RU2800724C1 - Mobile multi-service telecommunication complex - Google Patents

Abstract

FIELD: communication means.

SUBSTANCE: communication and control systems used to create field communication networks that perform switching and transmission of various types of information over trunk communication lines.

A mobile multiservice telecommunication complex containing an automated workstation (AWS) of an operator equipped on the basis of a laptop computer, three multiplexers of combined communication systems, two electronic cross-sections of Ethernet streams, two electronic cross-sections of E1 streams, a multiprotocol information encoder, integrated switching unit (ISU), synchronous input-output multiplexer (SIOM) of the SDH system, broadband radio access stations, radio relay stations, HDSL modem(s), data transmission equipment (DTE), standard frequency and time receiver (SFTR) from the core network synchronization of the unified automated digital communication system, SFTR from radio stations, the standard frequency and time receiver of the GLONASS system, synchronization signal multiplication equipment (SSME), control channels and information channels of a local area network (LAN), a communication line with a synchronous output of a synchronous input-output multiplexer of the SDH systems and fiber-optic communication lines for issuing/receiving E3 streams to group communication users, additionally introduced a workstation for a cross-country mechanic equipped on the basis of a laptop computer, a printing device, a second LAN switch, cable communication lines for organizing HDSL exchange and telecommunications equipment consisting of a control module, a converter, an encoder, a laser source with a modulator, a transmitter module, a transmitting antenna, a receiving antenna, a photodetector module, a signal processing device with a preamplifier, a decoder and an atmospheric channel.

EFFECT: increasing the efficiency of the deployment of communication lines and the organization of various directions of communication, the compilation of paths and communication channels in the transport network, the expansion of the functionality of the device in terms of ensuring the deployment of atmospheric optical communication system equipment on its basis for a combination of atmospheric communication, radio and radio relay communication.

1 cl, 1 dwg

Description

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

There are various communication complexes designed to provide certain types - radio, radio relay, tropospheric, satellite and wired 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, satellite and wired communication systems. They ensure the deployment of radio communication networks, radio relay, tropospheric, satellite and wire communication lines, through which various types of services are provided to consumers, including telephone and telegraph communications, facsimile messages and data transmission.

The use of these means of communication each separately 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 required for the laying of connecting lines for the transmission of channels between consumers and the channel-forming means of communication used.

The closest in technical essence to the proposed invention is the complex hardware transport communication network chosen as a prototype, the structural diagram and technical capabilities of which are described in the patent of the Russian Federation No. 2440684 C1, IPC H04L 12/00, 2012 [1]. This complex equipment room contains an automated workstation (AWS) of the operator, three multiplexers of combined communication systems (MCSS), two electronic cross-sections of Ethernet streams, two electronic cross-sections of E1 streams, a multiprotocol information encoder (MSI), an integrated switching device (ICU), a synchronous input multiplexer -output (SMVV) of the SDH system, broadband radio access stations, radio relay stations, HDSL modem (s), data transmission equipment (DTE), frequency and time reference signal receiver (FRTSCHV) from the OADSS core network synchronization network, frequency and time reference signal receiver from specialized radio stations of the State Standard of Russia, a receiver of reference signals of frequency and time of the GLONASS system, synchronization signal multiplication equipment (ARSS), control channels of a local area network (LAN) and a communication line with a sync output of a synchronous input-output multiplexer of the SDH system.

The main disadvantage of the device according to the prototype is the lack of efficiency in organizing communication directions and establishing a connection along them due to the presence in the complex of only one workstation of the operator with one switch of the local area network, the inability to deploy communication channels based on the equipment of the atmospheric optical communication system in areas ( industrial areas, mountainous terrain, railways), where laying communication cables is impossible or impractical due to the high cost of this laying.

The aim of the invention is to increase the efficiency of the deployment of communication lines and the organization of various directions of communication, the compilation of paths and communication channels in the transport network, the expansion of the functionality of the device in terms of ensuring the deployment of atmospheric optical communication system equipment on its basis for a combination of atmospheric communication, radio and radio relay communication.

This goal is achieved by the fact that in a mobile multiservice telecommunication complex containing an automated workstation (AWS) of an operator equipped on the basis of a laptop computer, three multiplexers of combined communication systems (MCSS), two electronic cross-sections of Ethernet streams, two electronic cross-sections of E1 streams, a multiprotocol encoder information (MSHI), integrated switching device (ICU), synchronous input-output multiplexer (SMVM) of the SDH system, broadband radio access stations (SRD), radio relay stations, HDSL modem (s), data transmission equipment (ADD), frequency signal receiver and time (PESCHV) from the core network synchronization network of the unified automated digital communication system (OADSS), the receiver of reference frequency and time signals from specialized radio stations of the State Standard of Russia, the receiver of reference signals of frequency and time of the GLONASS system, synchronization signal multiplication equipment (ARSS), control channels and information channels of a local computer network, a communication line with a synchronous output of a synchronous input-output multiplexer of the SDH system and fiber-optic communication lines (FOCL) for issuing / receiving E3 streams to group communication users; a printing device, a second local area network (LAN) switch, cable communication lines for organizing HDSL exchange and telecommunications equipment, consisting of a control module, a converter, an encoder, a laser radiation source with a modulator, a transmitter module, a transmitting antenna, a receiving antenna, a photodetector module, a signal processing device with a preamplifier, a decoder and an atmospheric channel, while the inputs-outputs of the printing device are connected via a USB interface to the first inputs-outputs of the operator's workstation portable computer, the second inputs-outputs of which are connected via an Ethernet interface to the first inputs-outputs the first switch of the local area network (LAN), the second, third, fourth, fifth, sixth, seventh, eighth, ninth, tenth and eleventh inputs-outputs of which are connected to the control and information inputs-outputs via control channels and information channels via the Ethernet network, respectively of the first and second multiplexers of combined communication systems (MCSS), the first electronic cross of Ethernet streams, the first electronic cross of E1 streams, a multiprotocol information encoder, an integrated switching device, the second electronic cross of Ethernet streams, the second electronic cross of E1 streams, the third multiplexer of combined communication systems and synchronous input-output multiplexer of the SDH system, channel inputs-outputs of broadband radio access stations are connected to the twelfth inputs-outputs of the first LAN switch, the thirteenth inputs-outputs of which are connected to the channel inputs-outputs of radio relay stations, the first inputs-outputs of the FOCL for issuing/receiving E3 group streams communication users are connected to the subscriber inputs-outputs of the first MCSS, the station inputs-outputs of which are connected to the station inputs-outputs of the first electronic cross-section of Ethernet streams, the channel inputs-outputs of which are connected to the station inputs-outputs of the multiprotocol information encoder, the channel inputs-outputs of which are connected to to the first station inputs-outputs of the second electronic cross-section of Ethernet streams, the first channel inputs-outputs of which are connected through the first LAN switch via the Ethernet interface to the channel inputs-outputs of broadband radio access stations, the second channel inputs-outputs of the second electronic cross-section of Ethernet streams are connected to the first station inputs - outputs of the third MKSS, the channel inputs-outputs of the first electronic cross-section of flows E1 are connected to the station inputs-outputs of the integrated switching device (ICU), the channel inputs-outputs of which are connected to the first station inputs-outputs of the second electronic cross-section of flows E1, the first channel inputs-outputs of which via the Ethernet interface through the first LAN switch are connected to the channel inputs-outputs of radio relay stations, the second channel inputs-outputs of the second electronic cross-flow E1 are connected to the second station inputs-outputs of the third MKSS, the first station inputs-outputs of the second MKSS are connected to the second station inputs-outputs of the second electronic cross-section of Ethernet streams, the second station inputs-outputs of the second MKSS are connected to the station inputs-outputs of the first electronic cross-section of streams E1, the third station inputs-outputs of the second MKSS are connected to the second station inputs-outputs of the second electronic cross-section of streams E1, station inputs-outputs of modems HDSL and channel inputs-outputs of data transmission equipment (ADD) are connected respectively to the second and third station inputs-outputs of the first electronic cross-section of E1 streams, the second channel inputs-outputs of the second electronic cross-section of Ethernet streams and the second electronic cross-section of E1 streams are connected respectively to the first and second to the station inputs-outputs of the synchronous input-output multiplexer (SMVV) of the synchronous digital hierarchy (SDH) system, to the linear input-output of which a communication line with a synchronous output is connected, the input of the receiver of frequency and time reference signals (PESCHVV) from the core network clock network synchronization OATsSS is connected to the sync output of the synchronous input-output multiplexer of the SDH system, the outputs of the receivers of the reference frequency and time signals from the core network clock network synchronization of the OATSS, from the radio stations of the State Standard of Russia and from the GLONASS system are connected respectively to the first, second and third inputs of the synchronization signal multiplication equipment (ARSS ), the inputs-outputs of which are connected to the fourteenth inputs-outputs of the first LAN switch, the first additional inputs-outputs of which are connected via the Ethernet junction to the first inputs-outputs of the cross-country mechanic's portable computer workstation, the second inputs-outputs of which are connected via the Ethernet junction with the first inputs- outputs of the second LAN switch, the second inputs-outputs of which are connected to the second additional inputs-outputs of the first LAN switch, the third and fourth inputs-outputs of the second LAN switch are connected to the inputs-outputs, respectively, of the control module and the converter of the atmospheric optical communication line (AOLS) telecommunication equipment, the output of which is connected to the input of the encoder, the output of which is connected to the input of the laser radiation source, the output of which is connected to the input of the transmitter module, the high-frequency output of which is connected to the high-frequency input of the transmitting antenna, the output of which is connected to the atmospheric channel, connected by air to the input of the receiving antenna, the high-frequency output of which is connected to the high-frequency input of the photodetector module, the output of which is connected to the input of the signal processing device with a preamplifier, the output of which is connected to the input of the decoder, the output of which is connected to the input of the converter.

Comparison with the prototype shows that the proposed mobile multiservice telecommunications complex is characterized by the presence of new blocks, namely: a portable computer of an automated workplace (AWS) of a cross-country mechanic, a printing device, cable communication lines for organizing data exchange using HDSL technology with interacting objects, a second local switch a computer network (LAN), telecommunications equipment for an atmospheric optical communication line (AOLS), including a control module, a converter, an encoder, a laser radiation source with a modulator, a transmitter module, a transmitting antenna, an atmospheric communication channel, a receiving antenna, a photodetector module, a signal processing device with a preamplifier and a decoder, as well as changing the links between known blocks and devices of the complex.

Thus, the claimed mobile multiservice telecommunications complex meets the criterion of "novelty".

Comparison of the claimed solution with other similar technical solutions shows that the blocks newly introduced into the proposed mobile multiservice telecommunication complex are realizable, well known to specialists in this field of technology and additional creativity, given the explanations below, is not required for their reproduction. At the same time, the proposed technical solution does not explicitly follow from the prior art and differs significantly from known devices in this field of technology, that is, it has an inventive step.

From the foregoing follows the conclusion about the compliance of the proposed technical solution with the criterion of "significant differences".

The claimed technical solution is implemented using existing equipment and devices used in telecommunication and computer technology, and is industrially applicable.

The drawing shows a structural electrical diagram of the proposed mobile multiservice telecommunications complex, which indicates:

1 - portable computer workstation (AWP) operator;

2 - the first switch of the local area network (LAN);

3 - the first multiplexer combined communication systems (MKSS);

4 - the second multiplexer combined communication systems (MKSS);

5 - the first electronic cross of Ethernet streams;

6 - the first electronic cross flow E1;

7 - multiprotocol information encoder (MSI);

8 - integrated switching device (IKU);

9 - the second electronic cross of Ethernet streams;

10 - second electronic cross flow E1;

11 - the third multiplexer combined communication systems (MKSS);

12 - synchronous input-output multiplexer (SMVV) of the SDH system;

13 - stations of broadband radio access (SRD);

14 - radio relay stations;

15 - HDSL modem(s);

16 - data transmission equipment (ADD);

17 - receiver of reference signals of frequency and time (PEVSCHV) from the core network synchronization OATSS;

18 - receiver of reference signals of frequency and time (PESCHV) from specialized radio stations of the State Standard of Russia;

19 - receiver of reference signals of frequency and time (PESCHV) of the GLONASS system;

20 - synchronization signal multiplication equipment (ARSS);

21 - control channels and information channels of the local area network;

22 - communication line with the sync output of the synchronous input-output multiplexer of the SDH system;

23 - fiber-optic communication lines for receiving / issuing E3 streams to group communication users;

24 - cable communication lines for organization of exchange using HDSL technology;

25 - printing device;

26 - portable computer workstation (AWP) mechanic cross;

27 - the second switch of the local area network (LAN);

28 - telecommunication equipment of atmospheric optical communication line (AOLS) consisting of:

29 - control module,

30 - converter,

31 - encoder,

32 - source of laser radiation with a modulator,

33 - transmitter module,

34 - transmitting antenna,

35 - atmospheric channel,

36 - receiving antenna,

37 - photodetector module,

38 - signal processing device with preamplifier,

39 - decoder.

Automated workstations (AWS) of the operator and mechanic of the cross, equipped on the basis of portable computers 1 and 26, are designed to control the operation of the technical means (hardware and equipment) of the complex, switching and distributing the received channels and digital streams, organizing the exchange of information and data with interacting objects .

Portable computers 1 and 26 are the basis of the workstation of the operator and the mechanic of the cross. They are intended for switching and distributing received channels and digital streams, organizing the interconnected operation of equipment and equipment of a mobile multiservice telecommunication complex in the process of setting channels, establishing the required connections and transmitting voice and facsimile messages, documentary information and data over the formed channels. At the same time, the operator and the mechanic of the cross-country with the help of portable computers AWP carry out:

a) input, storage, display and documentation of information;

b) exchange of information with interacting workstations via a data exchange network;

c) collection, generalization, display and documentation of information about the state of communication, channels and equipment;

d) remote control of equipment from the composition of a mobile multiservice telecommunication complex to the extent of the capabilities provided for in the equipment;

e) solving information and calculation problems for organizing directions, paths and communication channels;

f) informational and functional interaction with the signal multiplication equipment 20, including automatic reception of data to determine the coordinates of one's location, reference frequency and time signals and entering them into the personal computer of each of the workstations.

As portable computers 1 and 26, a personal electronic computer (PC) of the EU-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 PC is a portable protected computer of the “Notebook” type, installed on a shock-absorbing frame in order to exclude its movement when a moving object is in motion.

Portable computers 1 and 26 of automated workplaces of the operator and the mechanic of the cross contain a system unit consisting of a motherboard on which a microprocessor is placed, an ISA / PCI type system bus (bus), RAM, flash ROM and a keyboard controller, a monitor adapter, a port adapter, disk controller, accessory controller, hard disk drive, floppy disk drive, system software and application software supplied on a hard disk drive, audio I/O cards, video I/O cards, and Ethernet cards, and also contain a plasma screen display, a standard keyboard and a graphical mouse.

The first 2 and second 27 LAN switches are designed to organize subscriber access to the formed local area network of the complex and fiber-optic communication lines (FOCL) with the provision of transmission over the formed data network via the Ethernet 10 BASE-FX interface between automated workstations of the operator, the mechanic of the cross-country and external workstations, as well as the formation of fiber-optic communication lines with a multicast transmission rate of 34368 kbps by combining several digital streams E1 into a multicast stream E3.

As switches 2 and 27 of the local area network, a commercially available network switch mobile type SKM-8, developed by SISTEMPROM OJSC (105066, Moscow, N. Krasnoselskaya St., 13, building 1), 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 PC 10TV type connectors) and a configuration port for working with VLAN (virtual LAN), provides full duplex and half duplex operation modes, supports 10/100 Mbps half/full duplex automatic transmission rate detection.

The first 3, second 4 and third 11 multiplexers of combined communication systems (MCSS) are designed to convert the signals of the E3 paths into the signals of the Ethernet and E1 paths, as well as into channels at the C1-I interface. MKSS is an integrated network access platform that combines the functions of multiplexing signals of all PDH and Ethernet levels, input, output and transit of the mentioned signals, as well as signals of voice frequency subscriber interfaces and the main digital channel (BCC), organization of linear paths over fiber optic or symmetrical communication cables, formation and switching of optical channels in the optical layer of fiber-optic networks using CWDM technology. MKSS supports E1, E2, E3 and E4 interfaces with optical and electrical outputs, Ethernet 10/100 Base-T, SDSL, BCC and TF.

The first 5 and second 9 electronic cross-sections of Ethernet streams, the first 6 and second 10 electronic cross-sections of E1 streams are an automated cross-switch with a switching field N'N input-output (communication channel). Structurally, the mentioned crosses are made in the form of a single monoblock, including the linear and station sides, to each of which N lines are connected with the possibility of increasing the capacity of the cross. Each block includes an electronic field, to which the connecting connectors of the line and station sides are connected. They are designed for cross-connection of channels and communication lines in any combination. This provides the possibility of interconnecting any N channels of the station side, interconnecting any N channels of the line side, as well as switching between the channels of the station side with the channels of the line side.

The multiprotocol information encoder 7 is a packet switch of Ethernet, E1 streams (channels) and channels at the C1-I junction, made on the basis of a cryptorouter, simultaneously converting part of the Ethernet streams into E1 streams and C1-I channels, and vice versa. As a multiprotocol information encoder 7, a cryptographic router can be used to create a high-speed secure multiservice telecommunication infrastructure on digital communication networks, to ensure routing and encryption of packets when the proposed mobile multiservice telecommunication complex operates in packet-switched networks. The information encoder 7 provides IP routing of the transmitted information, including data, voice messages and video information, when operating over voice frequency channels, digital communication channels on an IP network with encryption of IP packets.

Integrated switching device (ICU) 8 is a software and hardware complex of switching and communication.

Integral switching device 8 provides operational switching in automatic mode or with the help of an operator (on a custom system) of telephone network subscribers between themselves and on long-distance communication channels with the provision of information exchange (speech, data, file exchange, electronic correspondence and documentary messages) in accordance with a certain status of the subscriber. The device provides automatic monitoring of the state of its functional units and the transition to backup modules when the main units exit.

Integral switching device 8 performs:

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

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

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

4) organization of interconnection with similar systems or devices;

5) the formation of networks of centralized calling and conference calls on applications received from workplaces equipped with multifunctional terminals;

6) simultaneous switching of all types of transmitted messages. Synchronous input-output multiplexer 12 (SMBV) of the SDH system

is a multiplexer that performs the formation of station Ethernet and E1 streams based on the STV-1 main channel streams, and the corresponding inverse conversion. In addition to channel and station inputs-outputs of high-speed streams and a control input-output for connecting a LAN control channel, the synchronous multiplexer has a synchronous output, through which synchronization signals are output from the basic clock network synchronization of the unified automated digital communication system (OADSS) to external devices.

Broadband radio access stations 13, together with the antennas included in them, are designed to form a wireless broadband radio access network at a communication services distribution node, an access node based on the 802.16-2004 standard, through which access to the public communication network is carried out, including by including in communication paths organized using the communication facilities available in the complex, as well as to ensure autonomous operation in the relay mode over a high-frequency path. The basis of the station is a radio unit operating in the microwave range. Stations 13 provide automatic organization of access networks, automatic relaying and routing of information, transmission and reception of digital information over the RS-232C interface with a maximum speed of 115 kbps, transmission and reception of digital information over the Ethernet interface with a maximum transmission rate of 10 Mbps according to IEEE 802.3, transmission and reception of speech information at the C1-PM interface.

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

Antenna station 13 broadband radio access is a wide-range omnidirectional antenna, which can be used as an omnidirectional antenna type AB 3.5/11.

The radio relay stations 14 contain 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 control unit and a device for automated remote adjustment of the antenna with electronic compass. The RRS transceiver operates in the VHF and microwave frequency range. RRS together with their antennas provide transmission of signals of multicast information streams at the E1, E3 and STM-1 junctions via the corresponding interfaces at speeds of 64, 2048 and 8448 kbps with the ability to access 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 AR-390/12-UM type is used. The composition of the specified antenna includes an automated turntable, with which it is possible to promptly change the direction of radiation and fine-tune the antennas.

Radio relay stations 14 are designed to build multi-span digital radio-relay communication lines. They are based on the use of DS-CDMA technology (Digital Signal-Code Division Multiple Access - multiple access with code division of signals) and are designed to provide field operation in the parking lot autonomously or in cooperation with other similar stations that are part of the field communication system node . In this case, up to four radio-relay communication directions, one direction of broadband wireless access (BWA) can be organized and network operation is provided using STM-1 technology. For each of the radio relay directions, the transmission of several E1 and E3 digital streams can be provided, as well as the transmission of information in the Ethernet network with an exchange rate of up to 100 Mbps.

Modem (modems) 15 HDSL (High Data-Rate Digital Subscriber Line) systems are designed to provide users with access to the Internet by organizing high-speed information transmission lines that provide data transfer in both directions up to 2.048 Mbps. It provides the conversion of analog signals into digital form and back.

The data transmission equipment 16 is a channel-forming equipment and is intended for use as a data terminal equipment when organizing a data exchange network over channels and paths in a transport communication network.

The receivers 17, 18 and 19 of the frequency and time reference signals are designed to receive signals, respectively, from the OATSS core network, specialized radio stations of the State Standard of Russia and from the GLONASS system. As such receivers, receivers that are part of the navigation equipment of the "Grot-V" type, designed to equip mobile objects, can be used.

The purpose of the synchronization signal multiplication equipment 20 is to select the optimal synchronization signal for compliance with the parameters of the synchronization signal based on the synchronization pulses arriving at its inputs from three different receivers of the reference frequency and time signals (17, 18 and 19), the formation of synchronization signals with the same parameters and their transmission via local computing networks for all elements of a mobile multiservice telecommunication complex.

Fiber-optic communication lines (FOCL) 23 are designed to provide group communication users with streams at the E3 junction and organize paths using STM-1 technology. These FOCLs can be implemented using optical cables of the SSKO-PKO-02 type of various lengths.

Cable communication lines 24 can be implemented using a field two-wire cable of the P-274M type and a field telephone distribution cable with a quad structure of the P-269M-2×4+1×2 type.

The printing device 25 is designed to transmit and print messages received via channels and communication lines, various data, including facsimile messages, data on the technical condition and operation of the equipment of a mobile multiservice telecommunication complex. As such a unit, a Smart Base MPC600F fax / printer multifunctional device that acts as a printer and a fax machine or an HP Laser Jet M 1132 MFP multifunctional device can be used.

Telecommunication equipment 28 atmospheric optical communication line (AOLS) as part of control module 29, converter 30, encoder 31, source 32 of laser radiation with a modulator, transmitter module 33, transmitting antenna 34, atmospheric communication channel 35, receiving antenna 36, photodetector module 37 device, a signal processing device 38 with a preamplifier and a decoder 39 is designed to form high-speed communication channels between various (moving, stationary) objects using the method of data transmission in open space by a highly directional laser beam in line-of-sight conditions. AOLS equipment is quite mobile and simple in its design. When this transmission is optoelectronic conversion of the signal coming from the output of the converter 30 to the input of the encoder 31 connected to the source 32 of laser radiation with a modulator. In the source 32, the signal is modulated by a laser emitter, the output of which is connected to the input of the module 33 of the transmitting device, the signal from the output of which, through the transmitting antenna 34 and the atmosphere 35, is transmitted over the air to the receiving side. On the receiving side, the response optical signal from the side of the correspondent through the atmosphere 35 and the receiving antenna 36 enters the input of the photodetector module 37, the output of which is connected to the input of the signal processing device 38 with a preamplifier, which converts the optical beam into an electrical signal. Further, the signal from the output of the signal processing device 38 with a preamplifier demodulated by the decoder 39 signal through the converter 30, the second switch 25 of the local area network (LAN) and the first switch 2 LAN is fed to the user equipment of the atmospheric channel.

The control module 29 is a device that, through the LAN switches 25 and 2, interacts with the devices of the equipment 28 of the atmospheric optical communication line (AOLS), namely, it performs logical data conversion. Structurally, the control module 29 can be made as a microcontroller.

The converter 30 is a device that converts the information signal into an output interface signal. It provides the formation of all the necessary signals for the functioning of wireless optical communication channels. As the converter 30 can be used a universal media converter, consisting of two transceivers that can transmit and receive data from each other.

As encoder 31, an encoder with a sequential information coding system can be used, in which the code corrects all distorted symbols containing an error, thereby increasing the noise immunity of atmospheric optical communication line equipment in a turbulent atmospheric communication channel. The encoder converts the parallel code into serial, forming the output pulse-code modulated signal.

The modulated laser source 32 is a device that converts input signals to transmit modulated infrared data via an atmospheric communication channel 35. A transceiver module with an output signal power of less than 100 mW can be used as a laser source 32 to maintain a high speed. data transmission and with a bandwidth of 100-155 Mbps over a distance of up to 1200 km or a commercial diode laser with a GaAIAs-based heterostructure and a wavelength of 820 mm with an output power of 50 mW. The source modulator 32 is a microcontroller and is designed to control the emitter of light waves in accordance with the signals received after data conversion.

The transmitter module 33 is a device in which a narrow collimated laser beam is generated by the transmitter optical system for transmission to the atmospheric channel 35.

As the transmitting antenna 34, a parabolic antenna with a mirror diameter of 0.6 to 1.2 meters can be used. Such an antenna has a prefabricated structure and during transportation it is placed on the roof of a moving object.

As the receiving antenna 36, a parabolic antenna with a mirror diameter of 0.6 to 1.2 meters can be used. It has a prefabricated structure and is placed on the roof of a movable object during transportation.

The photodetector module 37 is a device in which an information optical signal is focused on a highly sensitive photodiode that receives an optical beam of encoded information. As a module 37 of the photodetector, a universal device can be used, consisting of cascades of subsequent amplification or digital cascades according to the direct detection method, where the optical signal is transformed through a matching element to a photodetector, a preamplifier that amplifies the electrical signal to the required signal-to-noise ratio, the main amplifier , which provides the necessary gain for the operation of subsequent devices, a corrector filter that equalizes the amplitude characteristic of the linear path, compensating for distortions introduced by the line and the input circuit of the photodetector.

The preamplifier signal processing device 38 is a device in which the received signal is amplified in order to transmit a message to the portable computer 1 of the telecom operator's workstation.

The decoder 39 is a device that generates a demodulated signal that is converted by the converter 30 into an output interface signal. The decoder 39 is designed to restore the received pulse code modulated (PCM) signal into a parallel code. As a decoder 39, a linear decoder can be used, containing a code converter, a logic device, and a reference current generator.

The work of the proposed mobile multiservice telecommunications complex is carried out as follows.

E3 information flows coming through the first inputs-outputs of the FOCL 23 from group users to the subscriber inputs-outputs of the first MKSS 3, from its station inputs-outputs in the form of Ethernet streams are sent to the station inputs-outputs of the first electronic cross 5 Ethernet streams, from channel inputs - the outputs of which are fed to the station inputs-outputs of the multiprotocol encoder 7 of information, from the channel inputs-outputs of which they are fed to the station inputs-outputs of the second electronic cross 9 Ethernet streams.

Information flows E3 coming through the second inputs-outputs of the FOCL 23 from group users to the subscriber inputs-outputs of the second multiplexer 4 of the combined communication systems, from its station inputs-outputs in the form of the corresponding Ethernet and E1 streams, are transmitted to the corresponding station inputs-outputs of the first electronic cross 6 E1 streams, station inputs-outputs of the second electronic cross 9 Ethernet streams and station inputs-outputs of the second electronic cross 10 E1 streams.

Information flows E1 from the channel inputs-outputs of the first electronic cross 6 flows E1, having passed the integral switching device 8, arrive at the corresponding station inputs-outputs of the second electronic cross 10 flows E1.

From the channel inputs-outputs of the second electronic cross 9 Ethernet streams and the second electronic cross 10 E1 streams, the corresponding information streams Ethernet and El are fed to the corresponding station inputs and outputs of the third multiplexer 11 of the combined communication systems, the synchronous multiplexer 12 of the input-output of the SDH system, to the inputs - the outputs of stations 13 of broadband radio access and radio relay stations 14, from the channel inputs-outputs of which in the form of corresponding high-speed backbone streams (STM-1, E3 and E1) via a fiber-optic cable or ether are transmitted to the associated backbone communication nodes, which can be both stationary and mobile communication objects, including similar mobile multiservice telecommunication complexes.

Thus, information received or transmitted via FOCL 23 from group users as part of E3 streams to the first 3 and second 4 ISS, having passed electronic crosses 5 and 6 or 6 and 10 and a multiprotocol encoder 7 of information or an integrated switching device 8, is transmitted to the corresponding nodes as part of high-speed trunk flows (STM-1, E3 or E1).

At the same time, information received or transmitted from group users as part of E3 streams to the second MKSS 4, due to the direct connection of the channel inputs/outputs of the second multiplexer 4 with the station inputs/outputs of the second electronic cross 9 Ethernet streams and the second electronic cross 10 E1 streams , can be transmitted to the corresponding nodes, bypassing the ICU 8, thereby forming a long-term structure of communication networks, resulting in a decrease in the volume of operational switching.

At the same time, the information coming to the channel inputs-outputs of the third MKSS 11 from the corresponding nodes as part of the main E3 streams can be transmitted by performing the appropriate transit cross-switching on the second electronic cross 9 of the Ethernet streams or on the second electronic cross 10 of the E1 streams to the opposite corresponding nodes as part of the main streams of the synchronous multiplexer 12 input-output system of the synchronous digital hierarchy (SDH), as well as in the opposite direction.

By means of connected to the station inputs-outputs of the first electronic cross 6 E1 streams of HDSL modems 15 and data transmission equipment 16, communication is provided via electric communication cables, respectively, with remote and nearby users. At the same time, information in the form of E1 streams from the terminal equipment of user data via a cable line 24 through a modem 15 or directly from the input-output of the data transmission equipment 16 enters the inputs-outputs of the first electronic cross 6 of the E1 streams, then information from the input-output of the cross 6 through the second MKSS 4 and FOCL 23 comes to nearby users, and from the input-output of the first electronic cross 6 of E1 streams through the information channels 21 of the LAN and the first switch 2 of the LAN, the information is transmitted through the channels of the station 13 of broadband radio access or through the channels of the radio relay station 14 to remote users.

The organization of transmission / reception of information to remote users located in the territory where it is not possible to lay cable communication lines or fiber-optic communication lines is carried out using telecommunication equipment 28 of an atmospheric optical communication line. At the same time, information from remote users connected to the channels of the atmospheric optical communication line from the input-output of the converter 30 through the second switch 27 of the local area network enters the second additional inputs-outputs of the first switch 2 of the LAN and then information on the information channels 21 of the LAN through the second electronic cross 9 Ethernet streams, multiprotocol encoder 7 information, the first electronic cross 5 Ethernet streams, the first MKSS 3 or the second MKSS 4 and FOCL 23 are transmitted to nearby group users, and through the second electronic cross 9 Ethernet streams, the second MKSS 4, the first electronic cross 6 streams E1, the HDSL modem 15 and cable links 24 are transmitted to other nearby users.

The presence of the paths and communication channels described above contributes to the increase in the flexibility and stability of the functioning of the transport communication network, thereby ensuring an increase in the volume and quality of communication services provided to users.

The speed of the mobile multiservice telecommunication complex ensures the operational adaptation of the equipment operation modes.

If it is impossible to provide the object with wired communication and radio communication, or if there are insurmountable obstacles of the natural landscape, using laptop computers 1 and 26, the operator and the cross-country mechanic deploy the telecommunications equipment 28 of the atmospheric optical communication line (FOCL), which acts as a backup system, perform tuning and alignment equipment, as a result of which a wireless atmospheric optical communication channel is created, which makes it possible to transfer data (Internet, voice, video, telephony, television) between interacting objects.

At the same time, due to the inclusion in the composition of the proposed mobile multiservice telecommunication complex equipment 28 AOLS, namely: a control module 29 that monitors the state of the AOLS equipment, a converter 30 that converts an electrical signal into a form acceptable for transmission by a source 32 of laser radiation and vice versa, an encoder 31 , which performs signal modulation with various noise-immune codes, a laser radiation source 32 with a modulator that performs further conversion and control of the emitter of light waves in accordance with the signals coming from the encoder 31, the module 33 of the transmitting device and the transmitting antenna 34, creating a light flux and performing vector focusing on a directional object, a receiving antenna 36 and a photodetector module 37 that receive the input signal, a signal processing device 38 with a preamplifier that amplifies the incoming signal and then converts it back into an electrical interface format, a decoder 39 that restores the electrical signal in its original form, provided:

creation of additional communication channels used to deploy backup communication lines in the transport network;

connection of subscribers through insurmountable barriers (there is no possibility for organizing cable communication lines and radio communication, the presence of various kinds of interference that degrade the quality of communication);

increasing the capacity of existing communication channels due to the ability of an optical signal to send and receive at the highest possible speed with sufficient power of the light beam;

creation of an almost unlimited number of channels in close proximity to each other due to the narrow radiation pattern;

high security of the communication channel without the possibility of intercepting information, due to the natural conditions that a narrow beam with low scattering creates, thereby making it impossible to install signal interception devices in standard places for this;

the ability to provide additional encryption by connecting to an encryption device that outputs an Ethernet signal;

no delay in the transmission of information as in radio links;

the possibility of combining several local computer networks.

The improvement of the operation of the mobile multiservice telecommunication complex is facilitated by the fact that the reference signals of frequency and time allocated to the corresponding receivers 17 from the core network of the OATSS, from specialized radio stations 18 of the State Standard of Russia and from the GLONASS system 19, are fed to the synchronization signal multiplication equipment 20, from where, by means of a local computer networks are transmitted to all elements of the mobile multiservice telecommunication complex and distributed among the elements of the transport communication network.

The control signals coming from the portable computer 1 of the operator's workstation or the laptop computer 26 of the cross-country mechanic's workstation, through the first 2 and second 27 switches of the local area network (LAN), control channels and information channels 21 LAN, are transmitted to all elements of the mobile multiservice telecommunication complex, for due to which long-term switching is carried out on electronic crosses 5 and 9 of Ethernet streams and electronic crosses 6 and 10 of E1 streams, as a result of which a long-term distribution structure of information flows (paths and transmission channels) is formed.

Operational management of information flows is carried out by performing packet switching by a multiprotocol information encoder 7 and an integrated switching device 8, while also providing control and management of all other elements of the complex.

In working condition, on the display of the portable computer 1 workstation of the operator and the portable computer 26 workstation of the mechanic of the cross-country, information is displayed on the operating modes of all the components of the complex and the cross-connected and operational switching of digital channels and streams. This information is also documented by the printer 25 and stored in its storage device. Information about the operating modes is received on the portable computer 1 of the operator's workstation and the portable computer 26 of the workstation of the cross-country mechanic from the components of the complex via control channels 21 and information channels of the LAN.

Based on the analysis of the current operational situation and the communication situation, the operator and the mechanic of the cross, within their authority, decide to change the operating modes of one or another equipment, to redistribute information flows by operational switching devices, or to rebuild the structure of the communication network by performing cross switching paths and communication channels .

At the same time, on the basis of the decision made, using the keyboard of portable computers 1 and 26 of the operator’s and the mechanic’s workstations, a set of appropriate control commands is carried out with their subsequent transmission via the control channels of the LAN network directly to the actuating devices of multiplexers, modems, data transmission equipment, a multiprotocol information encoder, an integrated switching devices, electronic cross-countries, stations of broadband radio access, radio relay stations, receivers of reference signals of frequency and time, synchronization signals multiplication equipment.

Immediate execution of control commands, which is immediately displayed on the display of the portable computer of the operator's workstation, ensures optimal adaptation of the operation modes of the complex equipment and the structure of the communication network to the prevailing conditions, thereby ensuring the maximum possible throughput of communication directions under these conditions.

At the same time, due to the presence in the complex of the synchronous multiplexer 12 of the input-output system SDH, the presence of a direct connection between the station inputs-outputs of the second MKSS 4 with the station inputs-outputs of the second electronic cross 9 Ethernet streams and the second electronic cross 10 E1 streams, the presence of modems 15 HDSL, data transmission equipment 16, three receivers 17, 18 and 19 of frequency and time reference signals, synchronization signal multiplication equipment 20 are provided with:

transmission (transfer), routing (switching) and distribution of integrated (heterogeneous) traffic flows, including high-speed synchronous digital hierarchy (SDH) paths between users located in different access networks at a considerable distance from each other;

transmission of information flows, bypassing the integral switching device (operational switching device);

organization of communication with nearby users and with remote users via fiber-optic communication lines and electric cables;

organization of communication with remote users via channels formed by atmospheric optical communication line telecommunication equipment;

the formation of radio relay communication lines using radio relay stations with the transmission of information over them at a speed of 34368 kbps and 155520 kbps;

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

formation of fiber-optic communication lines using MKSS multiplexers with an information transfer rate in the communication line of 34368 kbps;

the formation of fiber-optic communication lines using a synchronous input-output multiplexer with different data transfer rates;

formation of cable communication lines using HDSL technology with interacting objects and external workstations using MKSS multiplexers with a transmission rate of up to 2048 kbps;

encrypted data transmission, including the exchange of telephone messages, video information, files, facsimile and telegraph messages from external sources via C1-I, Ethernet, E1 interfaces and routing of all types of information encapsulated in an IP packet using a cryptographic router;

exit from the workstations of the operator and the mechanic of the cross-country through the integrated switching device (ICU) 7 to the encrypted telephone network using telephone sets of the PBX system to interact with operators of similar hardware communications and higher communications officials;

creation of a distributed network of clock network synchronization of elements of a transport communication network.

The work of the proposed mobile multiservice telecommunications complex is carried out as follows.

After turning on the equipment and means of communication in operation, setting up communication paths and channels, the displays of portable computers of the operator's workstation and the mechanic of the cross display all information about the operating modes of all the components of the complex, the cross-connect and operational switching of digital paths, flows and communication channels, and as well as deployed subscriber telephone networks and connecting lines for issuing channels to consumers. This information is recorded in the memory of portable computers and documented using a printer. Information about the operating modes is received by the computers of the workstation from the components of the complex through the control channels of the LAN network.

During the operation of the complex, based on an analysis of the current operational situation and the communication situation, the operator and the mechanic of the cross, within their powers, can decide to change the operating modes of one or another equipment, to redistribute information flows by operational switching devices, or to rebuild the communication network by performing cross switching channels and transmission paths.

Therefore, it can be concluded that the goal set for this invention has been achieved.

The technical and economic effect due to the use of the proposed multi-service telecommunication complex consists in a significant increase in maneuverability, flexibility in the configuration and size of the network, universality of interfaces, the presence of a wide bandwidth that does not affect the data transfer rate, high security, efficiency and quality of management of the structure of communication networks, in improving the efficiency of the functioning of communication networks, increasing the efficiency of deploying communication lines, compiling communication paths and communication channels in the transport network by introducing a portable computer workstation of a cross-country mechanic and a second LAN switch, expanding the volume of communication services provided to consumers and ensuring the protection of information transmitted over formed paths and communication channels, achieved through the introduction of new means of switching and control, telecommunications equipment AOLS. On the basis of the decision made, by means of the keyboard of portable computers of the workstation, a set of appropriate control commands is carried out with their subsequent transmission through the control channels of the LAN network directly to

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

A very significant advantage of the proposed complex is that all its constituent elements are by now quite well known and mastered in industry.

Information sources.

1. RU, patent No. 2440684 C1, IPC H04L 12/00, published by Bull. No. 2, 01/20/2012 (prototype).

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

Claims (1)

A mobile multiservice telecommunication complex containing an automated workstation (AWS) of an operator equipped on the basis of a laptop computer, the first switch of a local area network (LAN), three multiplexers of combined communication systems (MCSS), two electronic cross-sections of Ethernet streams, two electronic cross-sections of E1 streams, multiprotocol information encoder (MSI), integrated switching device (ICU), synchronous input-output multiplexer (SMI) of the SDH system, broadband radio access stations (SRD), radio relay stations, HDSL modems, data transmission equipment (ADD), receiver of frequency reference signals and time (PESCHV) from the core network synchronization network of the unified automated digital communication system (OADSS), the receiver of reference frequency and time signals from radio stations, the receiver of reference signals of frequency and time of the GLONASS system, synchronization signal multiplication equipment (ARSS), control channels and information channels of the local computer network, a communication line with a synchronous output of the synchronous input-output multiplexer of the SDH system and fiber-optic communication lines (FOCL) for issuing / receiving E3 streams to group communication users, characterized in that it additionally includes an automated workstation of a cross-country mechanic, equipped on the basis of a laptop computer, a printing device, a second local area network (LAN) switch, cable communication lines for organizing HDSL exchange and telecommunications equipment, consisting of a control module, a converter, an encoder, a laser radiation source with a modulator, a transmitter module, a transmitting antenna, a receiving antenna, a photodetector module, a signal processing device with a preamplifier, a decoder and an atmospheric channel, while the inputs/outputs of the printing device are connected via a USB interface to the first inputs/outputs of the operator's workstation portable computer, the second inputs/outputs of which are connected via an Ethernet interface to the first inputs-outputs of the first switch of the local area network (LAN), the second, third, fourth, fifth, sixth, seventh, eighth, ninth, tenth and eleventh inputs-outputs of which are connected to the control and information inputs via control channels and information channels via the Ethernet network - outputs, respectively, of the first and second multiplexers of combined communication systems (MCSS), the first electronic cross-section of Ethernet streams, the first electronic cross-section of E1 streams, a multiprotocol information encoder, an integrated switching device, the second electronic cross-section of Ethernet streams, the second electronic cross-section of E1 streams, the third multiplexer of the combined systems communication and synchronous input-output multiplexer of the SDH system, channel inputs-outputs of broadband radio access stations are connected to the twelfth inputs-outputs of the first LAN switch, the thirteenth inputs-outputs of which are connected to the channel inputs-outputs of radio relay stations, the first inputs-outputs of FOCL for issuing/receiving E3 flows of group communication users are connected to the subscriber inputs-outputs of the first MKSS, the station inputs-outputs of which are connected to the station inputs-outputs of the first electronic cross-section of Ethernet flows, the channel inputs-outputs of which are connected to the station inputs-outputs of the multiprotocol information encoder, channel inputs-outputs which are connected to the first station inputs-outputs of the second electronic cross-section of Ethernet streams, the first channel inputs-outputs of the second electronic cross-section of Ethernet streams are connected to the first station inputs-outputs of the third MKSS, the second inputs-outputs of the FOCL for issuing/receiving E3 streams of group communication users are connected to subscriber inputs-outputs of the second MKSS, the first station inputs-outputs of which are connected to the first station inputs-outputs of the first electronic cross-section of flows E1, the channel inputs-outputs of which are connected to the station inputs-outputs of the integrated switching device (ICU), the channel inputs-outputs of which are connected to the first station inputs-outputs of the second electronic cross-section of streams E, the first channel inputs-outputs of which are connected to the second station inputs-outputs of the third MKSS, the second station inputs-outputs of the second MKSS are connected to the second station inputs-outputs of the second electronic cross-section of Ethernet streams, the third station the inputs-outputs of the second MCSS are connected to the second station inputs-outputs of the second electronic cross-section of E1 streams, the station inputs-outputs of HDSL modems and the channel inputs-outputs of data transmission equipment (ADD) are connected respectively to the second and third station inputs-outputs of the first electronic cross-section of E1 streams , the second channel inputs-outputs of the second electronic cross-section of Ethernet streams and the second electronic cross-section of flows E1 are connected respectively to the first and second station inputs-outputs of the synchronous input-output multiplexer (SMBV) of the synchronous digital hierarchy (SDH) system, to the linear input-output of which the the communication line with the synchronous output of the synchronous input-output multiplexer of the SDH system, the inputs-outputs of the cable communication lines for organizing the exchange using HDSL technology are connected to the inputs-outputs of the HDSL modems, the input of the receiver of frequency and time reference signals (PESChV) from the core network clock network synchronization of the OATSS is connected to the sync output of the communication line with the sync output of the synchronous input-output multiplexer of the SDH system, the outputs of the receivers of reference frequency and time signals from the core network clock network synchronization OATSS, from radio stations and from the GLONASS system are connected respectively to the first, second and third inputs of the synchronization signal multiplication equipment (ARSS ), the inputs-outputs of which are connected to the fourteenth inputs-outputs of the first LAN switch by means of control channels and information channels over the Ethernet network, the first additional inputs-outputs of which are connected via the Ethernet interface to the first inputs-outputs of the cross-country mechanic's workstation portable computer, the second inputs-outputs which are connected via the Ethernet interface to the first inputs/outputs of the second LAN switch, the second inputs/outputs of which are connected to the second additional inputs/outputs of the first LAN switch, the third and fourth inputs/outputs of the second LAN switch are connected to the inputs/outputs of the control module and the telecommunications converter, respectively. atmospheric optical link equipment (AOLS), the output of which is connected to the input of the encoder, the output of which is connected to the input of a laser radiation source with a modulator, the output of which is connected to the input of the transmitter module, the high-frequency output of which is connected to the high-frequency input of the transmitting antenna, the output of which is connected to atmospheric channel, connected over the air to the input of the receiving antenna, the high-frequency output of which is connected to the high-frequency input of the photodetector module, the output of which is connected to the input of the signal processing device with a preamplifier, the output of which is connected to the input of the decoder, the output of which is connected to the input of the converter, while the signals control coming from a portable computer (1) operator workstation or a portable computer (26) workstation of a cross-country mechanic, through the first (2) and second (27) local area network (LAN) switches, control channels and information channels (21) LAN are transmitted to all elements of a mobile multiservice telecommunication complex, due to which long-term switching is carried out on electronic crosses (5) and (9) of Ethernet streams and electronic crosses (6) and (10) of E1 streams, resulting in a long-term distribution structure of information flows (paths and transmission channels).

Images