RU2792024C1 - Terrestrial mobile communication repeater - Google Patents

Abstract

FIELD: radio communication engineering.

SUBSTANCE: invention can be used to provide communication and information relaying in general-purpose automated communication systems for communication with remote mobile and stationary objects. A terrestrial mobile communication repeater comprising a radio communication module, consisting of a control and switching unit, a transceiver in the meter wave (MW) band, a separation filter unit in the MB band and an antenna in the MW band, a transceiver in the decimetre waves range (DWR), a crossover filter unit for the DWR band and an antenna for the DWR band, a central control unit, a universal router, a switchboard for switching channels and communication lines (SCCL), an automated workstation (AWS) for controlling the repeater equipped on the basis of a laptop computer, a connecting line (CL) for communication and fibre-optic communication line (FOCL), is additionally introduced with a satellite communication station comprising an antenna system, an antenna system control unit, transceiver equipment and a modem, portable radio stations, navigation equipment with a built-in antenna, a video recorder with a solid state drive, an IP camera, a fixed reference station, and the radio communication module additionally includes a transceiver for the decametre wave band (DMWB), a separation filters unit for the DMWB band and an antenna for the DMWB band.

EFFECT: expanding the functionality of the communication repeater in terms of increasing the number of retransmission paths formed, through which the transmission/reception of various multicast streams is carried out, and increasing the throughput.

1 cl, 1 dwg

Description

SUBSTANCE: invention relates to radio communication engineering and can be used to provide communication and information relaying in general-purpose automated communication systems for communication with remote mobile and stationary objects.

To deploy transport communication networks in the field, various means of communication are used, including wired means of communication, radio and radio relay stations. However, their use to provide communication over long distances is difficult due to the limited technical capabilities of these means of communication. It is possible to increase the range of provided communications by using communication repeaters. Such repeaters can be placed on flight-lifting facilities and mounted in vehicles of various carrying capacities.

Known repeater of the communication system described in [1]. This repeater contains two relay channels, each of which consists of a receive frequency memory block, a receiver, a transmit frequency memory block, a transmitter, a command decoder, an OR element, a time interval generator, a command encoder, the first and second switches, a decision block, a quality evaluation block signal, channel state analyzer, accumulator, input signal bus and programmer.

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

A disadvantage of the known device is the limited number of information relay paths formed and their low bandwidth, which makes it difficult to use it on balloon communication repeaters that have limited capabilities for placing equipment and communication facilities in them.

Also known is a repeater placed on an aircraft (aircraft), described in the book Vlasenko V.I., Serkov V.P., Chernoles V.P. Antennas of military communication equipment / Aircraft repeater [2]. The device includes a relay communication center located on the aircraft, consisting of three semi-sets of a radio relay station with antennas, two sets of a relay station, an onboard antenna module, a repeater automated control unit, an equipment switching unit and a power supply unit.

The well-known repeater provides long intervals of the relay communication line, thanks to the possibility of lifting and loitering at altitudes up to several kilometers.

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

Also known is a multi-band radio repeater on a tethered balloon, the structural diagram and technical capabilities of which are described in the RF patent for the invention No. No. 1 [3]. This repeater contains a balloon with on-board 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 a power source for the balloon and on-board communications, band-pass and notch filters, and a VHF-SV radio station.

The disadvantage of the known device is the limited number of generated information relay paths and their low bandwidth.

The closest in technical essence to the proposed invention is the communication repeater on a tethered balloon chosen as a prototype according to the patent of the Russian Federation No. Bull. No. 5 [2]. This communication repeater contains a balloon with on-board communications equipment and a cable-rope, which includes cores for power supply of on-board communications equipment and systems of the balloon, on-board communications equipment, including two radio communication modules, each of which contains a transceiver in the meter wave range (MB), a block of crossover filters for the MB range and an antenna for the MB range, a control and switching unit; a central control unit, a universal router, a broadband radio access base station (BS) with an antenna, two radio relay stations (RRS) with antennas, two decimeter wave (UHF) radio relay stations with antennas, three microwave radio relay stations with antennas, a network multiplexer, two optical switches, a switching board for channels and communication lines (CCLS) and an automated workstation (AWS) for controlling the repeater, a fiber-optic communication line (FOCL) and a connecting line (SL) placed in a cable-rope.

The main disadvantages of the device according to the prototype are the limited possibilities for organizing radio networks and wireless radio access with an increased communication range, as well as the bulkiness of the equipment, which does not allow placing on-board communications in a small-sized ground vehicle.

The objective of the invention is to create a ground-based mobile communication repeater placed in a car with a low payload and increased cross-country ability, which makes it possible to organize multi-channel networks of radio and satellite communications with an increased range due to the relaying of transmitted signals and messages.

The aim of the invention is to expand the functionality for deploying a multi-channel radio network and satellite communications with increased bandwidth of communication directions and automatic relaying of the formed channels and paths.

This goal is achieved by the fact that in a terrestrial mobile communication repeater containing a radio communication module, consisting of a control and switching unit, a transceiver in the meter wave (MV) range, a crossover filter unit in the MV range and an antenna in the MV range, a transceiver in the decimeter range waves (UHF), a block of separation filters in the UHF range and an antenna in the UHF range, a central control unit, a universal router, a switching board for channels and communication lines (CCLS), an automated workstation (AWS) for controlling the repeater, equipped on the basis of a laptop computer, a connecting line ( SL) communication and fiber-optic communication line (FOCL), a satellite communication station was additionally introduced, including an antenna system, an antenna system control unit, transceiver equipment and a modem, portable radio stations, navigation equipment with a built-in antenna, a video recorder with a solid state drive , IP camera, st a stationary binding point, and the radio communication module additionally includes a decameter wave band (DCMW) transceiver, a DHMW band separation filter unit and a DHMW band antenna, while the control input-output of the antenna system control unit is connected to the control input-output of the antenna system , the microwave input-output of which is connected to the microwave input-output of the transceiver equipment of the satellite communication station, the control input-output of which is connected to the control input-output of the antenna system control unit, the channel input-output of the transceiver equipment of the satellite communication station connected to the line input-output of the modem, the channel inputs-outputs of which are connected via the Ethernet junction to the first inputs-outputs of the universal router, the first, second and third inputs-outputs of the transceiver of the meter wave range (MW) via the RS-232, C1 interfaces -FL and Ethernet are connected respectively to the first, second and third to its inputs-outputs of the transceiver of the decimeter wave range (UHF), the high-frequency input-output of which is connected through the block of dividing filters of the UHF range to the high-frequency input-output of the antenna of the UHF range, and the high-frequency input-output of the transceiver of the MB range through the block of dividing filters of the MB range is connected to the high-frequency input-output of the antenna of the MB range, the seventh, eighth and ninth inputs-outputs of the control and switching unit of the radio communication module at the RS-232, S1-FL and Ethernet interfaces are connected, respectively, to the first, second and third inputs-outputs of the receiving - a transmitter in the decameter wave range (DCMW), the high-frequency input-output of which, through a block of separation filters in the DHMW range, is connected to the high-frequency input-output of the antenna in the DHMW range, the first, second and third control inputs-outputs of the control and switching unit of the radio communication module are connected, respectively, to the first , the second and third control inputs m-outputs of the central control unit, the fourth control input-output of which is connected to the control input-output of the universal router, the second input-output of which is connected via the Ethernet interface to the tenth input-output of the control and switching unit of the radio communication module, the fifth control input-output of the central unit control via an Ethernet interface is connected to the control input-output of a portable computer of an automated workstation (AWP) to control a communication repeater, the information input-output of which is connected via an RS-232 interface to the information input-output of navigation equipment with a built-in antenna, the input-output of an IP camera is connected with the first input-output of a video recorder with a solid-state drive, the second input-output of which is connected to the input-output of a portable computer workstation for controlling a communication repeater, the first and second station inputs-outputs of the channel switching board and communication lines (CCLS) are connected via Ethernet joints, respectively, to the inputs - outputs of the central control unit and to the second inputs-outputs of the universal router, the first and second linear inputs-outputs of the circuit switching board and communication lines are connected respectively to the input-output of the connecting line (SL) of communication and to the first input-output of the fiber-optic communication line (FOCL) ), the second input-output of which is connected to the input-output of the fixed anchor point, portable radio stations are connected over the air to the MB antenna and / or the UHF band antenna.

A comparable analysis with the prototype shows that the proposed terrestrial mobile communication repeater is distinguished by the presence of new blocks: a satellite communication station, including an antenna system, an antenna system control unit, a transceiver equipment and a modem, a transceiver of the decameter wave range, a separation filter unit UHF range and UHF range antenna introduced into the radio communication module, portable radio stations, navigation equipment with a built-in antenna, IP camera, video recorder with a solid state drive and a fixed anchor point, as well as changing the links between known blocks of the communication repeater.

Thus, the claimed terrestrial mobile communication repeater meets the criterion of the invention "novelty". Comparison of the proposed solution with other technical solutions shows that the introduced blocks are widely known and additional creativity in their implementation is not required. However, when they are introduced in the specified connection with the rest of the circuit elements in the claimed communication complex, the above blocks exhibit new properties, which leads to the achievement of the set goal.

This allows us to conclude that the technical solution meets the criterion of "significant differences".

The claimed solution does not explicitly follow from the prior art and has an inventive step.

The drawing shows a structural electrical diagram of a land-based mobile communication repeater. In this case, the drawing indicates:

1 - satellite communication station consisting of:

2 - antenna system;

3 - antenna system control unit;

4 - receiving-transmitting equipment;

5 - station modem;

6 - radio communication module consisting of:

7 - transceiver in the range of meter waves (MB);

8 - block of separation filters of the MB range;

9 - MB band antenna;

10 - control and switching unit of the radio communication module;

11 - transceiver of the decimeter wave range (UHF);

12 - a block of crossover filters for the UHF range;

13 - UHF band antenna;

14 - transceiver of the decameter wave band (DKMV);

15 - block of separation filters for the range of DKMV;

16 - antenna range UHF;

17 - portable radio stations;

18 - central control unit;

19 - universal router;

20 - portable computer workstation (AWP) control relay communications;

21 - navigation equipment with built-in antenna;

22 - IP camera;

23 - DVR with solid state drive;

24 - switchboard of channels and communication lines (KKLS);

25 - connecting line (SL) communication;

26 - fiber-optic communication line (FOCL);

27 - stationary anchor point.

The control input-output of the antenna system control unit 3 is connected to the control input-output of the antenna system 2, the microwave input-output of which is connected to the microwave input-output of the transceiver equipment 4 of the satellite communication station 1, the control input-output of which is connected to control input-output of the antenna system control unit 3, the channel input-output of the transceiver equipment 4 of the satellite communication station 1 is connected to the line input-output of the modem 5, the channel inputs-outputs of which are connected via the Ethernet interface to the first inputs-outputs of the universal router 19. The first, second and third inputs-outputs of the transceiver 7 of the range of meter waves (MB) at the joints of RS-232, S1-FL and Ethernet are connected respectively to the first, second and third inputs-outputs of the control and switching unit 10 of the radio communication module 6, the fourth, fifth and sixth inputs-outputs of which are connected via the RS-232, S1-FL and Ethernet interfaces, respectively, to the first, second and the third input-outputs of the transceiver 11 of the decimeter wave (UHF) range, the high-frequency input-output of which is connected through the block 12 of the separation filters of the UHF range to the high-frequency input-output of the antenna 13 of the UHF range, and the high-frequency input-output of the transceiver 7 MB range through block 8 crossover filters of the MB range is connected to the high-frequency input-output of the antenna 9 of the MB range, the seventh, eighth and ninth inputs-outputs of the control and switching unit 10 of the radio communication module 6 at the RS-232, S1-FL and Ethernet interfaces are connected, respectively, to to the first, second and third inputs-outputs of the transceiver 14 of the range of decameter waves (DCMW), the high-frequency input-output of which is connected to the high-frequency input-output of the antenna 16 of the range of DHMW through the filter unit 15 of the range of DHMW. The first, second and third control inputs/outputs of the control and switching unit 10 of the radio communication module 6 are connected respectively to the first, second and third control inputs/outputs of the central control unit 18, the fourth control input/output of which is connected to the control input/output of the universal router 19, the second input-output of which via the Ethernet interface is connected to the tenth input-output of the control and switching unit 10 of the radio communication module 6, the fifth control input-output of the central control unit 18 via the Ethernet interface is connected to the control input-output of the portable computer 20 of the workstation (AWP) control of a communication repeater, the information input-output of which is connected via the RS-232 interface to the information input-output of the navigation equipment 21 with a built-in antenna, the input-output of the IP camera 22 is connected to the first input-output of the video recorder 23 with a solid-state drive, the second input-output of which connected with input-output portable th computer 20 AWP control repeater communication, the first and second station inputs-outputs of the board 24 switching circuits and communication lines (KCLS) via Ethernet junctions are connected respectively to the inputs-outputs of the central control unit 18 and to the second inputs-outputs of the universal router 19, the first and the second linear inputs-outputs of the switchboard 24 of channels and communication lines are connected, respectively, to the input-output of the connecting line (SL) of communication 25 and to the first input-output of the fiber-optic communication line 26 (FOCL), the second input-output of which is connected to the input- the output of the fixed point 27 binding, portable radio stations 17 on the air connected to the antenna 9 of the MB band and/or the antenna 13 of the UHF band.

The satellite communication station 1 is designed to organize satellite communication radio links when operating through the trunks of spacecraft (SC) repeaters in the Ku and C bands under any conditions and under the influence of deliberate interference. It provides operation in two modes: with signal processing on board (OSB) of the repeater and with direct signal relay (PR). At the same time, the station provides encrypted telephone communication and data transmission, including machine-to-machine exchange data, over one or two channels with a bandwidth of 1.2 ... 4.8 kbps via fixed channels and radio-ATS channels or in one direction with a bandwidth of 1 .2…9.6 kbps and 16 kbps.

Satellite communication station 1 provides reception of radio signals from GLONASS and GPS space navigation systems in order to determine the full coordinates of the station location (longitude, latitude, altitude), current time and ensure correction of the reference frequency of the station relative to the frequency of the navigation signal with an accuracy of no worse than 1 × 10-9 .

Antenna system 2 includes an antenna, which is an antenna array in the form of a multilayer board and a rotator. Antenna system 2 is designed to receive and transmit electromagnetic energy through a repeater on a spacecraft (SC) that is in geostationary or highly elliptical orbits. Guidance of the antenna system 2 to the spacecraft is carried out automatically by entering the initial data for calculating target designations from the control unit, or in the manual mode of entering the azimuth and elevation parameters of the spacecraft.

As the antenna system 2 of station 1, an antenna system of the Satcom-On-The-Move Ku-band type can be used.

As the antenna system control unit 3, a mobile antenna system controller supporting SNMP or open AMIP can be used.

The transceiver equipment 4 of the satellite communication station 1 contains a duplexer, a transmitter, a low-noise amplifier and a radio receiver.

Modem 5 is designed to convert signals from analog to digital and vice versa, exchange information over channels and communication lines.

As modem 5, an EASTAR UHP-200 modem router with software version 3.5.x (or equivalent) can be used with TTS (DTTS) delay calculation mode.

The radio communication module 6 is designed to organize multichannel radio communication lines in the ranges of meter (MB), decimeter (UHF) and decameter (DKMV) waves with automatic relaying and transit transmission of various digital streams over them.

The transceiver 7 of the range of meter waves of the module 6 of the radio communication together with the block 8 of the crossover filters of the MB range, the antenna 9 of the MB range, the control and switching unit 10 is designed to form paths for the transit transmission (retransmission) of information on the sections of the trunk lines of long-distance radio communication in the MB range with the possibility of access through the satellite station 1 with an antenna system 2 to local radio links to remote subscribers of mobile and stationary objects.

The control and switching unit 10 of the radio module 6 is designed to ensure the interconnected operation of the transceivers 7, 11 and 14 of the radio module 6, the organization of information transmission paths, the implementation of switching, distribution and retransmission of channels in communication directions in the formed group flows.

The transceiver 11 of the UHF range, together with the block 12 of the crossover filters of the UHF range and the antenna 13 of the UHF range, is designed to form paths and retransmit transmitted information on sections of long-range radio communication trunk lines in the UHF range with the possibility of isolating channels and accessing them to zonal (local) radio communication lines to remote subscribers of mobile and stationary objects.

The transceiver 14 of the decameter wave range (DCMW) together with the block 15 of the splitting filters of the DHMW range and the antenna 16 of the DHMW range are designed to form paths and retransmit transmitted information on sections of long-distance radio communication trunk lines in the DHMW range with the possibility of channel selection and output on them to zonal (local) radio communication lines to remote subscribers of mobile and stationary objects.

As antenna 9 of the MB band, a whip antenna of the ASh-1.5 / 3 0 type is used, and as antennas 13 and 16 of the UHF and DKMV bands, dipole antennas of the AD-30/520 type and whip antennas of the ASh-520 type can be used /2500-BV.

As a radio communication module 6, a portable radio station of the Angstrem-V type manufactured by the industry can be used. This radio station provides four independent multichannel directions of communication.

Portable radio stations 17 are designed to organize radio communications in networks of meter and decimeter bands, automatic relaying of transmitted signals and messages, telephone communications and data exchange.

As portable radio stations 17 can be used portable radio station "Angstrem-Sh" developed by the industry. This radio station provides the possibility of organizing a direct radio network with similar portable radio stations and access to the channels of long-distance radio links for communication with remote subscribers, maintaining telephone communications with subscribers of radio networks organized by the radio communication module 6.

The central control unit 18 is designed to ensure the interconnected operation of communication, switching and organization of automatic relaying of the formed channels and information flows in the process of setting up and operating a terrestrial mobile communication repeater.

The universal router 19 is intended for routing, switching and distribution of information flows formed by means of communication of the relay on communication networks between communication nodes, subscribers of stationary and mobile objects. Block 19 is a fully accessible switch-router that provides automatic choice of communication direction and distribution of paths and communication channels in the process of establishing and maintaining communication between interacting objects (subscribers).

As such a router, for example, a universal router (Universal Access Routers) of the ACX1000-DC 8 × T1 / E1 type, 8 × GbE copper, 4 × GbE combination (copper or SFR), dual feed DC power or an industrial Ethernet switch can be used type KTM-1373, developed by OJSC "Morion" (Perm), which is a packet information transmission equipment designed to build technological and dedicated data transmission networks, as well as local computer networks for industrial use.

The automated workstation (AWS) for the control of the repeater, equipped on the basis of a laptop computer 20, is intended for setting up and monitoring the technical condition of the equipment, means of communication and control of the repeater, organizing channels and paths when providing services to officials for the duration of their operational work. At the same time, with the help of a portable computer 20 workstations for controlling the repeater, the following is provided:

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 communication repeater to the extent of the capabilities provided for in the equipment;

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

f) informational and functional interaction with the GPS/GLONASS navigation receiver, including the automatic reception of data to determine the coordinates of one's location and entering them into the personal computer AWS.

The portable computer 20 of the workstation (AWP) for the control of the repeater also provides:

accumulation, storage, registration and processing of received information;

visual control of information exchange;

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

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

automatic equipment control;

preservation of information and data during a short-term power outage.

The control commands are entered by the operator through the keyboard of a laptop computer or remotely via service radio channels, organized with the help of transceivers of the radio module 6.

As a portable computer 20 workstations for controlling the repeater, a personal computer of the EC-1866 type, made in a single monoblock like a laptop, can be used. The PC contains a hardware platform, a secure operating system, software for protecting information from unauthorized access (NSA), software for anti-virus protection and e-mail tools. It provides for the possibility of installing third-party specialized application software (SPO) compatible with the hardware and software platform.

As navigation equipment 21 with a built-in antenna, navigation equipment of the "Azimuth" or "Grot-V" type, installed in mobile objects at various transport bases, can be used. The specified equipment is designed to measure the current navigation parameters according to the signals of the GLONASS and GPS space navigation systems and determine, on their basis, the coordinates of the location of moving objects, speed in absolute and differential modes, as well as to synchronize the internal time scale to the GLONASS and GPS system time scales, coordinated UTC (SU) and UTC times. Structurally, the equipment consists of an electronic unit and an antenna module. The electronic unit provides the processing of signals of navigation parameters and the issuance of navigation data to the consumer.

The IP camera 22 is intended for video filming and organizing the transmission of video images to the portable computer 20 of the repeater control workstation about objects located in the area around the ground-based mobile communication repeater, with subsequent conversion of video images into digital signals and transferring them to the memory of the video recorder 23 with a solid state drive.

An ISE-30/36ZWDN650FD controlled video camera can be used as an IP camera 22.

The video recorder 23 with a solid state drive is designed to receive video signals from external video cameras, process them and convert them into digital signals, which are transmitted to the portable computer 20 of the workstation for controlling the communication repeater.

Shield 24 switching channels and communication lines (KCLS) is designed to distribute information flows and switching circuits to external devices. The specified board KKLS carries out fully accessible switching of signals coming from any input to any of the outputs. Shield 24 is a patch panel, which contains switching elements and connectors for connecting subscriber lines and digital paths.

The connecting line 25 is intended for communication with subscribers of interacting mobile objects and access to public communication networks. It can be performed using a twisted-pair cable of a field telephone distribution cable with a quad structure type P-269M or a multicore field cable P-274M.

The fiber-optic communication line 26 is intended for the issuance/reception of digital paths to the fixed point 27 of the binding and the organization of the transit of communication channels (paths) on the public communication network. It can be performed using a field optical cable POK-B-4.

Stationary anchor point 27 includes switching equipment, operator workstations and fiber-optic communication lines, which provide access to public communication networks.

The ground mobile communications repeater is designed to provide access and automatic relaying to the resources of radio and satellite communications networks while stationary and on the move. It provides:

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

restoration, redundancy 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 public communication network lines;

establishing communication in hard-to-reach areas, including mountainous, swampy and wooded areas;

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

formation of a satellite communication line using a satellite communication subscriber station with a capacity of up to 2048 kbit / s at a stop and on the move;

organization of radio communications in networks of meter, decimeter and decameter bands using transceivers of a portable mobile radio station;

counter work with radio stations of meter and decameter ranges in the mode of fixed frequencies (FF);

organization of a radio access network (RAN) in duplex mode in networks of meter and decimeter wave bands;

retransmission (in automatic mode) of signals and messages from any transceiver of a portable station to any other transceiver of a radio station with routing to a satellite communication station;

access to the data transmission network using a satellite communication station;

internal switching and routing;

service radio communication in the meter and decameter wave bands when moving in a column using transceivers of the radio module 6;

organization of work in mobile radio networks with provision of automatic telephone communication and data exchange with remote subscribers via established radio channels;

storage and processing of digital information and data using a block of the operator's workplace and a video recorder with a solid state drive;

determining the coordinates of your location using navigation equipment with a built-in antenna.

The main mode for organizing and maintaining communication sessions with external subscribers (including via compound channels) is the automatic mode.

The technical effect of the proposed invention consists in expanding the functionality of the communication repeater in terms of increasing the number of formed relay paths through which the transmission / reception of various multicast streams is carried out, and increasing the throughput of the communication repeater, achieved by introducing a multi-channel satellite communication station into the composition of the communication repeater, operating in two frequency ranges and providing the organization of retransmission of channels and paths in two directions, access to the radio network through the transceivers of the radio communication module of three wavelengths (meter, decimeter and decameter), each of which provides the organization of relay paths in the specified ranges, as well as output via a connecting communication line and a fiber-optic communication line through a fixed point of attachment in a wired communication network to subscribers of remote stationary and mobile objects.

The advantage of the proposed terrestrial mobile communication repeater is also the fact that it is equipped in a cross-country vehicle and with its help radio communication networks can be organized in hard-to-reach places.

Information sources.

1. SU, copyright certificate No. 1081808 A, class. H04B 7/02, 1984.

2. V. I. Vlasenko, V. P. Serkov, and V. P. Chernoles, Acoust. Antennas for military communications equipment / Aircraft repeater. - L .: VAS, 1986, p. 122, 123; rice. 5.17.

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

4. RU patent No. 2680008. IPC H04B 7/04, H01Q 7/65. Bull. No. 5 dated February 14, 2019 (prototype).

Claims (1)

Ground-based mobile communication repeater, containing a radio communication module, consisting of a control and switching unit, a transceiver for the meter wave (MB) range, a crossover filter unit for the MB range and an antenna for the MB range, a transceiver for the decimeter wave range (UHF), a separation unit UHF range filters and UHF range antennas, a central control unit, a universal router, a switching board for channels and communication lines (CCLS), an automated workstation (AWS) for controlling a repeater equipped on a laptop computer, a connection line (SL) for communication and a fiber-optic a communication line (FOCL), characterized in that it additionally includes a satellite communication station, including an antenna system, an antenna system control unit, transceiver equipment and a modem, portable radio stations, navigation equipment with a built-in antenna, a video recorder with a solid state drive, IP camera, fixed a binding point, and the radio communication module additionally includes a decameter wave band (DCMW) transceiver, a DHMW band separation filter unit and a DHMW band antenna, while the control input-output of the antenna system control unit is connected to the control input-output of the antenna system, microwave input-output of which is connected to the microwave input-output of the transceiver equipment of the satellite communication station, the control input-output of which is connected to the control input-output of the antenna system control unit, the channel input-output of the transceiver equipment of the satellite communication station is connected with a linear input-output of the modem, the channel inputs-outputs of which are connected via the Ethernet junction to the first inputs-outputs of the universal router, the first, second and third inputs-outputs of the transceiver of the meter wave range (MB) via the RS-232, C1- FL and Ethernet are connected respectively to the first, second and third inputs-in to the outputs of the control and switching unit of the radio communication module, the fourth, fifth and sixth inputs-outputs of which are connected via the RS-232, S1-FL and Ethernet interfaces, respectively, to the first, second and third inputs-outputs of the transceiver of the decimeter wave range (UHF), the high-frequency input-output of which, through a block of crossover filters of the UHF range, is connected to the high-frequency input-output of the antenna of the UHF range, and the high-frequency input-output of the transceiver of the MB range, through the block of crossover filters of the MB range, is connected to the high-frequency input-output of the antenna of the MB range, the seventh, the eighth and ninth inputs-outputs of the control and switching unit of the radio communication module at the RS-232, S1-FL and Ethernet interfaces are connected, respectively, to the first, second and third inputs-outputs of the decameter wave band (DCMW) transceiver, the high-frequency input-output of which connected to the high-frequency input-output of the ante the range of UCMV, the first, second and third control inputs-outputs of the control and switching unit of the radio communication module are connected respectively to the first, second and third control inputs-outputs of the central control unit, the fourth control input-output of which is connected to the control input-output of the universal router, the second input-output of which is connected via the Ethernet interface to the tenth input-output of the control and switching unit of the radio communication module, the fifth control input-output of the central control unit is connected via the Ethernet interface to the control input-output of the portable computer of the workstation (AWP) for controlling the communication repeater, the information input-output of which is connected via the RS-232 interface to the information input-output of navigation equipment with a built-in antenna, the input-output of the IP camera is connected to the first input-output of the video recorder with a solid state drive, the second input-output of which is connected to the input-output of a portable computer and the communication repeater control workstation, the first and second station inputs-outputs of the circuit switching board and communication lines (CCLS) are connected via Ethernet joints, respectively, to the inputs-outputs of the central control unit and to the second inputs-outputs of the universal router, the first and second linear inputs-outputs switching boards of channels and communication lines are connected respectively to the input-output of the connecting line (SL) of communication and to the first input-output of the fiber-optic communication line (FOCL), the second input-output of which is connected to the input-output of the stationary anchor point, portable radio stations on the air are connected to an MB band antenna and/or a UHF band antenna.

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