RU184423U1 - MOBILE CRIPTOTERMINAL - Google Patents

Abstract

The utility model relates to the field of automatic contactless identification of objects, in particular, to data readers from cryptometacs installed at facilities, the ability to transfer data from cryptomets and connected sensors through networks of cellular communication operators to the blockchain network. The utility model can be widely used in automatic contactless optical-electronic authentication and identification of packages in the pharmaceuticals movement monitoring system of the pharmaceutical industry, Blockchain technology. The technical result of this utility model is the enhanced functionality by introducing a barcode scanner, flash memory and secure authentication chip, which allows authentication, reading and storage of data from cryptotells. Specified by The result is achieved due to the fact that the mobile crypto terminal contains a GLONASS / GPS receiver, a cellular modem, a microcontroller, a multiplexer, two antistatic protection units and two SIM card readers, three I / O ports, power supply stabilizers for 4.5 V and 3, 3 V, a connector for connecting a cellular antenna, a connector for connecting a GLONASS / GPS antenna, a barcode scanner, a flash memory and a security authentication chip.

Description

The utility model relates to the field of automatic contactless identification of objects, in particular, to data readers from cryptometacs installed at facilities, the ability to transfer data from cryptomets and connected sensors through networks of cellular communication operators to the blockchain network. The utility model can be widely used in automatic non-contact optical-electronic authentication and identification of packages in the pharmaceuticals movement monitoring system of the pharmaceutical industry, Blockchain technology.

The most part of mobile terminals (patents for utility models No. 37581 from 01/28/2004, No. 38432 from 03/02/2004, No. 39433 from 03/29/2004, No. 40123 from 13/05/2004, No. 41219 from 11.06.2004, No. 41155 from 12.07.2004 ) constructively represent a set of serially connected chips: a cellular modem, a microcontroller (processor), a navigation receiver and an input / output port.

Known mobile communication terminal for networks of the global system of mobile communications GSM, described in the patent of the Russian Federation for useful model No. 32652 from 05.05.2003. A mobile communications terminal for GSM global mobile communications networks consists of the following components: a GSM modem, a navigation unit (GPS or GLONASS receiver), a processor, a switch, and an input / output port.

A disadvantage of this device is the impossibility of simultaneous operation in two satellite navigation systems (SNS) GPS (USA) and GLONASS (Russia) and as a result, the low accuracy of the coordinates. Another disadvantage of the described device is that the work is carried out only in one GSM network (one telecom operator), which is clearly not enough when the network is lost or radio-electronic interference is turned on (GSM signal suppression).

The known mobile terminal for the GSM global system of mobile communications, described in the patent of the Russian Federation for useful model No. 32653 of 05.14.2003. The mobile terminal for GSM global mobile communications networks consists of the following components: a GSM modem, a navigation node, two processors, an input / output device, two storage devices, and an input / output port.

However, this mobile terminal also has a drawback: low reliability, since it can work only in one GSM network.

Known navigation communication terminal, described in the patent of the Russian Federation for useful model No. 32943 from 26.05.2003. Navigation communication terminal consists of the following components: GSM modem, GPS receiver, processor, Bluetooth wireless device and I / O port. The navigation communication terminal also has a drawback: the low accuracy of determining the coordinates, since it has the ability to work only in one GPS SNA.

Known from the prior art and described, for example, in the journal "Electronic Components", No. 4, 2007, in an article by Igor Korneev, Vladimir Nemudrov, Vadim Politsikov and Oleg Lagutin "Specialized VLSI is the basis of the digital navigation receiver GLONASS / GPS", which the simultaneous use of two GLONASS and GPS systems makes it possible to radically improve the accuracy of determining the coordinates to a level unattainable in any single system.

Known mobile navigation terminal described in the patent of the Russian Federation for useful model No. 68821 from 09/06/2007. The mobile navigation terminal described in the Russian patent for useful model No. 68821 of September 6, 2007, consists of the following components: GLONASS / GPS receiver, cellular modem, microcontroller, multiplexer, two antistatic protection units and two SIM card readers, three input ports output, power stabilizers at 4.5 V and 3.3 V, connector for connecting a cellular antenna, connector for connecting the GLONASS / GPS antenna. We will choose this terminal as a prototype.

The mobile navigation terminal described in the Russian patent for useful model No. 68821 of September 6, 2007, has a significant drawback: the impossibility of automatic contactless identification of cryptographic tags (crypto tags) since it does not have the ability to read two-dimensional matrix symbols of the bar code of the ECC200 version executed according to the specifications of the symbolics of the Data Matrix and the QR Code, the US national drug code and serial number, i.e. has low functionality.

Thus, the technical result of this utility model is the extension of functionality due to the introduction of a barcode scanner, flash memory and a secure authentication chip, which allows authentication, reading and storage of data from crypto tags.

The technical result is achieved due to the fact that the mobile crypto-terminal, containing the first power stabilizer at 4.5 volts and the second power stabilizer at 3.3 volts, a cellular modem configured to work in the global mobile communications system and the packet switching system in mobile networks communications (General Packet Radio Service - GPRS), a GLONASS / GPS receiver capable of simultaneous operation with the global navigation satellite system of Russia (GLONASS) and the US global positioning system (Global Positioning System). ing System - GPS), RS-232 level converter, designed to convert logical levels into RS-232 interface levels, microcontroller, GSM antenna connector, GLONASS / GPS antenna connector, first input-output port, intended for switching with a power source and a personal computer, a second I / O port for switching with external actuators and sensors, a third I / O port for programming a microcontroller, a first SIM reader (Subscriber Id entification Module - SIM) cards and a second SIM card reader for reading data from SIM cards in memory, which are necessary for authenticating a mobile crypto terminal in a cellular network and implementing a number of application services, the first antistatic protection unit and the second antistatic protection unit, designed to prevent damage to SIM-cards at the time of inserting / removing SIM-card readers to / from, a multiplexer designed for switching signals between a cellular modem, the first SIM-card reader and a second SIM card reader, additionally contains a barcode scanner for reading barcodes from cryptomeasures, a flash memory for storing data, a secure authentication chip designed for generating keys and authenticating a mobile crypto terminal, the fourth input / output of the said the multiplexer is connected to the first input-output of the first SIM card reader and the first input of the first antistatic protection unit; the fifth input-output of the mentioned multiplexer is connected to the first input-output the house of the second SIM card reader and the first input of the second antistatic protection unit; the cellular communication modem is connected to the first input-output of the GSM antenna connector and the second input-output is connected to the first input-output of the microcontroller and the third input to the modem The cellular connection is connected to the first output of the multiplexer, the fourth input is connected to the first output of the power supply stabilizer of 4.5 volts, the second input of which is connected to the first output of the first input port - output, the first output of a 4.5 volt power regulator is connected to the first input of a 3.3 volt power regulator, the second output of which is simultaneously connected to the second input of the second I / O port and the second input of the RS-232 level converter, and the second input of the microcontroller , and a second GLONASS / GPS receiver input, and a second multiplexer input, the first input of the GLONASS / GPS receiver is connected to the first output of the GLONASS / GPS antenna connector, the third input-output of the GLONASS / GPS receiver is connected to the third input-you ode microcontroller, the fourth input-output of which is connected to the first input-output of the second port I / o, the fifth output of the said microcontroller is connected to the first input of the third input-output port, the second output of which is used to transmit analog data and connected to the sixth input of the microcontroller, the third the output of the third port I / o is designed to transmit digital data and is connected to the sixth input of the microcontroller, the seventh output of which is connected to the third input of the multiplexer, the eighth input-output mentioning The first microcontroller is connected to the first input-output of the RS-232 level converter, the third input-output of which is connected to the second input-output of the first input / output port, the ninth input-output of the microcontroller is connected to the first input-output of the barcode scanner, the tenth input- the output of the mentioned microcontroller is connected to the first input-output of flash memory, the eleventh input-output of the microcontroller is connected to the first input-output of the security chip (security chip).

The claimed utility model is illustrated by the following drawings: FIG. 1, which shows a block diagram of a mobile crypto-terminal 1, FIG. 2, which shows a diagram of the operation of a mobile crypto-terminal 1.

Consider the structure of a mobile crypto-terminal (MKT) 1.

As can be seen from FIG. 1, MKT 1 contains a GSM antenna connection connector 2, to which a GSM antenna 18 is connected, which receives and transmits messages (data) from / to a base station (not shown) of a cellular network and a cellular modem 5, which is connected to a multiplexer 4 and the microcontroller 11, which is connected to the RS-232 level converter 12. The RS-232 level converter 12 is connected to the first I / O port 14 and the second I / O port 15. In addition, the MKT 1 contains a connector for connecting the GLONASS / GPS antenna 3 to which GLONASS / GPS antenna 19 and GLONASS / GPS are connected The receiver 6, which is connected to the microcontroller 11, and it is connected to the third I / O port 13 and the multiplexer 4. MKT 1 contains a multiplexer 4, which is connected to the first reader of the SIM card 7 and the first antistatic protection unit 9, in addition, the multiplexer 4 is connected with the second reader of the SIM card 8 and the second antistatic protection unit 10. The ninth input-output of the microcontroller 11 is connected to the first input-output by the barcode scanner 20, the tenth input-output of the mentioned microcontroller 11 is connected to the first input-output of the flash memory 21, odi The nineteenth input-output of the microcontroller 11 is connected to the first input-output of the security authentication chip (security chip) 22. As can be seen from the drawing of FIG. 1, the MKT 1 contains a 4.5 volt power regulator 16 connected to a cellular modem 5 and a 3.3 volt power regulator 17, the output of which is simultaneously connected to an RS-232 level converter 12 and a second I / O port 15, and microcontroller 6, and GLONASS / GPS receiver 6, and multiplexer 4.

Consider the operation of MKT 1 in FIG. 2. MKT 1 works as follows. The user of the Internet network 31, which includes the blockchain network 32, makes a request to check the product data 24. The message from the user of the blockchain network 32 goes through the Internet network 31 to the network of the cellular operator 30, and through the elements of the cellular network (not shown) are transmitted to GSM antenna 18, then through the connector connection of GSM antenna 2, the message enters the cellular modem 5. The cellular modem 5 performs the function of a transceiver for receiving and sending messages (data). Receiving a command to request the coordinates of geodetic points, a cellular modem 5, transmits a command to the microcontroller 11, in which the program runs on request of geodetic data received from the GLONASS / GPS receiver 6.

The signals from the two GLONASS SNS and GPS 33 are continuously fed to the GLONASS / GPS antenna 19, then through the antenna 3 connection connector to the GLONASS / GPS receiver 6. The received GLONASS / GPS data receiver 6 transmits to the microcontroller 11, which analyzes the received coordinates of geodetic points. The microcontroller 11 can perform an operation to change the data by a given value of the standard deviation of coordinates. The coordinates of the geodetic points are transmitted to the cellular modem 5 and then transmitted to the GSM antenna 18 via the GSM antenna connector 2, then the navigation data is transmitted to the base station of the GSM network operator (not shown in the drawing). Navigation data via cellular communication network 30 is transmitted to the Internet network 31 and then to the user of the blockchain of network 32. Thus, the user of the blockchain of network 32 will know the location of the product 24, which is transported by vehicle 25. The coordinates of geodetic points and points on the earth's surface can be sent using SMS messages of cellular operators or GPRS technology, the transmission channel will determine the cellular modem 5. Microcontroller 11 has the ability to encrypt the coordinates of the geodetic points received from GLONASS / GPS receiver 6.

Multiplexer 4 controls the operation of the first SIM card reader 7 and the second SIM card reader 8. Since SIM cards can be different operators, MKT 1 has the ability to work in two cellular networks (but not simultaneously). In case the GSM network of one cellular operator disappears, for example, the network of which is identified by the first SIM card that is in the first SIM reader 7, multiplexer 4 switches to the second operator’s GSM network, the network of which is identified by the SIM card that is in the second reader of the SIM card 10. When exposed to external electronic warfare devices (EW) on MNT 1 (not shown), the microcontroller 11 analyzes the presence of a GSM signal. In the frequency band where the signal will not be suppressed by the EW device, microcontroller 11 will instruct multiplexer 4 to connect the first SIM card reader 7 or the second SIM card reader 8 and GSM modem 5 will continuously receive or transmit messages or data.

The first reader of the SIM card 7, the second reader of the SIM card 8, are designed to read the data stored in the memory of SIM-cards (not shown), which are necessary for authenticating MKT 1 in the GSM network and implementing a number of application services. The first antistatic protection unit 9 and the second antistatic protection unit 10 are designed to prevent damage to SIM cards at the moment of insertion / removal to / from the first 7 and second 8 SIM card readers, respectively. Cellular network availability analysis 30 occurs at the program level in microcontroller 11, which issues switching commands to multiplexer 4. Cellular modem 5 can operate in several frequency ranges of 890-915 MHz and 935-960 MHz, 1710-1785 MHz and 1805-1880 MHz. Thus, the reliability of the MKT 1 operation increases with the disappearance of the cellular communication network 30 or electronic suppression by EW devices.

MKT 1 has the ability to connect various sensors and devices, for example, a temperature sensor and relative humidity 26, which can be connected to I / O ports 13,14,15. MKT 1 has the ability to connect a nuclear magnetic resonance scanner (NMR - scanner). When an event occurs from the sensors, for example, temperature sensor 26 in the automobile refrigerator 25 connected by cable 28 to the second I / O port 15 MKT 1 triggered, the signal goes to the RS-232 level converter 12 and further to the microcontroller 11, where authentication occurs (setting authenticity) events and decisions to send messages 29 (based on algorithms stored in the memory of the microcontroller 11) [not shown].

In addition, when sending a message 29 from the sensors (not shown), geodesic data that is in memory (not shown) of the microcontroller 11 received from receiver 6 can be transmitted. Next, the cellular modem 5 performs the operation to send a message to the user of the blockchain of the network 32. The message can be sent and received via the short message service of SMS of cellular operators or packet switching technology in mobile networks GPRS. The transmission channel and transmission method selects a digital signal processor (not shown) of the cellular modem 5. The message goes to modem 5, connector 2, antenna 18 and is transmitted to the base station (not shown) of the cellular network operator 30 and further to Internet network 31 and users of the blockchain network 32.

Under the blockchain network 32 in the utility model we mean a continuous sequential chain of blocks (a linked list), built according to certain rules, containing information. Most often, copies of block chains are stored on many different computers independently of each other.

The first I / O port 14 is designed for switching with a power source and a personal computer (not shown in the drawing). The power supply of terminal 1 can be carried out from a power supply battery, which can be a rechargeable battery (not shown), or an external source connected to an external power supply port, which is located in the first input / output port 14. The second input / output port 15, designed for switching with external actuators and sensors (not shown in the drawing). The third I / O port 13 is for programming the microcontroller 11 using a programmer or a computer (not shown), one output of the I / O port 13 is analog and the other is digital. RS-232 12 level converter, is intended for converting logical levels into RS-232 interface levels.

The voltage for the power supply of terminal 1 is supplied to the power supply stabilizer 4.5 volts 16 and then to the power supply stabilizer 3.3 volts 17, through which power is supplied to all elements of the MKT 1. The power supply voltage of the cellular modem 5 is supplied from the power supply stabilizer 4.5 V 16 .

For antistatic protection of SIM cards of mobile operators, SIM card readers 7,8 have two antistatic protection blocks 9 and 10.

The presence in the MKT 1 GLONASS and GPS receiver 6 allows you to simultaneously receive satellite navigation signals 33 from two SNS, which allows to increase the reliability of receiving satellite navigation data 33 from two satellite navigation systems GLONASS and GPS 34. In MKT 1, multiplexer 4 was used in combination with a microprocessor 11 to perform the functions of diagnosing the presence of networks of cellular operators 30 or electronic suppression by EW devices, thus increasing the reliability of data transmission and reception over channels of cellular networks thirty.

When loading and transporting products 24, for example, in a car refrigerator 25, on products (boxes) 45 of which is a cryptographic 23, MKT 1 has the ability to automatically authenticate cryptometry 23. For this, MKT 1 has a barcode scanner 20, flash memory 22 and Security Chip 23.

A cryptographic 23 made on a substrate contains two-dimensional matrix symbology of a bar code complied with the Data Matrix specification of the ECC200 version or QR Code, or the national US drug code and serial number. The national drug code (NDC) contains no more than 11 digits in the 5-4-2 format: 5 digits — the label code (labeler code), 4 digits — the product code (product code) and 2 digits — the packaging code (package code), and The serial number (SN) contains no more than 20 letters and / or numbers, with the NDC and SN meeting the requirements of the regulations of the United States Department of Health and Human Services (Food and Drug Administration). The two-dimensional matrix symbology of the bar code is made according to the specification of the Data Matrix symbolism of the ЕСС200 version, according to the requirements of the COLES 16022: 2006 standard or GOST R ISO IEC 16022-2008 or performed according to the QR Code symbology specifications, according to the requirements of ISO / IEC 18004: 2015 or GOST R ISO IEC 18004-2015.

To correctly perform authentication, it is necessary that the barcode scanner 20 and the barcode cryptometer 23 use the same key. To identify itself, cryptometry 23 sends its identification code 27 to barcode 20 MKT 1 on scanner. After that, barcode scanner 20 MKT 1 can identify this cryptographic marker 23 and determine which cryptographic key should be used. The barcode scanner 20 MKT 1 generates a random number R, which is the initial value of the encryption algorithm. To increase security, a random number is encrypted using a part of the cryptokey and gets the value of R1. The scanner 20 translates the cryptographic 23 into a cryptographic mode, sending the corresponding opcode to it, followed by an R1 request.

Cryptographic 23 receives the encrypted number R1, then it restores the random number R, originally generated by the scanner 20. To verify the authenticity of the received request, the cryptographic 23 cyclically sends to the scanner 20 a checksum. If the checksum is incorrect, the cryptographic 23 goes out of the cryptographic mode and immediately goes into the identification mode, passing the identifier code (not shown in the drawing). The scanner 20 MKT 1 and the cryptometer 23 begin to encrypt the number R. While the results of the encryption of the number R are being calculated, the cryptometer 24 cyclically sends the checksum of the request to the scanner 20. As soon as the cryptometry 23 finishes the calculation, it interrupts the transfer of the checksum, sending a response to the checker to the scanner 20. Cryptometry 23 sends the answer back to the scanner 20 for comparison. If the correct keys were used, the result generated inside the scanner 20 should be identical to the result sent by the cryptometer 23. Based on a comparison of these results, the MKT scanner 20 can decide whether the cryptometer 23 passed authentication or not. Next, the scanner 20 transmits data to the microcontroller 11 and through the cellular modem 5 to the cellular communication network 30. The cellular communication network 30, which consists of the switching system and the base station system (not shown), connects the Internet via the switching node of the cellular communication network the network 31, to which the users of the blockchain of the network 32 are connected. The servers (not shown) of the blockchain of the network 32 are in essence a distributed database, where the identification data previously recorded in the crypto network 24 is taken into account GOVERNMENTAL individual data object 24, such as drugs previously listed in the database server, i.e. The box 24 (object) is identified on which the cryptometer 23 is glued.

Cryptographic 23 can have not only a metal transponder consisting of ferromagnetic, antiferromagnetic or ferrimagnetic powder, which has the properties of nuclear magnetic resonance, but also a radio frequency chip, on which a bar code is attached. Security Chip (SC) 22 generates a cryptographic key (not shown in the drawing). The scanner 20 will start only after running the Firmware program, which resides in the microcontroller 11. The firmware (recorded in the non-volatile memory of the microcontroller 11) accesses SC 22. The SC 22 contains security keys generated in the chip by a physically-non-cloned function (PUF ). The key is generated by changes in the threshold voltage of the MOSFET, which is a random process. In the same crystal, a so-called partner public key is generated, which is necessary for encrypting the public key and excluding issuing the private key outside the chip. The firmware of microcontroller 11, receiving the key from SC 22, starts operation. Thus, Security Chip 22 provides the protection circuit for the initial loading of the microcontroller 11, authentication of the scanner 20 and the MKT 1. The key can only be obtained under laboratory conditions, however, it does not bring benefit to those intending to crack SC 22. Even SC 22 made from one plate does not have key relationships. The key extraction in the laboratory itself is a rather expensive process. The main cryptographic key does not remain in the SC 22 memory or in some static state. When required, the circuit generates a unique key-specific SC 22, which instantly disappears if it is no longer used. When hard physical attacks are attempted, the sensitive electrical characteristics of the circuit change, making it difficult to carry out an attack on S 22. If the SC 22 authentication procedure fails, no information is transmitted from the SC 22 to the microcontroller 11, the microcontroller 11 turns on the alarm mode and turns off all elements MKT 1 from the power supply unit (not shown in the drawing). Thus, if SC 22, not fake, authenticates scanner 20 and MKT 1, and microcontroller 11 starts further operation of MKT 1. In case of successful completion of authentication procedure of scanner 20, a parcel is formed, which enters the microcontroller 11. Next, information is exchanged between cryptometer 23 and MKT scanner 20 1. Microcontroller 11 transmits the information read from the cryptometer 23 to the cellular modem 5, which through the antenna 18 transmits information to the base transceiver station of the cellular operator (in the drawing not azano).

Cryptographic information 23: the national drug code (NDC) contains no more than 11 digits in 5-4-2 format: 5 digits - the label code (labeler code), 4 digits - the product code (product code) and 2 digits - the packaging code (package code), and the serial number (SN) contains no more than 20 letters and / or numbers, while the national drug code (NDC) and serial number (SN) meet the requirements of regulatory documents of the US Department of Health and Social Services. Cryptographic 23 may contain information on the identification number of the drug, the serial number of the package, the number of the drug in the national drug supply system (if applicable), the series number, expiration date and other data recorded in accordance with the ISO Matrix Data Matrix specification, IEC 16022: 2006 or GOST R ISO IEC 16022-2008 or QR Code symbology specifications, in accordance with the requirements of ISO / IEC 18004: 2015 or GOST R ISO 18004-2015. Next, information from the base transceiver station of the cellular operator is transmitted to the base station controller (not shown) of the cellular communication network 30. Next, the signal from the base station controller of the cellular communication operator enters the mobile switching center and through the router enters the Internet network 31, which is connected to the server receiving and processing data (not shown). On the server receiving and processing data, the data of the cryptographic tag 24 is identified. Data from the server receiving and processing data can be transferred to the blockchain network 32.

The microcontroller 11 has the ability to encrypt the transmitted data from the scanner 20. The architecture of modern microcontrollers 11 makes it possible to effectively implement hardware support for national encryption algorithms (for example, Russian GOST R 34.10-2001, GOST 28147-89, GOST R 34.11 94) and present this implementation together with the original codes for certification to the competent authorities. In this case, the microcontroller 11 can support both existing Western data encryption algorithms and, accordingly, ensures compatibility with existing applications, and national data encryption algorithms. Flash memory 21 allows you to record and store data MKT 1, including encrypted data received from the cryptographic tag 23 using the scanner 20.

The power supply of the MKT 1 is carried out from the power supply unit through which all the elements of the device are powered (not shown in the drawing). The power supply unit may comprise a battery, a voltage converter and a power supply stabilizer (not shown in the drawing). Through the external power port, the battery is charged (not shown) of the power supply unit.

Thus, due to the introduction of barcode scanner 20, flash memory 21 and secure authentication chip 22, the technical result of this utility model is achieved: enhanced functionality of the MKT 1, which allows authentication, reading and storage of data from cryptomeasures 23.

The manufacture of the MKT 1 shown in FIG. 1, is carried out from typical radio-electronic components (REC). RECs can be: Motorola modem 5 G20, GLONASS / GPS receiver 6, for example, TII PROGRESS AO TFAG50, microcontroller 11, for example, ATMEL 128EG-8AU ATMEGA MEGA AVR. Multiplexer 4 can be used on the basis of the CD74AC157M microcircuit, RS-232-12 level converter, for example, based on the MAX 3232ESE. Power Stabilizers 4.5 V - 16 - LM1084IT-ADJ, 3.3 V - 17 -TPS76833QD. Security Chip 23 type DS28E38 company Maxim. The remaining elements are typical RECs widely used in industry.

Prototypes of MKT 1 are made. Tests have shown that they meet the requirements of identification tools.

Claims (1)

Mobile crypto-terminal containing the first 4.5 volt power supply stabilizer and the second 3.3 volt power supply stabilizer, cellular communication modem, designed to work in the global mobile communications system and packet switching system in mobile networks (General Packet Radio Service - GPRS ), GLONASS / GPS receiver, made with the possibility of simultaneous operation with the global navigation satellite system of Russia (GLONASS) and the global positioning system of the USA (Global Positioning System - GPS), RS-232 level converter, designed conversion of logic levels to RS-232 interface levels, microcontroller, GSM antenna connector, GLONASS / GPS antenna connector, the first I / O port for switching with a power source and a personal computer, the second I / O port for switching with external actuators and sensors, the third input-output port for programming the microcontroller, the first SIM (Subscriber Identification Module - SIM) card reader and the second SIM-card reader, Designed for reading data stored in the memory of SIM-cards, which are necessary for authenticating a mobile crypto-terminal in a cellular network and implementing a number of application services, the first antistatic protection unit and the second antistatic protection unit, designed to prevent damage to SIM cards at the moment of insertion / extraction into / from SIM-card readers, multiplexer, designed for switching signals between a cellular modem, the first SIM-card reader and the second SIM-card reader, characterized in that additionally contains a barcode scanner for reading barcodes from crypto switches, a flash memory for storing data, a secure authentication chip designed for key generation and authentication of a mobile crypto terminal, the fourth input / output of said multiplexer is connected to the first input- the output of the first SIM card reader and the first input of the first antistatic protection unit; the fifth input-output of the mentioned multiplexer is connected to the first input-output of the second SIM card reader and the first input of the second antistatic protection unit, while the cellular modem is connected to the first input-output of the GSM antenna connection socket by the first input output and connected to the first input-output of the microcontroller by the second input, the cellular communication modem is connected to the first input by the third input the output of the multiplexer, the fourth input, the cellular modem is connected to the first output of a 4.5 volt power stabilizer, the second input of which is connected to the first output of the first I / O port, the first output is stabilized A 4.5 volt power supply is connected to the first input of a 3.3 volt power regulator, the second output of which is simultaneously connected to the second input of the second I / O port and the second input of the RS-232 level converter, and the second input of the microcontroller, and the second input of the GLONASS / GPS receiver, and a second multiplexer input, with the first GLONASS / GPS receiver input connected to the first output of the GLONASS / GPS antenna connection connector, the third GLONASS / GPS receiver input-output connected to the third input of the microcontroller, quarters The first input-output of which is connected to the first input-output of the second I / O port, the fifth output of the said microcontroller is connected to the first input of the third I / O port, the second output of which is used to transmit analog data and is connected to the sixth input of the microcontroller, the third output of the third port I / O is designed to transmit digital data and is connected to the sixth input of the microcontroller, the seventh output of which is connected to the third input of the multiplexer, the eighth input-output of the mentioned microcontroller n the first input-output of the RS-232 level converter, the third input-output of which is connected to the second input-output of the first input-output port, the ninth input-output of the microcontroller is connected to the first input-output of the bar code scanner, the tenth input-output of the mentioned the microcontroller is connected to the first input-output of flash memory, the eleventh input-output of the microcontroller is connected to the first input-output of the security authentication chip (security chip).