RU2660800C1 - Portable satellite communication station - Google Patents

Abstract

FIELD: satellite communication technology.

SUBSTANCE: invention relates to satellite communication facilities and can be used to organize satellite communications radio links when operating via spacecraft repeater trunks located in a geostationary orbit in the 4/6 GHz band. For this purpose, a band pass filter is additionally introduced into the portable satellite communication station, band pass filter, very high frequency (VHF) unit, broadband signal processing unit (BSP), external interface unit, station control panel, headset, communication line for receiving / transmitting signals at the C1-FL-BI joint, Ethernet line, communication line for receiving / transmitting signals over the RS-232 interface and connecting line (CL) from the ATS station, in order to reduce the mass-dimensions of the station and improve its operational and technical characteristics, the antenna-feeder device, band pass filters for receiving and transmitting, low-noise amplifier and power amplifier are functionally and structurally integrated into the antenna module, a high frequency integrated unit, a block of amplifiers-transmitters for receiving and transmitting, a modulator-demodulator unit, a channel-forming equipment and a processing unit for broadband signals.

EFFECT: technical result consists in the creation of a portable satellite communication station operating in multiple-access networks with a code and frequency-code division of channels, that provides the expansion of the functionality for organizing a radio network.

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Description

The invention relates to satellite communications and can be used to organize satellite radio links when operating through the trunks of repeaters of spacecraft (SC) located in the geostationary orbit, in the range of 4/6 GHz.

Satellite communications stations are increasingly used to provide communications directly from the workplaces of officials located in mobile facilities or from remote workplaces. For this purpose, small-sized personal wearable satellite communication stations are used.

A known satellite communication subscriber station according to the RF patent for invention No. 2293442, which includes an antenna system, a device for separating transmission and reception paths, a transceiver, channelization equipment, a control unit for operating modes of elements of a satellite communication subscriber station and an antenna system guidance system [1 - RU Patent No. 2293442, Bull. No. 4 dated 02/10/2007].

The known station employs a multiple access system with frequency division multiplexing, which requires the allocation of a significant frequency resource, and this system and, accordingly, a station built according to this principle, has low noise immunity. The equipment of such a station is relatively cumbersome and its use as a personal station is limited for these reasons.

Of the known satellite communication subscriber stations, the closest in technical essence is the subscriber station, a structural diagram of which is given in [2, Fig. 15.1, p. 419].

A well-known satellite communications subscriber station (Fig. 15.1, p. 419) contains an antenna system, an antenna pointing system, a duplexer, a low-noise amplifier, a block of transmit-receive frequency converters, a modulator-demodulator block, a power amplifier, channel-forming equipment, and a control processor.

The main disadvantage of the known station is the bulkiness of its equipment, especially the antenna system and the antenna pointing system. This leads to a limitation of its use in modern systems of personal satellite communications.

The aim of the present invention is the creation of a portable satellite communications station operating in multiple access networks with code and frequency-code division multiplexing, providing enhanced functionality for organizing a communication network and having low overall dimensions by combining a number of station equipment into separate structural modules.

This goal is achieved by the fact that in a portable satellite communications station containing an antenna system, an antenna guidance system, a low-noise amplifier, a block of amplifiers-converters of the frequency of reception and transmission, a modulator-demodulator block, a power amplifier and channel-forming equipment, an additional band-pass reception filter, a band-pass transmission filter, microwave (UHF) unit, broadband signal processing unit (SHPS), external interface unit, station control panel, headset headset, communication line for receiving / transmitting signals at the interface C1-FL-BI, an Ethernet line, a communication line for receiving / transmitting signals at the interface RS-232 and a connecting line (SL) from the PBX station, while the output of the antenna-feeder device is connected to the input of the bandpass filter reception, the output of which is connected to the input of a low-noise amplifier, the output of which is connected to the first input of the microwave unit, the first output of which is connected to the input of the power amplifier, the output of which is connected to the input of the bandpass transmission filter, the output of which is connected to the input of the antenna-feeder device, W The second output of the microwave unit is connected to the first input of the block of amplifiers-frequency converters (OCH) of reception and transmission, the first output of which is connected to the second input of the microwave unit, the third output of which is connected to the first input of the modulator-demodulator block, the first output of which is connected to the third input of the block Microwave, the second output of the block of the modulator-demodulator is connected to the second input of the block of the receive and receive converter, the second output of which is connected to the second input of the block of the modulator-demodulator, the input of the channel-forming equipment is connected to the third output the ode of the modulator-demodulator unit, the third input of which is connected to the output of the channel-forming equipment, the information input-output of which is connected to the information input-output of the external interface unit, the control input-output of which is connected to the control input-output of the channel-forming equipment, the control input-output of which is connected with a control input-output of the microwave unit, the first information input-output of which is connected to the first information input-output of the broadband signal processing unit, the second information the input-output of which is connected to the second information input-output of an external interface unit, the second control input-output of which is connected to the control input-output of the broadband signal processing unit, the control input-output of the station control panel is connected via Ethernet to the third control input-output an external interface unit, the third information input-output of which is connected to the information input-output of the headset headset, the second information input-output of the microwave unit is connected to the information by the way-output of the on-board beacon receiver, which plays the role of the station’s antenna pointing system, the fourth, fifth, sixth and seventh information inputs and outputs of the external interface unit are connected to the inputs and outputs of the communication line for receiving / transmitting signals at the junction C1-FL-BI, lines Ethernet, communication lines for receiving / transmitting signals at the RS-232 interface and trunk line (SL) from the PBX station, while reducing the overall dimensions of the station and improving its operational and technical characteristics antenna-feeder devices , bandpass transmit and receive filters, a low-noise amplifier and a power amplifier are functionally and constructively integrated into an antenna module, and a microwave module, a block of transmit and receive amplifiers-converters, a modulator-demodulator block, channel-forming equipment, and a broadband processing unit are functionally and structurally combined into a hardware module signals.

A comparable analysis with the prototype shows that the invention is characterized by the presence of new units: bandpass filters for receiving and transmitting, a microwave unit, a processing unit for broadband signals, an external interface unit, a station control panel, a headset, a communication line for receiving / transmitting signals at the C1- FL-BI, Ethernet lines, communication lines for receiving / transmitting signals at the RS-232 interface and trunk line (SL) from the PBX station, as well as changing communications between known station blocks.

Thus, the claimed portable satellite communications station meets the criteria of the invention of "novelty." Comparison of the proposed solution with other technical solutions shows that the introduced blocks are widely known and additional creativity for their implementation is not required. However, when they are introduced in this connection with the remaining elements of the circuit into the claimed satellite communication station, the above blocks exhibit new properties, which leads to the achievement of the goal, namely, the creation of a portable satellite communication station operating in multi-station access networks with code and frequency-code separation of channels, providing enhanced functionality for the organization of a radio communication network and having low overall dimensions by combining a number of station equipment in the department lnny constructive modules.

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

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

The inventive portable satellite communications station can be implemented using existing apparatus and equipment, telecommunications and computer technology and is industrially applicable.

The drawing shows a structural diagram of a portable satellite communications station.

A portable satellite communications station comprises an antenna-feeder device 1, a reception bandpass filter 2, a low-noise amplifier 3, a power amplifier 4 and a transmission bandpass filter 5, which are functionally and structurally integrated into an antenna module; a microwave unit 6, a unit 7 of transmitting and transmitting amplifier (UHF), a transmitting and receiving apparatus 8, a channelization apparatus 9, and a broadband signal processing unit (WPS) 10, which are functionally and structurally integrated into a hardware module (AM); external interface unit 11, station control panel 12, on-board beacon receiver 13, headset 14, communication line 15 for receiving / transmitting signals at the C1-FL-BI interface, Ethernet line 16, communication line 17 for receiving / transmitting signals at the RS interface -232 and trunk line (SL) 18 from the PBX station.

The output of the antenna-feeder device 1 is connected to the input of the reception bandpass filter 2, the output of which is connected to the input of a low-noise amplifier 3, the output of which is connected to the first input of the microwave unit 6, the first output of which is connected to the input of the power amplifier 4, the output of which is connected to the input of the bandpass filter 5 of the transmission, the output of which is connected to the input of the antenna-feeder device 1, the second output of the microwave unit 6 is connected to the first input of the block 7 of the receiving and transmitting frequency amplifier (converter), the first output of which is connected to the W the input of the microwave unit 6, the third output of which is connected to the first input of the modulator-demodulator unit 8, the first output of which is connected to the third input of the microwave unit 6, the second output of the modulator-demodulator unit 8 is connected to the second input of the transmit and receive amplifier unit 7, the second output which is connected to the second input of block 8 of the modulator-demodulator. The input of the channel-forming equipment 9 is connected to the third output of the modulator-demodulator unit 8, the third input of which is connected to the output of the channel-forming equipment 9, the information input-output of which is connected to the information input-output of the external interface unit 11, the control input-output of which is connected to the control input the output of the channel-forming equipment 9, the control input-output of which is connected to the control input-output of the microwave unit 6, the first information input-output of which is connected to the first information input-output the unit of the broadband signal processing unit 10, the second information input-output of which is connected to the second information input-output of the external interface unit 11, the second control input-output of which is connected to the control input-output of the broadband signal processing unit 10, the control input-output of the control panel 12 at the Ethernet interface, it is connected to the third control input-output of the external interface unit 11, the third information input-output of which is connected to the information input-output of the headset 14. The second information input-output of the microwave unit 6 is connected to the information input-output of the receiver 13 of the on-board beacon, which acts as the antenna guidance system of the station, the fourth, fifth, sixth and seventh information inputs and outputs of the external interface unit 11 are connected to the inputs and outputs of the line 15 communications for receiving / transmitting signals at the interface of C1-FL-BI, Ethernet line 16, communication lines 17 for receiving / transmitting signals at the interface of RS-232 and trunk line (SL) 18 from the PBX station. At the same time, to reduce the overall dimensions and improve the operational and technical characteristics of the station, the antenna-feeder device 1, bandpass filters for receiving 2 and transmission 5, low-noise amplifier 3 and power amplifier 4 are functionally and constructively integrated into the antenna module, and into the hardware module (AM) functionally and a microwave unit 6, a unit 7 of transmit and receive amplifiers-converters, a modulator-demodulator unit 8, a transceiver apparatus 9, and a broadband signal processing unit 10 are structurally combined.

The antenna module as part of an antenna-feeder device 1, a reception bandpass filter 2, a low noise amplifier 3, a power amplifier 4 and a transmission bandpass filter 5 simultaneously provides right-handed polarization signals and left-handed polarization signals. The station has the ability to change the polarization to the opposite. The design of the antenna provides manual pointing of the antenna to the geostationary repeater in azimuth and elevation. The station antenna provides operation at wind speeds of up to 20 m / s.

Antenna-feeder device 1 contains an antenna, which includes a collapsible reflector with a diameter of 600 mm, consisting of six interchangeable segments of the same size, and an irradiator having a flange, into the slot of which segments of the reflector, a waveguide path, and a reference rotary device (OPU) are inserted. The gain of the antenna with a diameter of 600 mm is: for receiving at least 24.0 dB in the 4 GHz band and for transmitting at least 26.0 dB in the 6 GHz band.

Low-noise amplifier 3 is designed to amplify the input signals received by the antenna station to the level necessary for the operation of the frequency converter of unit 7 of the station. The design of the amplifier 3 allows it to work outdoors in conditions of rainfall.

Power amplifier 4 is designed to amplify signals in the frequency range from 5725 to 6225 MHz. The amplifier has three amplification stages, a notch filter for suppressing noise in the frequency range of the reception, a power sensor, decoupling ferrite gate and circulator. It provides an output power in saturation mode of at least 12 W and a gain of at least 41 dB.

Turning the power amplifier on and off, removing the output power control signal from the power sensor is carried out from the output of the microwave unit 6.

Unit 6 microwave performs the following functions:

transferring signals from the intermediate frequency (IF) range of 140 MHz to the transmission range of 6 GHz;

signal transfer from the 4 GHz receiving band to the IF band of 140 MHz;

transfer of the onboard beacon signal from the 4 GHz band to the IF band of 140 MHz;

transferring a signal from a transmission range to a reception range for implementing a self-monitoring scheme;

the formation of three reference signals of 10 MHz for the modem and on-board receiver of the beacon.

Spectrum transfers are carried out by two frequency transformations.

The hardware module (AM) of the station in the above composition (blocks 6, 7, 8, 9 and 10) is designed to process information signals and provides:

processing of external interfaces C1-FL-BI, RS-232;

temporary compaction-decompression of information signals;

coding and decoding of signals;

modulation and demodulation of signals;

interference protection by the frequency hopping method in the range (40 ... 400) MHz and FM-ShPS at speeds from 0.48 to 19.2 Mbit / s.

Hardware module equipment is controlled from the control panel of the 12th station via a two-wire communication line at the RS-485 interface.

Block 7 amplifiers-converters of the frequency of reception and transmission provides amplification and frequency selection of the intermediate frequency (IF) signals of 140 MHz supplied to its input.

Block 8 of the modulator-demodulator is designed to modulate and demodulate group signals.

Channel-forming equipment 9 is designed to control all modes of operation of the equipment, encoding the transmitted information with a convolutional code and decoding according to the Viterbi algorithm, turbo-coding information, realizing the transmission mode of the signal by the frequency hopping method, forming a service communication channel for transmitting vocoder information in the group signal header.

The block 10 for processing broadband signals is designed to process the received broadband signals in the path of the main and additional group signal, generating signals for transmission in the path of the main group signal.

An external interface unit 11, together with a control station 12 station, is designed to control a satellite communications station and provides operation at a distance of up to 350 meters from the hardware module (AM). Block 11 provides the physical interaction of the control panel 12 with the station devices at the Ethernet interface while providing information exchange in all specified operating modes of the portable station.

The external interface unit 11 provides various types of interfacing with external equipment at different speeds at the junction of C1-FL-BI, at the junction of RS-232, at the junction of Ethernet, at the subscriber and telephone interfaces with the PBX station.

The station control panel 12 is made on the basis of an industrial computer with characteristics similar to a Getac V100 (V110) Base type portable computer from the MVK-150 complex. It is designed to control all modes of the station, display information about the status and quality of communication provided by the satellite communications station.

The control system of the satellite communication station provides the installation of the operating modes of the station, the issuance of control and operability data of the station equipment, the setting of the level of radiated power and the setting of transmission and reception frequencies.

The receiver 13 of the onboard beacon is designed to receive signals from the onboard beacon, which are used to determine the coordinates of the station’s location and point the station’s antenna to spacecraft (SC) in geostationary orbit, as well as adjust the frequency of the reference oscillator 10 MHz.

The headset headset 14 is a telephone-microphone one-ear headset with a soft headband and is designed for two-way voice communication. It can operate in harsh mechanical and climatic conditions, in increased noise, on moving objects in both duplex and simplex modes. To switch to simplex transmission mode, you must press the tangent, which is part of the headset. The tangent of the headset 14 has a spring clip for attaching to clothing.

The communication line 15 for receiving / transmitting signals at the junction C1-FL-BI, the communication line 17 for receiving / transmitting signals at the junction RS-232 and the connecting line 18 from the PBX station are made using a field distribution cable with four-way structure of P-269M type -2 × 4 + 1 × 2, and the Ethernet line 16 is a twisted pair cable.

The connection of lines 15, 16, 17 and 18 to the block 11 is carried out using the corresponding connecting sockets.

A portable satellite communications station operates as follows.

The satellite communications station provides the organization of satellite communications radio links when operating through the trunks of transponders of spacecraft in geostationary orbit (GSO) in the 4/6 GHz band under any conditions and under the influence of intentional interference.

The station operates in a mode with signal processing on board (RSB) of the repeater. At the same time, the station provides encrypted duplex telephone communication and data transfer, including inter-machine data, over one or two channels with a throughput of 1.2 to 4.8 kbit / s when working in networks when processing signals on board as through fixed channels, and through the channels of the radio-PBX.

The station also provides a mode of operation with direct relay of signals (PR). At the same time, encrypted duplex telephone communication and data transmission, including inter-machine data, in one direction with a bandwidth from 1.2 to 16.0 kbit / s are provided.

The satellite communications station also provides the ability to conduct video conferencing using digital channels with transmission speeds of 48, 64, 128, 256 kbit / s via an Ethernet interface.

When the station is operating, an information signal from terminal equipment (OA) located in external hardware communication is transmitted at various transmission speeds (from 1.2 to 256 kbit / s) via communication lines 15, 16, 17 or 18 to an external unit 11 interfaces on one of the subscriber interfaces: C1-FL-BI, RS-232, ATS or Ethernet. When conducting official telephone communications, information signals are transmitted directly from the headset 14 connected to the external interface unit 11.

From the external interface unit 11, the signal, together with the station control signals generated in the control panel 12, is transmitted to the modulator-demodulator unit 8 through two two-wire communication lines through the channel-forming equipment 9. In block 8, the information signal is encoded, scrambled (masked), modulated at a frequency of 140 MHz. The reference frequency signal of 10 MHz, in which Doppler frequency compensation is provided, is fed to block 8 from the output of microwave unit 6.

The generated signal at a frequency of 140 MHz through the block 7 of the amplifier-frequency converters is fed to the input of the microwave unit 6. In block 6 of the microwave information signal using heterodyne frequencies is transferred to the transmitting frequencies of the satellite communications station. From the output of the microwave unit 6, the generated transmission signal is fed to the input of the power amplifier 4, in which it is amplified and transmitted through the bandpass filter 5 to the irradiator of the 4/6 GHz antenna of the antenna-feeder device 1 and radiated by the antenna.

When the station is operating, the received RF signals from the 4/6 GHz irradiator antenna of the antenna-feeder device 1 are received through the bandpass filter 2 of the receiver, which attenuates the transmitter signals, to the input of the low-noise amplifier 3. From the output of the low-noise amplifier 3, the amplified received signal is fed to the input of the block 6 microwave, in which it is amplified and transferred to an intermediate frequency of 140 MHz. From the output of block 6, the generated signal is fed to the input of block 7 of the frequency converter amplifiers, in which it is amplified and converted to an intermediate frequency. From the output of block 7, the signal is fed to the input of block 8 of the modulator-demodulator. In block 8, the received signal is digitized. After that, the first and second reception channels are allocated. The second reception channel in narrowband mode is a control channel. In block 8 (modem), the narrow-band signals coming from the output of block 7 and 6 are demodulated, descrambled, decoded (each in its own channel). In the mode of broadband signals, the modem (in block 10) demodulates the signal, converts it, and then, as in narrow-band mode, descrambles and decodes according to the Viterbi method.

The received signals from the output of block 8 of the modulator-demodulator are fed to the input of the channel-forming equipment 9. The equipment 9 provides detection of interaction signals (control commands) transmitted via the control channel, signals the operator about the receipt of commands, and automatically transmits these commands for execution to block 8 (during operation in the mode with the provision of channels on demand - FCT). The information signal from the output of the channel-forming equipment 9 is transmitted to the external interface unit 11 via a two-wire line.

From the external interface unit 11, an information signal is supplied to the interface adapter and then to the terminal equipment via one of the subscriber interfaces: C1-FL-BI, RS-232, ATS or Ethernet. In the mode of conducting business telephone communications, information signals are sent directly to a microphone headset 14 connected to an external interface unit 11.

The reception of signals from the beacon by the receiver 13 is carried out on a separate path of the microwave unit 6 and the hardware module (AM). An analog path with automatic gain control in the hardware module provides amplification and filtering in a narrow band of the FM signal received by receiver 13 from the onboard repeater. Next, the signal is digitized and fed to a digital mixer. The filtered signal is fed to the input of the FFT scheme (fast Fourier transform), which selects the frequency components of the FM signal. The data array is processed in the control module of the channel-forming equipment 9, the preamble is allocated, information about the number of the spacecraft (SC) and is recorded in the modem registers of block 8 of the modulator-demodulator. This information is used by the station operator when pointing the antenna of the satellite communication station to the spacecraft repeater.

The control interface from the remote control 12 exchanges commands and service information with the FCT device (providing a channel on demand - FCT) and modem control in all modes of the station. It also provides reception and issuance of information by the modem of unit 8 via CAN and RS-232 buses.

A portable satellite communications station provides interfacing with complexes and means of terminal and external channel-forming equipment at the C1-FL-BI interface via a four-wire circuit with various speeds, along the RS-232C asynchronous (start-stop) interface with signal parameters in accordance with ITU-V.28 recommendations T, on the Ethernet interface and on two-wire subscriber or connecting lines of communication with the telephone exchange or telephone sets with the transmission of dialing pulses by direct current with signaling parameters and electrical parameters of the subscriber or connecting lines.

The technical effect of the present invention is to create a portable satellite communications station operating in multiple access networks with code and frequency-code separation of signals, providing enhanced functionality for the organization of a radio communication network and having low overall dimensions by combining a number of station equipment in separate structural modules .

The advantage of a portable satellite communications station is also that its design in the form of separate modules made it possible to stack them in special satchels and cases for carrying the station by one or two people from the service personnel. At the same time, the assembly time of the station from the worker to the stowed position is no more than 3 minutes, and the deployment time of the portable satellite communications station for work in the parking lot is no more than 5 minutes.

Information sources

1. RU, patent No. 2293442, IPC Н04В 7/26, BI No. 4 of 02/10/2007.

2. Satellite Communications and Broadcasting: A Guide. - 3rd ed., Revised. and add. / V.A. Bartenev, G.V. Bolotov, V.L. Bulls and others; under the editorship of L.Ya. Cantor. - M .: Radio and communications, 1997, fig. 15.1, p. 419 (prototype).

Claims (1)

A portable satellite communications station comprising an antenna system, an antenna pointing system, a low-noise amplifier, a block of amplifiers-converters of the frequency of reception and transmission, a modulator-demodulator block, a power amplifier and channel-forming equipment, characterized in that an additional band-pass reception filter and a band-pass filter are introduced therein transmissions, microwave unit, broadband signal processing unit (SHPS), external interface unit, station control panel, headset, communication line for reception / broadcast signal transfer at the C1-FL-BI interface, an Ethernet line, a communication line for receiving / transmitting signals at the RS-232 interface and a connecting line (SL) from the PBX station, while the output of the antenna-feeder device is connected to the input of the receive bandpass filter, output which is connected to the input of a low-noise amplifier, the output of which is connected to the first input of the microwave unit, the first output of which is connected to the input of the power amplifier, the output of which is connected to the input of the bandpass transmission filter, the output of which is connected to the input of the antenna-feeder device, the second output of the block Microwave is connected to the first input of the block of amplifiers-frequency converters (OCH) of reception and transmission, the first output of which is connected to the second input of the microwave unit, the third output of which is connected to the first input of the modulator-demodulator block, the first output of which is connected to the third input of the microwave unit, the second the output of the modulator-demodulator block is connected to the second input of the receive and transmit unit, the second output of which is connected to the second input of the modulator-demodulator block, the input of the channel-forming equipment is connected to the third output of the module block a torus-demodulator, the third input of which is connected to the output of the channel-forming equipment, the information input-output of which is connected to the information input-output of an external interface unit, the control input-output of which is connected to the control input-output of the channel-forming equipment, the control input-output of which is connected to the control the input-output of the microwave unit, the first information input / output of which is connected to the first information input-output of the broadband signal processing unit, the second information input-output which is connected to the second information input-output of the external interface unit, the second control input-output of which is connected to the control input-output of the broadband signal processing unit, the control input-output of the station control panel at the Ethernet interface is connected to the third control input-output of the external interface unit, the third information input-output of which is connected to the information input-output of the headset headset, the second information input-output of the microwave unit is connected to the information input-output of the receiver of the onboard beacon, which plays the role of the station’s antenna pointing system, the fourth, fifth, sixth and seventh information inputs and outputs of the external interface unit are connected to the inputs and outputs of the communication line for receiving / transmitting signals at the interface C1-FL-BI, Ethernet line, line communications for receiving / transmitting signals at the junction of RS-232 and trunk line (SL) from the PBX station, while reducing the overall dimensions of the station and improving its operational and technical characteristics, the antenna-feeder device, band pass filters ry transmission and reception, the low noise amplifier and a power amplifier functionally and structurally integrated into the antenna module and a hardware module functionally and structurally combined RF unit, a receiving unit and transmitting converters amplifiers, power modulator-demodulator, channel-forming apparatus and processing block broadband signals.

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