RU2729037C1 - Mobile station of satellite communication - Google Patents

Abstract

FIELD: means of satellite communication.

SUBSTANCE: invention relates to satellite communication means and can be used for arrangement of satellite communication radio lines during operation through transponder channels of spacecrafts located on geostationary and high-elliptical orbits. In a mobile satellite communication station, comprising an antenna system, a duplexer, a low-noise amplifier, a receiving frequency amplifier-converter unit, modem, a unit of amplifier-converters of transmitting frequency and a power amplifier, further includes an antenna remote control unit, a navigation system, a signal digital processing unit, reference generator unit, receiving frequency synthesizer, transmitting frequency synthesizer, station control unit, channel switch, combined multiplexer of communication systems, input shield, a connecting line (CL) for receiving/transmitting channels over the connection of S1-FL-BI, a fiber-optic communication line (FOCL) for receiving/transmitting group flow signals to a consumer, a connecting line for receiving/transmitting channels over an Ethernet connection, two-wire communication line and a communication line for connection with external subscribers, and also achieved by using PDSK signaling method with FHSS, broadband phase-shift keying method and method of noise-protection coding, implementation of three antenna control methods in station, including automatic guidance of an antenna to a spacecraft, manual control and automatic tracking during operation of a mobile station of satellite communication at a standstill, from short stops and in motion.

EFFECT: provision of formation of various channels with increased throughput capacity and maintenance of stable communication on them under various operating conditions of the station during operation both at parking and in motion.

1 cl, 1 dwg

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 geostationary and highly elliptical orbits.

Satellite communication stations are increasingly being used to provide communication directly from the workplaces of officials in mobile objects or from remote workplaces. For this purpose, small-sized personal portable satellite communication stations and satellite communication stations are used, placed in van bodies on various transport bases.

Known subscriber station satellite communications for the RF patent for invention No. 2293442, which includes an antenna system, a device for dividing the transmission and reception paths, a transceiver, channel-formation equipment, a control unit for operating modes of elements of a satellite communications subscriber station and a guidance system of the antenna system [1 - RU, patent No. 2293442, Bull. No. 4 dated 10.02.2007].

In the known station, a frequency division multiple access system is used, which requires the allocation of a significant frequency resource and this system and, accordingly, a station built on 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 ground-based satellite communication stations, the closest in technical essence is the subscriber station, the structural diagram of which is shown in Fig. 15.1, p. 419 in the book Satellite Communications and Broadcasting: A Handbook. - 3rd ed., Rev. and add. / V.A. Bartenev, G.V. Bolotov, V.L. Bykov and others; Ed. L. Ya. Cantor. - M .: Radio and communication, 1997 [2].

A well-known satellite communication station (Fig. 15.1, p. 419) contains an antenna system, an antenna pointing system, a duplexer, a low-noise amplifier, a unit of amplifiers-converters of the receiving and transmitting frequencies, a modem (modulator-demodulator unit), a power amplifier, channel-forming equipment and a control CPU.

The main disadvantage of the known station is the cumbersomeness of its equipment, especially the antenna system and the antenna pointing system. This does not allow the station equipment to be placed in mobile objects on different transport bases and leads to a limitation of its use in modern satellite communication systems.

In addition, the known satellite communication station does not provide the ability to automatically aim the antenna at a repeater located on an artificial earth satellite (AES), which significantly reduces the quality of satellite communication services due to a constant change in the location of the satellite and, accordingly, a sharp decrease in the received signal level.

The aim of the invention is to create a portable satellite communication station that provides the organization of various channels with increased bandwidth and maintaining stable communication when working both at a stop and on the move.

This goal is achieved by the fact that a remote control unit for the antenna, a navigation system is additionally introduced into the mobile satellite communication station, which contains an antenna system, a duplexer, a low-noise amplifier, a unit of amplifiers-converters of the receiving frequency, a modem, a unit of amplifiers-converters of the transmitting frequency and a power amplifier. digital signal processing unit, reference generator unit, receiving frequency synthesizer, transmitting frequency synthesizer, station control unit, channel switch, combined communication system multiplexer, input board, connecting line (SL) for receiving / issuing channels at the C1-FL-BI interface, a fiber-optic communication line (FOCL) for receiving / issuing signals of a group flow to a consumer, a connecting line for receiving / issuing channels via an Ethernet interface, a two-wire communication line and a communication line for connecting with external subscribers, while the information output of the navigation system is connected to the information input remote control unit antenna, the input-output of which is connected to the input-output of the antenna system, the high-frequency input-output of which is connected to the high-frequency input-output of the duplexer, the output of which is connected to the input of a low-noise amplifier, the output of which is connected to the input of the unit of amplifiers-converters of the receiving frequency, the output of which connected to the input of the modem, the first and second outputs of which are connected respectively to the first and second inputs of the unit of amplifiers-converters of the transmission frequency, the control input of which is connected to the control output of the transmitting frequency synthesizer, the first output of the reference oscillator unit is connected to the input of the receiving frequency synthesizer, the control output of which connected to the control input of the unit of amplifiers-converters of the receiving frequency, the second output of the reference generator unit is connected to the input of the transmitting frequency synthesizer, the first, second and third control inputs-outputs of the station control unit are connected to the control inputs-outputs, respectively bl remote control of the antenna, modem and channel switch, the first, second and third inputs-outputs of the modem are connected respectively to the first station input-output of the channel switch, to the first and second input-outputs of the digital signal processing unit, the third and fourth inputs-outputs of which are connected respectively, to the second and third station inputs-outputs of the channel switch, the output of the unit of amplifiers-converters of the transmission frequency is connected to the input of the power amplifier, the output of which is connected to the input of the duplexer, the first linear input-output of the channel switch is connected to the first input-output of the multiplexer of the combined communication systems, the second input-output of which is connected to the first station input-output of the input board, the second, third and fourth linear inputs-outputs of the channel switch are connected respectively to the second, third and fourth station inputs-outputs of the input board, to the first, second, third, fourth and the fifth line inputs-outputs to second, the inputs-outputs are connected, respectively, of the connecting line (SL) for receiving / issuing channels via the C1-FL-BI interface, a fiber-optic communication line for receiving / issuing signals from the group flow to the consumer, a connecting line for receiving / issuing channels via the Ethernet interface, two-wire communication lines and communication lines for connection with external subscribers.

Comparable analysis with the prototype shows that the proposed mobile satellite communication station is distinguished by the presence of new units: an antenna remote control unit, a navigation system, a digital signal processing unit, a reference generator unit, a high-speed and transmitting frequency synthesizer, a station control unit, a channel switch, a combined system multiplexer. communication, input board, SL for receiving / issuing channels at the C1-FL-BI interface, FOCL for receiving / issuing signals of the group flow to the consumer, SL for receiving / issuing channels via the Ethernet interface, two-wire communication line and communication line for connecting with external subscribers , as well as changing the connections between the known blocks of the station.

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

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

The claimed solution clearly does not follow from the prior art and has an inventive step, and the equipment and equipment used in the station are widely known and additional creativity is not required for their implementation, which confirms the possibility of industrial implementation of the proposed mobile satellite communication station.

The drawing shows a block diagram of a mobile satellite communication station.

The mobile satellite communication station contains an antenna system (AS) 1, a unit 2 for remote control of the antenna, a navigation system 3, a duplexer 4, a low-noise amplifier 5, a unit 6 of amplifiers-converters of the receiving frequency, a modem 7, a digital signal processing unit 8, a reference generator unit 9 , the receiving frequency synthesizer 10, the transmitting frequency synthesizer 11, the station control unit 12, the unit 13 of the transmit frequency amplifiers, the power amplifier 14, the channel switch 15, the multiplexer 16 of the combined communication systems, the input shield 17, the SL 18 for receiving / issuing channels on interface C1-FL-BI, fiber-optic communication line (FOCL) 19 for receiving / issuing signals of the group flow to the consumer, SL 20 for receiving / issuing channels via the Ethernet interface, two-wire communication line 21 and communication line 22 for connecting with external subscribers ...

In this case, the information output of the navigation system 3 is connected to the information input of the antenna remote control unit 2, the input-output of which is connected to the input-output of the antenna system 1, the high-frequency input-output of which is connected to the high-frequency input-output of the duplexer 4, the output of which is connected to the input of the low-noise amplifier 5, the output of which is connected to the input of the unit 6 of amplifiers-converters of the receiving frequency, the output of which is connected to the input of the modem 7, the first and second outputs of which are connected respectively to the first and second inputs of the unit 13 of the amplifiers-converters of the transmitting frequency, the control input of which is connected to the control the output of the transmitting synthesizer 11 frequency. The first output of the block 9 of the reference generator is connected to the input of the receiving frequency synthesizer 10, the control output of which is connected to the control input of the unit 6 of amplifiers-converters of the receiving frequency, the second output of the block 9 of the reference generator is connected to the input of the transmitting frequency synthesizer 11. The first, second and third control inputs-outputs of the station control unit 14 are connected to the control inputs-outputs, respectively, of the antenna remote control unit 2, the modem 7 and the channel switch 15. The first, second and third inputs-outputs of the modem 7 are connected, respectively, to the first station input-output of the switch 15 channels, to the first and second inputs-outputs of the digital signal processing unit 8, the third and fourth inputs-outputs of which are connected to the second and third station inputs, respectively - 15 channels switch outputs. The output of the unit 13 of amplifiers-converters of the transmission frequency is connected to the input of the power amplifier 14, the output of which is connected to the input of the duplexer 4. The first linear input-output of the channel switch 15 is connected to the first input-output of the multiplexer 16 of the combined communication systems, the second input-output of which is connected to the first station entrance-exit of the shield 17 input. The second, third and fourth linear inputs-outputs of the channel switch 15 are connected, respectively, to the second, third and fourth station inputs-outputs of the input board 17, to the first, second, third, fourth and fifth linear inputs-outputs of which the inputs-outputs are connected respectively to the connecting line (SL) 18 for receiving / issuing channels at the interface C1-FL-BI, fiber-optic communication line 19 for receiving / issuing signals of the group flow to the consumer, connecting line 20 for receiving / issuing channels at the Ethernet interface, two-wire communication line 21 and line 22 connections to connect with external subscribers.

Antenna system 1 includes an antenna, which is an antenna array in the form of a multilayer board, and a rotary support (PAD). The slewing support is made according to the scheme of a biaxial orthogonal suspension having a horizontal guidance axis (HN) and a vertical guidance (VN) axis. The OPU contains an electric drive that rotates the antenna array along the horizontal pointing axis by 360 ° without limitation, and along the vertical pointing axis - from 0 to 110 degrees.

Antenna system 1 is designed to receive and transmit electromagnetic energy through a repeater on a spacecraft (SC), which is in geostationary or highly elliptical orbits. The antenna system 1 is guided to the spacecraft automatically due to the input into the control device of the initial data for calculating target designations from the station control unit 12, or in the mode of manual input of the spacecraft azimuth and elevation parameters using the antenna system remote control unit 2.

Antenna remote control unit 2 is designed to enter and calculate the parameters of the antenna control system required to control the antenna in various pointing modes, as well as to display information on the antenna control. Block 2 contains a character display, consisting of four lines, each of which has twenty characters, as well as a keyboard, consisting of twenty buttons.

Antenna remote control unit 2, when working in conjunction with station control unit 12, provides modes: manual pointing, programmed antenna pointing, setting to specified coordinates, automatic (auto tracking) and manual tuning to the maximum of the received antenna signal.

Antenna pointing control is carried out according to target designations coming from the antenna remote control unit 2, which are calculated taking into account the navigation parameters received from the navigation system 3.

The navigation system 3 of the station includes an antenna device and a receiving module. An antenna device of the MRK-PAP-U type can be used as an antenna device, and an MRK-11-PRM-16 type module from the MRK-32 multifunctional radio navigation complex is used as a receiving module.

Duplexer 4 is a waveguide and is designed to separate the receiving and transmitting signals in the common high-frequency path of the antenna-feeder device of the satellite communication station. It provides a direct connection between an inductive diaphragm waveguide in the receive channel and a two-mode transmit filter on a circular waveguide.

The low-noise amplifier 5 is designed to amplify the input high-frequency signals received by the antenna 1 of the station and coming from the output of the duplexer 4 to the level necessary for the operation of the unit 6 of amplifiers-converters of the station's receiving frequency.

Unit 6 of amplifiers-converters of the receiving frequency is designed to convert and amplify high-frequency signals of the receiving frequency range from 7250 to 7750 MHz, arriving at its input from the LNA 5 output, into an intermediate frequency signal of 140 MHz.

Modem 7 includes modulator, demodulator units, time-division multiplexing equipment, pseudo-random frequency tuning equipment (GTPRCH) and broadband signal equipment (BSS). It performs modulation and demodulation of signals, coding and decoding of signals, conversion of signals at the TTL interface into signals of external interfaces, organization of telephone exchange and service communication during vocoder transmission of speech, noise protection in the transmission mode by means of frequency hopping or FM-ShPS, time-division multiplexing-decompression of information signals ... The modem 7 is controlled by control signals coming from the station control unit 12.

Modem 7 at the reception demodulates the signals received and converted by block 6 of the intermediate frequency 140 MHz into TTL signals for their subsequent processing by block 8, generating a three-bit demodulated signal for the Viterbi decoder, differential decoding of received information, generating output signals for time division multiplexing equipment and issuing information signals at the junction levels C1-FL-BI.

When transmitting signals, the modem 7 converts information signals by the PFT manipulation method in the mode of phase-shift keyed broadband signals (PSS), coming from the consumer's terminal equipment in digital form, into high-frequency signals for their subsequent transformation into group signals of the station transmitter.

Block 8 digital signal processing is designed to process information signals coming through the input board 17 and the switch 15 channels from the terminal equipment of the consumer and directed to it. It ensures the operation of a satellite communication station in the mode with signal processing on board (OSB) of the spacecraft and in the mode of direct relaying (LR). Unit 8 includes a transmission and reception unit for broadband signals (SHPS), an exciter of decimeter waves, a SHPS modulator, a Viterbi decoder, time division multiplexing equipment, a unit for packet control and signal transmission in the mode of pseudo-random frequency tuning (PFC) and an interface unit.

Block 8 digital processing provides processing of information signals, including:

modulation and demodulation;

coding and decoding of signals;

conversion of signals from a TTL junction to a C1-FL-BI, C1-TG or TLF-ATC, RS-232;

frequency transfer from modulated signals to the decimeter wavelength range (UHF);

noise immunity for transmission by the frequency hopping method with coding and for reception and transmission by the FM-NLS method with coding;

management of the blocks that make up it.

Block 9 of the reference generator is designed to generate signals of the reference frequency of 100 MHz and output them to the control inputs of the receiving frequency synthesizer 10 and the transmitting frequency synthesizer 11.

The receiving frequency synthesizer 10 is designed to generate heterodyne signals and transmit them to the inputs of the unit 8 of amplifiers-converters of the receiving frequency.

The transmitting frequency synthesizer 11 is designed to generate heterodyne control signals and transmit them to the input of the unit 13 of the transmit frequency amplifiers-converters.

The station control unit 12 is a control electronic computer and contains a computer made in the form of an IBM compatible computer with a design of increased strength, small overall dimensions, an expanded set of input-output functions, a highly efficient video subsystem and deployed controls, a drive, a CAN controller and a cartridge (flash memory), which is a removable storage medium. As such a laptop, a personal electronic computer (PC) of the EC-1866 type can be used.

Block 12 provides maximum simplification of the control procedure and ease of use due to the high degree of integration of the processor, graphic display, keyboard, external interface device and input device for initial data from the cartridge.

The station control unit 12 is designed to implement the software and hardware of the automated control subsystem of the satellite communication station. It provides loading of the operating system from the cartridge, under the control of which the application software of the station functions, the integration of the software and hardware of the station equipment into a single hierarchical subsystem of the station control on the principles adopted in the unified satellite communication system with the implementation of modern exchange protocols, input of the initial data from the cartridge and alphanumeric text from the keyboard, organizing a window for servicing interactive programs of station blocks on the block indicator, establishing or releasing connections at the logical level of four satellite channels with secondary network channels, maintaining signaling in all modes of station operation, displaying the current state of the blocks on the block indicator, and paths of the station, the organization of control of the station from an external operator when working in a parking lot, with remote control from the radio access network when working in motion and from short stops.

The block 13 of amplifiers-converters of the transmission frequency is intended for transferring the signals of the decimeter part of the exciter, formed at an intermediate frequency of 140 MHz, into signals in the transmission frequency range from 7900 to 8400 MHz. The conversion is carried out under the influence of signals arriving at the control input of the unit 13 from the output of the transmitting frequency synthesizer 11.

Amplifier 14 power (PA) is designed to amplify high-frequency signals in the operating frequency range from 7900 to 8400 MHz. It provides an output power in nominal mode of at least 80 W.

The 15-channel switch is designed for organizing and switching station communication channels. It is a manual channel switch, in which switching is performed with plug jumpers and patch cords that are part of the switch. In this case, the switching of the main modes is carried out with four-pin jumpers, and the switching of additional modes is carried out using two-wire cords.

The multiplexer 16 combined communication systems provides reception / transmission of a digital E1 or Ethernet signal with its conversion into an SHDSL interface.

The input board 17 contains an input panel, on which there are connecting connectors for connecting cable communication lines and communication lines to the station for connecting with similar stations and with external subscribers. The panel contains hardware half-couplings, an M12 Ethernet connector, a fiber-optic connector for connecting an optical cable, and terminals for connecting two-wire transmission / reception lines from the multiplexer.

The connecting line 18 is intended for receiving / issuing channels at the C1-FL-BI interface. It can be performed using a field distribution cable with a quadruple structure of the P-269M type.

Fiber-optic communication line 19 (FOCL) is designed to send / receive signals from digital group paths from similar stations or to connect with external consumers of channels and paths. FOCL 24 can be made using a field optical cable of the OK-VM-4 type.

The connecting line 20 is intended for receiving / issuing channels to an external consumer via an Ethernet interface. It can be performed using a field distribution cable with a quadruple structure of the P-269M type.

Two-wire communication line 21 is intended for transmitting / receiving signals from the multiplexer of the combined communication systems using the xDSL technology. It can be performed using a two-wire field cable of the P-274M type.

Communication line 22 for connection with external subscribers can be performed using a field distribution cable with a quadruple structure of the P-269M type.

The equipment and equipment of the mobile satellite communication station are structurally made in the form of modules that can be placed in van bodies installed on various transport bases, for example, in a van body mounted on the chassis of a KAMAZ-5350 cross-country vehicle.

A mobile satellite communication station provides communication without manual search and adjustment, providing reception of signals in the frequency range from 7250 to 7550 MHz and transmission of signals in the frequency range from 7900 to 8400 MHz. It provides duplex communication in nodal, radial-nodal, radial and radio-automatic telephone exchange networks of the unified satellite communication system (ECCS), in communication networks in fixed directions, as well as duplex communication in high-speed trunk lines.

A mobile satellite communication station provides the following types of communication and operating modes:

duplex telephone communication and data transmission, as well as conducting telephone communication or machine-to-machine communication in the mode of a remote ATS subscriber when working in radial-nodal communication networks through fixed channels or channels operating on the principles of radio-ATS with continuous information transfer;

data transmission in data transmission networks;

duplex communication and data transmission over four channels with a throughput of 1.2 to 4.8 kbps, organized in four communication directions through fixed channels or channels used in the radio-automatic telephone exchange mode when operating in continuous mode.

The station control system, implemented on the basis of the station control unit 12, is an integral part of the automated control system for the satellite communication network and provides:

automatic control of the station equipment in accordance with the space communication data entered into the station processor and control commands;

receiving, storing and documenting space communication data received both through control channels and from the station control unit, necessary to set the station operating parameters in accordance with the required operating modes;

automatic generation of messages containing control data and their transmission via control channels, periodically and upon request, to the higher control body of the communication network;

masking of messages transmitted over the space control channel and over the space automated control channels;

organization of service communication between the operator of a given station and the operators of those stations of the system with which communication is organized through the channels of machine-to-machine exchange (MMO);

automatic control of the state of devices, individual channels formed by the station with their binding to the directions of communication.

At the same time, the station provides automated tuning to the required operation mode based on the space communication data available in the station's memory by commands received from the control channel or the machine-to-machine communication channel, as well as by the command from the station control unit 12.

The passage of signals along the paths of the station is discussed below.

Receiving tract. The signal emitted by the repeater on the spacecraft (SC) in the frequency range from 7490 to 7540 MHz is received by the antenna system 1 of the station and through the duplexer 4 is fed to the input of the low-noise amplifier 5. In this case, the protection of LNA 5 from the signals of its own transmitter is provided by a band-stop filter with a level suppression of at least 60 dB of transmission signals from 7900 to 8400 MHz.

The signal amplified by the LNA unit 5 is fed to the input of the unit 6 of amplifiers-converters of the receiving frequency. The heterodyne signal from the output of the receiving frequency synthesizer 10 converts the spectrum of the received signal in the frequency band from 7490 to 7540 MHz into an intermediate frequency signal of 140 MHz. From the output of the block 6 of amplifiers-converters of the receiving frequency, the signal in the 140 MHz frequency band is fed to the input of the modem 7.

Modem 7 demodulates and decodes the 140 MHz IF signal. When the station operates in the ECCS network, the demodulated and decoded signals undergo a time division operation, as a result of which up to four digital telephone channels with speeds of 1.2 can be allocated; 2.4; 4.8 and 9.6 kbps. Signals from digital telephone channels are fed to the station channel switch 15, input shield 17, and then via connecting communication lines (18-22) to the channel consumers.

When working in trunk communication networks, the demodulated and decoded group stream with rates from 16 to 2048 kbit / s enters the digital signal processing unit, in which the necessary high-speed signal joints are formed.

When operating at speeds from 16 to 64 kbit / s, it is possible to provide decompression of the group signal in the signal multiplexer of the digital signal processing unit 8 up to five channels with a bandwidth of 1.2 ... 32 kbit / s. The group flow of the high-speed signal from the output of the modem 7 or the decompressed group signal from the output of the digital signal processing unit 8 is fed through the channel switch 15 to the station input shield 17 and then to the channel consumers.

In block 8 of digital processing, the signal is demodulated, a three-bit demodulated signal is formed, which is decoded using the Viterbi algorithm and fed to the time division multiplexing equipment.

The time division multiplexing equipment, which is part of the station digital processing unit 8, provides time division of the multichannel signal into four TTL interface channels of the form 4 × 1.2 kbps or 2 × 2.4 kbps or 1 × 4.8 kbps ... Further, the subscriber signals in the bi-pulse code are fed to the input of the interface unit. The block of interfaces converts the dedicated digital telephone channels of the TTL joint into the joints of the consumer's terminal equipment, including: C1-FL-BI joints for digital telephone communication, RS-232 joints for data transmission, C1-FL-BI for a mobile network with a transmission rate 1.2 kbps, etc.

When working through the channels in the mode of interfacing with an external automatic telephone exchange in the interface block of the digital signal processing unit 8, the vocoder conversion of the information signal at a rate of 4.8 kbit / s into the interface of the secondary public telephone network is performed.

Information signals of the dedicated communication channels through the channel switch 15 are output to the input panel 17 and then through the communication lines 18, 19 and 20 are transmitted to the consumer.

Reception of information signals with group rates from 1.5 to 600.0 kbit / s by the FT manipulation method, with decoding according to the Viterbi algorithm in the FM SHPS mode.

The intermediate frequency signal 140 MHz is fed to the intermediate frequency amplifier (IF) of the digital signal processing unit 8. The IF amplifier contains mainly the linear part of the receiving intermediate frequency path, provides relative filtering and amplification. In the mode of receiving signals with NLS modulation, an amplifier with a converter generates an intermediate frequency signal of 140 MHz and transmits it to the noise protection unit.

The anti-jamming unit receives and processes the NLS signal, removes the pseudo-random sequence (PRS), after which the narrow-band signal in the 3 MHz band enters the amplifier again. After appropriate processing, the signal is sent to the demodulator of the modem 7 to demodulate it.

In the demodulator, the signal is demodulated, a three-bit demodulated signal is generated for the Viterbi decoder and enters the Viterbi decoder.

In a Viterbi decoder, the signal is decoded using the Viterbi algorithm and returned to the demodulator. Further, the signal of the TTL interface enters the subscriber unit of the time division multiplexing unit 8 of digital signal processing. The subscriber unit provides time division of a multichannel signal up to four TTL interfaces: 4 × 1.2 kbps or 2 × 2.4 kbps or 1 × 4.8 kbps. From the subscriber unit of the time division multiplexing equipment, the subscriber signals in the bi-pulse code enter the interface unit of the digital signal processing unit 8. The block of interfaces converts the dedicated digital telephone channels of the TTL interface into the joints of the consumer's terminal equipment.

Through the input shield 17, information signals are output on lines 18, 19, 20, 21 and 22 to the consumer.

Transmitting path.

When operating in ECCS networks, information signals of telephone channels arriving via communication lines 18, 19, 20, 21 and 22 through input shield 17 and channel switch 15 are fed to the interface block of digital signal processing unit 8. The block of interfaces converts the signals of telephone channels from the C1-FL-BI interface into TTL levels. Further, the converted signals are fed to the input of the time division multiplexing equipment, which is part of the digital signal processing unit 8, where they are compressed into a group stream.

When working in trunk communication networks, the group information flow coming from the consumer via communication lines, through the input shield 17 and the channel switch 15, enters the modem 7, bypassing the compression equipment of the digital signal processing unit 8.

The station has the ability to multiplex up to four information channels with rates from 1.2 to 32 kbit / s.

The signals at the SHDSL junction, coming from the consumer via the two-wire communication line 21, are fed through the input shield 17 to the multiplexer 16 of the combined communication systems, where they are converted into signals of the E1 or Ethernet junctions and then through the channel switch 15 to the modem 7.

The modem organizes one of the modes of direct transmission (PR), frequency hopping, shPS, modulation of the carrier signal with a frequency of 140 MHz with a group signal coming from the time division multiplexing equipment of the digital signal processing unit 8.

The modulated signal from the output of the modem 7 enters the block 13 of the amplifiers-converters of the transmission frequency, where it is converted into a signal with a transmission frequency of 7900 to 8400 MHz and then enters the input of the power amplifier 14. The amplified signal up to a power of 80 W from the output of the power amplifier 14 through the duplexer 4 enters the antenna system 1 for radiation into space towards the repeater on the spacecraft (SC).

Thus, information signals enter the transmitting path of the station in the form of a group information signal (GS) with a transmission rate of 1.5; 3.0; 6.0 kbps. Information signals transmitted by terminal equipment of a similar satellite communication station or interacting communication node have a transmission rate of 1.2; 2.4; 4.8 kbps.

In a satellite communication mobile station, a signal transmission method is used with pseudo-random tuning of operating frequencies and the use of frequency hopping equipment in the transmission path of the station. The electrical speeds during the transmission of OFT signals by the frequency hopping method, respectively, take on the values of 15, 30 and 60 kbit / s.

The group information signals arriving at the block 8 of digital processing are encoded with a convolutional code and then fed to the block 13 of amplifiers-converters of the transmission frequency, where they are processed in accordance with the information coming from the time division multiplexing equipment, modulated by the block 8 and in the frequency band from 675 to 700 MHz to the input of the block 13 of amplifiers-converters of transmission frequency In block 13, group signals in the frequency band from 675 to 700 MHz are converted into the transmission frequency band from 7900 to 8400 MHz, amplified by an amplifier and fed to the input of the power amplifier 14. In the power amplifier 14, the transmission signals are amplified to the required level (80 dB) and from its output through the duplexer 4 the signals are transmitted to the antenna system 1, which emits them into the air.

Group signals are encoded with a convolutional code, for which a Viterbi encoder is used, they are fed to the modulator, where they are modulated and in the frequency band from 675 to 700 MHz are fed to the input of the power amplifier 14, where they are amplified and through the duplexer 4 they enter the antenna system 1, which emits them on the air.

Along with the mode of transmitting OFT signals by the frequency hopping method, the mode of transmitting signals by the method of wideband phase modulation is realized in the satellite communication station. An information flow with group rates up to 6 kbit / s arrives at the input of the NPS modulator of the digital signal processing unit 8. The NLS modulator of block 8 generates wideband video signals FM-NLS with superimposed pseudo-random sequences PSP-1 and PSP-2.

After passing the conversion, the generated signal in the 675 to 700 MHz band with a level of 6 mW enters the centimeter wave exciter (CMW), where the signal from the UHF range from 675 to 700 MHz is converted to the operating frequency range from 7900 to 8400 MHz. Further, the signal from the exciter is fed to the input of the power amplifier 14. The signal amplified to 80 W is fed through the duplexer 4 to the input of the antenna system 1 and is emitted by it into the air.

The signals at the SHDSL interface, transmitted from the communication center or from the interacting station via the two-wire communication line 21, are fed through the input shield 17 to the input of the multiplexer 16 of the combined communication systems, where they are converted into signals of the E1 or Ethernet joints and through the channel switch 15 are fed to the interface unit modem 7. Modem 7 modulates the 140 MHz carrier signal with a group signal.

The modulated signal from the output of the modem 7 is fed to the unit 13 of the frequency amplifiers-converters, in which it is converted into a signal with a transmission frequency of 7900 to 8400 MHz and then enters the input of the power amplifier 14. In the power amplifier 14, the signal is amplified by a house of 80 W power and through the duplexer 4 is fed to the antenna system 1 for radiation into space in the direction of the repeater on the spacecraft.

The technical effect of the proposed invention is to ensure the formation of various channels with increased throughput and maintaining stable communication on them under various operating modes of the station both at a stop and in motion, achieved through the use of methods for transmitting PFT signals with frequency hopping, the method of broadband phase shift keying and the method of anti-jamming coding, as well as the implementation of three methods of antenna control, including automatic antenna pointing to the spacecraft, manual control and auto-tracking during the operation of a mobile satellite communication station at a stop, from short stops and in motion.

The advantage of the claimed mobile satellite communication station is the modular construction of its nodes, covered by constant monitoring of their state, which made it possible, by significantly reducing the paths of information signals, to increase the reliability of the station, reduce the time indicators of organizing and conducting communication through the formed communication channels and paths.

Sources of information.

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

2. Satellite communications and broadcasting: Handbook. - 3rd ed., Rev. and add. / V.A. Bartenev, G.V. Bolotov, V.L. Bykov and others; Ed. L. Ya. Cantor. - M .: Radio and communication, 1997, fig. 15.1, p. 419 (prototype).

Claims (1)

A mobile satellite communication station containing an antenna system, a duplexer, a low-noise amplifier, a unit of amplifiers-converters of the receiving frequency, a modem, a unit of amplifiers-converters of the transmitting frequency and a power amplifier, characterized in that an antenna remote control unit, a navigation system, a unit digital signal processing, reference generator unit, receiving frequency synthesizer, transmitting frequency synthesizer, station control unit, channel switch, combined communication system multiplexer, input panel, connecting line (SL) for receiving / issuing channels at the C1-FL-BI interface, fiber - optical communication line (FOCL) for receiving / issuing signals of the group flow to the consumer, a connecting line for receiving / issuing channels via the Ethernet interface, a two-wire communication line and a communication line for connecting with external users, while the information output of the navigation system is connected to the information input of the unit remote control antenna d, the input-output of which is connected to the input-output of the antenna system, the high-frequency input-output of which is connected to the high-frequency input-output of the duplexer, the output of which is connected to the input of the low-noise amplifier, the output of which is connected to the input of the amplifier-converters of the receiving frequency, the output of which is connected with the input of the modem, the first and second outputs of which are connected respectively to the first and second inputs of the unit of amplifiers-converters of the transmission frequency, the control input of which is connected to the control output of the transmitting frequency synthesizer, the first output of the reference oscillator unit is connected to the input of the receiving frequency synthesizer, the control output of which is connected with the control input of the unit of amplifiers-converters of the receiving frequency, the second output of the reference generator unit is connected to the input of the transmitting frequency synthesizer, the first, second and third control inputs-outputs of the station control unit are connected to the control inputs-outputs, respectively, of the remote unit antenna control, modem and channel switch, the first, second and third inputs-outputs of the modem are connected respectively to the first station input-output of the channel switch, to the first and second inputs-outputs of the digital signal processing unit, the third and fourth inputs-outputs of which are connected respectively to the second and third station inputs-outputs of the channel switch, the output of the unit of amplifiers-converters of the transmission frequency is connected to the input of the power amplifier, the output of which is connected to the input of the duplexer, the first linear input-output of the channel switch is connected to the first input-output of the multiplexer of the combined communication systems, the second input - the output of which is connected to the first station input-output of the input board, the second, third and fourth linear inputs-outputs of the channel switch are connected respectively to the second, third and fourth station inputs-outputs of the input board, to the first, second, third, fourth and fifth linear the inputs-outputs of which are connected dy-outputs, respectively, of a connecting line (SL) for receiving / issuing channels at the C1-FL-BI interface, a fiber-optic communication line for receiving / issuing signals of a group flow to a consumer, a connecting line for receiving / issuing channels via an Ethernet interface, a two-wire communication line and communication lines for connecting with external subscribers.

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