RU2710471C1 - Radio-controlled lock with imitatively protected exchange of commands - Google Patents

Abstract

FIELD: radio engineering and communication.

SUBSTANCE: invention relates to the field of engineering, which is engaged in development and manufacture of various radio-controlled shut-off devices of residential and non-residential premises, safes, cabinets, gates, and can be used for protection of access to physical objects of various forms of ownership.

EFFECT: improved imitation protection of radio communication between a transponder and a stationary part responsible for access to a physical object, as well as simplified technical implementation compared to known devices.

1 cl, 2 dwg

Description

FIELD OF THE INVENTION

The present invention relates to the field of technology engaged in the development and manufacture of a variety of radio-controlled locking devices for residential and non-residential premises, safes, cabinets, gates and designed to protect access to physical objects of various ownership forms.

State of the art

A self-contained electromechanical lock for furniture with remote control is known, consisting of a locking device with a retractable pin, a stop-limiter, a remote control for the lock and a radio signal receiver from the remote control, while the locking device contains an electric motor and a system for transmitting torque from an electric motor to a pin, moreover the lock contains a photocell, a microcontroller with volatile memory for storing valid remote controls, switches for programming elements and batteries (International application WO 2011/031185 "Autonomous electromechanical lock for furniture with remote control", published on March 17, 2011).

The disadvantage of this device is the lack of security of the transmitted commands from the imposition of false data.

It is also known a device of a radio-controlled lock, consisting of a key fob, which includes a key generation and storage unit for closing and opening the lock, a close button, an open button, a transmitter with an antenna, an autonomous replaceable power source; an electronic control unit, which includes a receiving antenna, a coded signal receiver, a processor, a first memory unit, a second memory unit, a third memory unit, a common bus; power supply unit of the electronic control unit, which includes a self-healing fuse block, a transformer, a rectifier, a charger, a battery, an electronic unit power distribution switch, a battery voltage meter with a light indicator of its discharge level, an audio generator, a timer; an electromechanical drive of the lock, which includes an electric drive, a kinematic link, a locking device, a turntable for opening (closing) the lock from the inside of the door; groups of external subscribers, which include subscribers (light, alarm) (Utility model No. 73476 "Radio-controlled lock", publ. 05/20/2008).

The disadvantage of this device is also the lack of security of the transmitted commands from the imposition of false data.

A solution to the problem of ensuring the protection of transmitted commands from imposing false data can be a device to prevent unauthorized use of a vehicle through the use of pseudo-random sequences (Patent No. 2592385 “Device to prevent unauthorized use of a vehicle through the use of pseudo-random sequences", published on July 20, 2016). This device consists of two parts - stationary, including a control unit, a random number generator unit, an outgoing codegram buffer, a transponder initialization unit, bi-directional communication lines and a first pseudorandom sequence generator unit; and also from the mobile part, including a control device, an identifier memory block, an instruction counter block, a first pseudo-random sequence generator block, an initialization block, an initialization value memory block, an outgoing codogram buffer, a transceiver unit, an incoming codogram buffer, a command determination unit, alarm unit. This device allows you to increase the immunity of radio communications between the transponder and the stationary part.

Disclosure of invention

The objective of the invention is the development of a radio-controlled lock with simulated exchange of commands, which allows to ensure simulated protection of commands transmitted over a wireless communication line between the stationary part and the transponder, by adding a unique pseudo-random sequence (PSP) to the transmitted command in order to provide protection against substitution of control commands , increase the level of protection of the wireless communication line of known devices and simplify technical implementation, compared with and Vestnik devices.

The technical result, which can be obtained using the present invention, is reduced to providing imitating teams transmitted over a wireless communication line and simplifying technical implementation, compared with known devices.

The technical result is achieved using a device consisting of a transponder 1, which includes a pseudo-random sequence generator 2 (hereinafter referred to as the PSP generator), a command counter 3, a transmitter 4, an XOR operation block 5 (logical operation “exclusive OR”), a codeogram generating unit 6 , block 7, a set of formalized instructions for read-only memory (hereinafter referred to as ROM), block 8 of the unique identifier of the transponder ROM; the wireless communication line 9 and the stationary part 10 of the device, including the SRP generator 11, a cycle counter 12, a random access memory unit (hereinafter referred to as RAM) block 13 for storing the sequence number of the previous codegram, a codeogram number comparison unit 14, a RAM code number block 15, a block alarm 16, block 17 programmable read-only memory (hereinafter EPROM) of the unique identifier of the transponder, block 18 comparing the unique identifier of the transponder, block 19 of the XOR operation, the receive buffer 20 Memory, a receiver 21, a RAM 22 the decoded overheads, a system bus 23, a processor 24, a block 25 sets formalized ROM commands unit 26 supply the electronic control unit, the control unit 27, an electromechanical actuator lock, wherein

command "Management" is fed to the first input of block 7 of a set of formalized ROM commands,

the first output of the SRP generator 2 is connected to the first input of the 3 command counter, the second output of the SRP generator 2 to the first input of the XOR operation block 5,

the first output of the counter 3 teams connected to the first input of block 6 forming the codogram,

the first output of the transmitter 4 is connected to the first input of the receiver 21 using line 9 of the wireless communication,

the first output of the XOR operation unit 5 is connected to the first input of the transmitter 4,

the first output of the codogram forming unit 6 is connected to the second input of the XOR operation unit 5, the first input-output of the coding pattern unit 6 is connected to the first input-output of the unique transponder identifier of the ROM unit 8,

the first output of block 7 of the set of formalized ROM commands is connected to the second input of block 6 of the formation of the codogram, the second output of block 7 of the set of formalized ROM commands is connected to the first input of the generator 2 of the SRP,

the first output of the SRP generator 11 as part of the stationary part 10 of the device is connected to the first input of the system bus 23, the second output of the SRP generator 11 is connected to the first input of the XOR operation unit 19, the first input-output of the SRP generator 11 is connected to the first input-output of the cycle counter 12 ,

the second input-output of the counter 12 of the cycle is connected to the first input-output of the block 13 RAM storage of the serial number of the previous codegram,

the first output of the block 13 RAM storage of the serial number of the previous codegram is connected to the third input of block 14 comparing the code number,

the first output of block 14 comparing the code number is connected to the first input of the counter 12 of the cycle, the second output of block 14 comparing the number of code is connected to the first input of the signaling unit 16,

the first output of the block 15 RAM numbers of the received codegram is connected to the second input of block 14 comparing the code number,

the first output of the EPROM block 17 of the unique identifier of the transponder is connected to the first input of the block 18 comparing the unique identifier of the transponder,

the first output of the unique transponder identifier comparing unit 18 is connected to the second input of the alarm unit 16, the second output of the unique transponder identifier comparing unit 18 is connected to the second input of the system bus 23, the third output of the unique transponder identifier comparing unit 18 is connected to the first input of the RAM storage unit 13 previous codogram

the first output of the XOR operation block 19 is connected to the first input of the RAM 22 of the decoded codegram,

the first output of the receive buffer 20 of RAM is connected to the first input of the block 15 of the RAM of the code entered, the second output of the receive buffer 20 of RAM is connected to the fourth input of the system bus 23, the third output of the receive buffer 20 of RAM is connected to the second input of the XOR operation block 19,

the first output of the receiver 21 is connected to the first input of the receive buffer 20 of RAM,

the first output of RAM 22 of the decoded encoding is connected to the second input of block 18 comparing the unique identifier of the transponder, the second output of RAM 22 of the decoded encoding is connected to the third input of the system bus 23,

the first output of the system bus 23 is connected to the first input of the code number comparison unit 14, the first input-output of the system bus 23 to the first input-output of the processor 24,

the second input-output of the processor 24 is connected to the first input-output of the block 25 of a set of formalized ROM commands, the third input-output of the processor 24 is connected to the first input-output of the power supply unit 26 of the electronic control unit,

the second input-output of the power supply unit 26 of the electronic control unit is connected to the first input-output of the control unit 27 of the electromechanical lock drive.

Brief Description of the Drawings

In FIG. 1 shows a block diagram of a stationary part of a device and a block diagram of a transponder, FIG. 2 shows a diagram of a codogram.

The transponder 1 includes an SRP generator 2, a command counter 3, a transmitter 4, an XOR operation block 5 (logical operation “exclusive OR”), a codogram generating unit 6, a block 7 of a set of formalized ROM commands, a unit 8 of a unique ROM transponder identifier;

Line 9 wireless;

The stationary part 10 of the device includes an SRP generator 11, a cycle counter 12, a RAM block 13 for storing the sequence number of the previous code, block 14 for comparing the code number, block 15 for the code number for the received code, signal block 16, block 17 for the EPROM of the unique identifier of the transponder, block 18 comparing the unique identifier of the transponder, XOR operation block 19, RAM receiving buffer 20, receiver 21, decoded codegram RAM 22, system bus 23, processor 24, formalized ROM instruction set block 25, power supply unit 26 the control unit, the control unit 27 of the electromechanical drive of the lock, and

command "Management" is fed to the first input of block 7 of a set of formalized ROM commands,

the first output of the SRP generator 2 is connected to the first input of the 3 command counter, the second output of the SRP generator 2 to the first input of the XOR operation block 5,

the first output of the counter 3 teams connected to the first input of block 6 forming the codogram,

the first output of the transmitter 4 is connected to the first input of the receiver 21 using line 9 of the wireless communication,

the first output of the XOR operation unit 5 is connected to the first input of the transmitter 4,

the first output of the codogram forming unit 6 is connected to the second input of the XOR operation unit 5, the first input-output of the coding pattern unit 6 is connected to the first input-output of the unique transponder identifier of the ROM unit 8,

the first output of block 7 of the set of formalized ROM commands is connected to the second input of block 6 of the formation of the codogram, the second output of block 7 of the set of formalized ROM commands is connected to the first input of the generator 2 of the SRP,

the first output of the SRP generator 11 as part of the stationary part 10 of the device is connected to the first input of the system bus 23, the second output of the SRP generator 11 is connected to the first input of the XOR operation unit 19, the first input-output of the SRP generator 11 is connected to the first input-output of the cycle counter 12 ,

the second input-output of the counter 12 of the cycle is connected to the first input-output of the block 13 RAM storage of the serial number of the previous codegram,

the first output of the block 13 RAM storage of the serial number of the previous codegram is connected to the third input of block 14 comparing the code number,

the first output of block 14 comparing the code number is connected to the first input of the counter 12 of the cycle, the second output of block 14 comparing the number of code is connected to the first input of the signaling unit 16,

the first output of the block 15 RAM numbers of the received codegram is connected to the second input of block 14 comparing the code number,

the first output of the EPROM block 17 of the unique identifier of the transponder is connected to the first input of the block 18 comparing the unique identifier of the transponder,

the first output of the unique transponder identifier comparing unit 18 is connected to the second input of the alarm unit 16, the second output of the unique transponder identifier comparing unit 18 is connected to the second input of the system bus 23, the third output of the unique transponder identifier comparing unit 18 is connected to the first input of the RAM storage unit 13 previous codogram

the first output of the XOR operation block 19 is connected to the first input of the RAM 22 of the decoded codegram,

the first output of the receive buffer 20 of RAM is connected to the first input of the block 15 of the RAM of the code entered, the second output of the receive buffer 20 of RAM is connected to the fourth input of the system bus 23, the third output of the receive buffer 20 of RAM is connected to the second input of the XOR operation block 19,

the first output of the receiver 21 is connected to the first input of the receive buffer 20 of RAM,

the first output of RAM 22 of the decoded encoding is connected to the second input of block 18 comparing the unique identifier of the transponder, the second output of RAM 22 of the decoded encoding is connected to the third input of the system bus 23,

the first output of the system bus 23 is connected to the first input of the code number comparison unit 14, the first input-output of the system bus 23 to the first input-output of the processor 24,

the second input-output of the processor 24 is connected to the first input-output of the block 25 of a set of formalized ROM commands, the third input-output of the processor 24 is connected to the first input-output of the power supply unit 26 of the electronic control unit,

the second input-output of the power supply unit 26 of the electronic control unit is connected to the first input-output of the control unit 27 of the electromechanical lock drive.

The implementation of the invention

The technical result is achieved using a device consisting of a transponder 1, which includes a pseudo-random sequence generator 2 (hereinafter referred to as the PSP generator), a command counter 3, a transmitter 4, an XOR operation block 5 (logical operation “exclusive OR”), a codeogram generating unit 6 , block 7, a set of formalized instructions for read-only memory (hereinafter referred to as ROM), block 8 of the unique identifier of the transponder ROM; the wireless communication line 9 and the stationary part 10 of the device, including the SRP generator 11, a cycle counter 12, a random access memory unit (hereinafter referred to as RAM) block 13 for storing the sequence number of the previous codegram, a codeogram number comparison unit 14, a RAM code number block 15, a block alarm 16, block 17 programmable read-only memory (hereinafter EPROM) of the unique identifier of the transponder, block 18 comparing the unique identifier of the transponder, block 19 of the XOR operation, the receive buffer 20 Memory, a receiver 21, a RAM 22 the decoded overheads, a system bus 23, a processor 24, a block 25 sets formalized ROM commands unit 26 supply the electronic control unit, the control unit 27, an electromechanical actuator lock, wherein

command "Management" is fed to the first input of block 7 of a set of formalized ROM commands,

the first output of the SRP generator 2 is connected to the first input of the 3 command counter, the second output of the SRP generator 2 to the first input of the XOR operation block 5,

the first output of the counter 3 teams connected to the first input of block 6 forming the codogram,

the first output of the transmitter 4 is connected to the first input of the receiver 21 using line 9 of the wireless communication,

the first output of the XOR operation unit 5 is connected to the first input of the transmitter 4,

the first output of the codogram forming unit 6 is connected to the second input of the XOR operation unit 5, the first input-output of the coding pattern unit 6 is connected to the first input-output of the unique transponder identifier of the ROM unit 8,

the first output of block 7 of the set of formalized ROM commands is connected to the second input of block 6 of the formation of the codogram, the second output of block 7 of the set of formalized ROM commands is connected to the first input of the generator 2 of the SRP,

the first output of the SRP generator 11 as part of the stationary part 10 of the device is connected to the first input of the system bus 23, the second output of the SRP generator 11 is connected to the first input of the XOR operation unit 19, the first input-output of the SRP generator 11 is connected to the first input-output of the cycle counter 12 ,

the second input-output of the counter 12 of the cycle is connected to the first input-output of the block 13 RAM storage of the serial number of the previous codegram,

the first output of the block 13 RAM storage of the serial number of the previous codegram is connected to the third input of block 14 comparing the code number,

the first output of block 14 comparing the code number is connected to the first input of the counter 12 of the cycle, the second output of block 14 comparing the number of code is connected to the first input of the signaling unit 16,

the first output of the block 15 RAM numbers of the received codegram is connected to the second input of block 14 comparing the code number,

the first output of the EPROM block 17 of the unique identifier of the transponder is connected to the first input of the block 18 comparing the unique identifier of the transponder,

the first output of the unique transponder identifier comparing unit 18 is connected to the second input of the alarm unit 16, the second output of the unique transponder identifier comparing unit 18 is connected to the second input of the system bus 23, the third output of the unique transponder identifier comparing unit 18 is connected to the first input of the RAM storage unit 13 previous codogram

the first output of the XOR operation block 19 is connected to the first input of the RAM 22 of the decoded codegram,

the first output of the receive buffer 20 of RAM is connected to the first input of the block 15 of the RAM of the code entered, the second output of the receive buffer 20 of RAM is connected to the fourth input of the system bus 23, the third output of the receive buffer 20 of RAM is connected to the second input of the XOR operation block 19,

the first output of the receiver 21 is connected to the first input of the receive buffer 20 of RAM,

the first output of RAM 22 of the decoded encoding is connected to the second input of block 18 comparing the unique identifier of the transponder, the second output of RAM 22 of the decoded encoding is connected to the third input of the system bus 23,

the first output of the system bus 23 is connected to the first input of the code number comparison unit 14, the first input-output of the system bus 23 to the first input-output of the processor 24,

the second input-output of the processor 24 is connected to the first input-output of the block 25 of a set of formalized ROM commands, the third input-output of the processor 24 is connected to the first input-output of the power supply unit 26 of the electronic control unit,

the second input-output of the power supply unit 26 of the electronic control unit is connected to the first input-output of the control unit 27 of the electromechanical lock drive.

Radio-controlled lock with simulated exchange of commands works as follows.

The interaction between the stationary part 10 and the transponder 1 occurs using the codogram (Fig. 2). The codogram includes (from left to right):

1) codogram number 28 - this field is intended to store the codogram number generated by the counter of 3 commands;

2) transponder identifier 29 - this field is intended to store the unique identifier of the transponder located in block 8 of the unique identifier of the transponder ROM;

3) formalized command 30 — this field is intended to store one of the commands located in block 7 of the set of formalized ROM commands of the transponder and block 25 of the set of formalized ROM commands of the stationary part.

To ensure the correct operation of the radio-controlled lock with a simulated exchange of commands by the manufacturer, the following blocks are preliminarily prepared:

1) the same unique numerical values are recorded, which serve as the identifier of the transponder, in block 8 of the unique identifier of the transponder of the ROM included in the transponder 1, and in block 17 of the ROM of the unique identifier of the transponder included in the stationary part 10 of the device;

2) in the generator 2 SRP and the generator 11 SRP - entered the same functions of the generation of SRP;

3) in block 7 of the set of formalized ROM commands and in block 25 of the set of formalized ROM commands - the same sets of formalized commands are entered (including the opening command and the closing command);

4) in the counter of 3 teams - a value equal to one is entered;

5) in block 13 of RAM storage of the serial number of the previous codogram - a value equal to zero is entered;

6) in the counter of the 12th cycle - a value equal to zero is entered.

The operation of the device begins with the selection by the user of the required command from block 7 of the set of formalized ROM commands.

At the same time, the selected command from the first output of block 7 of the set of formalized ROM commands is transmitted to the second input of the codogram block 6 and in the “formalized command” field of the codogram 30 (Fig. 2).

Simultaneously with the operation of selecting a command for the second output of block 7 of a set of formalized ROM commands, the generator 2 of the SRP is launched through its first input.

The SRP generator 2 produces a new SRP value transmitted from the first output to the first input of the counter of 3 teams, which leads to an increase in the counter value by 1, and the new SRP value also comes from the second output of the SRP generator 2 to the first input of the XOR operation block 5.

At the stage of generating the codogram, the codogram number from the counter of 3 commands is received in the codogram field 28, then the value of the unique device identifier set by the manufacturer from the first input-output of unit 8 of the unique identifier of the transponder ROM is supplied to the first input-output of the codogram forming unit 6 and is recorded in the field 29 codograms (Fig. 2).

In block 5 of the XOR operation, the transponder identifier and the formalized command are added in accordance with the XOR rule (codogram fields 29 and 30, Fig. 2) with the SRP value prepared in the 3 command counter, the SRP length must be equal to the sum of the lengths of the fields 29 and 30 )

The resulting combination is transmitted from the first output of the XOR operation unit 5 to the first input of the transmitter 4, and through the wireless communication line 9 enters the first input of the receiver 21.

The received codogram comes from the first output of the receiver 21 to the first input of the receive buffer 20 of RAM.

The number of the codogram (field 28, Fig. 2) is entered through the first input into the RAM block 15 of the number of the entered codogram, then from the first output of the block 15 of RAM the numbers of the received codogram is transmitted through the second input to the block 14 of the comparison of the code number, and compared with the number of the previous processed codogram stored in block 13 of RAM storage of the serial number of the previous codogram.

If, as a result of the comparison, it turns out that the number of the received codegram is less than or equal to the number of the previous codeogram, then this codeogram is rejected, and the signaling block 16 is notified from the second output of the codeogram comparison unit 14 through the first input.

If the number of the received code is greater than the number of the previous code, then the difference between the number of the received code and the number of the previous code is transmitted to the first input of the cycle counter 12.

This value will determine the number of necessary iterations of the generation cycle of the next SRP values so that, ultimately, the SRP generator 11 generates a value corresponding to the SRP value prepared in the transponder SRP generator 2.

The generated value of the generator 11 SRP from the second output goes to the first input of the block 19 of the operation XOR.

At the same time, from the third output of the RAM receive buffer 20, the value of the transponder identifier fields and the command from the received codogram is sent to the second input of the XOR operation block 19 (fields 29 and 30, Fig. 2).

As a result of the XOR operation in the XOR operation block 19, between the SRP value prepared in the SRP generator 11 and the transponder and command identifier field values (fields 29 and 30, Fig. 2), the values of the unique transponder identifier and the received command, which are transmitted to the first input of RAM 22 of the decoded codegram.

The value of the unique transponder identifier is transmitted from the first output of RAM 22 of the decoded code to the second input of the unique transponder identifier comparing unit 18, in which this value is compared with the unique transponder identifier stored in the ROM unit 17 of the unique transponder identifier.

If these values do not match, an error message is generated that from the first output of the unit 18 comparing the unique identifier of the transponder through the second input notifies the signaling unit 16, after which further processing of the codogram is interrupted.

If the values of the unique identifier of the transponder coincide, the unit 18 comparing the unique identifier of the transponder through the third output gives a command to the RAM block 13 to store the sequence number of the previous code to change the code number in the stationary part, after which the processor 24 is allowed to execute the command through the second input of the system bus 23 .

After that, from the second output of RAM 22 of the decoded codegram, the value of the formalized command is received in the third input of the system bus 23, which is then transmitted to the processor 24.

The processor 24 compares the received command through the second input-output with the set of commands stored in block 25 of the set of formalized ROM commands. If the commands coincide, the processor 24 generates a control signal and transfers it through the third input-output to the first input-output of the power supply unit 26 of the electronic control unit.

The received control signal from the second input-output of the power supply unit 26 of the electronic control unit is transmitted to the first input-output of the control unit 27 of the electromechanical drive of the lock.

The control unit for the electromechanical drive of the lock is carried out in accordance with the prototype (Utility model No. 73476 "Radio-controlled lock", published on 05/20/2008).

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

1) an increased level of imitation protection of the transmitted commands on the communication line;

2) simplified technical implementation.

Claims (22)

A radio-controlled lock with an imitated exchange of commands consists of a transponder, which includes a pseudo-random sequence generator (hereinafter referred to as a PSP generator), a command counter, a transmitter, an XOR operation block (logical operation “exclusive OR”), a codogram generation unit, a set of formalized read-only memory commands devices (hereinafter ROM), a block of a unique identifier for the transponder ROM; the wireless communication line and the stationary part of the device, including the memory generator, a cycle counter, a random access memory (hereinafter referred to as RAM) unit for storing the sequence number of the previous codegram, a codeogram number comparison unit, a RAM code number for the received codegram, an alarm unit, a programmable read-only memory unit (hereinafter EPROM) of a unique identifier of a transponder, a unit for comparing a unique identifier of a transponder, a block for performing an XOR operation, a receive buffer of RAM, a receiver, RAM d an encoded codogram, a system bus, a processor, a block of a set of formalized ROM commands, a power supply unit for an electronic control unit, a control unit for an electromechanical lock drive, command "Management" is fed to the first input of a block of a set of formalized ROM commands, the first output of the PSP generator is connected to the first input of the command counter, the second output of the PSP generator is connected to the first input of the XOR operation block, the first output of the command counter is connected to the first input of the coding unit, the first output of the transmitter is connected to the first input of the receiver using a wireless link, the first output of the XOR operation unit is connected to the first input of the transmitter, the first output of the codogramming unit is connected to the second input of the XOR operation unit, the first input-output of the codogramming unit is connected to the first input-output of the ROM transponder unique identifier unit, the first output of the block of a set of formalized instructions of the ROM is connected to the second input of the block forming the codogram, the second output of the block of the set of formalized commands of the ROM is connected to the first input of the generator CAP, the first output of the SRP generator as part of the stationary part of the device is connected to the first input of the system bus, the second output of the SRP generator is connected to the first input of the XOR operation unit, the first input-output of the SRP generator is connected to the first input-output of the cycle counter, the second input-output of the cycle counter is connected to the first input-output of the RAM block storing the sequence number of the previous codogram, the first output of the RAM block storing the sequence number of the previous codegram is connected to the third input of the codeogram number comparison unit, the first output of the code number comparison unit is connected to the first input of the cycle counter, the second output of the code number comparison unit is connected to the first input of the signaling unit, the first output of the RAM unit number of the received codegram is connected to the second input of the codeogram number comparison unit, the first output of the EPROM unit of the unique transponder identifier is connected to the first input of the comparison unit of the unique transponder identifier, the first output of the unit for comparing the unique identifier of the transponder is connected to the second input of the signaling unit, the second output of the unit for comparing the unique identifier of the transponder is connected to the second input of the system bus, the third output of the unit for comparing the unique identifier of the transponder is connected to the first input of the RAM unit storing the serial number of the previous codegram, the first output of the XOR operation execution unit is connected to the first RAM input of the decoded codegram, the first output of the RAM receive buffer is connected to the first input of the RAM block of the incoming codogram number, the second output of the RAM receive buffer is connected to the fourth input of the system bus, the third output of the RAM receive buffer is connected to the second input of the XOR operation block, the first output of the receiver is connected to the first input of the receive buffer of RAM, the first RAM output of the decoded codegram is connected to the second input of the comparison unit of the unique transponder identifier, the second RAM output of the decoded codegram is connected to the third input of the system bus, the first output of the system bus is connected to the first input of the codogram number comparison unit, the first input-output of the system bus is connected to the first input-output of the processor, the second input-output of the processor is connected to the first input-output of the block of a set of formalized ROM commands, the third input-output of the processor is connected to the first input-output of the power supply of the electronic control unit, the second input-output of the power supply unit of the electronic control unit is connected to the first input-output of the control unit of the electromechanical lock drive.

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