, via a communication line, to the first input of the signal selection unit, which is part of the translator, the second output of the signal selection unit included in the transmission unit is connected to the second input of the matching device, the first output of the starting sequence memory block, which is part of the information processing unit, is connected to the first input of the conversion unit the n-bit parallel combination into serial, the second output of the starting sequence memory block, which is part of the information processing unit, is connected to the key generator input, the second output of the n-bit parallel to serial combination conversion unit is connected to the second modulator input, the modulator output is connected to the first input of the matching device, the second output of the matching device is connected to the first input of the signal selection unit, which is part of the translator, the first output of the matching the signaling device is connected to the input of the demodulator, the second output of the signal selection unit, which is part of the translator, is connected to the second input of the matching device, the first output of the signal selection unit, which is part of the translator, is connected, via communication lines, to the second input of the signal selection unit, incoming to the transmission unit, the first output of the key generator is connected to the first input of the PSP-1 generator, the second output of the key generator is connected to the reset input to the initial state of the PSP-1 generator, the reset input to the initial the state of the control value memory block, the reset input to the initial state of the PSP-2 generator, the reset input to the initial state of the first storage unit, the output of the PSP-1 generator is connected to the input of the control value memory block and to the second input of the n-bit parallel combination conversion unit in serial, the output of the memory block of the control value is connected to the input of the PSP-2 generator, the output of the PSP-2 generator is connected to the input of the first storage device, the output of the first storage device is connected is connected to the second input of the comparison unit, the first output of the comparison unit is connected to the second input of the PSP-1 generator, the second output of the comparison unit is connected to the input of the control unit included in the information receiving unit, the output of the second storage device is connected to the first input of the comparison unit, the output of the unit converting the serial combination to n-bit parallel is connected to the input of the second storage device, the output of the demodulator is connected to the input of the conversion unit of the serial combination to n-bit pa an allelic one, and a random number generator, an adder modulo two, a control code generating device containing a storage register, an encoder, an A-encoder, a combining device, and a generator included in the transmission unit are introduced into the information processing unit included in the translator; a generator is introduced random numbers, modulo two adder, control code removal device containing a separation device, modulo two adder, A-encoder, decoder, control circuit, memory register, and the first output of the demodulator is connected to the input separation device included in the control code removal device, the first output of the separation device is connected to the first input of the adder modulo two, which is part of the control code removal device, the second output of the separation device is connected to the decoder input, the output of the A-encoder is connected to the second input of the adder by module two, the output of the adder modulo two, which is part of the control code removal device, is connected to the first input of the control circuit, the second input of which is connected to the output of the decoder, and the first and second the outputs of the control circuit are connected to the first and second inputs of the accumulation register, the first output of which is connected to the installation input of the A-encoder, and the second output of the accumulation register is connected to the first input of the adder modulo two, which is part of the sensor, the second input of the adder modulo two is connected to the first output of the RNG generator, the second output of which is connected to the third input of the accumulative register. The modulator output of the adder is connected to the first input of the serial combination to n-bit parallel conversion unit, the second input of the serial combination to n-bit parallel conversion unit is connected to the second output of the demodulator, the second output of the start sequence memory block is connected to the input of the RNG generator. The output of the random number generator included in the information processing unit is connected to the first input of the adder modulo two, the second input of which is the first output of the n-bit parallel to serial combination conversion unit, and the output of the adder modulo two is connected to the input of the accumulative register included in control code generation device, the first output of the accumulation register is connected to the encoder input, the first output of which is connected to the first input of the combining device, the second output of the encoder is connected to the first input of the A-encoder, the second input of which is the second output of the accumulation register, and the output of the A-encoder is connected to the second input of the combining device, the output of which is connected to the first input of the modulator, the second input of the modulator is connected to the second output of the conversion unit of n-bit parallel combination in serial. The output of the control unit, which is part of the information reception unit, is connected simultaneously to the inputs of the starting sequence memory unit and the random number generator included in the information processing unit.

The drawing shows a block diagram of a device for simulating controlled objects.

The device for protection of controlled objects contains a sensor 1 containing a memory block 2 of the starting sequence, a comparison unit 3, a second pseudorandom sequence generator 4 (PSP-2 generator 4), a n-bit parallel to serial combination conversion unit 5, a memory unit 6, a conversion unit 7 a serial combination into n-bit parallel, a demodulator 8, a modulator 9, a matching device 10, an information processing unit 11, comprising a starting sequence memory unit 12, an n- conversion unit 13 parallel parallel to serial, modulator 14, matching device 15, key generator 16, first pseudo-random sequence generator 17 (PSP-1 generator 17), control value memory unit 18, second pseudo-random sequence generator 19 (PSP-2 generator 19), block a first storage device 20, a comparison unit 21, a second storage unit 22, a serial combination to parallel conversion unit 23, a demodulator 24, a signal selection unit 25 included in the transmission unit 26, l communications 27, a signal selection unit 28, which is part of the translator 29, a control unit 30, which is part of the information reception unit 31, a random number generator 32, included in the information processing unit, an adder modulo two 33, a control code generating device 34, comprising a storage register 35, an encoder 36, an A-encoder 37, a combiner 38, a random number generator 39, an adder modulo two 40 included in the sensor 1, a device for removing the control code 41, comprising a separation device 42, an adder modulo two 43, A-encoder 44, decoder 45, control circuit 46, accumulative register 47, wherein the second output of the start sequence memory unit 2 is connected to the input of the RNG generator 39, the first output of the start sequence memory unit 2 included in the sensor 1 is connected to the first input of the comparison unit 3, the first output of the unit comparison 3 is connected to the reset input to the initial state of the memory unit 6 and the reset input to the initial state of the generator 4 PSP-2, the second output of the comparison unit 3 is connected to the first input of the generator 4 PSP-2, the output of the generator 4 PSP-2 is connected to the input of the block 5 converting an n-bit parallel combination to serial, the output of block 5 converting an n-bit parallel combination to serial is connected to the input of the modulator 9, the output of the memory unit 6 is connected to the input of the comparison unit 3 and to the second start input of the generator 4 ПСП-2, the output of the modulator 9 is connected to the first input of the matching device 10, the output of the block 7 converting the serial combination into n-bit parallel is connected to the input of the memory unit 6, the first output of the demodulator 8 is connected to the input of the device section 42, included in the control code removal device 41, the first output of the separation device 42 is connected to the first input of the adder modulo two 43, which is part of the control code removal device 41, the second output of the separation code 42 is connected to the input of decoder 45, the output of the A-encoder connected to the second input of the adder modulo two 43 included in the control code removal device 41, the output of the adder modulo two 43 included in the control code removal device 41 is connected to the first input of the control circuit 46, the second input which is connected to the output of the decoder 45, and the first and second outputs of the control circuit 46 are connected to the first and second inputs of the accumulator register 47, the first output of which is connected to the installation input of the A-encoder 44, and the second output of the accumulator register 47 is connected to the first input of the adder modulo two 40, the output of which is connected to the first input of block 7 converting the serial combination to n-bit parallel, the second input of block 7 of converting the serial combination to n-bit parallel is connected to the second output to the demodulator, the second output of the starting sequence memory block 2 included in the sensor 1 is connected to the input of the random number generator 39, the first output of which is connected to the second input of the adder modulo two 40, and the second output of the random number generator 39 is connected to the third input of the accumulative register 47, the first output of the matching device 10 is connected to the input of the demodulator 8, the second output of the matching device 10 is connected to the first input of the block signal selection 25, which is part of the transmission unit 26, the first output of the block selection signal 25, which is part of the transmission unit 26, is connected, through the communication line 27, to the second input of the signal selection block 28, which is part of the translator 29, the second output of the signal selection block 25, which is part of the transmission block 26 is connected to the second input matching device 10, the first output of the starting sequence memory block 12, which is part of the information processing unit 11, is connected to the first input of the n-bit parallel combination to serial conversion block 13, the second output of the starting memory block 12 the sequence included in the information processing unit 11 is connected to the input of the key generator 16, the output of the random number generator 32 is connected to the first input of the adder modulo two 33, the second input of which is the first output of the block 13 converting the n-bit parallel combination to serial, and the adder output modulo two 33 is connected to the input of the accumulative register 35 of the control code generation device 34 included in the information processing unit 11 of the translator 29, the first output of the accumulative register 35 is sub is connected to the input of the encoder 36, the first output of which is connected to the first input of the combiner 38, the second output of the encoder 36 is connected to the first input of the A-encoder 37, the second input of which is the second output of the accumulator register 35, and the output of the A-encoder 37 is connected to the second input combining device 38, the output of which is connected to the first input of the modulator 14 of the information processing unit 11 of the translator 29, the output of the modulator 14 is connected to the first input of the matching device 15, the second input of the modulator is the second output of the n- conversion unit 13 a parallel parallel combination into a serial, the second output of the matching device 15 is connected to the first input of the signal selection block 28, which is part of the translator 29, the first output of the matching device 15 is connected to the input of the demodulator 24, the second output of the signal selection block 28, which is part of the translator 29, connected to the first input of the matching device 15, the first output of the signal selection block 28, which is part of the translator 29, is connected, via a communication line 27, to the second input of the signal selection block 25, included to the transmission unit 26, the first output of the key generator 16 is connected to the start input of the PSP-1 generator 17, the second output of the key generator 16 is connected to the reset input of the PSP-1 generator 17, the reset input of the control unit 18 the reset input to the initial state of the PSP-2 generator 19, the reset input to the initial state of the first storage unit 20, the output of the 17 PSP-1 generator is connected to the input of the memory block 18 of the control value and the n-bit parallel to the second input of the conversion block 13 combination in serial, the output of the memory block 18 of the control value is connected to the start input of the generator 19 PSP-2, the output of the generator 19 PSP-2 is connected to the input of the first storage device 20, the output of the first memory device 20 is connected to the second input of the comparison unit 21, the first output the comparison unit 21 is connected to the second input of the generator 17 PSP-1, the second output of the comparison unit 21 is connected to the input of the control unit 30, which is part of the information reception unit 31, the output of the second storage device 22 is connected to the first ode of the comparison unit 21, the output of the serial combination to n-bit parallel conversion unit 23 is connected to the input of the second storage device 22, the output of the demodulator 24 is connected to the input of the serial combination to n-bit parallel conversion unit 23, the output of the control unit 30 included in the unit 31 information reception, is connected simultaneously to the inputs of the memory block 12 of the starting sequence and the random number generator 32 included in the information processing unit 11.

The device imitating controlled objects works as follows.

When a start signal is supplied from the control unit 30, which is part of the information reception unit 31, to the inputs of the RNG generator 32 and the start sequence memory block 12, the command to restore the information processing unit 11 to the initial state is received from the second output of the start sequence memory block 12, for of this, through the key generator 16, the reset command is sent to the reset inputs to the initial state of the generator 17 ПСП-1, memory block 18 of the control value, generator 19 ПСП-2, block of the first storage device 20, with ne Vågå output of the storage unit 12 receives the starting sequence stored in the block starting binary sequence at a first input of n-bit conversion unit 13 parallel to serial combination. From the first output of block 13 converting an n-bit parallel combination into a sequential starting sequence in the form of binary symbols, it enters the second input of the adder modulo two 33. The sequence of binary symbols generated by the generator RNG 32, which is part of the information processing unit 11, is fed to the first input an adder modulo two 33. The generated binary sequence as a result of summing modulo two 33 two sequences of binary characters is input to the accumulative p register 35, which is part of the device for generating the control code 34. In the accumulation register 34, the sequence of binary characters is divided into two blocks with equal lengths. From the first output of the accumulative register 35, the first block of binary symbols is input to the encoder 36, and from the second output of the accumulative register 34, the second block of binary symbols is input to the A-encoder 37. Each block of binary symbols is encoded by a linear block systematic binary noise-tolerant (n, k) code, where k is the length of the block of information symbols of the code and n is the length of the code block. In encoder 36, a block of binary checks and a block of information binary symbols are extracted from the encoded block of binary symbols. A dedicated block of check symbols from the second output of the encoder 36 goes to the first input of the A-encoder 37. A block of information symbols from the first output of the encoder 36 goes to the first input of the combiner 38. The second code block from the second output of the accumulator register 35 goes to the second input of the A-encoder 37. The A-encoder 37 generates a control code (authenticator) from the block of check characters received from the second output of the encoder 36, and the second block of a sequence of binary characters from the second output of the accumulative register 35. In the A-encoder 37, each character of the binary sequence is assigned a sequence number. Next, remember the number of the binary character of the sequence, if in the sequence of binary characters it stands in place of "1". The control code (authenticator) is formed as a sequence of stored “1” characters. The control code (authenticator) in the form of a binary sequence is input to the combining device 38. A code word is generated in the combining device 38 by concatenating the control code and the information symbol block extracted from the first binary symbol sequence block in the encoder 36. From the output of the combining device 38, the code word in the form of a sequence of binary characters is supplied to the first input of the modulator 14, the matching device 15, the signal selection block 28, which is part of the translator 29, line c Vyaz 27, the signal selection block 25, which is part of the transmission unit 28, matching device 10, demodulator 8. From the first output of the demodulator 8, the code word in the form of information symbols and a control code (authenticator) generated as a result of concatenation is input to the separation device 42 included in the device for removing the control code 41 from the composition of the sensor 1. In the separation device 42, the code word is divided into a block of information symbols and a control code (authenticator). From the second output of the separation device 42, a dedicated block of information binary symbols is fed to the input of the decoder 45, and from the first output of the separation device 42 is supplied to the first input of the adder modulo two 43 control codes (authenticator). The sequence of binary symbols formed in the generator of the RNG39 is supplied to the third input of the accumulation register 47, and from the first output of the accumulation register 47, a block of binary symbols is input to the input of the A-encoder 44 to generate a verification check code (authenticator). The generated control code (authenticator) of the verification as a sequence of stored “1” characters from the output of the A-encoder 44 is fed to the second input of the adder modulo two 43. If the output of the adder modulo two 43 to the input of the control circuit 46 receives “1” as a result of summing modulo two control codes (authenticators) and control codes (authenticators) of verification, the control circuit 46 generates a “Prohibition” signal, and a sequence of binary characters does not arrive at the input of accumulator register 47 from the output of decoder 45. If the output of the adder modulo two 43 to the input of the control circuit 46 receives "0" as a result of summing modulo two control code (authenticator) and control code (authenticator) of the test, from the output of decoder 45, through the control circuit 46, to the input of the accumulative register 47 is a sequence of binary characters. From the second output of the accumulation register 47, a sequence of binary symbols is supplied to the first adder input modulo two 40. At the same time, the sequence generated by the RNG generator 39 is fed to the second adder input modulo two 40. As a result of summing modulo two, from the output of the adder modulo two 40, the first input of the block 7 converting the serial combination into n-bit parallel receives the formed initial binary start sequence, which is recorded in the memory block 6. From the memory block In step 6, the starting sequence is sent to comparison block 3, where it is compared with the sequence stored in the starting sequence memory block 2 (the starting sequence memory blocks 2, 12 contain the same starting sequence) and, if the sequences coincide, the comparison block 3 generates a signal for installation in the initial state of the memory block 6 and the generator 4 PSP-2, thereby preparing the generator 4 PSP-2 to receive the parcel from the generator 17 PSP-1. At the same time, the starting sequence received from the memory block 12 of the starting sequence starts the key generator 16, which generates a combination of starting the generator 17 PSP-1. Formed in the generator 17 PSP-1, the first value of the binary first pseudo-random sequence (PSP-1) is stored in the memory block 18 of the control value. The first PSP-1 value stored in the memory block 18 of the control value starts PSP-2 generator 19 (the functions of generating the second pseudo-random sequence of generators 4, 19 PSP-2 are identical), the first value of the second pseudo-random sequence (PSP-2) generated by the PSP-2 generator 19 stored in the block of the first storage device 20. At the same time, the first value of the PSP-1 formed in the generator 17 PSP-1 is fed to the second input of the block 13 converting n-bit parallel to serial combination. From the second output of the block 13 converting the n-bit parallel combination to serial, to the second input of the modulator 14, from the output of the modulator 14, through the matching device 15, the signal selection block 28, which is part of the translator 29, the communication line 27, the signal selection block 25, which is part of the transmission unit 26, the matching device 10, from the second output of the demodulator 8, to the second input of the block 7 converting the serial combination into n-bit parallel. From the output of block 7 converting a serial combination to n-bit parallel, the first value of PSP-1 is fed to the input of memory block 6, where it is stored. The first PSP-1 value stored in the memory block 6 is compared in the comparison block 3 with the starting sequence permanently stored in the memory block 2. If the sequences do not match, the command to set the sensor 1 to its initial state is not generated, and the first PSP-1 value stored in the memory unit 6 gives the command to the PSP-2 generator 4 to generate a pseudo-random sequence. Formed in the generator 4 PSP-2, the first value of PSP-2 is fed to the input of block 5 for converting an n-bit parallel combination into serial and through a modulator 9, matching device 10, signal selection block 25, which is a part of transmission block 26, communication line 27, the signal selection block 28, which is part of the translator 29, matching device 15, the demodulator 24 is fed to the input of the block 23 converting the serial combination into n-bit parallel, converted in block 23 converting the serial combination The n-bit parallel first value of PSP-2 is recorded in the block of the second memory device 22. Thus, in the block of the first memory device 20, the first value of PSP-2, generated by the PSP-2 generator 19, which is part of the information processing unit 11, is stored in the second storage unit 22 stores the first PSP-2 value generated by the PSP-2 generator 4, which is part of the sensor 1. Based on the fact that the gene function 4, 19 PSP-2 uses the same gene function to generate pseudo-random sequences The pseudo-random sequence generated by the PSP-1 generator 17, the values found in blocks 20 and 22 should be the same (in the absence of unauthorized replacement of the transmission block or damage to the communication line). To check the immunity of the communication line 27 and the transmission unit 28, the values stored in the blocks 20, 22 are compared in the comparison unit 21. If the values coincide, the comparison unit 21 generates a “normal” command, which starts the generator 17 ПСП-1 to generate the next value of ПСП- one. In the event of a discrepancy between the values (violation of the imitation protection mode), the comparison unit 21 issues an alarm signal to the input of the control unit 30, which is part of the information reception unit 31.

The invention, in comparison with the prototype and other known technical solutions, has the following advantages:

- increase the immunity of the communication line in the initialization phase of the device;

- elimination of the possibility of falsification of the start sequence in the "Start" mode of the device of imitation protection by the active intruder, even when using modern technical means;

- expanding the functionality of known devices of imitation protection to monitor the status of the communication line and guarded objects.

Claims (1)

A device for imitating controlled objects, comprising a signal selection unit included in the transmission unit, a signal selection unit included in the translator, a control unit included in the information receiving unit, a communication line, a sensor included in the transmission unit containing the matching device, modulator, demodulator, block for converting a serial combination to n-bit parallel, a memory block, a memory block for the starting sequence, a comparison block, a second pseudo-random generator in series STI (PSP-2 generator), a unit for converting an n-bit parallel to a serial combination, an information processing unit containing a matching device, a modulator, a demodulator, a unit for converting a serial combination to an n-bit parallel, a starting sequence memory block, a key generator is inserted into the translator , a first pseudorandom sequence generator (PSP-1 generator), PSP-2 generator, a control value memory unit, a first storage device, a second storage device, a unit with avoniya, block conversion of n-bit parallel combination into serial, and the output of the starting sequence memory block included in the sensor is connected to the first input of the comparison unit, the first output of the comparison unit is connected to the reset input to the initial state of the memory unit and the reset input to the initial state PSP-2 generator, the second output of the comparison unit is connected to the first input of the PSP-2 generator, the output of the PSP-2 generator is connected to the input of the n-bit parallel combination conversion unit in series y, the output of the n-bit parallel to serial combination conversion unit is connected to the modulator input, the memory block output is connected to the second input of the comparison unit and to the PSP-2 generator start input, the modulator output is connected to the first input of the matching device, the output of the serial combination conversion unit in n-bit parallel is connected to the input of the memory block, the first output of the matching device is connected to the input of the demodulator, the second output of the matching device is connected to the first input of the block signals, which is part of the transmission unit, the first output of the signal selection unit, which is part of the transmission unit, is connected via a communication line to the first input of the signal selection unit, which is part of the translator, the second output of the signal selection unit, which is part of the transmission unit, is connected to the second input of the matching device, the first output of the starting sequence memory block, which is part of the information processing unit, is connected to the first input of the n-bit parallel combination conversion unit in p consequently, the second output of the starting sequence memory block, which is part of the information processing block, is connected to the key generator input, the modulator output is connected to the first input of the matching device, the second output of the matching device is connected to the first input of the signal selection block, which is part of the translator, the first output matching device is connected to the input of the demodulator, the second output of the signal selection block, which is part of the translator, is connected to the second input of the matching device, p The first output of the signal selection block, which is part of the translator, is connected via a communication line to the second input of the signal selection block, which is part of the transmission block, the first output of the key generator is connected to the first input of the PSP-1 generator, the second output of the key generator is connected to the reset input to the initial state of the PSP-1 generator, the reset input to the initial state of the control value memory block, the reset input to the initial state of the PSP-2 generator, the reset input to the initial state of the block of the first storage device, output q PSP-1 generator is connected to the input of the control value memory block and to the second input of the n-bit parallel to serial combination conversion unit, the output of the control value memory block is connected to the PSP-2 generator input, the output of the PSP-2 generator is connected to the input of the first storage device , the output of the first storage device is connected to the second input of the comparison unit, the first output of the comparison unit is connected to the second input of the PSP-1 generator, the second output of the comparison unit is connected to the input of the control unit, included in the information reception unit, the output of the second storage device is connected to the first input of the comparison unit, the output of the serial combination conversion unit into n-bit parallel is connected to the input of the second storage device, the demodulator output is connected to the input of the serial combination conversion unit into n-bit parallel, characterized in that in the information processing unit included in the translator, a random number generator (RNG), an adder modulo two, a device for generating a control code containing a storage register, an encoder, an A-encoder, a combining device, a random number generator, an adder modulo two, a device for removing a control code containing a separation device, an adder modulo two are entered into a sensor included in the transmission unit, A- an encoder, a decoder, a control circuit, a storage register, wherein the first output of the demodulator is connected to the input of the separation device included in the device for removing the control code, the first output of the separation device is connected to the first input of the adder via the module two, which is part of the device for removing the control code, the second output of the separation device is connected to the input of the decoder, the output of the A-encoder is connected to the second input of the adder modulo two, the output of the adder modulo two, which is part of the device for removing the control code, is connected to the first input a control circuit, the second input of which is connected to the output of the decoder, and the first and second outputs of the control circuit are connected to the first and second inputs of the storage register, the first output of which is connected to the installation input of the A-encoder, and in The second output of the accumulative register is connected to the first input of the adder modulo two, which is part of the sensor, the second input of the adder modulo two is connected to the first output of the RNG generator, the second output of which is connected to the third input of the accumulative register, the output of the adder modulo is connected to the first input of the block converting a serial combination to n-bit parallel, the second input of the block for converting a serial combination to n-bit parallel is connected to the second output of the demodulator, the second output is bl As the memory of the starting sequence is connected to the input of the RNG generator, the output of the random number generator included in the information processing unit is connected to the first input of the adder modulo two, the second input of which is the first output of the n-bit parallel to serial combination conversion unit, and the adder output is module two is connected to the input of the accumulative register included in the control code generation device, the first output of the accumulative register is connected to the input of the encoder, the first output of which is connected it is connected to the first input of the combining device, the second output of the encoder is connected to the first input of the A-encoder, the second input of which is the second output of the storage register, and the output of the A-encoder is connected to the second input of the combining device, the output of which is connected to the first input of the modulator, the second input of the modulator connected to the second output of the conversion unit of n-bit parallel to serial, the output of the control unit, which is part of the information reception unit, is connected simultaneously to the inputs of the start memory block th sequence and the random number included in the information processing unit.

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