RU2629426C1 - Complex communication equipment room for transport network of field communication system - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: complex communication equipment room contains an APM operator and a mechanic, four LAN switches, two multiplexers of the combined communication systems, two electronic cross-channels, an integrated switching device, a group information coder, a broadband radio access station, three microwave stations, two laptop computers, a network multiplexer, two primary multiplexers, two group information encoders, an individual information encryptor, two telephone sets of the automatic telephone systems, three optical channel crosses, two cable entries, scanning and printing devices, a navigation equipment, fiber-optic lines, cable lines, connection lines, four-wire subscriber telephone lines, two-wire intercom lines, VHF radio intercom with antenna, service communication hardware, two remote controls and a communication control panel.

EFFECT: increasing the deployment efficiency of the communication lines, compiling routes and communication channels of the transport network, expanding the volume of communication services provided to consumers, increasing the protection of information transmitted along the generated paths and communication channels.

1 dwg

Description

The invention relates to communication and control systems and can be used to create field communication networks that carry out switching and transmission of various types of information over communication lines.

There are various communication systems designed to provide individual genera - radio, radio relay, tropospheric, satellite and wire communications, as well as types of communications, including telephone, telegraph and facsimile communications, data transmission. These include radio communication systems, radio-relay and tropospheric communication systems, satellite and wire communication systems. They provide the deployment of radio communication networks, radio-relay, tropospheric, satellite and wire lines of communication, through the channels of which various types of services are provided to consumers, including telephone and telegraph communications, fax and data transmission.

The use of these means of communication individually leads to an increase in the total volume of equipment, since their mutual use requires common switching devices and additional matching devices due to the use of various signal processing methods in them, and also leads to a decrease in the efficiency of communication due to an increase in time necessary for laying the connecting lines for the transmission of channels between consumers and the used channel-forming means of communication.

Of the known communication systems, the closest in technical essence to the proposed invention is selected as a prototype of the integrated hardware communications described in [1]. This communication hardware contains the operator's automated workstation (AWP), local area network switch (CLWS), two multiplexers of combined communication systems (MCCS), network transport units, two electronic cross-channels of Ethernet channels, two electronic cross-channels of E1 channels, multi-protocol information encoder (MSI ), an integrated switching device (IKU), broadband radio access stations, radio relay stations and LAN control channels.

In the well-known complex hardware communication, the problem of increasing the throughput of organized communication directions based on the operational change of the operating modes of the equipment and performing long-term (cross) switching of the formed channels and transmission paths is solved.

The main disadvantages of the well-known complex hardware communications are the insufficient efficiency of organizing communication directions and establishing connections through them due to the presence of only one operator workstation with one local network switch in the hardware, as well as insufficient security of various information transmitted through communication channels and paths. This is especially true for the initial setup of lines and the organization of transit connections, since at least two operators or an operator and a cross mechanic must participate in this process.

The aim of the invention is to increase the efficiency of deployment of communication lines, compiling paths and communication channels for the transport network, expanding the range of communication services provided to consumers and ensuring the protection of information transmitted through established paths and communication channels.

This goal is achieved by the fact that in the integrated equipment room for the transport network of the field communication system containing the operator's automated workstation (AWS), a local area network (LAN) switch, two multiplexers of combined communication systems (MCCS), two electronic cross-channels of channels, an integrated switching device (IKU), a group information encoder, a broadband radio access station (SHRD) with an antenna and two radio relay stations with antennas, an automated workstation (AWS) was added cross channel anics, two laptop computers designed for operator’s workstation equipment and channel cross mechanics, one radio relay station with antenna, network multiplexer (SM), two primary multiplexers (MP), three LAN switches, a second group information encoder, an individual information encoder, two telephones of the automatic telephone communication system (ATS), three optical cross-channels, two cable inputs, a scanning and printing device (USP), navigation equipment with a built-in antenna, fiber -optic communication lines (FOCL) for issuing channels at the E3 interface, cable communication lines for organizing xDSL data exchange with interacting hardware, FOCL for organizing paths using STM-1 technology, fiber-optic communication lines for organizing data exchange with consumers via E3 interface, cable communication lines for organizing xDSL technology data exchange with external workstations, trunk lines for channel transmission at C1-I junctions to consumers, four-wire telephone subscriber lines (AL), two-wire intercom lines, ultra a short-wave (VHF) service radio station with an antenna, service communication equipment (ACC), two control panels and a communication panel (PS), while the first channel inputs and outputs of the SHRD station, the high-frequency input-output of which is connected to the high-frequency input-output of the antenna, at the Ethernet junction, they are connected to the first inputs and outputs of the first LAN switch, the second, third, and fourth inputs and outputs of which are connected at the Ethernet joints, respectively, to the inputs and outputs of the AWP laptop computer cross-channel mechanics, to the first inputs and outputs of the second about the LAN switch and the first MCCS, the second inputs and outputs of which at the E3 interface are connected to the station inputs of the first optical cross-channel, the linear inputs and outputs of which at the E3 interface are connected to the first station inputs and outputs of the first cable input, the second station inputs and outputs of which the xDSL interface is connected to the linear inputs and outputs of the first electronic cross-channel, the station inputs and outputs of which at the xDSL interface are connected to the third inputs and outputs of the first MCCS, the fourth inputs and outputs of which are connected at the E1 interface with the first linear inputs and outputs of the network multiplexer, the second, third and fourth linear inputs and outputs of which at the E1 interface are connected respectively to the linear inputs and outputs of the first and second primary multiplexers and at the STM-1 interface to the station inputs and outputs of the second optical cross-channel , the linear inputs and outputs of which are connected to the third station inputs and outputs of the first cable input, the first, second and third station inputs and outputs of the network multiplexer at the joints E1 are connected to the channel inputs and outputs I will give, respectively, the first RRS, the high-frequency input-output of which is connected to the high-frequency input-output of the RRS antenna, the second RRS, the high-frequency input-output of which is connected to the high-frequency input-output of the RRS antenna, and the third RRS, whose high-frequency input-output is connected to the high-frequency input the RRS antenna output, the second channel inputs and outputs of the ShRD station at the Ethernet interface are connected to the first channel inputs and outputs of the cryptographic router, the second and third channel inputs and outputs of which are connected via the Ethernet interface respectively to the fifth inputs and outputs of the first multiplexer of the combined communication systems (MCCS) and to the fifth line inputs and outputs of the network multiplexer, the station inputs and outputs of the second multiplexer of the primary (MP) are connected to the second inputs and outputs of the second LAN switch, the first, second and third the linear inputs and outputs of the first cable input are connected to the FOCL inputs and outputs for issuing channels at the E3 interface, cable communication lines for organizing data exchange using xDSL technology with interacting hardware and fiber-optic communication lines for organizing paths using STM-1 technology, the first subscriber inputs / outputs of a cryptographic router at the Ethernet interface are connected to the first I / O inputs of the IKU, the second, third and fourth inputs and outputs of which at the E1 interface are connected to the subscriber inputs and outputs of the first and the second group information encoders and the individual information encoder, channel inputs and outputs of the first and second group encoders at E1 are connected respectively to the fourth and fifth station inputs and outputs of the network mult tiplexer, the first channel inputs-outputs of an individual encoder at interface E1 are connected to the station inputs and outputs of the first MP, and the second channel inputs and outputs of an individual encoder of information at interface C1-I are connected to discrete inputs and outputs of an VHF service station radio station, high-frequency input-output which is connected to the high-frequency input-output of the VHF antenna of the radio station, the linear inputs and outputs of the first and second telephone exchanges of the ATS system are connected via a four-wire interface to the first and second ICU subscriber sets, the fifth inputs and outputs of which at the Ethernet interface are connected to the first inputs and outputs of the third LAN switch, the second inputs and outputs of which at the Ethernet interface are connected to the first inputs and outputs of the second MCC, the second inputs and outputs of which are connected to the second subscriber inputs the outputs of the cryptographic router, the sixth inputs and outputs of the IKU at the E1 interface are connected to the third inputs and outputs of the second MCCS, the fourth inputs and outputs of which at the E3 interface are connected to the station inputs of the third optical cross channels, the linear inputs and outputs of which at the EZ interface are connected to the first station inputs and outputs of the second cable input, the second station inputs and outputs of which at the xDSL interface are connected to the linear inputs and outputs of the second electronic cross channel, the station inputs and outputs of which are connected at the xDSL interface with fifth inputs and outputs of the second MKSS, the third station inputs and outputs of the second cable input at the C1-I junction are connected to the seventh IKU inputs and outputs, the third inputs and outputs of the third LAN switch over the Ethernet junction are connected to the the inputs and outputs of the fourth LAN switch, the second inputs and outputs of which are connected via Ethernet to the first inputs and outputs of the operator’s portable computer, the second and third inputs and outputs of which are connected to the scan and printing and navigation equipment with a built-in antenna, the first, second, third, fourth and fifth linear inputs and outputs of the second cable input are connected to the FOCL inputs and outputs for organizing data exchange with consumers at the junction E3, cable communication lines for organizing data exchange using xDSL technology with external workstations, trunk lines for transferring channels at the interfaces C1-I to consumers, four-wire telephone subscriber lines (AL) and two-wire service communication lines, the fourth station inputs and outputs of the second cable input are connected to linear inputs and outputs of intercom equipment, the first, second and third station inputs and outputs of which are connected to the inputs and outputs of the first control panel, second control panel and communication console, respectively, channel inputs s-outs equipment intercom the junction of the PM is connected to the analog inputs-outputs VHF radio intercom.

Comparison with the prototype shows that the proposed integrated hardware communications for the transport network of the field communication system is characterized by the presence of new units, namely: an automated workstation (AWP) for channel cross-link mechanics, two laptop computers designed for the operator's AWP equipment and channel cross-link mechanics, one radio relay stations with an antenna, a network multiplexer (SM), two primary multiplexers (MP), three LAN switches, a second group information encoder, an individual encoder information, two telephone exchanges of the PBX system, three optical cross channels, two cable inputs, a scanning and printing device (USP), navigation equipment with a built-in antenna, fiber optic communication lines (FOCL) for issuing channels at the junction E3, cable communication lines for organization of data exchange using xDSL technology with interacting hardware, fiber-optic communication lines for arranging paths using STM-1 technology, fiber-optic communication lines for organizing data exchange with consumers at the junction of E3, cable communication lines for org xDSL technology data exchange with external workstations, trunk lines for transmission of channels at C1-I junctions to consumers, four-wire telephone subscriber lines (AL), two-wire service communication lines, ultra-short-wave (VHF) service radio station with antenna, service communication equipment (ACC) ), two control panels and a communication panel (PS), as well as a change in the connections between known units and devices.

Thus, the claimed integrated hardware communications for the transport network of the field communication system meets the criterion of "novelty."

Comparison of the claimed solution with other similar technical solutions shows that the blocks newly introduced into the proposed integrated hardware communications are realizable, well-known to specialists in this field of technology and additional creativity, given the explanations below, is not required to reproduce them. Moreover, the proposed technical solution does not explicitly follow from the prior art and differs significantly from known devices in the art, that is, it has an inventive step.

From the above, a conclusion follows on the conformity of the claimed technical solution to the criterion of "significant differences".

The claimed technical solution is implemented using existing equipment and devices used in telecommunication and computer engineering, and is industrially applicable. This is confirmed by the manufacture of prototypes, the equipment of which is located in a van on the chassis of a cross-country vehicle, and tests performed, the results of which confirmed the technical feasibility and achievement of the goal set in the proposed application for invention.

The drawing shows a structural electrical diagram of the proposed integrated hardware communications for the transport network of the field communication system, which indicates:

1 - broadband radio access station (SHRD);

2 - antenna of the ShRD station;

3 - the first radio relay station (RRS);

4 - antenna of the first RRS;

5 - second PPC;

6 - antenna of the second RRS;

7 - the third RRS;

8 - antenna of the third RRS;

9 - the first switch local area network (LAN);

10 - the first multiplexer combined communication systems (MCCS);

11 - network multiplexer (SM);

12 - the first primary multiplexer (MP);

13 - the second primary multiplexer (MP);

14 - the second LAN switch;

15 - laptop computer workstation (AWS) mechanics of cross channels;

16 - the first optical cross channels;

17 - the first electronic cross channel;

18 - the second optical cross channel;

19 - the first cable entry;

20 - fiber optic communication lines (FOCL) for issuing channels at the junction E3;

21 - cable communication lines for organizing data exchange using xDSL technology with interacting hardware;

22 - FOCL for the organization of tracts using STM-1 technology;

23 - cryptographic router;

24 - integrated switching device (RZHU);

25, 26 - the first and second group encoders;

27 - individual encoder;

28, 29 - the first and second telephone sets of an automatic telephone communication system (ATS);

30 - second MKSS;

31 - the third LAN switch;

32 - the fourth LAN switch;

33 - portable computer automated workplace (AWP) operator;

34 - scanning and printing device (USP);

35 - navigation equipment with a built-in antenna;

36 - the third optical cross channel;

37 - second electronic cross channel;

38 - the second cable entry;

39 - FOCL for organizing data exchange with channel consumers at the junction of E3;

40 - cable communication lines for organizing xDSL technology data exchange with external workstations;

41 - connecting lines (SL) for transmitting channels at the junction C1-I to consumers;

42 - four-wire subscriber lines (AL) telephone;

43 - two-wire communication lines;

44 - ultra-short-wave (VHF) intercom radio station;

45 - antenna VHF radio station intercom;

46 - intercom equipment (ACC);

47, 48 - the first and second control panels (PU) intercom equipment;

47 - communication panel (PS).

The first channel inputs and outputs of the ShRD 1 station, the high-frequency input-output of which is connected to the high-frequency input-output of the antenna 2, is connected at the Ethernet interface to the first inputs and outputs of the first 9 LAN switch, the second, third and fourth inputs and outputs of which are connected at the Ethernet joints respectively, to the inputs and outputs of a laptop computer AWP 15 channel cross mechanics, to the first inputs and outputs of the second 14 LAN switch and the first MCCS 10, the second inputs and outputs of which at junction E3 are connected to the station inputs of the first optical cross 16 to a channel, the linear inputs and outputs of which at the E3 interface are connected to the first station inputs and outputs of the first cable input 19, the second station inputs and outputs of which at the xDSL interface are connected to the linear inputs and outputs of the first 17 electronic cross-channels, the station inputs and outputs of which are connected xDSL are connected to the third inputs and outputs of the first MCCS 10, the fourth inputs and outputs of which at the E1 interface are connected to the first linear inputs and outputs of the network multiplexer 11, the second, third and fourth linear inputs and outputs of which are connected in E1 are respectively connected to the line inputs-outputs of the first 12 and second 13 multiplexers primary and the junction of the STM-1 to the station inputs-outputs of said second optical cross 18 channels, linear inputs and outputs are connected with the third Stationary inputs-outputs of the first cable entry 19.

The first, second and third station inputs and outputs of the network multiplexer 11 at the E1 junctions are connected to the channel inputs and outputs of the first RPC 3, the high-frequency input-output of which is connected to the high-frequency input-output of the antenna 4 RRS, the second RRS 5, the high-frequency input-output of which connected to the high-frequency input-output of the antenna 6 RRS, and the third RRS 7, the high-frequency input-output of which is connected to the high-frequency input-output of the antenna RRS 8.

The second channel inputs and outputs of the SHRD station 1 at the Ethernet interface are connected to the first channel inputs and outputs of the cryptographic router 23, the second and third channel inputs and outputs of which are connected via the Ethernet interface to the fifth inputs and outputs of the first multiplexer 10 of the combined communication systems (MCCS) and to the fifth linear inputs and outputs of the network multiplexer 11, the station inputs and outputs of the second multiplexer 13 of the primary (MP) are connected to the second inputs and outputs of the second 14 LAN switch.

The first, second and third linear inputs and outputs of the first cable entry 19 are connected to the input-output ports of the FOCL 20, respectively, for outputting channels at the E3 interface, cable lines 21 for organizing data exchange using xDSL technology with interacting hardware and FOCL 22 for organizing paths using technology STM-1. The first subscriber inputs and outputs of the cryptographic router 23 at the Ethernet interface are connected to the first inputs and outputs of the IKU 24, the second, third and fourth inputs and outputs of which at the E1 interface are connected to the subscriber inputs and outputs of the first 25 and second 26 group information encoders and an individual encoder 27 information, the channel inputs and outputs of the first 25 and second 26 group encoders at the E1 interface are connected respectively to the fourth and fifth station inputs and outputs of the network multiplexer 11, the first channel inputs are the passages of the individual encoder 27 at the junction E1 are connected to the station inputs-outputs of the first MP 12, and the second channel inputs and outputs of the individual encoder 27 of the information at the junction C1-I are connected to discrete inputs-outputs of the VHF radio station 44 service communication, the high-frequency input-output of which is connected with a high-frequency input-output antenna 45 VHF radio stations.

The linear inputs and outputs of the first 28 and second 29 telephone exchanges of the PBX system are connected via a four-wire interface to the first and second subscriber sets IKU 24, the fifth inputs and outputs of which are connected via Ethernet to the first inputs and outputs of the third 31 LAN switch, and the second inputs and outputs which, at the Ethernet junction, are connected to the first inputs and outputs of the second MKSS 30, the second inputs and outputs of which are connected to the second subscriber inputs and outputs of the cryptographic router 23, the sixth IKU 24 inputs and outputs at the E1 joint are dined with the third inputs and outputs of the second MKSS 30, the fourth inputs and outputs of which at the E3 interface are connected to the station inputs of the third 36 optical cross-channel, the linear inputs and outputs of which at the E3 interface are connected to the first station inputs and outputs of the second cable input 38, the second station the inputs and outputs of which at the xDSL interface are connected to the linear inputs and outputs of the second electronic cross of 37 channels, the station inputs and outputs of which at the xDSL interface are connected to the fifth inputs and outputs of the second MKSS 30, the third station inputs a second input-output of the cable 38 on the junction of C1-AND inputs are connected to the seventh-outs 24 ICU.

The third inputs and outputs of the third 31 LAN switch are connected via Ethernet to the first inputs and outputs of the fourth 32 LAN switch, the second inputs and outputs of which are connected via Ethernet to the first inputs and outputs of the operator's portable computer 33, the second and third inputs and outputs of which USB and RS-232 are connected to the inputs and outputs of the device 34 scan and print and navigation equipment 35 with a built-in antenna.

The first, second, third, fourth and fifth linear inputs and outputs of the second cable input 38 are connected to the fiber optic inputs and outputs 39 for organizing data exchange with consumers at the junction of E3, cable communication lines 40 for organizing data exchange using xDSL technology with external workstations, SL 41 for transmitting channels at the interfaces C1-I to consumers, four-wire subscriber lines (AL) 42 telephone communications and two-wire communication lines 43. The fourth station inputs and outputs of the second cable entry 38 are connected to the linear inputs and outputs of the service communication equipment 46, the first, second and third station inputs and outputs of which are connected to the inputs and outputs of the first 47 control panels, the second 48 control panels, and the communication panel 49, channel inputs and outputs of the equipment 46 for official communication at the junction of the PM are connected to the analog inputs and outputs of the VHF radio station 44 for official communication.

Broadband radio access station 1 together with antenna 2 is intended for the formation of a wireless broadband radio access network at a communication service distribution node, an access node based on the standard 802.16-2004, through which access to the public communication network is carried out, including by including it in communication paths organized using the communications equipment available in the hardware, as well as to provide autonomous operation in the relay mode on the high-frequency path. Its basis is a radio unit operating in the microwave range. Station 1 provides automatic organization of radio networks, automatic relay and routing of information, transmission and reception of digital information at the RS-232C interface with a maximum speed of 115 kbit / s, transmission and reception of digital information at the Ethernet interface with a maximum transmission rate of 10 Mbit / s according to IEEE 802.3 , transmission and reception of voice information at the junction of C1-PM.

As such a station, a WIMIC-2000s type radio access station and the R-169B radio station from the R-169 radio complex can be used commercially available by industry [2].

The antenna 2 of the ShRD station 1 is a wide-range omnidirectional antenna, which can be used as an AV 3.5 / 11 omnidirectional antenna.

Each of the three PPCs (3, 5, and 7) contains a digital modem and a transceiver made in the form of transceivers of the lower and upper subbands operating in accordance with DC-CDMA radio access technology, and also contains an antenna-feeder device, an antenna-rotary device, a unit controls and device for automated remote antenna alignment with an electronic compass. The RRS transceiver operates in the VHF and microwave frequency range. RRS together with their antennas provide the transmission of signals of group information streams at the E1, E3 and STM-1 junctions via the corresponding interfaces with speeds of 64, 2048 and 8448 kbit / s with the possibility of accessing the trunk lines of the public communication network through which communications with subscribers are established stationary and moving objects.

As an antenna for the mentioned RRS, a sector antenna of the type AP-390/12-UM is used. The composition of the specified antenna includes an automated slewing ring, with the help of which it is possible to quickly adjust the radiation direction and accurately align the antennas.

Radio relay stations 3, 5 and 7 are intended for the construction of multi-span digital radio relay communication lines. They are based on the use of DS-CDMA (Digital Signal-Code Division Multiple Access) technology and are designed to provide autonomous work in the field in the parking lot or in conjunction with other similar stations that are part of the field communication system node . In this case, up to four radio-relay communication lines can be organized, one direction of broadband wireless access (BWA) and network operation using STM-1 technology is ensured. For each of the radio-relay directions, the transmission of several digital streams E1 and E3 can be ensured, as well as the transmission of information on an Ethernet network with an exchange speed of up to 100 Mbps.

Each of the radio relay stations can operate in terminal mode, relay mode, and in the organization of broadband wireless access (BWA).

Antennas 4, 6 and 8 are part of the antenna-feeder device of the said RRS. Two antennas can be installed on the telescopic mast (not shown in the diagram), each of which belongs to one of two subbands (lower and upper).

To provide microwave communication in the lower range, an in-phase array can be used, which is a Z-shaped antenna consisting of four Z-emitters made of aluminum alloy pipes, a flat reflector and a power divider. It is designed for directional radiation and directional reception of signals in the specified frequency range.

As an antenna for the operation of each of the three radio relay stations in the upper range, a parabolic antenna with a mirror diameter of 1.5 m can be used.

The first 9, second 14, third 31 and fourth 32 LAN switches are designed to provide subscribers with access to an established local area network of hardware communication and fiber optic communication lines (FOCL) with data transmission over the established network via Ethernet 10 BASE-FX interface between automated jobs of officials of the hardware and external workstation.

As switches 9, 14, 31 and 32 of the local area network, a SKM-8 mobile network switch, commercially available by the industry, developed by SISTEMPROM OJSC (1350, N. Krasnoselskaya St., 105066, Moscow, Russia) can be used. . The specified switch complies with the IEEE 802.3u Fast Ethernet 10/100 Base T / TX Switch standard, has a 10/100 Base T / TX network interface (eight ports with 10TV PC connectors) and a configuration port for working with VLAN (virtual LAN), provides duplex and half duplex modes of operation, supports automatic detection of the transmission rate of 10/100 Mbit / s half / full duplex.

The first 10 and second 30 combined multiplexers of communication systems (MCCS) are intended for the formation of fiber-optic communication lines with a group transmission rate of 34368 kbit / s by combining several digital streams E1 in a group stream EZ.

Each of the two (10 and 30) combined multiplexers of communication systems is an integrated platform that combines the functions of multiplexing signals of all stages of PDH, Ethernet, signals of spectral multiplexing equipment (CWDM), equipment for organizing linear paths via fiber-optic communication cable and equipment channel allocation. It contains system and interface units, including a control unit with an integrated liquid crystal display (LCD) that monitors and controls the router, a multiplexer unit that converts several component E1 signals to an aggregate signal E3, and a linear optical unit that converts the E3 signal to linear an optical signal, and an electronic commutator of component signals E1, which performs the switching of flows E1 to E3 (performed programmatically) and switching channel intervals fishing in E1 (performed by software).

Multiplexers 10 and 30 carry out I / O functions and support interfaces: optical channel spectral multiplexing (CWDM), E1 and E3 with optical and electrical outputs, Ethernet 10/100 Base-T, data transmission (V35, V36), bcc and RS- 232.

Network multiplexer 11 is a device for flexible multiplexing of levels E0 / E1 / E2 / E3 / STM-1 and terminal equipment of linear paths, which is intended for the formation of various types of digital streams and their transmission in multi-channel signals via electric or optical cables with transmission rates from 64 up to 155520 kbit / s with the possibility of organizing the transit of channels between multi-channel signals, as well as input and allocation of n × 2 kbit / s channels from E0 / E1 / E2 / E3 streams, input and allocation of n × 64 kbit / s channels from E2 / streams E3 / STM-1 and tests th control channel formed.

The first 12 and second 13 primary multiplexers (MPs) are multifunctional equipment used on trunk lines that perform the functions of a multiplexer / demultiplexer of C1-TCH, C1-TG, and C1-I interfaces into USB interface channels. It provides signal transmission at a speed of 2048 kbit / s.

Automated workstations (AWS) of the mechanics of the cross-channel and operator, equipped on the basis of a portable computer 15 and 33, are designed to control the operation of hardware (hardware and equipment) hardware, switching and distribution of received channels and digital streams, organizing the exchange of information and data with interacting hardware (stations). At the same time, portable computers 15 and 33 AWP mechanics of cross-channel and operator provide:

1) input, storage, display and documentation of information using available in the hardware device 34 scan and print;

2) information exchange with interacting workstations through a data exchange network;

3) collecting, summarizing, displaying and documenting information on the status of communications, channels and equipment of integrated hardware communications;

4) accumulation, storage, registration and processing of received information;

5) visual control using a computer monitor information exchange;

6) automatic testing of communication channels, analysis and selection of optimal frequencies;

7) automatic diagnostics of equipment with a visual display of its technical condition;

8) remote control of the equipment from the integrated hardware in the amount of capabilities provided for in the equipment;

9) conducting telephone conversations and exchanging data on established communication channels and paths;

10) the solution of information and settlement problems in organizing areas of exchange of documentary information and communication channels;

11) information and functional interaction with navigation equipment, including the automatic reception of data to determine the coordinates of their location and entering them into the memory of a portable computer.

To perform these functions, each portable computer has a functional application software (FPO).

Portable computers 15 and 33 of the operator’s automated workstations and channel cross-country mechanics contain a system unit consisting of a motherboard on which a microprocessor, an ISA / PCI type system bus (bus), RAM, flashing ROM and keyboard controller, monitor adapter, port adapter are located , disk controller, controller for additional devices, hard magnetic disk, floppy disk drive, system software and application software, supplied On the hard disk drive, there are audio I / O cards, video I / O cards and Ethernet cards, and they also have a plasma screen display, a standard keyboard, and a mouse-type graphics pad.

As portable computers 15 and 33, a personal computer (PC) of the EC-1866 type can be used, which is a multifunctional terminal supplemented with hardware and software for navigation, communication and data transmission. Structurally, the EC-1866 type personal computer is a portable protected Notebook computer installed on a shock-absorbing frame in order to prevent its movement when the moving object is in motion.

The first 16, second 18 and third 36 optical cross-channels are a local area network (LAN) switch. The first 16 and second 18 optical cross-sections of channels are designed for switching optical signals and organizing access from a laptop computer 15 AWP mechanics to cross channels on external communication networks to ensure data transmission through them at the Ethernet 10/100 Base TX interface, and the third optical cross of 36 channels is intended for switching optical signals and organizing access from the operator’s laptop 33 to the channels and connecting lines to consumers, ensuring data transmission through them at the E1, C1-I and Ethernet 10/100 Base TX interfaces.

As the mentioned optical cross channels, a SKM-8 mobile network switch, commercially available by the industry, developed by SISTEMPROM OJSC (105066, Moscow, N. Krasnoselskaya St., 13, bldg. 1) can be used.

The first 17 and second 37 electronic cross-channels are an automated cross-switch with a switching field N × N input-output (communication channel). Structurally, crosses 17 and 37 are made in the form of a single monoblock, including linear and station sides, N lines are connected to each of them with the possibility of increasing the capacity of the cross. Each unit includes an electronic field, to which the connecting connectors of the linear and station sides are connected. They are designed for cross-connection of channels and communication lines in any combination. At the same time, it is possible to interconnect any N channels of the station side, interconnect any N channels of the linear side, as well as to interconnect the channels of the station side with the channels of the linear side.

The first 19 and second 38 cable entries contain connecting and switching elements (connectors, distribution combs and pins), to which, using cable connectors, connecting lines from external interacting objects and stations are connected. They are designed to distribute information and control circuits to the apparatus and equipment of a multifunctional document exchange station. Structurally, the first 19 and second 38 cable entries are made according to the same type in accordance with the industry standard, but differ in the number of connecting connectors installed on the input panels and the wiring of the cables (lines) of the connected cables and communication lines.

Fiber-optic communication lines (FOCL) 20 and 22 are designed to issue channels to consumers at the E3 interface and organize paths using STM-1 technology. These FOCLs can be implemented using optical cables of the type SSKO-PKO-02 of various lengths.

Cable communication lines 21 can be implemented using a field two-wire cable of type P-274M and a field telephone distribution cable with a quadruple structure of type P-269M-2 × 4 + 1 × 2.

Cryptographic router 23 is designed to create a high-speed secure multi-service telecommunications infrastructure on digital communication networks, provide routing and encryption of packets when the proposed integrated hardware communications in packet-switched networks. It provides IP routing of transmitted information, including data, voice messages and video information, when working on tonal frequency channels, digital communication channels on an IP network with encryption of IP packets.

Router 23 provides the formation of two digital streams E1 with a data transfer rate of 2048 kbit / s and two bcc channels with a transmission speed of 64 kbit / s. It has a modular design and contains a subscriber unit, switching and network units. At the same time, an integral switching device is connected to the subscriber unit at two E1 or Ethernet joints, and a multiplexer 30 combined at the Ethernet and E1 joints to output the corresponding digital streams is connected to the network unit, a second cable entry 38 at the E1, BCC and C1-I joints for output digital paths and communication channels to consumers.

As a protection device for the information transmitted via communication channels as part of the router 23, the encryptor of the data transmitted in the TCP / IP network "Crypto-TCP / IP" can be used. The specified data encoder is a hardware-software complex based on a personal computer such as IBM PC 486, Pentium and equipped with a touch-memory device to prevent unauthorized loading of the operating system. The complex provides data encryption and authentication with verification of the integrity of the transmitted information. The hardware-software complex is running the FreeBSD operating system and provides an exchange rate of 10 Mbps. The Ethernet protocol is used as the network interface.

To perform these functions, the cryptographic router 23 has physical interfaces RS-232C, C2, G.703, C1-FL-BI, Ethernet / IEEE 802.3 and it supports the following protocols (packet switching): Ethernet / IEEE 802.3, HDLC, UART , BISYNC.

To work on channels with a temporary separation of the flow, the router has the ability to connect to the T1, E1, PCM, ISDN lines through a removable interface module.

Integrated Switching Device (IKU) 24 is a hardware-software complex of switching and communication facilities.

IKU 24 provides operational switching in automatic mode or with the help of an operator (on a customized system) of telephone network subscribers between themselves and long-distance communication channels with the possibility of conducting information exchange (speech, data, file exchange, electronic correspondence and documentary messages) in accordance with a certain subscriber status. The device provides automatic monitoring of the state of its functional units and the transition to redundant modules when the main units exit.

The device 24 provides:

1) automatic and custom switching in the modes of incoming, outgoing and transit connections, as well as the organization of long-term channel transit on demand;

2) the possibility of information exchange through communication channels at the junctions C1-I and G.703;

3) automatic or custom communication with subscribers of moving objects and field communication systems;

4) the organization of interworking with similar systems or devices;

5) the formation of centralized call and conferencing networks according to applications received from workstations equipped with multifunctional terminals;

6) simultaneous switching of all types of transmitted messages.

The first 25 and second 26 group information encoders are designed to protect high-speed information transmitted through digital paths and communication channels with corresponding interfaces. These encoders contain a temporary compaction and decompression unit, a high-speed encoder, input and output matching devices. Information encryption principles are set forth in the relevant standards.

An individual information encoder 27 is designed to protect information transmitted via medium-speed digital communication channels at the C1-I junctions, with the aim of hiding the content of transmitted messages, protecting against entering false information and intercepting transmitted messages. It contains a temporary seal and decompression unit, an encoder, input and output matching devices. As such an individual encoder, the confidential communication device described in RF patent No. 2117401 [3] can be used, which contains a speech-conversion device analyzer, a pseudo-random sequence generator, a cipher overlay unit, a linear block (adder, digital-to-analog converter), and the receiving path includes a linear block (low-pass filter, analog-to-digital converter), a pseudo-random sequence generator, a cipher removal unit, a speech synthesizer a converting device, as well as a frequency forming unit.

As telephone sets 28 and 29 of the automatic telephone exchange system, telephone sets of the AT-3031 type can be used, intended for the operator and mechanic to cross-channel integrated hardware communication channels into an encrypted telephone communication network via an integrated switching device 24.

Scanning and printing device 34 is a multifunctional device designed for scanning A4 printed documents and converting from print to electronic form for subsequent transmission by e-mail, documenting various information received on channels and communication lines related to the organization of communication lines and directions, channels and tracts, documentation of data on the state of equipment and communications of integrated hardware.

As such a device, a multifunction device such as an HP Laser Jet M 1132 MFP can be used.

Navigation equipment 35 with a built-in antenna is a GPS / GLONASS navigation receiver, which is designed to receive and register data with the current coordinates of the location of the integrated hardware communications in the area with the display of the received data on the computer screen and ensure its binding to a single navigation system. Navigation equipment 35 receives data from a global satellite system GPS or GLONASS, which is designed for high-precision determination of the three coordinates of the place that make up the velocity and time vectors of various moving objects.

Navigation equipment 35 includes an antenna module and an electronic unit interconnected by high-frequency cables.

As such equipment can be used, for example, navigation equipment type 14Ts21.

Fiber-optic communication line 39 for organizing data exchange with consumers at the junction E3 can be performed using an optical cable type SSKO-PKO-02 of various lengths.

Cable communication lines 40 for organizing data exchange with external workstations can be implemented using a two-wire field cable of the P-274M type and a telephone distribution telephone cable with a quadruple structure of the P-269M-2 × 4 + 1 × 2 type.

Connecting lines 41 for transmitting channels at the C1-I junctions to consumers, four-wire telephone lines 42 and two-wire service lines 43 can be made using a field telephone distribution multi-pair cable with a four-structure type P-269M-4 × 4 + 2 × 4 .

The VHF intercom station 44 contains a microcomputer, a transceiver, a transceiver unit, a control, switching and pairing unit, a control panel and an external control panel that can be carried up to ten meters. The operation of all the components of the radio station is controlled through the serial I / O line of the micro-computer, which receives commands from the operator through the controls of the radio station and issues all the necessary messages to the display organs located on the front panel.

VHF radio station 44 is a frequency-modulated transceiver station and is designed to provide radio communications between ground-based moving objects in the parking lot and in motion when conducting the following types of work: telephone, auditory voice telegraph and digital signal-code communication.

As the VHF radio station 44, a VHF radio station of the R-168-25U-2 type with a power of up to 25 W can be used. This radio station is a VHF transceiver station with frequency modulation. It is designed to enter the radio communication network and to conduct automated, searchless and un tuned radio communications in the operating frequency range from 30 to 108 MHz between ground and mobile objects in the parking lot and in motion. Using the radio station 44, radio communication is carried out by accessing the radio network and exchanging voice and formalized messages.

The radio station provides various operating modes, including single-frequency and dual-frequency simplex, transmission and reception of a circular, address and tone call, standby mode of receiving a tone call at one of eight pre-set frequencies, noise reduction, manual or automated input of radio data, automated control serviceability.

As the antenna 45 for the VHF radio station 44 can be used transport wide-range antenna (TSDA). The TShDA antenna belongs to the pin type and consists of three rods connected by a threaded connection, and a shock absorber. A bracket is rigidly attached to the antenna body, with which the TShDA antenna is attached to a moving object.

Service communication equipment 46 is intended for organization of service communication with operators of interacting objects, including hardware communications and channel-forming facilities.

As the communication communication equipment 46, the “Dispatcher communication device” (patent of the Russian Federation No. 2307475, CL H04M 9/08, 09/27/2007) and the “Dispatch communication device” (RF patent No. 2132596, CL H04M) can be used 9/08, 06/27/1999).

These devices contain switching units and control panels that provide the connection of two-wire lines and communication channels, send them selective and circular calls, conduct on the connected lines of telephone service and speakerphone.

The first 47 and second 48 control panels and communication panel 49 are functionally complete terminal devices incorporating a standard telephone keypad, calling devices, handset and speakerphone (microphone with amplifier and loudspeaker). The mentioned control and communication panels are designed for telephone and loud-speaking communication via two-wire physical circuits, two- and four-wire tonal frequency channels and digital channels, KB and VHF radio channels with transmission rates of 1200, 2400 bit / s and 16 kbit / s.

The proposed integrated hardware communications for the transport network of the field communication system provides:

the provision of communication services to officials located in mobile facilities while working in the field;

the formation of fiber-optic communication lines using the MCCS multiplexer with a data transfer rate of 34368 kbit / s;

deployment of anchor lines with the formation in them of paths and communication channels with interfaces C1-I, BCC, PM, E1 for connecting to access nodes of a public communication network;

Deployment of subscriber lines of automatic telephone encrypted communication for the provision of communication services to users using RZHU;

the organization of several medium-speed independent directions of encrypted telephone communication with C1-I interfaces in automatic telephone exchange and RTS mode using IKU;

organization of several independent high-speed directions of encrypted telephone communication on E1 interfaces in automatic telephone exchange mode using IKU;

the formation of up to three radio-relay communication lines using radio-relay stations with the transmission of information on the lines with a speed of 2048 kbit / s;

the formation of microwave links using three RRS with the transmission of information through them at a speed of 34368 kbit / s and 155520 kbit / s;

the formation of a broadband radio access network at the access node using station 1 wideband radio access standard 802.16;

the formation of fiber-optic communication lines using MCCS multiplexers with a data transfer rate of 34368 kbit / s in the communication line;

the formation of fiber-optic communication lines using a network multiplexer with different information transfer rates;

formation of cable communication lines using xDSL technology with interacting hardware and external workstations using MKSS multiplexers with a transmission speed of up to 2048 kbit / s;

multiplexing, switching of digital channels with interfaces C1-I, TCH, BCC using primary multiplexers (MP);

multiplexing, switching and transmitting digital streams E1 using a network multiplexer;

encrypted data transmission, including the exchange of telephone messages, video information, files, facsimile and telegraph messages from external sources at the junctions C1-I, Ethernet, El and routing all types of information encapsulated in an IP packet using a cryptographic router;

encryption of high-speed channels with E1 interfaces using group information encoders;

encryption of medium-speed channels with the C1-I interface using an individual information encoder;

exit from operator’s workplaces and channel cross mechanics through an integrated switching device (IKU) 24 to an encrypted telephone network using telephone exchanges of the PBX system to interact with operators of similar hardware communications and higher-level communications officials;

formation of a broadband radio access network at access nodes of the field transport network;

official telephone communication with interacting hardware using service communication equipment (ACC), control panels and a communication panel;

official radio communication with the possibility of receiving and sending a selective call over a radio network using an VHF radio station, control panels and a communication panel of office communication equipment, including from a driver’s cabin;

support for a single time service, determining the coordinates of one's location using navigation equipment with a built-in antenna and displaying information on an electronic map of the area in the display of the operator’s portable computer.

The work of the proposed integrated hardware communications for the transport network of the field communication system is as follows.

After turning on the equipment and communications equipment in the work, setting the paths and communication channels on the displays of the laptop computers of the operator's operator and the mechanics of the cross-channel, all the information about the operating modes of all components of the hardware is displayed, which is accomplished by the cross and operational switching of digital channels, streams and communication channels as well as deployed subscriber telephone networks and trunk lines for issuing channels to consumers. This information is recorded in the memory of laptop computers and documented using a scanning and printing device. Information about operating modes is received on AWP computers from the components of hardware communication via LAN control channels.

In the process of functioning of complex hardware communication based on the analysis of the current operational and communication situation, the operator and the cross-country mechanic, within their authority, may decide to change the operating modes of a particular equipment, to redistribute the information flows by online switching devices, or to rebuild the communication network by performing cross switching channels and transmission paths. Based on the decision made, a set of appropriate control commands is carried out using the keyboard of the AWP portable computers, followed by their transfer via LAN control channels directly to the switching device actuators, which in this case are the multiplexers included in the hardware, optical and electronic cross-sections of the channels, a cryptographic router, integrated switching device, broadband radio access station and radio relay stations. Immediate execution of control commands, which is immediately displayed on the displays of portable computers of the operator’s workstation and channel cross mechanics, provides optimal adaptation of the operating modes of the entire complex of communication equipment and complex hardware communication equipment and, accordingly, the communication network structure to the prevailing conditions, thereby ensuring the maximum possible in these conditions increasing the efficiency of compiling paths and communication channels of the transport network and, accordingly, the throughput of organized directions th communication. At the same time, the protection of information transmitted through paths and communication channels through the use of high-speed group and individual information encoders is also provided.

Improving the efficiency of deployment of communication lines, compiling paths and communication channels of the transport network is also achieved due to the fact that the proposed integrated hardware allows access to operators of interacting hardware via office telephone and VHF radio networks using the ACC and VHF equipment introduced into it radio stations that operate both in the equipment parking lot and during its movement.

The technical effect of the proposed integrated hardware communications for the transport network of the field communication system is to increase the efficiency of deployment of communication lines, compiling paths and communication channels in the transport network, expanding the volume of communication services provided to consumers and ensuring the protection of information transmitted through established paths and communication channels, achieved through the introduction of new switching and control tools, including workstations, LAN switches and multiplexers, and hardware telephone service communication and service radio communication, which made it possible to provide direct interaction with operators of other hardware and consumers of communication services.

All this makes it possible to automate the processes of tuning, switching and switching paths and channels in the transport network from one communication direction to another, which allows for the transfer of information in bypass directions and thereby increase the structural and operational reliability of the field communication system itself.

Information sources

1. RU, patent No. 2390100 C2, IPC H04L 12/28, published Bull. No. 14, May 20, 2010 (prototype).

2. A set of technical means of mobile radio communications R-169. OJSC "Ryazan Radio Plant".

3. RU, patent No. 2117401, class. H04K 1/00, 1998.

Claims (1)

Integrated communications equipment for the field network communication system transport network containing an operator's automated workstation (AWS), a local area network (LAN) switch, two combined communication systems multiplexers (MKSS), two electronic channel cross-channels, an integrated switching device (IKU), a group encoder information station broadband radio access (SHRD) with an antenna and two radio relay stations with antennas, characterized in that it additionally introduced an automated workstation (AWS) mechanics to rosa channels, two laptop computers designed for equipment of the operator's workstation and channel cross mechanics, one radio relay station with antenna, network multiplexer (SM), two primary multiplexers (MP), three LAN switches, the second group information encoder, an individual information encoder, two telephone sets of automatic telephone communication system (ATS), three optical cross-channels, two cable inputs, a scanning and printing device (USP), navigation equipment with a built-in antenna, fiber optic communication lines (FOCL) for issuing channels at the E3 interface, cable communication lines for organizing data exchange using xDSL technology with interacting hardware, fiber optic links for organizing paths using STM-1 technology, fiber-optic communication lines for organizing data exchange with consumers at the interface E3, cable communication lines for organizing data exchange using xDSL technology with external workstations, trunk lines for transmitting channels at C1-I junctions to consumers, four-wire telephone subscriber lines (AL), two-wire communication lines, ultra-short Cow wave (VHF) service communication station with antenna, service communication equipment (ACC), two control panels and a communication panel (PS), while the first channel inputs and outputs of the ShRD station, the high-frequency input-output of which is connected to the high-frequency input-output of the antenna, at the Ethernet junction, they are connected to the first inputs and outputs of the first LAN switch, the second, third, and fourth inputs and outputs of which are connected at the Ethernet joints to the inputs and outputs of the cross-channel mechanics workstation portable computer, and to the first inputs and outputs of the second comm LAN and the first MCSS, the second inputs and outputs of which at the E3 interface are connected to the station inputs of the first optical cross-channel, the linear inputs and outputs of which at the E3 interface are connected to the first station inputs and outputs of the first cable input, the second station inputs and outputs of which are connected xDSL are connected to the linear inputs and outputs of the first electronic cross-channel, the station inputs and outputs of which at the xDSL junction are connected to the third inputs and outputs of the first MCCS, the fourth inputs and outputs of which at the E1 junction are connected to linear linear inputs and outputs of the network multiplexer, the second, third and fourth linear inputs and outputs of which at the E1 interface are connected respectively to the linear inputs and outputs of the first and second primary multiplexers and at the STM-1 interface to the station inputs and outputs of the second optical cross-channel, linear the inputs and outputs of which are connected to the third station inputs and outputs of the first cable input, the first, second and third station inputs and outputs of the network multiplexer at the joints E1 are connected to the channel inputs and outputs of the co respectively, the first RRS, the high-frequency input-output of which is connected to the high-frequency input-output of the RRS antenna, the second RRS, the high-frequency input-output of which is connected to the high-frequency input-output of the RRS antenna, and the third RRS, whose high-frequency input-output is connected to the high-frequency input-output RRS antennas, the second channel inputs and outputs of the ShRD station at the Ethernet interface are connected to the first channel inputs and outputs of the cryptographic router, the second and third channel inputs and outputs of which are connected via the Ethernet interface respectively only to the fifth inputs and outputs of the first multiplexer of the combined communication systems (MCCS) and the fifth line inputs and outputs of the network multiplexer, the station inputs and outputs of the second multiplexer of the primary (MP) are connected to the second inputs and outputs of the second LAN switch, the first, second, and third linear the inputs and outputs of the first cable input are connected to the inputs and outputs of the FOCL, respectively, for issuing channels at the E3 interface, cable communication lines for organizing data exchange using xDSL technology with interacting hardware and FOCL To organize paths using STM-1 technology, the first subscriber inputs / outputs of the cryptographic router at the Ethernet interface are connected to the first IKU inputs and outputs, the second, third and fourth inputs and outputs of which at the E1 interface are connected to the subscriber inputs and outputs of the first and second group information encoders and an individual information encoder, channel inputs and outputs of the first and second group encoders at the E1 interface are connected respectively to the fourth and fifth station inputs and outputs of the network multiplex ora, the first channel inputs and outputs of an individual encoder at interface E1 are connected to the station inputs and outputs of the first MP, and the second channel inputs and outputs of an individual encoder of information at interface C1-I are connected to discrete inputs and outputs of an VHF service station radio station, high-frequency input-output which is connected to the high-frequency input-output of the VHF antenna of the radio station, the linear inputs and outputs of the first and second telephone exchanges of the ATS system are connected via a four-wire interface to the first and second IKU Intent sets, the fifth inputs and outputs of which are connected at the Ethernet interface to the first inputs and outputs of the third LAN switch, the second inputs and outputs of which are connected at the Ethernet interface to the first inputs and outputs of the second MCC, the second inputs and outputs of which are connected to the second subscriber inputs the outputs of the cryptographic router, the sixth IKU inputs and outputs at the E1 interface are connected to the third inputs and outputs of the second MCCS, the fourth inputs and outputs of which at the E3 interface are connected to the station inputs of the third optical cross channel , the line inputs and outputs of which at the E3 interface are connected to the first station inputs and outputs of the second cable input, the second station inputs and outputs of which at the xDSL interface are connected to the linear inputs and outputs of the second electronic cross-channel, the station inputs and outputs of which at the xDSL interface are connected to the fifth inputs and outputs of the second MCCS, the third station inputs and outputs of the second cable input at the C1-I interface are connected to the seventh IKU inputs and outputs, the third inputs and outputs of the third LAN switch over the Ethernet interface are connected to the first inputs the outputs of the fourth LAN switch, the second inputs and outputs of which are connected at the Ethernet interface to the first inputs and outputs of the operator’s portable computer, the second and third inputs and outputs of which are connected to the scan and print devices respectively at the USB and RS-232 interfaces and navigation equipment with a built-in antenna, the first, second, third, fourth and fifth linear inputs and outputs of the second cable input are connected to the FOCL inputs and outputs for organizing data exchange with consumers at the junction of E3, cable lines communications for organizing data exchange using xDSL technology with external workstations, trunk lines for transmitting channels at the joints of C1-I consumers, four-wire telephone subscriber lines (AL) and two-wire service lines, the fourth station inputs and outputs of the second cable input are connected to linear inputs - outputs of intercom equipment, the first, second and third station inputs and outputs of which are connected to the inputs and outputs of the first control panel, second control panel and communication panel, channel inputs and outputs, respectively intercom equipment at the junction of the PM is connected to the analog inputs / outputs of the VHF intercom radio station.

Images