RU2715554C1 - Transported tropospheric station - Google Patents

Abstract

FIELD: radio engineering and communication.

SUBSTANCE: invention relates to tropospheric radio communication facilities and can be used to transmit information in tropospheric lines and communication systems. In transportable tropospheric station, comprising antenna, transceiver, modem, temporary sealing hardware, unit of reference generator and synchronization unit, additionally introduced are antenna control unit, modem control unit, station control panel, printing device, in-station transient device, navigation equipment, digital linear circuits interface equipment, service communication unit via digital channels, service communication panel via cable communication lines, a service link via a radio link, a unit for input and switching of lines, connecting lines (CL) for dispensing / receiving channels, CL for supply / reception of digital paths to consumers, device for communication on radio channel and radio communication station, and the transceiver comprises a superhigh frequency (SHF) channel unit, an input low-noise amplifier (LNA) of the lower range (LR), an input low-noise amplifier (LNA) of the upper range (UR), a unit for separating and adjusting the transmitter power and a transmitter.

EFFECT: technical result consists in improvement of throughput capacity of channels and communication channels, increase in range and quality of radio communication provided by station in conditions of action of various interferences.

1 cl, 1 dwg

Description

The invention relates to the field of radio engineering, namely to means of tropospheric radio communications and can be used to transmit information in tropospheric lines and communication systems in various departments and areas of the national economy.

Known tropospheric radio link for multipath channels using phase-shift keyed signals with multiple frequency diversity, containing on the transmitting side a phase manipulator, a transmitter, a clock isolator, a discrete delay element with feedback, serial frequency diversity signal generators, a trigger and electronic keys, at the receiving the side contains an input block, phase detectors, integrators, regenerators, electronic keys, a multiplier, narrow-band filters and a sync block timing [1].

However, the known radio link has a low noise immunity when communicating in conditions of significant interference.

The closest in technical essence to the present invention is the tropospheric communication station AN / TRC-105WX, developed by Motorola, the structural diagram and technical capabilities of which are shown in Fig. 2.5 on pages 66-69 [2]. This station contains an antenna, a transceiver consisting of a preselector, a high-frequency amplifier, a mixer, an intermediate-frequency amplifier, a reference local oscillator, a driver, a subcarrier amplifier, a converter, a power amplifier, and an antenna filter, a modem that includes a receiving part, a transmitting part, and equipment temporary seal, reference generator block and synchronization block.

The specified tropospheric station operates in the range of 4400-5000 MHz and provides communication over twelve telephone channels and one service channel over a distance of 148 km. The station uses a method based on the transmission of information using a complex of signals spaced in frequency and time.

The main disadvantages of the prototype station are the limited range of radio communications, insufficient quality of the provided communications and the inability to use the station in multi-channel radio links.

The aim of the invention is to increase the throughput of paths and communication channels, increasing the range and quality provided by the radio communication station under the influence of various interference.

This goal is achieved by the fact that in the transported tropospheric station containing an antenna, a transceiver, a modem, a temporary compaction equipment, a reference generator unit and a synchronization unit, an antenna control unit, a modem control unit, a station control panel, a printing device, an in-line transition device are additionally introduced, navigation equipment, digital linear path interface equipment, intercom unit for digital channels, intercom unit for cable communication lines, remote illicit communication over a radio line, a line input and switching unit, communication connecting lines (SL) for issuing / receiving channels, SL for issuing / receiving digital paths to consumers, a radio communication device and an intercom radio station, the transceiver comprising a microwave unit (UHF) the path, the low-noise input amplifier (LNA) of the lower range (ND), the low-noise input amplifier of the upper range (VD), the transmitter power separation and control unit and the transmitter, while the high-frequency antenna inputs and outputs s are connected to the high-frequency inputs and outputs of the microwave path unit, the first and second outputs of which are connected to the inputs of the input LNA ND and the input LNA VD, the output of the input LNA ND is connected to the first input of the modem, the second input of which is connected to the output of the input LNA VD, control input - the modem output is connected to the first control input-output of the modem control unit, the second and third control inputs and outputs of which are connected respectively to the first inputs and outputs of the reference generator unit and the synchronization unit, the second the move-output of which is connected to the synchronizing input-output of the reference generator unit, the information input-output of which is connected to the first input-output of the navigation equipment, the control input-output of the antenna is connected to the first input-output of the antenna control unit, the second input-output of which is at the junction RS-485 is connected to the first input-output of the in-plant transition device, the second input-output of which at the RS-485 interface is connected to the first input-output of the station control panel, the second input-output of which is connected via USB with the input-output of the printing device, the output of the modem is connected to the input of the separation and control unit of the transmitter power, the output of which is connected to the input of the transmitter, the output of which is connected to the input of the microwave unit, the input-output of the separation and control unit of the transmitter power is connected to the third input-output an in-plant transition device, the fourth input-output of which is connected to the second input-output of the navigation equipment, the modem inputs and outputs are connected to the first inputs and outputs of the temporary control equipment relays, the second inputs and outputs of which are connected to the first inputs and outputs of the digital linear paths interface equipment, the second inputs and outputs of which are connected to the first station inputs and outputs of the input and switching unit, the second station inputs and outputs of which are connected to the channel inputs and outputs of the equipment temporary compaction, the inputs and outputs of the digital channel of the intercom system of the digital linear paths interface equipment are connected to the inputs and outputs of the unit of the intercom system via digital channels, the inputs and outputs of the console with the cable communication lines are connected to the third station inputs and outputs of the line input and switching unit, the fourth station inputs and outputs of which are connected to the line inputs and outputs of the service communication panel via a radio line, the station inputs and outputs of which are connected to the inputs and outputs of the service communication channel modem, the first and second linear inputs and outputs of the input and switching unit of the lines are connected to the inputs and outputs, respectively, of the trunk for issuing / receiving channels and trunk for issuing / receiving digital paths to consumers, heels e station inputs and outputs of the input and switching unit of the lines are connected to the station inputs and outputs of the communication device over the radio channel, the channel inputs and outputs of which are connected to the channel inputs and outputs of the service communication radio station.

Comparative analysis with the prototype shows that the proposed transport tropospheric station differs from the prototype in the presence of new units: an antenna control unit, a modem control unit, a station control panel, a printing device, an in-station transition device, navigation equipment, digital line paths interfacing equipment, and an office communication unit for digital channels, a service communication console via cable lines, a radio communication service desk, line input and switching unit, trunk for issuing / receiving channels, trunk lines for issuing / receiving digital paths to consumers, a communication device over a radio channel and an intercom radio station, by performing a transceiver that includes a microwave unit, an input LNA of the lower range, an input LNA of the upper range, a separation and adjustment unit power of the transmitter and transmitter, as well as changing the connections between the known blocks.

Thus, the claimed transported tropospheric station meets the criteria of the invention of "novelty." Comparison of the proposed solution with other technical solutions shows that the equipment and units newly introduced into the proposed transportable tropospheric station are well known to specialists in this field of technology and additional creativity, given the explanations below, it is not required to reproduce them.

This solution is significantly different from the known solutions in the art. The claimed solution explicitly does not follow from the prior art and has an inventive step.

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

The claimed solution can be implemented using existing equipment, instruments and devices used in telecommunications, radio engineering and computer engineering, and is industrially applicable.

The drawing shows a structural electrical diagram of a transported tropospheric station, which indicates:

1 - station antenna;

2 - transceiver, including:

3 - block microwave (microwave) path,

4 - input low-noise amplifier (LNA) of the lower range (ND),

5 - input LNA upper range (VD),

6 - block separation and adjustment of the transmitter power,

7 - transmitter;

8 - modem;

9 - antenna control unit;

10 - modem control unit;

11 - block reference generator;

12 - block synchronization;

13 - station control panel;

14 - printing device;

15 - in-plant transition device (VPU);

16 - navigation equipment;

17 - temporary compaction equipment;

18 - equipment for pairing digital linear paths (CLT);

19 - service communication unit (BSS) via digital channels;

20 - service communication panel (PSS) via cable communication lines;

21 - remote control communications via radio;

22 - block input and switching lines;

23 - connecting lines (SL) for issuing / receiving channels;

24 - SL for issuing / receiving digital paths to consumers;

25 - a device for maintaining official communications over a radio channel;

26 - intercom radio.

The high-frequency inputs and outputs of the antenna 1 of the station are connected to the high-frequency inputs and outputs of the unit 3 of the microwave path of the transceiver 2, the first and second outputs of which are connected to the inputs of the input LNA 4 of the lower range and the input LNA 5 of the upper range, respectively. The output of the LNA ND 4 is connected to the first input of the modem 8, the second input of which is connected to the output of the LNA VD 5, the control input-output of the modem 8 is connected to the first control input-output of the modem control unit 10, the second and third control inputs and outputs of which are connected to the first inputs and outputs of the reference generator unit 11 and the synchronization unit 12, the second input-output of which is connected to the synchronizing input-output of the reference generator unit 11, the information input-output of which is connected to the first input-output of the navigation unit aratura 16. The control input-output of the antenna 1 of the station is connected to the first input-output of the antenna control unit 9, the second input-output of which at the RS-485 interface is connected to the first input-output of the in-plant transition device 15, the second input-output of which is at the RS interface -485 is connected to the first input-output of the station control panel 13, the second input-output of which is connected via USB to the input-output of the printing device 14. The output of the modem 8 is connected to the input of the separation and adjustment unit 6 of the transmitter, the output of which is connected to the input a transmitter house 7, the output of which is connected to the input of the microwave unit 3 of the transceiver 2 path. The input-output of the transmitter power separation and adjustment unit 6 is connected to the third input-output of the in-house transition device 15, the fourth input-output of which is connected to the second input-output of the navigation equipment 16.

The inputs and outputs of the modem 8 are connected to the first inputs and outputs of the temporary compaction equipment 17, the second inputs and outputs of which are connected to the first inputs and outputs of the digital linear paths interface equipment 18, the second inputs and outputs of which are connected to the first station inputs and outputs of the input unit 22 and line switching, the second station inputs and outputs of which are connected to the channel inputs and outputs of the temporary compression equipment 17, the inputs and outputs of the digital communication channel of the communication equipment 18 of digital linear paths interfacing with are connected to the inputs and outputs of the intercom unit 19 via digital channels, the inputs and outputs of the intercom panel 20 via cable lines are connected to the third station inputs and outputs of the line input and switching unit 22, the fourth station inputs and outputs of which are connected to the linear inputs and outputs remote control 21 intercom via a radio line, the station inputs and outputs of which are connected to the inputs and outputs of the communication channel of the modem 8.

The first and second linear inputs and outputs of the line input and switching unit 22 are connected to the input and outputs of the connecting lines 23 for issuing / receiving channels and SL 24 for issuing / receiving digital paths to consumers. The fifth station inputs and outputs of the line input and switching unit 22 are connected to the station inputs and outputs of the radio communication device 25, the channel inputs and outputs of which are connected to the channel inputs and outputs of the intercom radio 26.

Antenna 1 of the station is designed for radiation, reception and amplification of electromagnetic field energy in the operating frequency range. Antenna 1 of the station is a two-mirror modified Cassegrain antenna with a paraboloid diameter of 2500 mm and a shape factor of 0.3. The irradiating system of the antenna 1 of the waveguide type provides reception and transmission of microwave energy of linear polarization. The structural implementation of the antenna suggests the possibility of changing the polarization.

The antenna 1 is controlled by the antenna control unit 9.

The antenna control unit 9 includes converter boards, power amplifier control boards, and a controller.

The antenna control is carried out remotely from the station control panel 13 through block 9, as well as manually directly from the panel of the antenna control unit 9.

Block 3 of the microwave path of the transceiver 2 is a waveguide feeder system designed to operate as part of a tropospheric station. It provides the passage and selection of reception and transmission signals in the ranges from 4400 to 4630 MHz (lower range) and from 4770 to 5000 MHz (upper range). The unit 3 of the microwave path includes duplexers, bandpass filters and switches.

The operation of unit 3 of the microwave path of the transceiver 2 is as follows. If the transmission is in the lower range (ND), then reception is carried out in the upper range (VD). The signal of the transmitter 7, passing through the high-speed remote switches, band-pass filters and duplexer gets to the input of the antenna 1 station.

The signal received by the antenna 1, having passed the duplexer, band-pass filters and a high-speed remote switch of the microwave unit 3, gets to the inputs of the LNA ND 4 and LNA VD 5.

The low-noise input amplifiers of the lower 4 and upper 5 ranges are designed to amplify the signals from the output of unit 3 of the microwave path of the transceiver 2. The low-pass filter included in the input LNA transmits the entire band of the received frequencies and protects the LNA input from the harmonic power of the station transmitter.

Block 6 separation and adjustment of the transmitter power is designed to separate the exciter signal into two channels, stabilize and adjust the power of the exciter signals received at the inputs of the transmitter 7. The block includes a control module, a microwave amplifier, adjustable attenuators and a voltage converter.

The transmitter 7 is a power amplifier made on a traveling wave lamp with secondary power sources and a cooling system. It is designed to enhance the power of the microwave signal to the level necessary for organizing tropospheric communication at given communication ranges.

The control of the transmitter 7 is carried out remotely from the control panel 13 of the station control unit 6 separation and power control. Control actions from the remote control 13 to the unit 6 is carried out via the CAN interface. Direct control of the transmitter 7 from block 6 is carried out by the wire-command method. This provides control and indication of parameters on the display of the remote control 13 station control.

Modem 8 is designed to modulate the carrier frequency of the station with digital streams and their demodulation, as well as to amplify, convert and process the received and transmitted signals by the tropospheric station. They provide the station with information speeds of 50 bit / s and from 2.4 to 2048 kbit / s with adaptation, coding, interleaving in the 50 MHz frequency band, designed to create frequency-diversity reception, slow pseudorandom tuning of operating frequencies to combat interference damage.

Modem 8 includes the following components:

a block of an amplifier-converter of microwave signals into a first intermediate frequency of 1040 MHz;

a unit of a two-channel device for convolution and conversion into a second intermediate frequency of 62.5 MHz;

block of a four-channel narrowband receiver-demodulator;

block asynchronous pairing, coding-decoding, interleaving-deinterleaving;

block of a two-channel frequency modulator 1040 MHz;

the block of the pathogen intended for the formation and transfer to the frequency range of the transmission signals of the modulator.

The modem control unit 10 is designed to implement various operating modes of the troposphere station.

Block 11 of the reference generator is designed to form a reference frequency of 100 MHz with automatic frequency correction from a highly stable signal source with a frequency of 10 MHz coming from navigation equipment 16.

Block 12 synchronization is designed to generate signals of a pseudo-random sequence (PSP), the second second pulse, the pulse of the beginning of the adjustment and control signals.

The station control panel 13 is a control electronic computer and contains a computer made in the form of an IBM compatible computer with a ruggedized design, small overall dimensions, an expanded set of input-output functions, a high-performance video subsystem and advanced controls, a drive, a CAN controller and a cartridge (flash memory), which is a removable storage medium.

From the remote control station 13 control and control of all units of the station. At the same time, the station blocks are controlled via the CAN interface and RS-485 interface using the KUI protocol. The CAN interface also controls the antenna 1 through an in-line adapter 15. The station control panel 13 displays the current status of the equipment and station blocks.

The printing device 14 is designed to print data monitoring the status of equipment and units of the station. As the printing device 14, a documenting device of the type UD-M312D is used.

The in-station transition device 15 is intended for switching control and power circuits between the station control panel 13 and the units, equipment, and station printing device. The adapter 15 is a monoblock with connecting elements, with the help of which the equipment and units of the station are connected. Rigid circuit switching is implemented inside the monoblock.

Navigation equipment 16 relates to the satellite navigation system GLONASS and GPS-NAVSTAR. It is designed to determine the geographical coordinates of the station (latitude and longitude), the height of the station above the conventional surface of the earth, the speed of movement of the station, the exact time to synchronize the frequency of the reference generator, true azimuth, roll angle and pitch angle (trim) of the station's equipment container.

Management of navigation equipment 16 is carried out from the remote control station 13 at the junction of RS-485. Navigation equipment 16 includes an antenna module, which is located on the upper edge of the reflector of the antenna 1 and receives signals from navigation satellites. As part of the navigation equipment 16 there is also a remote control of the equipment 16. The display of the control panel of the equipment 16 displays the navigation parameters of the car, including the current coordinates, speed, track angle and current time.

As the equipment 17 temporary compaction, the equipment of compaction type I331 is used, designed to operate in one direction of communication with providing a one-stage temporary compaction and decompression of tropospheric radio links with transmission rates of group signals 4.8; 9.6; 48; 64; 128; 256; 512; 1,024; 2048 kbit / s. This equipment provides the formation of up to thirty analogue tone frequency channels (TCH) and their conversion into digital channels with a different interface: TCH joint, E1 joint, main digital channel (BCC) and HDB3 group stream. At the same time, the PM channels received by the consumer from the consumer during the transmission are converted by the equipment into an information group digital stream, which from the equipment output goes to the modem 8 and then to the microwave unit 3 for transmission to the correspondent.

Reception, decompression and conversion of digital channels into PM channels occurs in the opposite direction to that described above. The information group stream received and received from the modem is decompressed by the apparatus 17 into channel streams, which from the output of the apparatus 17 through the digital line path pairing apparatus 18, the line input and switching unit 22 and the corresponding trunk lines (23 and 24) are sent to the channel and path consumers.

In the station, it is possible to transmit (receive) a digital stream with a certain transmission rate from the input and switching line unit 22 in transit through the time compression equipment 17 to the modem 8. The received digital stream from the modem 8 enters in transit through the equipment 17 to the line input and switching unit 22 and further on trunk to consumers of channels and digital paths. In addition, in the station there is the possibility of transmitting (receiving) a group information digital stream coming from the consumer via SL 24 through the line input and switching unit 22, equipment 18 for pairing digital linear paths and then to modem 8.

The service communication unit 19 is designed to provide service communication with channel consumers via separate service channels formed by the apparatus 18 for interfacing digital linear paths with a transmission speed of 16.0 kbit / s via a cable communication line.

The service communication console 20 is designed to provide service communication over cable communication lines with receiving and transmitting an inductor call or an alternating current call with a frequency of 50 Hz. At the same time, communication with the remote control 20 is carried out in telephone mode, for which it includes a handset and a speakerphone (microphone and receiving amplifier with a loudspeaker).

The remote control 20 communication can work on each of the channels in three modes:

1) in the PBX mode, when the channel is connected to an automatic telephone exchange;

2) in the Central Bank mode (central battery) with making and receiving a call with direct current;

3) in MB mode (local battery) with sending and receiving an inductor call.

The operating modes of the channels of the remote control 20 are set by programming them before starting work. At the same time, it is possible to connect a speakerphone (GGS) to the channel instead of the handset.

The radio communications office remote control 21 is designed to provide telephone vocoder communications through the digital communications channels of a radio link with an information rate of 1200 bps and formalized communications through telegraphic communications channels of a radio link with an information rate of 50 bits / s. At the same time, remote control 21 provides a selective (selective) call to any radio station and a circular call to all radio stations.

The remote control 21 intercom includes three independent and mutually switched communication directions, each of which provides the reception and transmission of a digital vocoder channel at a speed of 1200 bit / s, three speech-converting devices (vocoders), switches for digital vocoder channels and telegraph channels, shapers and receivers of selective and circular call commands, as well as formalized official communication commands via telegraph channels. In this case, the digital vocoder channel has an interface C1-FL-BI, formed by a symmetrical two-wire circuit in each direction of transmission.

Block 22 input and switching lines is designed to connect connecting lines and cable communication lines through which channels and communication paths from consumers are transmitted and received to the connecting elements of the block, the distribution of information and control circuits to the plant equipment and equipment. On the switching field of block 22 there are switching sockets. At the same time, the switching of channel sockets on the switching field of block 22 is carried out using eight-pin plug-in jumpers (main switching). Fully accessible switching of any channel coming from the consumer via the trunk to the input of block 22, to any of the channels of the temporary compression equipment, is carried out using four-wire switching cords.

The group signals of the digital paths from the output of the equipment 17 temporary consolidation are fed directly to the output connecting elements of the block 22 and then transmitted to the consumers via the trunk.

Connecting lines 23 for issuing / receiving channels can be performed using a field telephone distribution cable with a quadruple structure of type P-269M.

SL 24 for issuing digital paths can be performed using a field communication cable of the P-296 type.

The radio communication device 25 is an intercom and ringing device including a handset and ringing devices. It is intended for communication on the channel of the radio 26 intercom. At the same time, a call is made and received on the channel, telephone and speakerphone communication with the correspondent of the radio communication network.

Radio station 26 with its antenna is designed to provide the operator with access to the troposphere station in the public communication network and communication with remote subscribers, to conduct official telephone radio communications with interacting objects when working in the field. As the radio station 26 can be used radio stations of the type R-168-5UT-2 or R-168-5V, which are transceiver stations with frequency modulation.

The transported tropospheric station provides duplex multichannel communication without searching and tuning at any frequency of the operating range from 4400 to 5000 MHz. At the same time, the station’s frequency range is divided into two ranges: the lower range (ND) - from 4400 to 4630 MHz, the upper range (VD) - from 4770 to 5000 MHz, and if radiation (transmission) is in the upper frequency range, then reception is in the lower range. For the corresponding tropospheric station, transmission and reception are performed in the opposite way: reception in the lower range, and transmission in the upper range.

Changing the ranges of radiation and reception is carried out promptly from the control panel 13 of the station.

The transported tropospheric station provides transmission and reception of:

group digital information stream with a speed of 64 (48); 256 (240) kbit / s, depending on the selected station operating mode, intercom channel, and machine-to-machine control (IMO) control channel;

group digital information stream with a speed of 256 (240); 512 (480); 2048 kbit / s, depending on the selected station operating mode, intercom channel, and MMO control channel.

At information speeds from 64 (48) to 2048 kbit / s, the tropospheric station provides from 1 to 30 analogue tone-frequency channels.

At the same time, the station provides communication without manually searching for a correspondent signal by frequency and without manually adjusting the operating frequencies in the process of communicating with simultaneous reception and transmission at given frequencies.

The station control system using the control panel 13 and control units 9 and 10 provides:

1) turning on and off the station equipment with an indication of the performance of these operations;

2) setting station operating modes, ranges and frequencies of transmission and reception;

3) adjustment of radiation power from minimum to maximum values;

4) indication of the transmitted and received signals;

5) the organization of the station’s self-test mode;

6) manual control of antennas in azimuth and elevation;

7) automatic search for a correspondent in azimuth and elevation;

8) an indication of the actual position of the antennas in azimuth and elevation;

9) blocking the rotation of the antenna of the station in azimuth and elevation in extreme angular positions;

10) periodic survey of the state of the equipment with an indication of the results of the survey;

11) interfacing with navigation equipment to solve the problems of correcting the frequency of the reference generator, the clock, determining the coordinates of the station and corrections of its installation, using the data obtained when deploying the station and finding directions to correspondents;

12) interfacing with the channels of inter-machine exchange (IMO) with interacting hardware and stations.

The troposphere station can be controlled remotely via MMO channels. For this purpose, there are two MMO channels, one of which is used in the organized tropospheric communication direction, and one MMO channel is output to the communication node via in-station transition device 15 and line input and switching unit 33. MMO channels between the station control panel and the modem of the interacting stations are formed at the RS-232C interface.

In the transported tropospheric station, it is possible to automatically search for the correspondent signal by the antenna in azimuth and to automatically adjust the antenna to the maximum signal of the correspondent in azimuth and elevation. In addition, it is possible to install the antenna in a direction specified by the correspondent (in azimuth and elevation) using information from navigation equipment 16.

The construction of the station is based on the principle of receiving signals in the microwave range, arriving at the reception point not in a straight line (within the line of sight, which is typical for communication at such frequencies), but from a correspondent located beyond the horizon. Radio communication using the long-range propagation of microwave due to scattering by inhomogeneities of the troposphere is called tropospheric or radio communication of tropospheric scattering.

The transported tropospheric station provides the deployment of single-interval tropospheric communication lines with a maximum length of up to 230 km, depending on the operating mode of the station and multi-interval tropospheric communication lines with a length of up to 1000 km.

To provide communication in two directions, the station has two antennas and two sets of transceiver equipment that operate independently and provide independent reception and transmission of two streams of information, while the frequency diversity of the transmitted and received signals is carried out using the FWM method. One set of equipment and station equipment works in one direction of communication, the second - in another direction of communication.

In the transmission mode with a speed of 2048 kbit / s, in order to increase the energy potential of the radio link, spatial diversity of transmitted and received signals is additionally carried out, in which both antennas and both sets of equipment work in the same communication direction, transmitting information to only one correspondent. In the station, spatial signal diversity is also provided for operation at speeds of 256 (240) and 512 (480) kbit / s.

Receiving path

The signal received by the antenna from the correspondent in the frequency range from 4400 to 4630 MHz or from 4770 to 5000 MHz, depending on the selected operating range, lower or upper, respectively, is input to the microwave unit 3. The polarization of the signals received and transmitted by the antenna is linear horizontal. Constructive implementation provides non-operational (by replacing the waveguide insert) polarization change to linear vertical.

In block 3 of the microwave path, the signal passes through a duplexer and an input bandpass filter tuned to the frequency band of the received signal in the lower or upper range. The microwave path is designed to separate the frequency of the received and transmitted signals by a single antenna. The isolation between the transmission and reception path is software dB. If the signal is received in the lower range, then the transmission is in the upper range and vice versa. This is due to the functional construction and construction of the microwave path. Changing the transmission and reception range is carried out quickly from the control panel of the station. Next, the received signal is fed to the input low-noise device of the lower range or LNA of the upper range, depending on the selected range.

In the transported tropospheric station, official communication is provided with the interacting stations in pairs of field distribution cable, through which the connecting lines 23 are deployed, using the service communication console 20, and when working on the trunk 24, service communication is provided using the equipment 17, 18 and service service unit 19 communication via digital channels.

The technical effect of the present invention is to increase the throughput of paths and communication channels, increase the range and quality provided by the radio communication station under the influence of various interference, achieved due to the presence of the specified equipment and equipment in the station, which provides increased throughput of the paths up to 2048 kbit / s, the communication range is up to 230 km (versus 148 km in the prototype), and it also provides the possibility of organizing both single-interval communication lines, and many ntervalnyh tropospheric communication lines. At the same time, the required quality of radio communication is ensured under the influence of various interference due to the use of adaptation, noise-resistant coding and interleaving of signals, as well as the use of the principle of noise protection by the method of pseudo-random tuning of operating frequencies and the implementation of the principle of modulation of the carrier frequency by digital streams using a two-channel frequency modulator and demodulator. Testing Specimen Preparation tropospheric stations showed that in the worst of weather conditions in the month of the year odnointervalnoy line the probability of erroneous reception P _osh was not worse 1⋅10 ^-4 corners with zero closing the horizon.

The advantage of the proposed tropospheric station is also that it uses technical analyzers of communication lines that determine their suitability for transmitting various types of information, automatic selectors for selecting and using the best communication channel, automatic calling devices to identify the correspondent and establish communication are introduced.

Sources of information.

1. SU, copyright certificate No. 510790, IPC Н04В 7/22, H04L 27/18,

1976.

2. Tropospheric communication / L.I. Yakovlev, G.V. Dedyukin, E.S. Kagramanov et al. - M.: Military Publishing House, 1984, p. 66-69 (prototype).

Claims (1)

A transported tropospheric station containing an antenna, a transceiver, a modem, temporary compaction equipment, a reference generator unit and a synchronization unit, characterized in that it further includes an antenna control unit, a modem control unit, a station control panel, a printing device, an in-line transition device, navigation equipment, equipment for interfacing digital linear paths, intercom unit for digital channels, intercom unit for cable communication lines, intercom unit and on a radio line, an input and switching unit for lines, trunk lines for issuing / receiving channels, a trunk for issuing / receiving digital paths to consumers, a radio communication device and a service radio station, the transceiver comprising a microwave unit, input low-noise amplifier (LNA) of the lower range (LN), input low-noise amplifier (LNA) of the upper range (VD), the transmitter power separation and control unit and the transmitter, while the high-frequency antenna inputs and outputs are connected to high-frequency inputs and outputs of the microwave path unit, the first and second outputs of which are connected to the inputs of the input LNA ND and input LNA VD, respectively, the output of the input LNA ND is connected to the first input of the modem, the second input of which is connected to the output of the input LNA VD, the control input-output of the modem connected to the first control input-output of the modem control unit, the second and third control inputs and outputs of which are connected respectively to the first inputs and outputs of the reference generator unit and the synchronization unit, the second input-output of which connected to the synchronizing input-output of the reference generator unit, the information input-output of which is connected to the first input-output of the navigation equipment, the control input-output of the antenna is connected to the first input-output of the antenna control unit, the second input-output of which is at the RS-485 interface connected to the first input-output of the in-plant transition device, the second input-output of which at the RS-485 interface is connected to the first input-output of the station control panel, the second input-output of which is connected to the input-output via a USB interface m of the printing device, the modem output is connected to the input of the transmitter power separation and adjustment unit, the output of which is connected to the transmitter input, the output of which is connected to the microwave path unit input, the input-output of the transmitter power separation and adjustment unit is connected to the third input-output of the in-line transition device the fourth input-output of which is connected to the second input-output of the navigation equipment, the modem inputs and outputs are connected to the first inputs and outputs of the temporary compression equipment, second its inputs and outputs are connected to the first inputs and outputs of the digital linear paths interface equipment, the second inputs and outputs of which are connected to the first station inputs and outputs of the line input and switching unit, the second station inputs and outputs of which are connected to the channel inputs and outputs of the temporary compression equipment , inputs and outputs of a digital channel for intercom of digital linear paths interface equipment are connected to inputs and outputs of an intercom unit via digital channels, inputs and outputs of an intercom console via cable communication lines connected to the third station inputs and outputs of the input and switching unit of the lines, the fourth station inputs and outputs of which are connected to the linear inputs and outputs of the service communication console via a radio line, the station inputs and outputs of which are connected to the inputs and outputs of the modem service communication channel, the first and second line inputs and outputs of the input and switching unit of the lines are connected to the inputs and outputs respectively of the trunk for issuing / receiving channels and trunk for issuing / receiving digital paths to consumers, the fifth station moves outputs the input block and switching lines connected with station input-output device conducting communication on the radio channel, the channel inputs and outputs of which are connected to the channel inputs-outputs intercom station.

Images