RU2680008C1 - Communication repeater at a bringed aerostat - Google Patents

Abstract

FIELD: radio engineering and communications.SUBSTANCE: invention relates to radio communication engineering and can be used to provide communication and relaying information in general-purpose automated communication systems for communication with remote mobile and stationary objects. Essence of the claimed solution lies in the fact that in the communication repeater on a tethered balloon containing a balloon with onboard communications and a cable-rope, having in its composition conductors for power supply of on-board communications and aerostat systems, on-board communications include the first radio communication module consisting of a meter-to-wave transceiver (MW), block separation filters of MW range and MW range antenna, control and switching unit (CWU) of the first radio module, decimeter wave transceiver (DMW) transceiver, block separation filters range DMW and antenna range DMW; the second radio module, consisting of a transceiver unit of the MW range, a block of separation filters of the range and an antenna of the MW range, control unit and switching the second radio module, transceiver DMW range, block separation filters DMW range and DMW antenna; central control unit, universal router, base station (BS) broadband radio access (BRA), antenna BS BRA, the first and second radio relay stations (RRS) bind with antennas, the first and second RRS of the decimeter wave (DMW) range with antennas, the first, second and third microwave ultra high-frequency (UHF) RRS with antennas, a network multiplexer, two optical switches, a switchboard of channels and communication lines and an AWS of control of a communication repeater, and a fiber-optic cable and an interconnecting line (CL) are added to the cable-rope structure.EFFECT: technical result of the present invention is to expand the functionality of the repeater in terms of increasing the number of relay paths formed and thereby increasing the capacity of the communication repeater.1 cl, 1 dwg

Description

The invention relates to radio communications technology and can be used to provide communication and relay information in general-purpose automated communication systems for communication with remote mobile and stationary objects.

A known repeater of the communication system described in [1]. This repeater contains two relay channels, each of which consists of a block of frequencies of a receiver, a receiver, a block of memory of a frequency of a transmitter, a transmitter, a decoder of commands, an OR element, a shaper of time intervals, an encoder of commands, the first and second switches, a decisive block, and a block for assessing quality signal, channel state analyzer, drive, input bus and programmer.

The known device provides automatic relaying of information in two independent communication directions with increased throughput of each of them.

A disadvantage of the known device is the limited number of formed channels for relaying information and their low throughput, which makes it difficult to use on aerostat communication relays that have limited ability to place communication equipment and means in them.

Also known is a repeater located on an aircraft (aircraft), described in the book by Vlasenko V.I., Serkov V.P., Chernoles V.P. Antennas for military communications technology / Aircraft repeater [2]. The device includes a relay station located on an airplane consisting of three half-sets of a relay station with antennas, two sets of a relay station, an on-board antenna module, an automated relay control unit, an equipment switching unit, and an electrical power unit.

The well-known repeater provides large intervals of the relay communication line, due to the possibility of lifting and barrage at heights of up to several kilometers.

A disadvantage of the known repeater is the relatively low mobility and high operating costs associated with the storage, maintenance and hours of flight of an aircraft.

The closest in technical essence to the present invention is a multi-band radio relay based on a tethered balloon selected as a prototype, the block diagram and technical capabilities of which are described in the RF patent for invention No. 2537798 C1 of January 10, 2015, IPC H01Q 1/28, Bull. No. 1 [3]. This repeater contains an aerostat with airborne communications equipment to which a cable rope is connected. At the same time, the lower end of the cable rope is connected to the control vehicle of the ground anchor point, which includes the power supply of the aerostat and airborne communications equipment, band-pass and notch filters, and an SDV-SV range radio station.

A disadvantage of the known device is the limited number of formed channels for relaying information and their low bandwidth.

The aim of the invention is to expand the functionality in terms of increasing the number of formed relay paths and increase due to this the throughput of the relay relay.

This goal is achieved by the fact that in a communication repeater on a tethered balloon containing an aerostat with on-board communications equipment and a cable rope having cores for powering the on-board communications equipment and aerostat systems, the on-board communications equipment includes a first radio communication module consisting of a meter wave band (MB) transceiver, an MB band isolation filter and an MB band antenna, a control and switching unit (BUC) of the first radio communication module, a transceiver it decimeter waves (UHF), dividing the filter unit UHF band and UHF band antenna; a second radio communication module, consisting of an MB range transceiver, an MB range isolation filter and an MB range antenna, a second radio communication module, a UHF range transceiver, a UHF range isolation filter and an UHF antenna; central control unit, universal router, broadband radio access base station (BSD), broadband radio access antenna (BSD), first radio relay station (RRS) with an antenna, second RS with a antenna, first UHF with an antenna, second RMS range of DMV with antenna, first, second and third RRS of microwave frequency range with antennas, network multiplexer, two optical switches, switchboard for channel and communication lines (CCLS) and automated workstation (AWS) of relay control a fiber optic communication line (FOCL) and a connecting line (SL), the first, second and third inputs and outputs of the MB transceiver of the first radio communication module at the RS-232, C1- joints FL and Ethernet are connected respectively to the first, second and third inputs and outputs of the control and switching unit of the first radio module, the fourth, fifth and sixth inputs and outputs of which at the RS-232, C1-FL and Ethernet interfaces are connected respectively to the first, second and third reception inputs a UHF band transmitter, the high-frequency input-output of which is connected to the high-frequency input / output of the UHF band antenna through a block of separation filters of the UHF band, and a high-frequency input-output of an MB range transceiver is connected to the high-frequency input-output of an MB band antenna ; the first, second and third inputs and outputs of the MB transceiver of the second radio communication module at the RS-232, C1-FL and Ethernet interfaces are connected respectively to the first, second and third inputs and outputs of the second radio communication control and switching unit, the fourth, fifth and sixth the inputs and outputs of which at the RS-232, C1-FL and Ethernet interfaces are connected respectively to the first, second and third inputs and outputs of a transceiver of the DMV range, the high-frequency input-output of which is connected through a block of isolation filters of the DMV range ene with a high frequency antenna input-output of UHF band, and a high-frequency input-output MB range transceiver device via dividing block MB band filter connected to the high frequency antenna input-output of band MB; the control input-output of the control and switching unit of the first radio communication module is connected to the first control input-output of the central control unit, the second control input-output of which is connected to the control input-output of the control and switching unit of the second radio communication module, and the seventh input-output of the control unit and switching the first radio module at the Ethernet interface is connected to the first input-output of the universal router, the second input-output of which at the Ethernet interface is connected to the seventh input-output of the control unit and switching of the second radio communication module, the third control input-output of the central control unit is connected to the control input-output of the universal router, the fourth control input-output of the central control unit is connected to the control input-output of the ShRD base station, the high-frequency input-output of which is connected to the high-frequency input - the antenna output of the BSA ShRD, and the channel input-output of the ShRD base station at the Ethernet interface is connected to the third input-output of the universal router, the fifth and sixth control inputs The s-outputs of the central control unit are connected to the control inputs and outputs of the first and second PPC bindings, the high-frequency input-output of which is connected to the high-frequency input-output of the antenna of the second PPC-binding, and the high-frequency input-output of the first PPC-binding is connected to the high-frequency input-output of the antenna the first PPC binding, the control inputs and outputs of the first and second PPC of the DMV range are connected respectively to the seventh and eighth control inputs and outputs of the central control unit, channel inputs and outputs The first and second PPC bindings at the Ethernet joints are connected respectively to the fourth and fifth inputs and outputs of the universal router, the sixth and seventh inputs and outputs of which at Ethernet joints are connected respectively to the channel inputs and outputs of the first and second PPCs of the DMV range, high-frequency input-output of the first The RMS range of the UHF range is connected to the high-frequency antenna of the first RRS range of the UHF range, and the high-frequency input-output of the second RRS range of the UHF range is connected to the high-frequency input-output antenna of the second RRS range of the UHF range, eighth, ninth the tenth and tenth inputs and outputs of the universal router are connected via Ethernet interfaces to the channel inputs and outputs of the first, second, and third RPCs of the microwave range, the high-frequency input-output of the first RPC microwave range is connected to the high-frequency input-output antenna of the first RPC microwave range, the high-frequency input-output of the second RRS microwave range is connected to the high-frequency input-output of the antenna of the second RRS microwave range, and the high-frequency input-output of the third microwave range RRS is connected to the high-frequency input the antenna path of the third RRS microwave range, the control inputs and outputs of the first, second and third RRS microwave range are connected respectively to the ninth, tenth and eleventh control inputs and outputs of the central control unit, the twelfth input-output of which is connected to the control input-output of the network multiplexer, eleventh the input-output of the universal router at the Ethernet interface is connected to the first input-output of the network multiplexer, the second input-output of which at the Ethernet interface is connected to the first input-output of the first opt switch, the second input-output of which at the Ethernet interface via a fiber-optic communication line is connected to the first input-output of the KKLS switchboard, the second input-output of which is connected via a connecting line (SL) to the third input-output of the network multiplexer, the fourth input-output which by means of power supply wires is connected to the third input-output of the KKLS shield, the fourth input-output of which is connected via Ethernet to the first input-output of the second optical switch, the second input-output of which is connected via Ethernet n with the first input-output of the repeater control AWP, the fifth input-output of the KCLS shield through the second input-output of the repeater control AWP is connected to an external power source.

Comparative analysis with the prototype shows that the present invention is distinguished by the presence of new units that are part of the on-board communications equipment of the communication relay, namely two radio communication modules, a central control unit, a universal router, a ShRD base station, two RRS antenna bindings, two UHF RRS ranges with antennas, three PPC microwave ranges with antennas and a cable rope, which also includes fiber optic links designed for transmitting / receiving group streams and exchanging information between channels aloobrazuyuschim equipment of the communications repeater and ground anchor point, a connecting line designed to organize information transmission paths between the communications repeater equipment on a tethered balloon and the hardware communications associated with it from the ground anchor point, network multiplexer, two optical switches and a switchboard for channel and communication lines (KKSL), as well as a change in the connections between the known blocks of the communication relay on a tethered balloon.

Thus, the claimed invention meets the criteria of the invention of "novelty." Comparison with known technical solutions shows that the proposed set of blocks with their respective connections contributes to the achievement of the goal. This allows us to conclude that the proposed invention meets the criterion of "significant differences". It clearly does not follow from the prior art and has an inventive step. In addition, it is industrially applicable, as evidenced by the manufacture of a communication repeater on a tethered balloon using existing commercially available communication equipment, units and assemblies, made on a modern elemental base.

The drawing shows a structural diagram of a communications repeater on a tethered balloon.

The communication repeater on a tethered balloon contains an aerostat with on-board communication equipment, including the first radio communication module 1, consisting of a transceiver 2 meters wave band (MB), block 3 separation filters MB band and antenna 4 band MB, control and switching unit 5 ( BUK) of the first 1 radio communication module, transceiver 6 of the decimeter wavelength range (UHF), block 7 of the separation filters of the UHF range and the antenna 8 of the UHF range; a second radio communication module 9, consisting of an MB range transceiver 10, an MB range isolation filter block 11, and an MB range antenna unit 9, a control and switching unit 9 of a second radio communication module, a UHF range transceiver device 14, a DMV range separation filter block 15, and an antenna 16 DMV range; central control unit 17, universal router 18, base station (BS) 19 broadband radio access (BRE), antenna 20 BS BRE, first 21 radio relay stations (RRS) binding, antenna 22 of the first RRS binding, second 23 RRS binding, antenna 24 of the second RRS bindings, the first 25 microwave relay station (RRS) of the decimeter wave band (UHF), antenna 26 of the first RMS range of the UHF range, the second 27 RRS range of the UHF range, antenna 28 of the second RRS range of the UHF range, the first 29 RRS of the microwave frequency range, antenna 30 of the first RRS of the microwave frequency range range, the second 31 RRS microwave range zone, antenna 32 of the second RRS of the microwave range, third 33 RRS of the microwave range, antenna 34 of the third RRS of the microwave range, network multiplexer 35, the first 36 optical switch, cable rope 37, comprising a fiber optic communication line 38 (FOCL), a connecting line (SL) 39 and power supply wires 40, a shield 41 for switching channels and communication lines (CCLS), a second 42 optical switch and an automated workstation (AWS) 43 for controlling a communication relay.

The first, second and third inputs and outputs of the transceiver 2 of the MB band of the first 1 radio module at the RS-232, C1-FL and Ethernet interfaces are connected respectively to the first, second and third inputs and outputs of the control and switching unit 5 of the first radio communication module 1, the fourth , the fifth and sixth inputs and outputs of which at the RS-232, C1-FL and Ethernet junctions are connected respectively to the first, second and third inputs and outputs of the transceiver device 6 of the DMV range, the high-frequency input-output of which through block 7 of the separation filters of the DMV range connected to the high-frequency input-output of the antenna 8 of the UHF range, and the high-frequency input-output of the transceiver 2 of the MB range through the block 3 of separation filters of the MB range is connected to the high-frequency input-output of the antenna 4 of the MB range.

The first, second and third inputs and outputs of the transceiver device 10 of the MB band of the second 9 radio communication module at the RS-232, C1-FL and Ethernet joints are connected respectively to the first, second and third input-outputs of the control and switching unit 13 of the second radio communication module 9, the fourth , the fifth and sixth inputs and outputs of which at the RS-232, C1-FL and Ethernet junctions are connected respectively to the first, second and third inputs and outputs of the transceiver device 14 of the DMV range, the high-frequency input-output of which is through block 15 of separation filters of the D band The MV is connected to the high-frequency input-output of the antenna 16 of the UHF range, and the high-frequency input-output of the transceiver 10 of the second radio module through the block 11 of the separation filters of the MB range is connected to the high-frequency input-output of the antenna 12 of the MB range.

The control input-output of the control and switching unit 5 of the first 1 radio communication module is connected to the first control input-output of the central control unit 17, the second control input-output of which is connected to the control input-output of the control and switching unit 13 of the second 9 radio communication module, and the seventh input - the output of the control and switching unit 5 of the first 1 radio communication module at the Ethernet interface is connected to the first input-output of the universal router 18, the second input-output of which at the Ethernet interface is connected to the seventh input-output of the unit 13 the board and the switching of the second radio communication unit 9. The third control input-output of the Central control unit 17 is connected to the control input-output of the universal router 18.

The fourth control input-output of the central control unit 17 is connected to the control input-output of the ShRD base station 19, the high-frequency input-output of which is connected to the high-frequency input-output of the ShRD BS antenna 20, and the channel input-output of the ShRD base station 19 is connected to the Ethernet interface the third input-output of the universal router 18. The fifth and sixth control inputs and outputs of the central control unit 17 are connected to the control inputs and outputs of the first 21 and second 23 RPC bindings, the high-frequency input-output of which is connected to sokochastotnym input-output of the antenna 24 of the second binding RRS, and a high-frequency input-output 21 of the first binding RRS coupled to the high-frequency input-output of the antenna 22 of the first binding RRS. The control inputs and outputs of the first 25 and second 27 PPC of the DMV range are connected respectively to the seventh and eighth control inputs and outputs of the central control unit 17.

Channel inputs-outputs of the first 21 and second 23 РРС bindings on Ethernet joints are connected respectively to the fourth and fifth inputs-outputs of universal router 18, the sixth and seventh inputs-outputs of which are connected via Ethernet joints respectively to channel inputs-outputs of the first 25 and second 27 РРС DMV range. The high-frequency input-output of the first 25 PPC of the DMV range is connected to the high-frequency input-output of the antenna 26 of the first PPC of the DMV range, and the high-frequency input-output of the second 27 PPC of the DMV range is connected to the high-frequency input-output of the antenna 28 of the second PPC of the DMV range.

The eighth, ninth and tenth inputs and outputs of the universal router 18 are connected at the Ethernet joints to the channel inputs and outputs of the first 29, second 31, and third 33 RRS microwave frequencies, respectively. The high-frequency input-output of the first 29 RRS microwave range is connected to the high-frequency input-output antenna 30 of the first RRS microwave range, the high-frequency input-output of the second 31 RRS microwave range is connected to the high-frequency input-output antenna 32 of the second RRS microwave range, and the high-frequency input third 33 RRS microwave range connected to the high-frequency input-output antenna 34 of the third RRS microwave range.

The control inputs and outputs of the first 29, second 31 and third 33 RRS microwave ranges are connected respectively to the ninth, tenth and eleventh control inputs and outputs of the central control unit 17, the twelfth control input-output of which is connected to the control input-output of the network multiplexer 35. The eleventh input the output of the universal router 18 at the Ethernet interface is connected to the first input-output of the network multiplexer 35, the second input-output of which at the Ethernet interface is connected to the first input-output of the first optical switch Ora 36, the second input-output of which at the Ethernet interface by means of a fiber-optic communication line 38, which is part of the cable rope 37, is connected to the first input-output of the switchboard 41 for switching channels and communication lines (CCLS), the second input-output of which the connecting line 39 is connected to the third input-output of the network multiplexer 35, the fourth input-output of which is connected through the power supply cores 40 to the third input-output of the control panel 40, the fourth input-output of which is connected via Ethernet to the first input-output of the automated circuit bochego space (ARM) 43 relay communication control, a fifth input-output board 41 and circuit switching communication lines through the second input-output repeater management workstation 43 is connected to an external power source.

Transceivers 2 and 10 meter wavelength bands of the first 1 and second 9 radio modules together with blocks 3 and 11 of separation filters of the MB band, antennas 4 and 12 of the MB band, as well as control and switching units 5 and 13 of the first 1 and second 9 radio modules, are intended for the formation of transit paths (relaying) of information on sections of long-distance radio trunk lines in the MB range with the possibility of accessing local radio communication lines to remote subscribers via the ShRD base station 19 with antenna 20 odvizhnyh and stationary objects.

As transceivers 2 and 10 of the MB range, radio stations commercially available from the KB industry, for example, radio stations of the R-168-100KA type, can be used.

Blocks 5 and 13 of the control and switching of the first 1 and second 9 radio communication modules are designed to provide interconnected operation of the transceiver devices 2, 6 and 10, 14 of the first 1 and second 9 radio communication modules, organization of information transmission paths, switching, distribution and relaying of channels in directions communications in the formed group flows.

Transmitters 6 and 14 of the UHF range together with blocks 7 and 15 of the separation filters of the UHF range, antennas 8 and 16 of the UHF range, as well as blocks 5 and 13 of the control and switching, are designed to form paths and relay the transmitted information on the sections of the long-distance radio communication lines in UHF range with the ability to allocate channels and exit through them to the zonal (local) radio links to remote subscribers of mobile and stationary objects.

The universal router 18 is intended for routing, switching and distribution of information flows formed by the communication means of the repeater on communication networks between communication nodes, subscribers of stationary and mobile objects.

As such a router can be used, for example, a universal router (Universal Access Routers) type АХХ1000-DC 8 × T1 / E1, 8 × GbE copper, 4 × GbE combination (copper or SFR), dual feed DC power.

A broadband radio access base station (SHRD) 19 together with an antenna 20 is 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 is made to the public communication network, including by connecting to communication paths organized by means of communication equipment of a repeater on a tethered balloon, as well as to ensure autonomous operation in relay mode on a high-frequency path. Its basis is the BSD radio unit operating in the frequency range 2-6 GHz. Base station 19 provides automatic organization of radio networks, automatic relaying 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 in accordance with GOST 25007.

As the base station 19 of the ShRD, for example, the R-169-4BS radio station commercially available from the industry from the R-169 radio complex can be used.

Antenna 20 BS ShRD is a wide-range omnidirectional antenna, which can be used as an omnidirectional antenna type AB 3,5 / 11.

The first 21 and second 23 radio relay binding stations together with antennas 22 and 24 are intended for organizing the tie lines of the communication repeater to the ground reference point for accessing the trunk lines of the public communication network, through which communications are established with subscribers of stationary and mobile objects.

Each of the RRS (21, 23) contains a transceiver and a digital modem operating in accordance with the DC-CDMA radio access technology. The RRS transceiver operates in the frequency range from 0.390 to 7.80 GHz, which is divided into four subbands. RRS 21 and 23 provide the transmission of signals of group information streams E1, E3 and STM-1 through the corresponding interfaces with speeds of 2.048; 34 and 155.52 Mbps.

As an antenna (22, 24) for the aforementioned RRS bindings, 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.

The first 25 and second 27 RRS ranges of the UHF range together with the antennas 26 and 28 of the UHF range are designed to organize two radio-relay communication lines in the decimeter wave range with the possibility of transmitting various types of information through them or organizing one relay path at a high frequency in the specified wavelength range.

As mentioned RRS of the DMV range, radio-relay stations commercially available by the industry, for example, of the R-419MTs type, operating in the frequency range from 160 to 645 MHz and providing information transfer rates of up to 2048 kbit / s via the radio relay line, can be used. When using external six-channel compression equipment, a group signal with a frequency spectrum of 0.3-32.0 kHz or with a frequency spectrum of 0.3-64 kHz for a twelve-channel compression equipment is transmitted (received) through the line, and when connecting external data transmission equipment, a group signal can transmitted (received) at various speeds, including at a speed of 48 to 2048 kbit / s.

Two types of antennas are used as antennas 26 and 28 for the RMS range of the DMV: a directional antenna, for example, type ЗБ11-1 and an omnidirectional antenna, type 2B12-1. A directional antenna is an in-phase array consisting of several emitters mounted on a frame that are connected to the antenna feeder through a power divider, and an omnidirectional antenna consists of two cones, a bracket and a power cable laid inside the bracket and ending with a connector. All metal parts of the antenna are made of aluminum alloys.

The first 29, second 31 and third 33 RRS microwave ranges, together with antennas 30, 32 and 34 microwave ranges, are designed to organize trunk lines of microwave links in the frequency range from 6 to 8 GHz with the provision of transit transmission of various digital streams through them.

The first 29, second 31 and third 33 RRS microwave range belong to the class of equipment of digital radio relay stations SDH hierarchy. Each of the stations provides a data transfer rate of 155 Mbps in one trunk and allows transmitting one STM-1 stream or n Е1 streams with the addition of Ethernet traffic within the trunk bandwidth.

Each station includes transceiver equipment, STM-1 level multiplexers (terminal and I / O) and a network management system. The transceiver equipment is made in the form of a module with a built-in digital modem or modem located in the access module. The STM-1 multiplexer provides multiplexing of digital streams and service channels. Modems built into the access module form the spectrum of the radio signal at an intermediate frequency and have built-in hardware support for spatial diversity. The control system provides an additional data channel with a software-selectable interface type RS-232/422/485 and two digital communication channels.

As the first 29, second 31, and third 33 radio relay stations, high-speed digital MRS-MIK-RL6 / 8 + RRSs containing transceiver devices, access modules with built-in modems and antenna systems made in common-mode arrays based on log-periodic emitters.

As the first 30, second 32 and third 34 RPC microwave antennas, the above antenna systems are used.

The network multiplexer 35 is an apparatus for transmitting synchronous digital information. It is designed to build networks of arbitrary topology with the formation, input / output, full-access cross-switching of group stream signals in six STM-1 directions with the ability to flexibly change the bandwidth for Ethernet interfaces (GFP / VCAT protocols), as well as electrical interfaces for working with signals 2, 34 and 155 Mbps (G.703 ITU-T), Ethernet 10/100 Base-T (IEEE 802.3), etc.

As the mentioned network multiplexer 35, a SM-1/4 type multiplexer developed by the open joint-stock company Supertel (Russia, 197101, St. Petersburg, Petrogradskaya embankment, 38 A) can be used. It has a modular design and provides the following operating modes: terminal, input / output, cross-switch, providing full-access switching up to 6 directions STM-1, linear regenerator.

The first 36 and second 42 optical switches are designed for switching and distributing optical signals of group streams from the channel-forming means of the relay and organizing access through FOCL 38 to the channels of an external public communication network with data transmission through them at the Ethernet 10/100 Base-TX interface to remote subscribers of stationary and mobile objects.

Cable rope 37 includes FOCL 38, SL 39 and core 40 of power supply for on-board communications and own balloon systems.

FOCL 38 is intended for transmission / reception of group streams and exchange of information between channel-forming equipment of a communications repeater and a ground-based communications facility located in a mobile communications facility. An optical cable of the P-294M type can be used as a cable for FOCL 40.

The connecting line 39 is intended for the organization of information transmission paths between the equipment of the communication repeater on the tethered balloon and the hardware communications associated with it from the ground anchor point 41, which acts as the ground repeater of the communication system. SL 39 can be made using a twisted pair cable.

Power supply cores 40 are designed to transmit electricity from a primary source to a secondary power source of on-board communications and proprietary aerostat systems. When this power is supplied through the cores 38 from the power source, which is part of the ground point 41 binding. The supply of electricity for on-board aerostat and communication repeater systems through power supply cores 38 helps to reduce the mass of equipment installed on a tethered balloon, by eliminating its primary source of electricity.

Shield 41 switching channels and communication lines is designed to distribute information flows and switching circuits to external devices. The specified KKLS panel provides full accessibility switching of signals coming from any input to any of the outputs.

The repeater control automated workstation 43 is designed to control a communication repeater on a tethered balloon, for which it includes a personal electronic computer (PC) and a device for controlling the balloon lift with on-board communications.

As a personal computer for AWP 43, a personal computer of the EC-1866 type can be used, made in a single monoblock of the type of a laptop. AWP contains a hardware platform, a secure operating system, software for protecting information against unauthorized access (NSD), software for anti-virus protection and email. It provides for the possibility of installing a third-party specialized application software (STR) compatible with the hardware and software platform.

The communication repeater on a tethered balloon provides:

organization of backup communication lines in case of failure of the main communication lines between interacting objects and remote subscribers;

restoration, reservation or rapid expansion of communication lines of the public transport communication network;

communication of interaction between control points of various departments;

organization of communication with subscribers of mobile objects operating at a considerable distance from settlements and lines of the public communication network;

communication in remote areas, including mountainous, marshy and wooded areas;

organization of communication with subscribers of mobile objects moving at high speed and in different directions from the main communication networks.

The technical effect of the present invention is to expand the functionality of the communication repeater in terms of increasing the number of formed relay paths through which the transmission / reception of various group streams is carried out, and increasing the capacity of the communication repeater, achieved by introducing two radio communication modules into the onboard communication means of the aerostat , each of which provides the organization of two relay paths in the ranges of meter and decimeter waves, the base station broadband radio access, two RRS bindings, two RRS ranges of decimeter waves, three RRS microwave ranges, a connecting line and a fiber optic communication line, which provide access through land-based binding points in a wired communication network to subscribers of stationary and mobile objects.

The advantage of the invention is also that the communication repeater on a tethered balloon of the indicated composition ensures the formation of at least four relay paths and five outputs along the tie lines in the public communication network for communication with subscribers located on remote mobile and stationary objects, and also in wireless radio access networks and cellular communication networks. At the same time, the throughput of the relay paths formed by the aerostat communication means increased from 1.2-2.4 kbit / s to 155 Mbit / s.

Information sources.

1. SU, copyright certificate No. 1081808 A, cl. HB04 7/02, 1984.

2. Vlasenko V.I., Serkov V.P., Chernoles V.P. Antennas for military communications technology / Aircraft repeater. - L .: YOU, 1986, p. 122, 123; fig. 5.17.

3. RU, patent No. 2537798 C1, IPC H01Q 1/28, 2015, Bull. No. 1 (prototype).

Claims (1)

A tethered balloon communications repeater comprising an aerostat with on-board communications equipment and a cable rope incorporating conductors for powering the on-board communications equipment and aerostat systems, the on-board communications equipment includes a first radio communication module consisting of a meter wavelength range transceiver (MB ), a block of separation filters of the MB range and an antenna of the MB range, a control and switching unit (BUC) of the first radio communication module, a decimetric wave band (UHF) transceiver, a stripped unit solid filters of the UHF range and antennas of the UHF range; a second radio communication module, consisting of an MB range transceiver, an MB range isolation filter and an MB range antenna, a second radio communication module, a UHF range transceiver, a UHF range isolation filter and an UHF antenna; central control unit, universal router, broadband radio access base station (BSD), broadband radio access antenna (BSD), first radio relay station (RRS) with an antenna, second RS with a antenna, first UHF with an antenna, second RMS range of DMV with antenna, first, second and third RRS of microwave frequency range with antennas, network multiplexer, two optical switches, switchboard for channel and communication lines (CCLS) and automated workstation (AWS) of relay control a fiber optic communication line (FOCL) and a connecting line (SL), the first, second and third inputs and outputs of the MB transceiver of the first radio communication module at the RS-232, C1- joints FL and Ethernet are connected respectively to the first, second and third inputs and outputs of the control and switching unit of the first radio module, the fourth, fifth and sixth inputs and outputs of which at the RS-232, C1-FL and Ethernet interfaces are connected respectively to the first, second and third reception inputs a UHF band transmitter, the high-frequency input-output of which is connected to the high-frequency input / output of the UHF band antenna through a block of separation filters of the UHF band, and a high-frequency input-output of an MB range transceiver is connected to the high-frequency input-output of an MB band antenna ; the first, second and third inputs and outputs of the MB transceiver of the second radio communication module at the RS-232, C1-FL and Ethernet interfaces are connected respectively to the first, second and third inputs and outputs of the second radio communication control and switching unit, the fourth, fifth and sixth the inputs and outputs of which at the RS-232, C1-FL and Ethernet interfaces are connected respectively to the first, second and third inputs and outputs of a transceiver of the DMV range, the high-frequency input-output of which is connected through a block of isolation filters of the DMV range ene with a high frequency antenna input-output of UHF band, and a high-frequency input-output MB range transceiver device via dividing block MB band filter connected to the high frequency antenna input-output of band MB; the control input-output of the control and switching unit of the first radio communication module is connected to the first control input-output of the central control unit, the second control input-output of which is connected to the control input-output of the control and switching unit of the second radio communication module, and the seventh input-output of the control unit and switching the first radio module at the Ethernet interface is connected to the first input-output of the universal router, the second input-output of which at the Ethernet interface is connected to the seventh input-output of the control unit and switching of the second radio communication module, the third control input-output of the central control unit is connected to the control input-output of the universal router, the fourth control input-output of the central control unit is connected to the control input-output of the ShRD base station, the high-frequency input-output of which is connected to the high-frequency input - the antenna output of the BSA ShRD, and the channel input-output of the ShRD base station at the Ethernet interface is connected to the third input-output of the universal router, the fifth and sixth control inputs The s-outputs of the central control unit are connected to the control inputs and outputs of the first and second PPC bindings, the high-frequency input-output of which is connected to the high-frequency input-output of the antenna of the second PPC-binding, and the high-frequency input-output of the first PPC-binding is connected to the high-frequency input-output of the antenna the first PPC binding, the control inputs and outputs of the first and second PPC of the DMV range are connected respectively to the seventh and eighth control inputs and outputs of the central control unit, channel inputs and outputs The first and second PPC bindings at the Ethernet joints are connected respectively to the fourth and fifth inputs and outputs of the universal router, the sixth and seventh inputs and outputs of which at Ethernet joints are connected respectively to the channel inputs and outputs of the first and second PPCs of the DMV range, high-frequency input-output of the first The RMS range of the UHF range is connected to the high-frequency input-output of the antenna of the first RRS range of the DMV, and the high-frequency input-output of the second RRS range of the UHF range is connected to the high-frequency input-output of the antenna of the second RRS of the UHF range , the eighth, ninth and tenth inputs and outputs of the universal router are connected via Ethernet interfaces to the channel inputs and outputs of the first, second and third RPCs of the microwave frequency range, the high-frequency input-output of the first microwave range RRS is connected to the high-frequency antenna input-output of the first RRS Microwave range, the high-frequency input-output of the second microwave range RRS is connected to the high-frequency input-output antenna of the second microwave range RRS, and the high-frequency input-output of the third microwave range RRS is connected to high the total input-output antenna of the third RRS microwave range, the control inputs and outputs of the first, second and third RRS microwave range are connected respectively to the ninth, tenth and eleventh control inputs and outputs of the central control unit, the twelfth input-output of which is connected to the control input-output of the network multiplexer, the eleventh input-output of a universal router at the Ethernet interface is connected to the first input-output of the network multiplexer, the second input-output of which is connected at the Ethernet interface to the first input-output the house of the first optical switch, the second input-output of which is connected via an Ethernet interface through a fiber-optic communication line to the first input-output of the KKLS panel, the second input-output of which is connected to the third input-output of the network multiplexer via a connecting line (SL), the fourth input - the output of which, through the power supply wires, is connected to the third input-output of the KKLS switchboard, the fourth input-output of which is connected at the Ethernet interface to the first input-output of the second optical switch, the second input-output of which is ku Ethernet connected to a first input-output of the repeater management workstation, a fifth input-output KKLS shield through the second input-output repeater management workstation connected to an external power source.

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