RU2556878C1 - Mobile equipment for sw-vhf radio communication - Google Patents

Abstract

FIELD: radio engineering, communication.SUBSTANCE: invention relates to radio communication. The technical result is facilitating the transmission of information over radio channels with a high degree of delivery in conditions where the radio equipment is exposed to various interferences. Said technical result is achieved due to that the mobile equipment for SW-VHF radio communication consists of four transceiving antennae, an antenna switch, a narrow band-pass filter unit, a multichannel radio receiving device, an automatic communication setup unit, a hardware server which includes an Ethernet switch and a personal computer, two operator automated workstations, each including a notebook computer, a liquid crystal monitor, a standard keyboard and a handset, a GPS/GLONASS navigation receiver, a universal time signal generating unit, an interface converter, a primary multiplexer, a multichannel radio transmitting device, a selective filter unit, a broadband modem, a digital radio relay station with an antenna, a mobile VHF radio station with an antenna, a portable SW radio station with an antenna, a unit for channel and line switching and linear input, which is connected to a connecting line for channel reception/output, a high-speed digital subscriber line and a fibre-optic communication line, a switching and calling unit, two communication panels and a VHF service communication radio station with an antenna.EFFECT: disclosed set of features, the multichannel design of the radio receiving and radio transmitting devices, which enable to set up at least four independent radio communication directions, in each of which up to four independent channels are formed, also enable to broaden the functional capabilities of the equipment and increase the throughput of the communication directions set up.3 cl, 3 dwg

Description

The invention relates to radio communications technology and can be used on radio communication networks of field communication nodes of various ministries and departments.

In modern communication systems, including radio communication systems, integrated networks that use various means of communication and computer technology are increasingly used. Such use contributes to the achievement of improved qualitative and quantitative communication services in various fields. To achieve these goals, modern means, complexes and radio communication systems are used in conjunction with automation based on computer technology, providing the ability to organize radio networks with high technical specifications for the establishment and maintenance of radio communications, as well as for the transmission of information and data with a high degree of information delivery [1 ].

The objective of the invention is the creation of a mobile hardware HF-VHF radio communication with advanced functionality, designed to organize radio communication networks on field communication nodes, operating in a wide frequency range and providing the ability to work both autonomously and as part of radio centers of field communication nodes.

The aim of the invention is the provision of transmission over radio channels formed by means of communication hardware, information and data with increased reliability of delivery under conditions of exposure to radio means of various interference of a natural and artificial nature.

This goal is achieved by the fact that the mobile HF-VHF radio communication equipment consists of four transceiver antennas, an antenna switch, a multi-channel radio receiving device (RPU), an automatic communication unit (AUS), a hardware server that includes an Ethernet switch and a personal electronic computer ( PC), the first automated workstation for the operator (ΑΡΜΟ), which includes a portable laptop, a liquid crystal (LCD) monitor, a standard keyboard and a mic-phone headset at (MTG), the second ΑΡΜΟ, which includes a portable laptop, an LCD monitor, a standard keyboard and MTG, a GPS / GLONASS navigation receiver with a built-in antenna, a unit for generating single-time signals (SEB), an interface converter, a primary multiplexer, a multi-channel radio transmitting device ( RPDU), selective filter unit (SF), broadband modem, digital radio relay station (RRS), digital RRS antenna, portable ultra-short-wave (VHF) radio station with an antenna, a portable short-wave (KB) radio station with antenna, channel and line switching unit (CCL), line input, to the first, second and third line inputs and outputs of which are connected respectively a trunk (SL) for receiving / issuing channels, a high-speed digital subscriber line (DSC) and fiber-optic line communication (FOCL), switching and calling unit (BKV), two communication panels (PS), VHF radio intercoms and antennas VHF radio intercoms, with high-frequency (HF) inputs and outputs of the first, second, third and fourth transceiver antennas are connected respectively to the first, second, third and fourth high-frequency (HF) inputs-outputs of the linear side of the antenna switch, the first, second, third and fourth HF inputs-outputs of the station side of which are connected respectively to the first, second, third and fourth inputs-outputs of the unit UV, the first, second, third and fourth high-frequency outputs of which are connected respectively to the first, second, third and fourth high-frequency inputs of a multi-channel RPU, the first, second, third and fourth channel outputs RS-485 is connected at the junction respectively to the first, second, third and fourth inputs of the hardware server Ethernet switch, the first input-output of which is connected via RS-232 interface to the PC server input-output of the hardware server, and the second input-output of the Ethernet switch via Ethernet connected to the input-output of the AUS unit, the first control output of which is connected to the control input of the multi-channel RPU, the third input-output of the Ethernet switch at the RS-232 interface is connected to the first input-output of the laptop первого the first, second, third and fourth the odes-outputs of which are connected to the inputs and outputs of the LCD monitor, standard keyboard, and MTG, respectively, the fourth input-output of the Ethernet switch at the RS-232 interface is connected to the first input-output of the second laptop ΑΡΜΟ, the second, third, and fourth inputs and outputs of which are connected to the inputs and outputs of the LCD monitor, standard keyboard, and MTG, respectively, the channel input-output of the GPS / GLONASS navigation receiver is connected to the information input-output of the SEV formation unit, whose control input-output is connected via Ethernet to the fifth input-output of the Ethernet switch, the sixth and seventh inputs and outputs of which are connected via Ethernet interface to the first and second inputs and outputs of the interface converter, the third and fourth inputs and outputs of which are connected respectively to the first and second inputs and outputs of the primary multiplexer, the third and the fourth inputs and outputs of which at the E1 interface are connected respectively to the first and second station inputs and outputs of the KKL unit, the first and second linear inputs and outputs of which are connected at the Ethernet 10Base-TX interface, respectively about to the first and second station line input-output inputs, the first, second and third line input-outputs of which are connected to the input-output respectively of the trunk for receiving / issuing channels, high-speed digital and fiber optic link, the first, second, third and fourth outputs of the Ethernet switch at the Ethernet junction, respectively, are connected to the first, second, third and fourth inputs of the multi-channel RPDU, the control input of which is connected to the second control output of the ACS block, the first and second RF outputs of the multi-channel RPDU are connected respectively to the first and second HF inputs of the antenna switch, the third and fourth HF inputs of which are connected respectively to the first and second HF outputs of the SF unit, the first and second high-frequency inputs of which are connected respectively to the third and fourth HF outputs of a multi-channel RPDU, the eighth input-output of the Ethernet switch the Ethernet interface is connected to the channel input-output of a broadband modem, the linear input-output of which at the Е1 interface is connected to the channel input-output of a digital PPC, the high-frequency input-output of which is connected to a high the digital PPC antenna’s frequency input-output antenna, the ninth Ethernet switch input-output at the Ethernet interface is connected to the channel input-output of a portable VHF radio station, the high-frequency input-output of which is connected to a high-frequency antenna input-output of a portable VHF radio station, the tenth Ethernet switch input-output Ethernet interface is connected to the channel input-output of a portable KB radio station, the high-frequency input-output of which is connected to a high-frequency input-output antenna of a portable KB radio station, the eleventh input-output of an Ethernet switch Ethernet is connected to the third station input-output of the line input, the third station input-output of the KKL unit is connected to the line input-output of the switching and calling unit, the first and second station inputs and outputs of which are connected respectively to the linear inputs and outputs of the first and second communication panels, the channel inputs and outputs of the switching and calling unit are connected to the channel inputs and outputs of the VHF service station radio, the high-frequency input-output of which is connected to the high-frequency input-output of the VHF antenna of the service station Noah connection.

This goal is also achieved by the fact that the multichannel RPU contains four receive path modules, a vector combiner unit, a control unit and a terminal equipment interface unit (OA), the inputs / outputs of the first, second, third and fourth receive path modules at the McBSP interface being connected respectively to the first, second, third and fourth inputs and outputs of the vector combiner unit, the fifth input-output of which is connected via USB 2.0 to the first input-output of the control unit, the second input-output of which is connected to USB 2.0 with the input-output of the terminal equipment interface unit (OA), while the high-frequency (HF) inputs of the first, second, third, and fourth modules of the receiving path are the first, second, third, and fourth RF inputs of the multichannel RPU, the first, second, third, and fourth the channel outputs of which are, respectively, the first, second, third and fourth outputs of the OA interface unit, and the control input of the control unit is the control input of a multi-channel RPU connected to the output of the automatic Communication links.

This goal is achieved by the fact that the multichannel RPDU contains a terminal equipment interface (OA) unit, a control unit, a vector combiner unit, and four exciter path modules, the input / output of the OA interface unit via USB 2.0 connecting to the first input / output of the control unit, the second input-output of which at the USB 2.0 interface is connected to the first input-output of the vector combiner unit, the second, third, fourth and fifth inputs and outputs of which at the McBSP interface are connected respectively to the input-output of the first, second, third and fourth of the pathogen path module, the first, second, third and fourth inputs of the OA interface unit are the first, second, third and fourth inputs of the multi-channel RPDU, the first, second, third and fourth high-frequency outputs of which are the outputs of the first, second, third and the fourth module of the path of the pathogen, and the control input of the control unit is the control input of a multi-channel RPDU connected to the second output of the automatic communication unit.

Search results for similar solutions in patent documentation and scientific and technical literature showed that at the time of filing the application for the proposed invention, such solutions and a combination of signs were not found.

Thus, the claimed invention meets the criteria of the invention of "novelty", and the proposed combination of blocks with their respective connections contributes to the achievement of the goal: to increase the reliability of the transmission of information and data under the influence of various interference to radio reception. The calculations of the quality of information transfer and analysis of the results showed that in the mobile hardware HF-VHF radio communications, the probability of element-wise error is not lower than 5 × 10 ^-2 when transmitting digital information even on low-quality radio channels. 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 positive test results of the manufactured prototype of the mobile HF-VHF radio communication equipment.

In FIG. 1 is a structural electrical diagram of a mobile hardware HF-VHF radio communication, and in FIG. 2 and 3 show structural electrical circuits of a multichannel radio receiving device and a multichannel radio transmitting device, respectively.

The mobile HF-VHF radio communication equipment (Fig. 1) consists of the first 1, second 2, third 3 and fourth 4 transmit-receive antennas, antenna switch 5, block 6 narrow-band filters (UV), multi-channel radio receiver (RPU) 7, block 8 automatic Communication Establishment (AUS), hardware server 9, which includes an Ethernet switch 10 and a personal electronic computer (PC) 11, a first operator workstation 12 (ΑΡΜΟ), including a portable laptop 13, a liquid crystal (LCD) monitor 14, mill an art keyboard 15 and a micro-telephone headset (MTG) 16, a second 17 ΑΡΜΟ, which includes a PC 18, a portable laptop 19, an LCD monitor 20 and MTG 21, a GPS / GLOHACC navigation receiver 22 with a built-in antenna, CEB formation unit 23, a 24 interface converter , primary multiplexer 25, multi-channel radio transmitting device (RPDU) 26, block 27 selective filters (SF), broadband modem 28, digital radio relay station (RRS) 29, antenna 30 digital RRS, transportable VHF radio station 31 with antenna 32, wearable KB radio station 33 with antenna 34, bl OKA 35 switching channels and lines (KKL), linear input 36, to the first, second and third linear inputs and outputs of which are connected respectively SL 37 for receiving / issuing channels, high-speed digital telephony line 38 and fiber optic communication line 39 (FOCL), unit 40 switching and calling, the first 41 and second 42 communication panels, VHF radio stations 43 service communication and antennas 44 VHF radio stations communication service.

High-frequency inputs-outputs of the first 1, second 2, third 3 and fourth 4 transceiver antennas are connected respectively to the first, second, third and fourth RF inputs-outputs of the linear side of the antenna switch 5, the first, second, third and fourth RF inputs-outputs of the station side which are connected respectively to the first, second, third and fourth RF inputs-outputs of the UV unit 6, the first, second, third and fourth high-frequency outputs of which are connected respectively to the first, second, third and fourth high-frequency the frequency (HF) inputs of a multi-channel RPU, the first, second, third and fourth channel outputs of which at the RS-485 interface are connected respectively to the first, second, third and fourth inputs of the Ethernet switch 10 of the server 9 hardware, the first input-output of which at the RS- interface 232 is connected to the input / output of the PC 11 of the hardware server, the second input-output of the Ethernet switch 10 at the Ethernet interface is connected to the input-output of the ACC block 8, the first control output of which is connected to the control input of the multi-channel RPU 7.

The third input-output of the Ethernet switch 10 at the RS-232 interface is connected to the first input-output of the portable laptop 13 of the first 12 ΑΡΜΟ, the second, third and fourth inputs and outputs of which are connected to the inputs and outputs of the LCD monitor 14, standard keyboard 15 and MTG 16, respectively , the fourth input-output of the Ethernet switch 10 at the RS-232 interface is connected to the first input-output of the portable laptop 18 of the second 17 ΑΡΜΟ, the second, third and fourth inputs and outputs of which are connected to the inputs and outputs of the LCD monitor 19, standard keyboard 20 and MTG 21. Channel input the output of the GPS / GLONASS navigation receiver 22 is connected to the information input-output of the SEB formation unit 23, the control input-output of which at the Ethernet interface is connected to the fifth input-output of the 10 Ethernet switch, the sixth and seventh inputs and outputs of which are connected to the first via the Ethernet interface and the second inputs and outputs of the interface converter 24, the third and fourth inputs and outputs of which are connected respectively to the first and second inputs and outputs of the primary multiplexer 25.

The third and fourth inputs and outputs of the primary multiplexer 25 at the E1 interface are connected respectively to the first and second station inputs and outputs of the KKL block 35, the first and second linear inputs and outputs of which at the Ethernet 10Base-TX interface are connected respectively to the first and second station inputs and outputs linear input 36, the first, second and third linear inputs and outputs of which are connected to the input-outputs of the trunk 37 for receiving / issuing channels, high-speed digital telephony center 38 and fiber optic link 39.

The first, second, third and fourth outputs of the Ethernet switch 10 at the Ethernet interface are connected respectively to the first, second, third and fourth inputs of the multi-channel RPDU 26, the control input of which is connected to the second control output of the ACC block 8, the first and second RF outputs of the multi-channel RPDU 26 are connected respectively, to the first and second RF inputs of the antenna switch 5, the third and fourth RF inputs of which are connected respectively to the first and second RF outputs of the SF unit 27, the first and second high-frequency inputs of which are connected s respectively to the third and fourth RF outputs of the multi-channel RPDU 26. The eighth input-output of the Ethernet switch 10 at the Ethernet interface is connected to the channel input-output of the broadband modem 28, the linear input-output of which at interface E1 is connected to the channel input-output of the digital PPC 29, the high-frequency input-output of which is connected to the high-frequency input-output of the antenna 30 of the digital RRS 29.

The ninth input-output of the Ethernet switch 10 at the Ethernet interface is connected to the channel input-output of the transportable VHF radio station 31, the high-frequency input-output of which is connected to the high-frequency input-output of the antenna 32 of the portable VHF radio station 31, the tenth input-output of the Ethernet switch 10 is connected at the Ethernet interface with channel input-output of a portable KB radio station 33, the high-frequency input-output of which is connected to a high-frequency input-output antenna 34 of a portable KB radio station 33.

The eleventh input-output of the Ethernet switch 10 at the Ethernet interface is connected to the third station input-output of the linear input 36, the third station input-output of the KKL block 35 is connected to the linear input-output of the switching and calling unit 40, the first and second station inputs and outputs of which are connected respectively, to the linear inputs and outputs of the first 41 and second 42 communication panels, the channel inputs and outputs of the switching and calling unit 40 are connected to the channel inputs and outputs of the VHF radio of the office communication station 43, the high-frequency input-output of which is connected to sokochastotnym input-output of the antenna 44 VHF radio 43 intercom.

A multi-channel radio receiving device (RPU) 7 contains (Fig. 2) a first 45 ₁ , a second 45 ₂ , a third 45 ₃ and a fourth 45 ₄ receiving path modules, a vector combiner unit 46, a control unit 47 and a terminal equipment (OA) interface unit 48, the inputs and outputs of the first 45 ₁ , second 45 ₂ , third 45 ₃ and fourth 45 ₄ receiving path modules at the McBSP interface are connected respectively to the first, second, third and fourth inputs and outputs of the block 46 vector combiners, the fifth input-output of which is at the junction USB 2.0 is connected to the input-output of the control unit 47, the second stroke-output of which through the joint USB 2.0 is connected to the input-output unit 48 terminal equipment interfaces (OA), wherein the high frequency (HF) inputs of the first 45 _1, the second 45 _2, third 45 ₃ and fourth 45 ₄ receiving channel modules are the first , the second, third and fourth RF inputs of the multi-channel RPU 7, the first, second, third and fourth channel outputs of which are the first, second, third and fourth outputs of the OA interface unit 48, and the control input of the control unit 47 is the control input of the multi-channel oh RPU 7 connected to the first output of block 8 automatic communication.

The multi-channel radio transmitting device (RPDU) 26 comprises (Fig. 3) terminal equipment interface (OA) block 49, a control unit 50, vector combiner unit 51 and four 52 (52 ₁ , 52 ₂ , 52 ₃ and 52 ₄ ) pathogen module, moreover, the input-output of the block 49 of the OA interfaces at the USB 2.0 interface is connected to the first input-output of the control unit 50, the second input-output of which at the USB 2.0 interface is connected to the first input-output of the vector combiner unit 51, the second, third, fourth, and fifth inputs the outputs of which at the junction of McBSP are connected respectively to the inputs and outputs of the first 52 ₁ , second 52 ₂ , third 52 ₃ and fourth 52 ₄ module of the pathogen pathway, while the first, second, third and fourth inputs of the OA interface unit 49 are the first, second, third and fourth inputs of the multi-channel RPDA 26, the first, second, third and a fourth high-frequency outputs which are the outputs of respectively the first 52 _1, 52 ₂ of the second, third and fourth ₃ 52 52 ₄ pathogen tract modules, and the control input of the control unit 50 is a multi-channel RPDU control input 26 connected to the second output block 8 automatic communication.

The first 1, second 2, third 3 and fourth 4 transceiver antennas are designed to receive and transmit signals in the KB (1.5-30 MHz) and VHF (30-108 MHz) frequency ranges when the mobile equipment is parked. At the same time, antennas are installed on masts with a height of 13 to 20 meters.

Antenna switch 5 is designed for switching high-frequency signals from antennas (1-4) of the KB and VHF ranges from any of the inputs and outputs of the line side to any of the inputs and outputs of the station side of the switch.

Block 6 of narrow-band filters is designed to separate the signals coming from the antenna switch 5 into separate channels.

Multichannel radio receiver 7 is a multifunctional radio receiver that provides four-channel reception for each of the RF antenna inputs, spatial diversity reception with automatic noise compensation, frequency filtering / transfer with subsequent digitization, digital frequency conversion, digital signal processing with demodulation, signal generation for terminal telephone and telegraph equipment or broadcasting of four channel level information flows ku Ethernet 10Base-TX.

Each of the four receiving path modules 45 includes a digital tuner and a preselector, an antenna input switch, a reference oscillator, and a reference signal conditioner. This structure provides the ability to simultaneously receive several independent channels in each path, allows you to increase the transmission rate of digital information by adding the bandwidth of several channels and the formation of one virtual channel.

Block 46 vector combiners contains a digital signal processor, read-only memory (ROM), random access memory (RAM), a USB controller, and a clock driver. Block 46 performs vector summation of signal samples, demodulation of signals, signal generation and data exchange with control unit 47.

The control unit 47 is designed to control all elements of the receive path module directly and remotely via the Ethernet 100 Base-TX interface. Block 47 is based on a single-board computer, which facilitates the implementation of standard network protocols that provide communication via the Ethernet interface and organize interaction with the main nodes of the multi-channel RPU 7 via the USB 2.0 interface.

Block 48 of the OA interfaces is designed to convert the channels of the USB group stream into the channels of the interfaces C1-ТЧ, С1-ТГ, C1-И and inverse conversion.

Block 8 automatic connection establishment (AUS) is designed to exchange data on galvanically isolated interfaces with external devices, to receive from the local area network (LAN) and transmit data and voice signals to the LAN, to implement the algorithm for automatic connection establishment in the mobile hardware and control all units hardware when working in automatic mode.

Hardware server 9 is intended for use as a server for managing and processing information, as well as for performing the function of switching information flows. It provides control of the radio equipment room through serial and USB ports according to the commands of operators and in automatic mode, operation as a local network server and a remote access server, storage and processing of radio data received during operation.

The hardware server 9 is also intended for the formation of duplex channels of the C1-TCH, C1-TG and C1-I interfaces, that is, the formation of terminal equipment (OA) interfaces. It provides the function of a multiplexer / demultiplexer of the C1-TCh, C1-TG, C1-I interfaces to the group channels of the USB interface.

Switch 10 Ethernet server 9 hardware is designed to provide access to the formed local computer network of the hardware and ensure data transfer through it at the interface Ethernet 100 Base-TX between the first 12 and second 17 automated workstations of operators (ΑΡΜΟ), as well as through communication channels.

A personal electronic computer 11 together with an Ethernet switch 10 acts as a packet switch of Ethernet channels into group USB channels or independently generated data streams.

As a personal computer 11, a personal computer of the EC-1866 type developed by NITSEVT OJSC (Moscow, decimal number PIRSH.466215.005) can be used. A personal computer is a multifunctional terminal, including a computer, supplemented with hardware and software for navigation, communication and data transmission. It performs computational functions, as well as the functions of input-output, storage, display and processing of information. It has technical, information, software, and operational compatibility with IBM PC / AT.

Structurally, the PC 11 is a portable secure laptop-type computer mounted on a cushioning frame, in order to prevent its movement when the mobile equipment is in motion.

The first 12 and second 17 ΑΡΜΟ perform the same type of functions, are intended for information exchange with equipment and communications equipment and provide:

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 control of multi-channel RPU and RPDU;

change of operating frequency grids, radio data and daily schedule of communication sessions;

saving information and data from a communication session during a short-term power outage.

Each of the portable laptops 13 and 18 of the first 12 and second 17 ΑΡΜΟ contains a system unit consisting of a motherboard on which a microprocessor, a system bus, random access memory (RAM), reprogrammable read-only memory (ROM) and a keyboard controller are located, also consisting from a monitor adapter, port adapter, disk controller, additional device controller, hard disk, floppy disk drive, system software, and application software supplied on a hard disk drive.

The system unit of laptops 13 and 18 is based on the industrial protected TS 702OT laptop DVI series (without built-in monitor) in an aluminum fanless housing.

Liquid crystal (LCD) monitors 14 and 19 are designed to visually display all the information coming from operators ΑΡΜΟ to the local area network and vice versa.

The standard keyboard 15 and 20 is designed to be used as an input / output device for portable laptops.

Microphone headsets (MTG) 16 and 21, respectively connected to laptops 13 and 18 предназначены, are designed for auditory reception of telephone and telegraph signals from the radio channel. In this case, the interface device, which is part of the laptops, converts the signals from the MTG to the sound card and the USB port of the computer. As the MTG 16 and 21 can be used headset type GSH-29, providing work in moving objects with a noise level of up to 120 dB.

The navigation receiver 22 is a GPS / GLONASS navigation receiver. It is designed to receive and register data with the current coordinates of the location of the mobile hardware on the ground with displaying them on a computer screen and ensuring its binding to a single navigation system. The navigation receiver 22 receives data from the global GLONASS or GPS satellite system, which is intended for high-precision determination of the three position coordinates that make up the speed and time vector of various moving objects, to the built-in antenna.

The navigation receiver 22 comprises an antenna module and an electronic unit interconnected by high-frequency cables. As such a receiver, a GPSmap 267 s navigation receiver can be used.

The unit 23 of the formation of signals of a single time (SEV) is designed to receive marks of a single time (MEB) in NMEA 0183 format from an external source of the current time - a navigation receiver 22 of the GPS / GLONASS system, the formation of their own marks of a single time of 1 second, synchronized with the UTC (SU ), distributing MEB to consumers for synchronization, including portable laptops ΑΡΜΟ 13, 18 and units 7, 8, 26 of the hardware.

Interface converter 24 is intended for converting group stream interface signals to terminal equipment (OA) signals C1-TCH, C1-TG, C1-I and vice versa, their subsequent transmission via line input 36 and SL 37 to telephone and telegraph communication terminal equipment, installed in interacting hardware field communication nodes. Block 24 provides a physical implementation of the terminal equipment interfaces from a packet USB transmission medium when docked with a multiplexer of 25 E1 streams.

The primary multiplexer 25 is a multifunctional equipment used on the trunk lines, performing the functions of the multiplexer / demultiplexer of the terminal equipment C1-TCH, C1-TG and C1-I into the group channels of the USB interface. It provides signal transmission at a speed of 2048 kbit / s.

Multichannel radio transmitting device (RPDU) 26 is a multifunctional device that provides the formation of high-frequency signals in a wide range of frequencies (from 0.1 to 700 MHz) on four channels simultaneously, exchange data at the interface with external devices, receive audio signals for telephone modes work and control of external units of narrow-band filters. It contains (see FIG. 3) a terminal equipment interface unit 49, a control unit 50, a vector combiner unit 51 and four 52 (52 ₁ , 52 ₂ , 52 ₃ , 52 ₄ ) pathogen pathway modules.

Block 49 of the OA interfaces is designed to convert the channels of the interfaces C1-ТЧ, С1-ТГ, C1-И into the channels of the USB group stream and transfer them through the control unit 50 to the block 51 of vector combiners for further conversion.

The control unit 50 is designed to control all elements of the RPDU 26 directly and remotely via the Ethernet 100 Base-TX interface. Block 50 is based on a single-board computer, which facilitates the implementation of standard network protocols that provide communication via the Ethernet interface and organize interaction with the main nodes of the multi-channel RPDU 26 via the USB 2.0 interface.

Block 51 vector combiners contains a digital signal processor, read-only memory (ROM), random access memory (RAM), a USB controller, and a clock driver. Block 51 performs vector summation of signal samples, modulation of signals, signal generation and data exchange with control unit 50.

Each module 52 of the pathogen path includes a digital pathogen block, a signal selection and amplification block, and a frequency synthesizer block. In addition, each module generates and transfers the spectrum of the modulated radio signal in frequency to the KB range, as well as transfers the frequency signals to the VHF range using the RF signal from the output of the frequency synthesizer, filtering out-of-band emissions and additional amplification of the high-frequency signal. The digital exciter unit is designed to generate a high-frequency signal in a wide frequency range (from 0.1 to 220 MHz and from 220 to 700 MHz) from the incoming sample stream of the low-frequency signal from the output of block 51 vector combiners.

The signals received from the terminal equipment in block 49 are subjected to analog-to-digital conversion and primary digital processing, as a result of which streams of digital samples are obtained, which are switched in block 50 of the control and transmitted to block 51 vector combiners. Block 51 modulates the signals received in it, and also provides the functions of modems of various types.

Vector samples of modulated signals from the output of block 51 of vector combiners via the McBSP interface enter four modules of digital exciters 52. Each digital exciter performs digital-to-analog data conversion. The analogue high-frequency signal obtained in this way, depending on the operating mode, can be directly output to the unit or can be frequency-transferred to the VHF range and further processed in block 27 selective filters (SF). When the signal is transferred in frequency to the VHF range, the RF signal is used, which is supplied from the output of the frequency synthesizer block.

In block 27, out-of-band emissions are filtered and the signal is amplified, after which the analogue RF signals are fed through the antenna switch 5 to the transceiver antennas and radiated by them.

Broadband modem 28 is designed to convert the terminal equipment signals of the interfaces C1-ТЧ, С1-ТГ, C1-И into group stream signals (interface type of the main digital stream G.703) for transmitting them via the channels of the remote control line formed using radio relay station 29 between the mobile equipment of the HF-VHF radio communication and the separate radio-receiving equipment, to which the terminal equipment of telephone and telegraph communication is connected via the trunk.

Digital РРС 29 is intended for organizing a remote control line and transmitting digital information over it in the frequency range from 390 to 645 MHz with a throughput of the main stream of up to 10 Mbit / s.

As RRS 29 digital radio-relay radio station “MIK-RL400PR” (decimal number ZhNKYU.464429.034) can be used.

As the antenna 30 of the digital RRS can be used antenna type AR 390 I2UT12T, which is an antenna array containing two Ζ-shaped emitters.

The transportable VHF radio station 31 contains a microcomputer, a transceiver, a transceiver unit, a control unit, switching and pairing, a control panel and an external control panel. The operation of all the components of the radio station is controlled through the serial input / output line of the microcomputer, which receives commands from the operator through the radio station controls and issues all the necessary messages to the display elements located on the front panel. It is designed to enter the radio communication network and to conduct automated, searchless and un tuned radio communications in the operating frequency range from 30 to 108 MHz between ground and mobile objects in the parking lot and in motion. Using the radio station 31, radio communication is performed by accessing the radio network and exchanging voice and formalized messages.

As the antenna 32 for the VHF radio station 31 can be used transport wide-range antenna (TSDA). The TShDA antenna belongs to the pin type and consists of three rods interconnected by a threaded connection and a shock absorber. A bracket is rigidly attached to the antenna body, with which the TShDA antenna is mounted on the body of a moving object.

Wearable KB radio station 33 is a subscriber wearable radio station designed to transmit and receive radio signals in the frequency range from 1.5 to 30 MHz. It provides the accumulation and editing of telegraph (alphanumeric) information; input and storage of information directly or through a removable storage medium; inputting signal-code information from its own keyboard and automatically maintaining a communication session for receiving and transmitting information; storing the received information, outputting the received telegraph information to external devices, and signal-code information to its own indicator board.

As the antenna 34 for the KB radio station, pin antennas with a counterbalance and a tilted beam antenna with a counterweight can be used.

Block 35 switching channels and lines (CCL) is an automated cross-switch with a switching field Ν × Ν input-output (channel or communication line). Structurally, the block 35 is made in the form of a single monoblock, including the linear and station sides, each of which connects N lines with the possibility of increasing the capacity of the cross. The unit includes an electronic field, to which the connectors of the linear and station sides are connected. It is designed to cross-connect channels and communication lines in any combination. At the same time, it is possible to interconnect any N channels of the station side, interconnect any N channels of the linear side, as well as to interconnect the channels of the station side with the channels of the linear side.

Line input 36 contains connecting and switching elements (connectors, distribution combs and pins) to which connecting cables 37, high-speed digital subscriber line 38 and fiber-optic communication line 39 from external interacting hardware and stations are connected using cable connectors. It is intended for the distribution of information and control circuits to the apparatus and equipment of the mobile hardware HF-VHF radio communications. Structurally, the linear input 36 is made according to the same type in accordance with the industry standard for existing linear and cable entries for moving objects, the equipment of which is mounted in a box body on the chassis of a cross-country vehicle.

The connecting line 37 for receiving / issuing channels can be performed using a field distribution cable with a four-channel structure of the type P-269M-4 × 4 + 2 × 4.

High-speed PAL 38 can be performed using either a P-269M-2 × 2 cable or a two-wire field P-274M cable.

Fiber-optic communication line 39 is designed to deploy a backup remote control line (remote control line between the mobile HF-VHF radio communication equipment and individual radio receiving hardware) and can be performed using any type of field optical cable.

The switching and calling unit (BKV) 40 together with the first 41 and second 42 communication panels is designed to provide telephone and speakerphone communications on physical lines, two- and four-wire tonal frequency channels, four-wire digital channels formed by wired and radio relay communication channels, KB and VHF radios with transmission rates of 1200, 2400 bps and 16 kbps.

Block 40 is designed to send a selective call to correspondents in the service radio communication network, organized using VHF radio station 43 service communication with the antenna 44, telephone and speakerphone communication between subscribers. As block 40, a well-known block of the BKV-PS type, developed by the Sigma research and production company (Kaluga) and which is part of the existing intercom equipment, can be used.

The first 41 and second 42 communication desks are functionally complete terminal devices incorporating a standard telephone keypad, calling devices, handset and speakerphone (microphone with amplifier and loudspeaker). The mentioned communication desks are designed for telephone and speakerphone communication over two-wire physical circuits, two- and four-wire tonal frequency channels and digital channels, KB and VHF radio channels with transmission rates of 1200, 2400 bit / s and 16 kbit / s.

The VHF radio communication station 43 is a frequency-modulated transceiver radio station and is designed to provide radio communication between ground-based moving objects in the parking lot and in motion during the following types of work: telephone, auditory voice telegraph and digital signal-code communication.

As the VHF radio station 43, a VHF radio station of the R-168-5UT-2 type with a power of 8 W can be used. This radio station is a VHF transceiver station with frequency modulation. It is designed to enter the radio communication network and to conduct automated, searchless and un tuned radio communications in the operating frequency range from 30 to 108 MHz between ground and mobile objects in the parking lot and in motion. Using the radio station 43, radio communication is carried out by accessing the radio network and exchanging voice and formalized messages.

As the antenna 44 for VHF radio station 43 intercom can be used transport wide-range antenna (TSDA). The TShDA antenna belongs to the class of whip antennas and consists of three rods connected by a threaded connection, and a shock absorber. A bracket is rigidly attached to the antenna body, with the help of which the TShDA antenna is mounted on a box body of a moving object.

The main apparatus and equipment of the mobile apparatus KV-VHF radio communications are located in the K-5350D box body on the chassis of the KamA3-5350 all-terrain vehicle.

In the mobile hardware HF-VHF radio communication, several options for transmitting / receiving information and operating modes are provided:

1) as part of a transmitting radio center when using the equipment room as a transmitting station. In this case, information is transmitted and received from terminal equipment via a remote control line organized with the help of a RRS or fiber optic link between a mobile HF-VHF radio communication equipment and individual radio receiving equipment located at a receiving radio center and to which a telephone and telegraph communication terminal equipment is connected and data transmission;

2) as part of a separate group of direct means of radio communication. In this case, the transmission and reception of information is carried out using the terminal means of telephone communication and data transfer, located in the hardware communications or directly at the workplaces of officials.

In the first case, the path for receiving / transmitting information includes: transceiver antennas (1-4) that receive signals from the opposite side, antenna switch 5, UV unit 6, multi-channel radio receiver 7, Ethernet server switch 10 hardware 9, broadband modem 28, digital PPC channels 29 and a digital PPC antenna 30, which emits high-frequency signals on the air. On the opposite side of the remote control line, organized with the help of RRS, the signals are received by a similar RRS installed in the radio reception equipment, selects channels and transmits them via a connecting line to the terminal equipment of telephone and telegraph communication or data transmission.

The transmission of information from the terminal equipment (OA) of telephone and telegraphic communications is carried out along a path including: OA, a connecting line, a radio receiving equipment, channels of a remote control line organized with the help of PPC, which transmits received information to the air. On the opposite side of the remote control line, the signals are received by the digital PPC antenna 30, then the signals are processed in the PPC 29 and through the broadband modem 28, the Ethernet switch 10, the dedicated channels of the C1-TCh, C1-TG, C1-I interfaces are input to the radio transmitting device 26. In the radio transmitting the device 26 converts the signals of the telephone and telegraph communication channels of the C1-TCh, C1-TG, C1-I interfaces into analog high-frequency radio signals that are output from the RPDU 26 to the antenna switch 5 directly or via the SF unit 27. Antenna switch 5 performs switching of RF signals to transceiver antennas (1-4), which emit RF signals on the air and which are received by the antennas of the radio-receiving equipment at the opposite end of the automated radio line.

In the second case, the channel for transmitting / receiving information includes: OA, the signals from which through the SL 37 are received through line input 36, KKL block 35, the primary multiplexer 25, converter 24 interfaces, switch 10 Ethernet server 9 hardware, multi-channel RPDU 26, antenna switch 5 or block 27, antenna switch 5 and transceiver antennas (1-4), which emit RF signals on the air and which are transmitted via the air to the radio receivers of individual radio receivers or to the RPU 7 of a similar KV-VHF radio communication equipment giving information on the OA. When receiving information, the path includes: RF signals from ether are received by antennas (1-4), transmitted through antenna switch 5 and UV block 6 to the input of a multi-channel RPU 7, which converts analog RF signals to individual channels and which through Ethernet switch 10, converter 24 interfaces, primary multiplexer 25, KKL block 35, line input 36 are transmitted via SL 37 to the telephone and telegraph or data terminal equipment installed in the hardware communications or directly at the workplaces of officials, Those who receive and transmit information.

In each of these operating modes, the mobile HF-VHF radio communications equipment provides automatic and automated transmission of telephone, telegraph information and data transmission simultaneously through two independent channels in the KB and VHF frequency bands under conditions of radio interference of natural and artificial nature. This provides remote control (DU) in the parking lot on the radio (radio-relay) channel or on a fiber-optic communication line, organized between the mobile HF-VHF radio communication equipment and individual radio receiving equipment.

When working in a batch mode of data transfer by means of communication with the hardware, a protocol for guaranteed data delivery with error correction and retransmission is implemented using a personal computer with software that implements the transport and data link layer of the data transfer protocol.

The equipment room has a system for automatically establishing a connection and maintaining radio communications, which ensures the organization of adaptive radio links or radio networks. Adaptation is carried out according to the channel frequency, speed and type of modem. Adaptation is also possible in automatic mode when operating the built-in modems, or upon request from external terminal equipment (OA) for streaming channels.

Thus, in the proposed mobile hardware HF-VHF radio communications, the following functions are provided:

work in the range from 1.5 to 80 MHz (with the possibility of expanding the range up to 108 MHz) with the transmission of telephone, telegraph information and data with guaranteed delivery via educated radio channels;

selection of optimal frequencies from the selected ones, their distribution and use, their formation into frequency groups;

functions of the post of the ionospheric-wave frequency-dispatching service, including track sounding of the ionosphere, measuring the level of interference and signals at a selected frequency and calculating the signal-to-noise ratio for each of the communication frequencies;

selection of frequencies taking into account the long-term forecast stored in memory, as well as the results of path sounding of the ionosphere;

work in the radio network of each of the channels formed by means of radio communication with the number of correspondents at least 30 and radio direction as the main or subordinate station using noise-protected operation modes;

work in duplex, simplex, dual-frequency simplex and relay modes;

work in one of the noise protection modes - using the interference canceller, frequency hopping mode, adaptive modes, diversity reception, or with a combination of the above modes.

When operating in demand mode, the mobile hardware provides:

providing a radio channel for transmitting data and transmitting data to a specified correspondent in various modes of communicating information;

provision of telephone and telegraph radio channels to terminal equipment via interfaces C1-ТЧ, С1-ТГ, C1-И with reception / transmission of information with speeds of 1.2 and 2.4 kbit / s via KB radio channel and up to 64.0 kbit / s via VHF radio channel;

automatic connection establishment between the mobile equipment room and individual radio equipment rooms with remote control of the connection and communication process;

counter-work with the terminal equipment of telephone and telegraph communications, as well as with the terminal equipment of the data of the interacting hardware and stations;

the issuance, upon request, to the control room of the current state of the communication channels, the health of the equipment, and the occupancy of the channels during communication;

information transfer via 10 Ethernet switch to Ethernet network and to remote objects.

The control room provides for operational (with the participation of operators ΑΡΜΟ 12 and 17) automated control of conducting two-way radio communication sessions using portable laptops 13 and 18 of the first and second ΑΡΜΟ. The path of transmission of signals and commands for transmission includes: telephone or telegraph communication terminal equipment of interacting hardware communication, remote control line on PPC, antenna 30 digital PPC, radio relay station 29 mobile hardware, broadband modem 28, Ethernet switch 10, multi-channel RPDA 26 and block 27 SF, antenna switch 5 and further, the signals are transmitted on the air of one of the four (1-4) transceiver antennas. At the reception, the path includes: transceiver antennas (1-4), antenna switch 5, UV unit 6, multi-channel RPU 7, Ethernet switch 10, broadband modem 28, PPC 29 and digital PPC antenna 30, then the signals are broadcast on the line Remote control on the RRS, the RRS of a separate radio receiving equipment is received, channels are allocated and transmitted via trunk to the terminal equipment of telephone, telegraph communication and data transmission of the interacting hardware communication at the opposite end of the radio line.

Acoustic telegraph signals are received in the control room using MTG 16 or 21 of the first 12 or second 17 ΑΡΜΟ along the path, including: transceiver antennas (1-4), antenna switch 5, UV unit 6, multi-channel RPU 7, 10 Ethernet switch, portable laptops 13 or 18 of the first 12 or second 17 ΑΡΜΟ, to which MTG 16 and 21 are connected.

The technical effect of the proposed mobile hardware HF-VHF radio communication is to ensure transmission over radio channels formed by means of communication of hardware, information and data with increased reliability of delivery under the influence of various natural and artificial interference on the radio, achieved through a new set of features, including the use of multi-channel multi-path radio receiving and transmitting devices, providing the possibility of organizing simultaneously not how many independent directions and communication channels capable of functioning independently from each other in several directions in the KB and VHF frequency bands. This allows you to transmit / receive at each workplace simultaneously and independently from each other, information from several correspondents in one radio channel with different speeds, including on KB channels with a speed of 1200 and 2400 bit / s, and in the VHF channel - from 64 to 2048 kbit / s. At the same time, a fairly good communication quality is ensured: verbal intelligibility is not lower than class 2 according to GOST 20775 when transmitting voice messages and the probability of an element-by-element error is not lower than 5 × 10 ′ when transmitting digital information.

In addition, automation of the processes of establishing a connection and maintaining communication allows to increase the reliability of information transfer and reliability of communication, to exclude or reduce the participation of the operator in the processes of establishing and maintaining communication, which significantly reduces the subjective errors of the operator during their implementation, and increases the efficiency of establishing a connection and radio .

Information sources

1. Golovin O. V., Prostov S. P. Systems and devices for short-wave radio communication / Ed. professors O.V. Golovin. - M .: Hotline-Telecom, 2006.

Claims (3)

1. Mobile HF-VHF radio communication equipment, consisting of four transceiver antennas, an antenna switch, a narrow-band filter (UV) unit, a multi-channel radio receiver (RPU), an automatic communication unit (AUS), a hardware server, which includes an Ethernet switch and a personal electronic computer (PC), the first automated workstation for the operator (ΑΡΜΟ), which includes a portable laptop, a liquid crystal (LCD) monitor, a standard keyboard, and a micro-telephone headset (MTG), the second ΑΡΜΟ, which includes a portable laptop, an LCD monitor, a standard keyboard and MTG, a GPS / GLONASS navigation receiver with a built-in antenna, a single time signal conditioning unit (SEB), an interface converter, a primary multiplexer, a multi-channel radio transmitting device (RPDU) ), a selective filter unit (SF), a broadband modem, a digital radio relay station (RRS), a digital RRS antenna, a portable ultra-short-wave (VHF) radio station with an antenna, a portable short-wave (KB) radio station with antenna, channel and line switching unit (CCL), linear input, to the first, second and third line inputs and outputs of which are connected respectively a trunk (SL) for receiving / issuing channels, a high-speed digital subscriber line (DSC) and fiber-optic line communications (FOCL), switching and calling unit (BKV), two communication panels (PS), VHF radio stations for intercom and VHF radio stations, while high-frequency (HF) inputs and outputs of the first, second, third and fourth transceiver antennas are connected respectively about to the first, second, third and fourth high-frequency (HF) inputs-outputs of the linear side of the antenna switch, the first, second, third and fourth high-frequency inputs-outputs of the station side of which are connected respectively to the first, second, third and fourth inputs-outputs of the UV unit , the first, second, third and fourth RF outputs of which are connected respectively to the first, second, third and fourth high-frequency (RF) inputs of a multi-channel RPU, the first, second, third and fourth channel outputs of which ku RS-485 are connected respectively to the first, second, third and fourth inputs of the Ethernet switch of the server hardware, the first input-output of which at the RS-232 interface is connected to the input-output of the PC server of the hardware, the second input-output of the Ethernet switch at the Ethernet interface is connected to the input-output of the AUS unit, the first control output of which is connected to the control input of a multi-channel RPU, the third input-output of the Ethernet switch at the RS-232 interface is connected to the first input-output of the laptop первого the first ΑΡΜΟ, the second, third and fourth inputs and outputs to They are connected to the inputs and outputs of the LCD monitor, standard keyboard and MTG, respectively, the fourth input-output of the Ethernet switch at the RS-232 interface is connected to the first input-output of the second laptop портатив, the second, third and fourth inputs and outputs of which are connected to the inputs- the outputs, respectively, of the LCD monitor, standard keyboard and headset (MTG), the channel input-output of the GPS / GLONASS navigation receiver is connected to the information input-output of the SEV formation unit, whose control input-output is at the Eth interface ernet is connected to the fifth input-output of the Ethernet switch, the sixth and seventh inputs and outputs of which are connected via Ethernet to the first and second inputs and outputs of the interface converter, the third and fourth inputs and outputs of which are connected respectively to the first and second inputs and outputs of the primary multiplexer , the third and fourth inputs and outputs of which at the E1 interface are connected respectively to the first and second station inputs and outputs of the KKL unit, the first and second linear inputs and outputs of which are connected at the Ethernet 10Base-TX interface respectively, to the first and second station line inputs / outputs, the first, second and third line inputs and outputs of which are connected to the SL inputs and outputs for receiving / issuing channels, high-speed digital telephony and fiber optic links, the first, second, third and fourth outputs of the Ethernet switch Ethernet interface are connected respectively to the first, second, third and fourth inputs of the multi-channel RPDU, the control input of which is connected to the second control output of the ACS block, the first and second RF outputs of the multi-channel RPDU are connected respectively to the first and second RF inputs of the antenna switch, the third and fourth RF inputs of which are connected respectively to the first and second RF outputs of the SF unit, the first and second high-frequency inputs of which are connected respectively to the third and fourth RF outputs of a multi-channel RPDU, the eighth input-output of the Ethernet switch at the junction Ethernet is connected to the channel input-output of a broadband modem, the linear input-output of which at the junction E1 is connected to the channel input-output of a digital PPC, the high-frequency input-output of which is connected to a high the digital RRS antenna input-output antenna, the ninth Ethernet switch input-output at the Ethernet interface is connected to the channel input-output of a transportable VHF radio station, the high-frequency input-output of which is connected to a high-frequency antenna input-output of a portable VHF radio station, the tenth Ethernet switch input-output Ethernet interface is connected to the channel input-output of a portable KB radio station, the high-frequency input-output of which is connected to a high-frequency input-output antenna of a portable KB radio station, the eleventh input-output of an Ethernet switch at interface E thernet is connected to the third station input-output of the linear input, the third station input-output of the KKL unit is connected to the linear input-output of the switching and calling unit, the first and second station inputs and outputs of which are connected respectively to the linear inputs and outputs of the first and second communication panels, the channel inputs and outputs of the switching and calling unit are connected to the channel inputs and outputs of the VHF radio of the service station, the high-frequency input-output of which is connected to the high-frequency input-output of the antenna of the VHF radio of the service station th connection. 2. The mobile equipment room according to claim 1, characterized in that the multichannel RPU contains four receiving path modules, a vector combiner unit, a control unit and terminal equipment interface unit (OA), the inputs and outputs of the first, second, third and fourth receiving path modules McBSP are connected respectively to the first, second, third and fourth inputs and outputs of the vector combiner unit, the fifth input-output of which is connected via USB 2.0 to the first input-output of the control unit, the second input-output of which is connected via USB 2.0 to terminal with the input-output of the terminal equipment interface unit (OA), while the high-frequency (HF) inputs of the first, second, third, and fourth modules of the receiving path are the first, second, third, and fourth RF inputs of the multichannel RPU, the first, second, third, and the fourth channel outputs of which are, respectively, the first, second, third and fourth outputs of the OA interface unit, and the control input of the control unit is the control input of a multi-channel RPU connected to the control output of the automatic automatic communication. 3. The mobile equipment room according to claim 1, characterized in that the multichannel RPDU comprises a terminal equipment (OA) interface unit, a control unit, a vector combiner unit, and four pathogen path modules, the input / output of the OA interface unit connected to the first via USB 2.0 input-output of the control unit, the second input-output of which at the USB 2.0 interface is connected to the first input-output of the vector combiner unit, the second, third, fourth and fifth inputs and outputs of which at the McBSP interface are connected respectively to the input-output of the first, second, third o and the fourth module of the path of the pathogen, while the first, second, third and fourth inputs of the OA interface unit are respectively the first, second, third and fourth inputs of the multi-channel RPDU, the first, second, third and fourth high-frequency outputs of which are the outputs of the first, second, the third and fourth modules of the pathogen path, and the control input of the control unit is the control input of a multi-channel RPDU connected to the second control output of the automatic ide.

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