RU98308U1 - DIGITAL AUTOMATIC TELEPHONE STATION - Google Patents

Abstract

 1. Digital automatic telephone exchange, comprising a control and switching unit, including a signal processor, switch, control controller, random access memory, clock generator, also containing n mezzanines, where n is the number of mezzanines, buses, and peripherals, characterized in that the control unit contains an additional parallel asynchronous bus with the possibility of high-speed access of the signal processor to random access memory, bus converter, zag narrow read-only memory, read-only memory, Ethernet controller, mezzanine block control controller, integrity controller, ensuring software integrity, connected by an input / output to the signal processor, the signal processor clock generator connected by its input / output with the input / output of the signal processor, a data bus between the control unit and mezzanines, a parallel asynchronous bus with access a signal processor to a bootable read-only memory device, to a read-only memory device for reading and writing information, to a control controller, Ethernet controller, to a mezzanine control controller, to mezzanines, and each mezzanine includes an external internal interface converter, an external mezzanine control controller, and also an external converter of the external interface connected by inputs / outputs to the control unit by means of connectors for installing mezzanines, and

Description

The utility model relates to telecommunication devices, in particular to digital automatic telephone exchanges, for use in communication networks, with the provision of a large number of additional services offered to subscribers.

The utility model can be used as equipment for access to IP networks, channelization equipment, signaling converters, office-production automatic telephone exchanges to serve a small number of subscribers (up to 80).

As a prototype, the well-known digital automatic telephone exchange (DSC) was selected according to the patent of the Russian Federation for utility model RU 63998, IPC Н04М 3/00 with priority dated January 30, 2007. A digital automatic telephone exchange, implemented on the basis of this patent, provides subscribers with an extensive list of services, provides technical means of access to a public communication network and / or the Internet. A digital automatic telephone exchange, implemented on the basis of this patent, can be used in various departments, equipped with various types of peripheral units, has all the features of a telephone exchange used for a significant number of subscribers (from 100 or more).

The disadvantages of the DATS include: the unjustifiably complex structure of the DATS when forming a station for a small number of subscribers (up to 80), respectively, a large number of elements and increased dimensions. This is due to the fact that when servicing a large number of subscribers, an increased reliability of the device is required, realized by the possibility of installation by the presence of redundant control units, accompanied by the complexity of the structure of the central telephone exchange.

The technical problem solved in the claimed device is to reduce the size of the PBX when providing communication services for a small and medium number of subscribers (up to 80), to increase the number of personalized PBX services for subscribers, including when working with VolP protocols, while maintaining the versatility of the purpose of the PBX and the possibility connections to both analog communication lines and digital lines, with the ability to work with digital system telephones.

The essential features common with the claimed device are: processor, digital switch, blocks with subscriber sets (in the claimed device - mezzanines for subscriber endings), the outputs of which are connected to analog subscriber lines, blocks of digital line endings with pulse-code modulation (in the claimed device - mezzanines of digital lines), the outputs of which are connected to streams with pulse-code modulation of digital connecting lines, a clock generator, blocks with sets of analog connecting lines x (in the disclosed device - mezzanine for external analog line), the outputs of which are connected to the analog PBX trunks counter.

The stated technical problem is solved due to the fact that the digital automatic telephone exchange contains a control and switching unit, including a signal processor, a switch, a control controller, random access memory, a clock generator, also contains n mezzanines, where n is the number of mezzanines, buses , and peripheral devices, while the control unit contains an additional parallel asynchronous bus with the possibility of high-speed access of the signal processor to random access memory device, bus converter, bootable read-only memory, read-only memory for reading and writing information, ETHERNET controller, mezzanine block control controller, integrity controller, ensuring software integrity, connected to the input / output signal processor, the clock processor of the signal processor, connected by its input / output to the input / output of the signal processor, the data exchange bus between the control unit and the mezzanines, in parallel an asynchronous bus with the ability of the signal processor to access the bootable read-only memory, to the read-only memory device, to the control controller, ETHERNET controller, to the mezzanine control controller, to mezzanines, and each mezzanine includes an external internal interface converter, an external controller control of this mezzanine, as well as an external converter of the external interface, connected by inputs to outputs with a control unit through connectors for I install mezzanines, and the signal processor is connected with its inputs / outputs with inputs / outputs of a parallel asynchronous bus, inputs / outputs with inputs / outputs of a clock generator, inputs / outputs with inputs / outputs of an integrity controller, inputs / outputs with inputs / outputs of a control controller , bootable read-only memory is connected by its inputs / outputs to the inputs / outputs of the control controller, its inputs / outputs with inputs / outputs of the internal parallel asynchronous bus, its strokes / outputs with inputs / outputs of an additional asynchronous bus, moreover, the read-only memory is connected with its inputs / outputs with inputs / outputs of the control controller, its inputs / outputs with inputs / outputs of an additional parallel asynchronous bus, and the RAM is connected with its inputs / outputs with inputs / outputs of the internal parallel asynchronous bus, while the control controller is connected with its inputs / outputs with the inputs / outputs of the signal processor, its inputs / outputs with inputs / outputs and bootable permanent storage device, its own inputs / outputs with inputs / outputs of read-only memory device, its own inputs / outputs with inputs / outputs of an internal parallel asynchronous bus, its own inputs / outputs with inputs / outputs of an Ethernet controller, its inputs / outputs with inputs / outputs bus converter, its inputs / outputs with inputs / outputs of an additional parallel asynchronous bus, its input with the output of the clock controller's clock generator, its inputs / outputs with inputs / outputs of the supervisor, its inputs / outputs with inputs / outputs of the mezzanine control controller, its inputs / outputs with switch inputs / outputs, and the mezzanine control controller is connected with its inputs / outputs with inputs / outputs of the control controller, its inputs / outputs with inputs / outputs of the synchronizer, its output with the input of the switch, its inputs / outputs with inputs / outputs of an additional parallel asynchronous bus, its inputs / outputs with inputs / outputs of the data bus, connectors for installing mezzanines are connected by their inputs / outputs to the inputs / outputs of the data bus, their inputs / outputs with inputs / outputs of an external converter of the internal interface, in turn, the external converter of the internal interface is connected by its inputs / outputs with the inputs / outputs of an external control controller a mezzanine, which, in turn, is connected to the inputs / outputs of the external converter of the external interface with its inputs / outputs, and is also connected to external lines, in addition, the control unit It contains a watch with an autonomous battery connected by the input to the signal processor, and the mezzanine control controller is provided with a synchronizer designed to synchronize the system frequency with the frequency of external lines, and it is connected with its input / output to the input / output of the mezzanine control controller.

The device is illustrated in the drawing, where figure 1 shows the structural diagram of the control module and mezzanines (in the prototype expansion module).

The device contains:

Internal parallel asynchronous bus A;

Additional parallel asynchronous bus B;

Data exchange bus C;

The signal processor 1, providing the execution of the main program. The signal processor 1 can be made in the form of a signal processor company "Texas Instruments" model TMS320C6713 or model TMS320C6412;

Bootable read-only memory 2, (ROM BOOT FLASH) is designed to load the main program into the signal processor 1. It is used when the device is turned on. The signal processor 1 has the ability to both read and write information to bootable read-only memory 2. Bootable read-only memory 2 can be made in the form of an AM29LV32008 chip;

Primary Read-Only Memory 3 (DATA FLASH ROM). The main permanent storage device 3 is designed to store utilities and data and is used constantly in the process. It has the ability to both read and write information. It can be made in the form of a chip K9F1G08UOB;

RAM 4, made in the form of a random access memory chip (RAM), is designed to store data and programs during processor operation. RAM 4 can be made in the form of microcircuit K4S561632H;

The control controller 5 is made in the form of a downloadable programmable logic integrated circuit (FPGA), which:

- contains a map of internal control registers;

- supports interface docking of various microcircuits.

The control controller 5 may be made in the form of a chip type CPLD company Xilinx.

The mezzanine control controller 6 is made in the form of a downloadable programmable logic integrated circuit (FPGA), which supports the docking of device interfaces. It can be made in the form of microcircuit type Spartan company Xilinx.

The switch 7 is made in the form of a switching field chip, which performs the required data switching on the data exchange bus C. It can be made in the form of an IDT72V90823 chip.

Network controller 8. Designed as an Ethernet controller, provides network equipment connection via Ethernet protocol.

The clock frequency generator 9 of the control controller 5. Generates a reference frequency for operation of the circuit and frequency adjustment of the PCM channel. It can be made in the form of a SG-8002 chip.

The clock frequency generator of the signal processor 10 generates a clock frequency for the internal PLL of the signal processor 1. It can be made in the form of an SG-8002 chip.

The synchronizer 11, is made in the form of a programmable chip phase-locked loop. Designed to multiply the frequency of 1.024 MHz to 65.536 MHz. It can be made in the form of a chip CY22150FC.

Bus converter 12. Designed to separate the high-speed internal parallel asynchronous bus A and the slower additional parallel asynchronous bus B.

Integrity Controller 13, provides software integrity;

Clock 14. They are made in the form of a microcircuit of a real-time clock complete with an autonomous power battery (not shown in FIG.

Supervisor 15 performs the following functions:

- initial system reset when power is turned on;

- manual reset of the system using the reset button;

- monitors the performance of the software using a watchdog.

Connectors for attics 16.

Mezzanine 17 (in the prototype expansion module) in its composition has:

External converter of the internal interface 18. Made in the form of a downloadable programmable logic integrated circuit. Installed on the mezzanine 17, it is designed to interface the mezzanine 17 with the data bus interface C through connector 16.

An external controller for controlling the mezzanine 19, is designed to analyze external data and to convert the output data between the external converter of the internal interface 18 and the external converter of the external interface 20.

The external converter of the external interface 20, is made in the form of a downloadable programmable logic integrated circuit. Installed on the mezzanine 17. Designed to pair the mezzanine 17 with external lines, it converts the external signal to digital for further processing by the external controller for controlling the mezzanine 19.

A connector for connecting to an IP network 21. For connecting an Ethernet network to a DATS.

Internal parallel asynchronous bus A is designed for high-speed access of signal processor 1 to RAM 4.

An additional parallel asynchronous bus B is intended for access of the signal processor 1 to the devices: bootable read-only memory 2, main read-only memory 3, control controller 5, mezzanine control controller 6, network controller 8, and also to the mezzanine 17 via switch 7 (switched to data exchange bus C). An additional parallel asynchronous bus B is isolated from the internal parallel asynchronous bus A, to which the signal processor 1 is connected via a bus converter 12.

The data exchange bus C is located between the elements of the control module 22 and the connectors 16. It contains serial and parallel parts.

The signal processor 1 is connected by the first input / output with the first input / output of the internal parallel asynchronous bus A, the second input / output with the input / output of the clock generator 10 of the signal processor 1, the third input / output with the input / output of the integrity controller 13, the fourth input / output with input / output of 14 hours, fifth input / output with the first input / output of the control controller 5.

Bootable read-only memory 2 (BOOT FLASH) is connected by its first input / output to the second input / output of the control controller 5, by its second input / output with the second input / output of the internal parallel asynchronous bus A, by its third input / output with the first input / output optional parallel asynchronous bus B.

Read-only memory 3 (DATA FLASH) is connected by its first input / output to the third input / output of the control controller 5, by its second input / output with the first input / output of an additional parallel asynchronous bus B.

RAM 4 is connected by its input / output to the third inputs / outputs of the internal parallel asynchronous bus A.

The control controller 5 is connected by its first input / output to the fifth input / output of the signal processor 1, by its second input / output with the first input / output of the bootable read-only memory 2 (BOOT FLASH), by its third input / output with the first input / output of the read-only memory devices 3 (DATA FLASH), with its fourth input / output with the fourth input / output of the internal parallel asynchronous bus A, its fifth input / output with the first input / output of the 8 Ethernet controller, its sixth input / output with the first input / output the bus converter 12, its seventh input / output with the second input / output of an additional parallel asynchronous bus B, its eighth input with the output of the clock generator 9 of the control controller 5, its ninth input / output with input / output of the supervisor 15, its tenth input / the output with the first input / output of the controller control mezzanines 6, its eleventh input / output with the first input / output of the switch 7.

The mezzanine control controller 6 is connected by its first input / output to the tenth input / output of the control controller 5, by its second input / output with the input / output of the synchronizer 11, by its third output from the second input of the switch 7, by its fourth input / output with the third input / output additional parallel asynchronous bus B, with its fifth input / output with the first input / output of data bus C.

The switch 7 is connected by its first input / output with the eleventh input / output of the control controller 5, by its second input / output with the third input / output of the mezzanine control controller 6, by its third input / output with the second input / output of bus C.

The Ethernet network controller 8 is connected by its first input / output to the fifth input / output of the control controller 5, by its second input / output with the fourth input / output of an additional parallel asynchronous bus B, by its third input / output with the first input / output of the Ethernet connector 21, which , in turn, is connected by its second input / output to the IP network.

The clock generator 9 of the control controller 5 is connected by the output to the eighth input of the control controller 5.

The clock generator of the signal processor 10 is connected by its input / output to the second input / output of the signal processor 1.

The synchronizer 11 is connected by its input / output to the second input / output of the mezzanine control controller 6.

The bus converter 12 is connected by its first input / output with sixth inputs / outputs of the control controller 5, by its second input / output with the fifth input / output of the internal parallel asynchronous bus A, by its third input / output with the fifth input / output of the additional parallel asynchronous bus B.

The integrity controller 13 is connected by its input / output to the third input / output of the signal processor 1.

Clock 14 is connected by its input / output to the fourth input / output of the signal processor 1.

The supervisor 15 is connected to its input / output with the ninth input / output of the control controller 5.

Connectors for installing mezzanines 16 are connected by their first inputs / outputs to the third inputs / outputs of the data exchange bus C, by their second inputs / outputs with the first inputs / outputs of the external converter of the internal interface 18.

The external converter of the internal interface 18 is connected by its first input / output to the second input / output of the connector for installing mezzanines 16, by its second input / output with the first input / output of the external controller for controlling the mezzanine 19.

The external controller for controlling the mezzanine 19 of the mezzanine 17 is connected by its first input / output to the second input / output of the external converter of the internal interface 18, by its second input / output with the first input / output of the external converter of the external interface 20.

The external converter of the external interface 20 is connected with its first input / output to the second input / output of the external control controller of the mezzanine 19, also connected with the inputs / outputs of external lines.

The bus converter 12 is used to separate the high-speed internal parallel asynchronous bus A between the signal processor 1 and the RAM 4 from the low-speed additional parallel asynchronous bus B of the other blocks of the control module 22. When the signal processor 1 is operating with the RAM 4 through the internal parallel asynchronous bus A, the bus the converter 12 is turned off. When accessing any of the peripheral devices (bootable read-only memory 2, read-only memory 3, control controller 5, mezzanine control controller 6, switch 7 or Ethernet controller 8), signal processor 1 sets the device selection signal, control controller 5 generates an operation enable signal buffers of the bus Converter 12, as well as a signal that determines the direction of data transmission through the bus Converter 12.

The reference frequency for the operation of the circuit and the adjustment of the PCM channel is set by the clock generator 9 of the control controller 5 through the output to the eighth input of the control controller 5.

The synchronizer 11 is designed to synchronize the system frequency with the frequency of external lines (for example, when working with E1 lines), connected with its input / output to the second input / output of the controller for controlling mezzanines 6.

The switch 7 provides switching of the mezzanine channels 17 via the communication bus C. It is controlled and configured by the signal processor 1 through the first input / output to the first input of the output of the internal parallel asynchronous bus A, using the control controller 5 through the first input / output to the fifth input / output and through the fourth input / output to the fourth input / output, transmitting data through the fifth input / output of the internal parallel asynchronous bus A to the second input / output of the bus converter 12, then through the third input / output of the bus converter Indicator 12 to the fifth input / output of the additional parallel asynchronous bus B, then through the third input / output of the additional parallel asynchronous bus B to the inputs / outputs of the mezzanine control controller 6, then through the third input / output of the mezzanine control controller 6 to the second input / output of the switch 7 .

The universality of the type of connection to connectors 16 and the design of the mezzanines 17 as separate units allows you to connect different types of external lines to the PBX simultaneously: analog communication lines FXO, FXOM, FXS, as well as digital lines. At the first input, the output of the mezzanines 17 uses connectors of different types (not shown in FIG. 1), which are connected to the connectors 16 (universal) of the control module 22 (through the first inputs / outputs to the second inputs / outputs). Directly external lines are connected to the corresponding connectors (not shown in FIG. 1) of the mezzanines 17 through the second input / output of the external converter of the external interface 20. Due to the use of mezzanines 17 as separate external line service cards and due to the compactness of the above-mentioned digital telephone exchanges, an increased density of interface channels .

Clock 14 is designed to implement user functions that operate with real time, such as "Alarm", "Date and time of receipt of voice messages in voicemail", "Date and time for call processing mode", etc.

The Ethernet network controller 8 provides the PBX to connect to the IP network via Ethernet through connector 21 to realize the possibility of setting up the PBX via the IP network from personal computers, as well as to implement the PBX using the SIP and H.323 protocols. When using SIP and H.323 protocols, users can use personalized communication services (Voice Mail, Personal Phone Book, Call Processing Mode, etc.). The internal parallel asynchronous A-EMIF bus is designed for high-speed access of signal processor 1 to RAM 4.

The operation of the device is as follows.

When you turn on the automatic digital station (ATC), the signal processor 1 through the first input / output to the first input / output of the internal parallel asynchronous bus A, then through the fifth input / output to the second input / output of the bus converter 12 gets access to an additional parallel asynchronous bus B through the third input / output to the fifth input / output, through which through the sixth input / output to the third input / output accesses the data of the bootable read-only memory 2. These data are received through the third input / output load permanent storage device 2 to the additional parallel asynchronous bus B through the sixth input / output, then using the bus converter 12 (through the fifth input / output to the third input / output) are transmitted via an internal parallel asynchronous bus A through the second input, the output to the fifth input / output to RAM 4 through the third input / output to the first input / output of RAM 4. In RAM 4, some code is generated, which the signal processor 1 starts to execute. All operations occur goes under the control of the control controller 5 through the first input / output to the fifth input / output.

Upon receipt of any type of signal (call, busy, etc.) from external communication lines to an external converter of the external interface 20, the external converter of the external interface 20 converts the external signal to digital and passes through the first input / output to the second input / output for processing to the external mezzanine control controller 19. The external mezzanine control controller 19 determines the presence of a call signal and supplies information through the first input / output to the second inputs of the outputs of the external converter of the internal interface 18, then through the first input / output to the second input / output of the mezzanine connection connector 16, then through the first input / output to the third input / output of the data exchange bus C. The mezzanine control controller 6 through the first input / output of the data exchange bus C to its fifth the input / output receives data from the data exchange bus C and sends it to the additional parallel asynchronous bus B through the fourth input / output to the third input / output of the additional parallel asynchronous bus B, from where it comes through the fifth input / output to the third input / output to the bus converter 12 and under the control of the control controller 5 through the sixth input / output to the first input / output of the bus converter 12, then the data goes through the second input / output to the fifth input / output of the internal parallel asynchronous bus A, and then through the first input / output to the first input / output to the signal processor 1. Information is processed by the signal processor 1, using random access memory 4 and data from the main read-only memory 3, access to which is via an internal parallel asynchronous A bus A is provided by the control controller 5 through the first input / output of the control controller 5 to the fifth input / output of the signal processor 1. Voice data for further processing (encoding, decoding, etc.) from the external converter of the external interface 20 is transmitted to the signal processor 1 in a similar way. Information about dialing numbers is transmitted in a similar way. The removal of the handset at the terminal subscriber unit is recognized by the external mezzanine control controller 19 through the first input / output of the external converter of the external interface 20 to the second input / output of the external mezzanine control controller 19 and is transmitted by the corresponding command along the described path.

The tone signals for analog external lines are provided by a tone generator (not shown in FIG. 1), integrated into the external mezzanine control controller 19, through the second input / output to the first input / output of the external converter of the external interface 20 under the control of the signal processor 1 through the first input / output to the first input / output of the internal parallel asynchronous bus A, using the control controller 5 through the first input / output to the fifth input / output and through the fourth input / output to the fourth input / output, passing data through the fifth input / output of the internal parallel asynchronous bus A to the second input / output of the bus converter 12, then through the third input / output of the bus converter 12 to the fifth input / output of the additional parallel asynchronous bus B, then through the third input / output of the additional parallel asynchronous bus B to the fourth input / output of the mezzanine control controller 6, then through the fifth input / output of the mezzanine control controller 6 to the first input / output of the communication bus C, then through the third inputs / outputs to p the first inputs / outputs of the mezzanine connectors 16, then through the second inputs / outputs of the mezzanine connectors 16 to the first inputs / outputs of the external converter of the internal interface 18 of the mezzanine 17. For digital lines, tones are generated programmatically without using a tone generator from the second inputs / outputs of the external mezzanine control controller 19.

If it is necessary to switch (according to the DATS routing settings from the main read-only memory 3), the switch 7 through the third input / output to the second input / output of bus C performs switching of the mezzanine channels 17 (or different mezzanines 17) under the control of the signal processor 1 through its first input / the output to the first input is the output of the internal parallel asynchronous bus A, using the control controller 5 through its first input / output to the fifth input / output of the signal processor 1 and through its fourth input / output to the fourth input / output of the internal parallel asynchronous bus A, transferring data through the fifth input / output of bus A to the second input / output of the bus converter 12, then through the third input / output of the bus converter 12 to the fifth input / output of the additional parallel asynchronous bus B, then through the third input / output of the additional parallel asynchronous bus B to the fourth input / output of the mezzanine control controller 6, then through the third input / output of the mezzanine control controller 6 to the second input / output of the switch 7.

The inventive device is structurally a separate device that is connected by a twisted pair cable to an Ethernet network, and to which analog or digital lines and devices can be connected. The inventive device is built on the basis of the so-called mezzanine technology - the device is divided into computing (control module 22) and interface parts (mezzanine 17 or n mezzanines 17). The computing part is represented by the control module 22. The main computing device is the signal processor 1 of the company Texas Instruments model TMS320C6713 or model Texas Instruments TMS320C6412. The interface part is a set of mezzanines 17 in the form of submodules connected to the control module 22. Up to ten mezzanines 17 can be installed on the control module 22. Each type of mezzanine 17 is designed to connect a certain type of external device (or line). The mezzanines 17 differ in the elemental base for different types of external lines, but they have a single structure.

In the prototype, the expansion module in comparison with the mezzanine 17 (acting as an expansion module in the claimed device) has large dimensions due to the presence of an external system bus and a large number of devices that implement the expansion module. For a small number of subscribers, an important factor is the provision of personalized communication services (personal notebooks, recording by a subscriber of his conversation in voicemail, various callback modes for a subscriber, receiving a fax to a personal mailbox, etc., i.e. those services which are implemented by the claimed technical solution.

The technical result is achieved by replacing the ISA universal bus with an internal parallel asynchronous bus A, designed for high-speed access of signal processor 1 to RAM 4, by introducing an additional parallel asynchronous bus B of its own format, designed for access of signal processor 1 to peripheral devices (bootable read-only memory 2 , read only memory 3, control controller 5, mezzanine control controller 6, switch 7 or to the Ethernet controller 8), as well as to the mezzanine 17 through switch 7 (switched to the data exchange bus C), a significant simplification of the structure of the expansion modules (mezzanines 17 in the claimed device), which led to a significant reduction in size, a different arrangement of blocks, the choice another element base.

Thus, the technical task posed has been solved, namely: there is a decrease in the size of the PBX when providing communication services for a small and medium number of subscribers, an increase in the number of personalized PBX services for subscribers, including when working via VolP protocols, while maintaining the versatility of the purpose of the PBX and the ability to connect to both analog communication lines and digital lines, with the ability to work with digital system telephones, also increases the density of interface channels.

Claims (3)

1. Digital automatic telephone exchange, comprising a control and switching unit, including a signal processor, switch, control controller, random access memory, clock generator, also containing n mezzanines, where n is the number of mezzanines, buses, and peripherals, characterized in that the control unit contains an additional parallel asynchronous bus with the possibility of high-speed access of the signal processor to random access memory, bus converter, zag narrow read-only memory, read-only memory, Ethernet controller, mezzanine block control controller, integrity controller, ensuring software integrity, connected by an input / output to the signal processor, the signal processor clock generator connected by its input / output with the input / output of the signal processor, a data bus between the control unit and mezzanines, a parallel asynchronous bus with access a signal processor to a bootable read-only memory, to a read-only memory device to read and write information, to a control controller, an Ethernet controller, to a mezzanine control controller, to mezzanines, and each mezzanine includes an external internal interface converter, an external control controller for this mezzanine, and also an external converter of the external interface connected by inputs / outputs to the control unit by means of connectors for installing mezzanines, the processor is connected with its inputs / outputs with inputs / outputs of a parallel asynchronous bus, inputs / outputs with inputs / outputs of a clock, inputs / outputs with inputs / outputs of an integrity controller, inputs / outputs with inputs / outputs of a control controller, a bootable read-only memory is connected its inputs / outputs with inputs / outputs of the control controller, its inputs / outputs with inputs / outputs of the internal parallel asynchronous bus, its inputs / outputs with inputs / outputs a solid asynchronous bus, and the read-only memory is connected by its inputs / outputs to the inputs / outputs of the control controller, its inputs / outputs with the inputs / outputs of an additional parallel asynchronous bus, and the RAM is connected by its inputs / outputs with the inputs / outputs of the internal parallel asynchronous bus, wherein the control controller is connected by its inputs / outputs with the inputs / outputs of the signal processor, its inputs / outputs with inputs / outputs of a bootable permanent storage devices, their inputs / outputs with inputs / outputs of read-only memory, their inputs / outputs with inputs / outputs of an internal parallel asynchronous bus, their inputs / outputs with inputs / outputs of an Ethernet controller, their inputs / outputs with inputs / outputs of a bus converter, their inputs / outputs with inputs / outputs of an additional parallel asynchronous bus, its input with the output of the clock generator of the control controller, its inputs / outputs with inputs / outputs of the supervisor, its own moves / outputs with the inputs / outputs of the mezzanine control controller, its inputs / outputs with the inputs / outputs of the switch, and the mezzanine control controller is connected with its inputs / outputs with the inputs / outputs of the control controller, its inputs / outputs with the inputs / outputs of the synchronizer, its output with switch input, its inputs / outputs with inputs / outputs of an additional parallel asynchronous bus, its inputs / outputs with inputs / outputs of the data exchange bus, while the connectors for installing mezzanines are connected its inputs / outputs with inputs / outputs of the data bus, its inputs / outputs with inputs / outputs of the external converter of the internal interface, in turn, the external converter of the internal interface is connected with its inputs / outputs with the inputs / outputs of the external controller for controlling the mezzanine, which, in in turn, its inputs / outputs are connected to the inputs / outputs of the external converter of the external interface, and also connected to external lines. 2. The device according to claim 1, characterized in that the control unit comprises a clock with an autonomous power battery connected to the signal processor by an input / output. 3. The device according to claim 1, characterized in that the mezzanine control controller is provided with a synchronizer designed to sub-synchronize the system frequency with the frequency of external lines, and it is connected with its input / output to the input / output of the mezzanine control controller.