RU2686456C1 - Radio communication system with mobile objects using radio-photon elements - Google Patents

Abstract

FIELD: radio engineering and communications.SUBSTANCE: invention relates to data exchange systems and can be used for implementation of information exchange via radio channels between ground systems (GS) and sources (recipients) of information located on aerial mobile objects (MO). Technical result is achieved due to introduction into onboard antenna-feeder paths of non-distorting phase-frequency and amplitude-frequency characteristics of nodes on radio-photon elements, controlled by onboard computer and distribution of n onboard wide-range antennae, and n onboard wide-band radio-frequency receiving-transmitting modules into four groups, each of which generates its beam pattern in the corresponding hemisphere shifted relative to neighboring hemispheres by 90°. For this purpose, the radio communication system with the use of radio-photon elements additionally includes not distorting the shape and spectrum of radio signals nodes on radio-photon elements, which are managed and controlled by two-way links connected to the corresponding inputs/outputs of the onboard computer.EFFECT: high noise-immunity of the radio communication system and longer range of stable communication.1 cl, 2 dwg

Description

The invention relates to data exchange systems and can be used to implement information exchange over the radio channels between ground complexes (NK) and sources (receivers) of information located on air mobile objects (SW).

In a radio communication system with mobile objects [1], during movement, air objects that are within the radio horizon, communicate with the ground communications system using the omnidirectional radiation of the onboard antenna of the radio signals of the transmitter. Messages received by the ground communications complex from the Air-Earth channel through the data transmission equipment (FDA) are sent to the computer of the operator’s automated workplace (APM), where, in accordance with the exchange protocol accepted in the system, the address received in the message is identified with its stored addresses of moving objects. If the address of the moving object coincides with the information stored in the list about the location, software movement parameters and the state of its sensors, it is displayed on the screen of the ground workstation monitor. In the computer calculator AWM on the basis of PC solves the problem of providing continuous radio communication with all N software. When at least one of the software goes beyond the limits of the radio horizon or when approaching the border of a stable radio communication zone, one of the software is defined programmatically, which is assigned by the message repeater. According to the results of the analysis of the location and motion parameters of the rest of the software, the optimal ways of delivering messages to the remote software from the radio horizon are determined. A message from the NC through a serial chain consisting of (N-1) software can be delivered to the Nth software. To do this, the NK in the shaper of the type of relayed messages in the pre-defined bits (header) of the transmitted codogram lay the number of the software assigned by the repeater and the addresses of air objects that provide the specified message traffic. Messages received using an omnidirectional on-board antenna on a mobile object are analyzed in the message type analysis block. After analysis, the issue of sending data on a bi-directional bus to the control system of a moving object or retransmitting it to a neighboring software is decided.

Shapers of the type of relayed messages allow for the exchange of digital data through the operator-pilot channel (CPDLC) instead of the existing voice information. They are intended to select the elements of the permission / information / request messages that correspond to the adopted speech phraseology, and to type arbitrary text. Displaying the dialed and received messages is carried out on the software data recording unit and the AWS NK monitor, respectively.

Messages from the receiver outputs of the signals of the global navigation satellite systems GLONASS / GPS are recorded in the memory of the ground and on-board computer with reference to the global time and are used to calculate the navigation characteristics and motion parameters of each software. Navigation messages received from NK from all software are processed in the calculator and displayed on the monitor of the AWS.

However, the above system has the following disadvantages associated with the circular shape of the radiation pattern in the azimuth of the onboard antenna, as a result of which the noise immunity decreases and the stable communication range decreases and the communication losses increase during moving object maneuvers.

In addition, the equipment of the system consists of hardware blocks with low instrumental reliability, which during the flight can fail and affect flight safety.

A known radio communication system with moving objects [2]. It differs from the above-mentioned system in that it additionally introduces backup ground and airborne communications, including long distance communication radio station. The radio communication system with mobile objects [2] incorporates N mobile objects connected by the air-to-air MB channels with each other, the air-to-earth MB channels of radio communication and the air-to-earth CMS channels of M separated from each other ground complexes, which are interconnected and with the corresponding control centers of air traffic control and airlines through the ground data transmission network.

The ground-based communication complex includes ground-based antennas MB and DKMV ranges associated respectively with radio stations MB and DKMV ranges connected by two-way communications through the data transmission equipment to the first input / output of the computer of the automated workplace, the second input / output of which is connected to the control input of the radio DFMS the third input / output is connected to the input / output of the terrestrial communication system, the first input is connected to the receiver of the signals of navigation satellite systems (GLONAS / GPS), the second input is connected to the control panel of the automated workplace, the third input - to the driver of the type of relayed messages, and the output - to the monitor of the automated workplace.

The mobile object is equipped with an on-board communication complex consisting of omnidirectional MB and DKMV on-board antennas connected to MB and DKMV radio stations, respectively, which are connected by two-way communications through the onboard data transmission equipment to the first input / output of the onboard computer, the second input / output which is connected to a bidirectional bus of the control system of a moving object, the third input / output - to the analyzer of the type of received messages, the fourth input / output - to the control input / output DCMB radio stations of the range, inputs to onboard sensors, driver of the type of retransmitted messages, receiver of signals from navigation satellite systems, output to the data recording unit.

The disadvantages of the analogue are associated with the distortion of the shape of the radiation pattern in azimuth, elevation angle when the airborne antennas are shaded by the roll and pitch by the glider of air objects, as a result of which the range of stable communication decreases sharply.

A radio communication system with mobile objects is known [3], which has in its composition M territorially separated ground complexes and N mobile objects interconnected by the Air-to-Air communication channels of the MB range, and by means of the Air-to-Earth radio channels of MB and DKMV ranges - with M ground complexes. NCs are interconnected via a terrestrial data network, through which continuous data exchange is provided. Each mobile object contains an onboard computer, the first input / output of which is connected to a bidirectional bus of the mobile object management system. The terrestrial complex contains terrestrial antennas of the MB and DCMB bands, respectively, associated with the ground radio stations of the MB and DCMB bands, which are connected by two-way communications through the ground-based data transmission equipment to the first input / output of the computer of the automated workstation. The second input / output of the AWS is connected to the input / output of the TC for the terrestrial data transmission network, the third input / output is connected to the shaper of the type of relayed messages, the first input is connected to the receiver of signals of navigation satellite systems (GLONASS / GPS), the second input is to the AWM control panel and the output is to the workstation monitor. At each mobile object there are b pairs of interconnected onboard omnidirectional broadband antenna-feeder devices and wideband radio frequency modules, the inputs / outputs of which are connected to the physical layer module (MFP) in accordance with the reference model of open systems interaction. Inputs / outputs of the MFP are connected to a computing communication module consisting of serially connected bidirectional links of the channel level module, router module (MM) and interface module (MI). The MI inputs are connected to the onboard sensors, the receiver of the navigation satellite system, the output is connected to the data acquisition unit, and the first input / output is connected to the onboard analyzer of the type of received messages, the second input / output is connected to the onboard driver of the type of retransmitted messages, the third input / output is onboard computer. In addition, in each ground complex, the fourth input / output of the computer of the automated workplace is connected to the first control input of the ground radio station of the HF range, and the fifth input / output of the computer of the automated workplace is connected to the first control input of the ground radio station MB of the range, where b is required to receive specified reliability parameters; the number of pairs of interconnected on-board omnidirectional wide-band antenna-feeder devices and wide-range radio frequency modes lei.

The disadvantages of the analogue are associated with the distortion of the shape of the radiation pattern in azimuth, elevation angle due to shading of the on-board antennas during roll and pitch by the metal glider of aerial objects, as a result of which the range of stable communication decreases sharply compared with direct (optical) visibility. In addition, the power losses of transmitted radio signals, their distortion due to the nonlinearity of the phase-frequency and non-uniformity of the amplitude-frequency characteristics in a given frequency range in the transmitting and receiving paths also reduce the range of stable communication and reduce noise immunity.

The closest in purpose and most essential features is a radio communication system with moving objects [4], which is adopted as a prototype. In this system, M territorially separated ground communication complexes and N mobile objects are interconnected by the air-to-air communication channels of the MB range, and by the air-to-ground communication channels of the MB and the KFB of the M bands to the ground-based systems. Ground complexes are interconnected and with external subscribers through the terrestrial data network. Each mobile unit contains n onboard wideband antennas connected directly to n onboard wideband radio frequency receiving and transmitting modules. The physical layer module is connected by two-way communications through a serially connected data link layer module, a router module and an interface module to an onboard computer that has a bidirectional interface of the onboard mobile object management system. The inputs of the interface module are connected to the onboard sensors and the receiver of the global navigation satellite system signals. The output of the onboard computer is connected to the data recording unit. The second input / output of the interface module is connected to the onboard analyzer of the type of received messages, the third input / output is connected to the onboard shaper of the type of retransmitted messages. Each ground-based complex contains ground-based antennas MB and DKMV bands associated respectively with ground-based radio stations MB and DKMV bands connected by two-way communications through ground-based data transmission equipment to the first input / output of the workstation computer (AWP). The second input / output of the AWS is connected to the input / output of the TC for the terrestrial data transmission network, the third input / output is connected to the shaper of the type of relayed messages, the fourth and fifth inputs / outputs are connected to the second inputs / outputs of the ground radio stations MB and DCMB, respectively. The first input of the ARM calculator is connected to the ground receiver of global navigation satellite systems signals, the second input is connected to the AWP control console, and the output is connected to the AWS monitor. On each software, n phase shifters are connected bilaterally as corresponding inputs / outputs n onboard wideband radio frequency transmit-receive modules and n inputs / outputs of the physical layer module. The control inputs / outputs of n phase shifters are connected by two-way links to the corresponding n inputs / outputs of the onboard computer.

The disadvantages of the prototype are the reduction of the noise immunity of the system and the reduction of the range of stable communication associated with the distortion of the pattern in azimuth, elevation and shading by the on-board antennas during the roll and pitch of the air objects directed to the called subscriber. In addition, the power losses of the transmitted radio signals in the radio frequency cables of the antenna-feeder paths, their distortion due to the non-linearity of the phase frequencies and the unevenness of the amplitude-frequency characteristics in a given frequency range in the transmitting and receiving paths also reduce the range of stable communication and reduce noise immunity.

The technical problem to which the invention is directed, is to increase the noise immunity of the system and increase the range of stable communication by introducing into the onboard antenna-feeder paths that do not distort the phase-frequency and amplitude-frequency characteristics of the nodes on the radiophotonic elements controlled by the on-board computer and the on-board distribution wide-band antennas, and n onboard wide-range radio frequency transceiver modules into four groups, each of which forms its own Agram of directionality in the corresponding hemisphere shifted relative to the neighboring by 90 °.

This technical result is achieved by the fact that in a radio communication system with mobile objects on radiophotonic elements, consisting of M territorially separated ground communication complexes and N mobile objects interconnected by the Air-Air communication channels of the MB range, and the Air-Earth radio communication channels "MB and DKMV bands with M terrestrial complexes that are interconnected and with external subscribers through a terrestrial data network, each mobile object contains n side wide-band antennas, n b a wideband radio frequency transceiver module, a physical layer module connected by two-way communications through a serially connected channel-level module, a router module and an interface module to an on-board computer that has a bidirectional interface of an on-board mobile control system, n phase shifters connected by two-way communications to n inputs / the outputs of the physical layer of the module, while the control inputs / outputs of n phase shifters are connected by two-way connections to the corresponding connected n inputs / outputs of the onboard computer, the inputs of the interface module are connected to the onboard sensors, the global navigation satellite system receiver, the output of the interface module is connected to the data acquisition unit, the second input / output of the interface module is connected to the onboard analyzer of the type of received messages, the third input / output - to the onboard shaper of the type of relayed messages, an optical transceiver is additionally inserted, connected by two-way communications from one side to the inputs / outputs of n phases rotators, and on the other hand, to the inputs / outputs of 2n fiber-optic communication lines, which are connected by two-way communications, respectively, to four group optical transceivers, whose inputs / outputs are through four groups n of onboard wide-range radio frequency receiving and transmitting modules connected to the four inputs / outputs groups of on-board wideband antennas, control inputs / outputs of the optical transceiver and four group n optical transceivers are connected bilaterally to the corresponding vuyuschim inputs / outputs onboard computer, the number n of nodes is selected based on the destination system.

In the optical transceiver, the radiation of the first laser through the first optical splitter enters the inputs for the carrier frequency n of the first optical modulators, the information inputs of which receive the output signals of n phase shifters, and the outputs of the first optical modulators are connected to the corresponding inputs of the first optical switch, the outputs of which are connected to inputs n the first fiber optic links, the outputs of the second fiber optic link via the second optical switch are connected to the inputs of four parallel branches of the optical transceiver, to Waiting for which consists of sequentially connected photodetectors of the i-th group and low-pass filters (LPF) of the i-th group, the LPF outputs of the i-th group are connected to the inputs of n phase shifters, the outputs of the first FOCLs are connected to the corresponding inputs of four parallel branches of the group optical transceivers each of which consists of series-connected optical switches for receiving the i-th group, photo-detectors of the i-th group, the low-pass filter of the i-th group, the output of the low-pass filter of the group of optical transceivers are connected to the corresponding inputs Some groups of on-board wideband radio-frequency transceiver modules, whose outputs through the corresponding optical modulators of the i-th group of each optical transceiver are connected to the corresponding inputs of the optical switch for the transmission of the i-th group, whose outputs are connected to the inputs n of the second VOLS, laser radiation i- group of each optical transceiver through the optical coupler of the i-th group is fed to the inputs for the carrier frequency of the optical modulators of the i-th group, control outputs of the first laser and l the i-th group of servers are connected to the corresponding inputs of the onboard computer, the control signals of the first and second optical switches, the optical switches for receiving and transmitting the i-th group are connected to the corresponding control outputs of the on-board computer, the number of groups i is four, the total number of nodes in four groups is equal to n, and the number of nodes in each group is determined by the purpose of the on-board communication complex.

The block diagram of the inventive radio communication system with software using radiophotonic elements is shown in FIG. 1, where the following notation is entered:

1 - ground communication complex (NK); 2 - terrestrial data network; 3 - airborne communication complex of a mobile object (PO); 4 - entrances / exits of ground communication complex 1 with external subscribers; 5 - onboard computer; 6 - onboard sensors; 7 - the on-board receiver of the global navigation satellite system signals, for example, GLONASS / GPS with an antenna; 8 - data recording unit; 9 - on-board analyzer of the type of received messages; 10 - onboard shaper type of relayed messages; 11 - computational communication module (IUD); 12 - interface module with onboard equipment (MI); 13 - routing module (MM); 14 - channel level module (MKU); 15 - physical layer module (MFP) (digital signal processing); 16 - four groups of n onboard wide-range radio frequency transmitting-receiving modules (STD RPPM); 17 - four groups of n onboard wide-band antennas (SM A); 18 — bidirectional bus of a moving object control system; 19 - n phase shifters; 20 - optical transmitter; 21 - 2n fiber optic communication lines (FOCL); 22 - four group optical transceivers; 23 - air-to-air and air-to-ground communication channels of the MB and DKMV bands.

The proposed system of radio communication with software using radiophotonic elements contains M territorially separated ground complexes 1 and N of mobile (air) objects equipped with airborne complexes 3 communications interconnected and with NK 1 radio channels 23 communications Air-Air and Air-Earth »MB and HF ranges. NC 1 is combined with each other and ground users who are not listed in FIG. 1, using the ground network 2 data transmission and I / O 4 NK 1.

A block diagram of an optical transceiver 20 connected with four groups of fiber-optic communication lines 21 in an amount of 2n with the equipment of four group optical transceivers 22 of the inventive radio communication system with mobile objects is shown in FIG. 2

FIG. 2 as part of the optical transmitter 20 are indicated:

24 - the first optical splitter; 25 - n first optical modulators; 26 - the first optical switch; 27 - second optical switch; 28 - d photodetectors of the fourth group; 29 - d low-pass filters (LPF) of the fourth group; 30 - the first laser.

FIG. 2 as part of each group optical transmitter 22 are indicated:

31 - four groups of optical switches at the reception; 32 - four groups of photodetectors; 33 - four groups of low-pass filters; 34 — laser of the fourth group; 35 - optical splitter of the fourth group; 36 - d optical modulators of the fourth group; 37 - optical switch to transmit the fourth group.

FIG. 2 are also indicated:

38 - output signals of n phase shifters; 39 - control output of the first laser 30; 40 - d outputs of the low-pass filter 29 of the fourth group of the optical transceiver 20; 41 - control signals nodes 26 and 27; 42 - input signals d onboard broadband radio frequency receiving-transmitting modules 16 of the fourth group; 43 - output control of the laser 34 of the fourth group; 44 - control signals nodes 31 ₂ ; 45 - control signals nodes 31 ₁ ; 46 - control signals nodes 31 ₃ ; 47 - control signals nodes 31 ₄ and 37 ₄ ; 48 - outputs of the first, second, third and fourth group low-pass filters.

Moreover, n SMA 17 are connected directly, for example, by the soldering method, to n SMs of RPMT 16. By integrating onboard wide-range radio frequency receiving and transmitting modules 16 and n SMA 17 into the design of mobile objects, for example, on the fuselage aircraft [5, 6], which allows you to organize through the use of four groups of nodes 16, 17, each working in its own hemisphere of space, and radiophotonic elements 20, 21, 22, a radio communication system with a circular communication zone in azimuth. The ability to transmit radio signals of various ranges using radio-photonic elements has been tested experimentally, they are based on advanced radio-electronic means [5, 6].

Phase shifters 19 and other nodes most sensitive to changes in climatic and mechanical conditions can be installed, for example, in the manned compartment of a moving object near the onboard computer 5, usually remote from nodes 16 and 17. Phase shifters 19 are connected to the corresponding inputs / outputs of module 15 a physical layer that has a two-way digital interface with a 14-level module connected to a two-way digital interface with a routing module 13 connected to a two-way digital interface 12 interfaces with onboard equipment, the inputs of which are connected to the onboard sensors 6, the receiver of 7 signals of global navigation satellite systems. The output of the MI 12 is connected to the data recording unit 8, the second input / output is connected to the onboard analyzer 9 of the type of received messages, the third input / output is connected to the onboard driver 10 of the type of retransmitted messages, the fourth input / output is connected to a bi-directional interface 18 with an on-board software control system, not shown in FIG. one.

FIG. 2, for example, also shows a block diagram of one of the optical transmitters of the 22nd group (fourth). The indices standing in the designation of nodes in FIG. 1 and FIG. 2, characterize the following: the first group index number (hemispheres of space into which the main beam of the on-board wide-band antennas 17 of each group is directed), the second index is the node number in the group, for example, in the first group - and nodes, in the second - b nodes, in the third - from the nodes, in the fourth - d nodes. The sum of the indices a + b + c + d - n. The number of nodes in each group is determined by the purpose of the on-board communication complex 3. For example, if there are less than 20 subscribers in each hemisphere of space, the numbers a, b, c, d can be chosen equal to four.

Optical switches 26 and 27, 31 and 37, controlled by the onboard computer 5, are used in the following procedures: when redistributing radio signals in case of failure of one of the optical modulators 25 or 36, fiber-optic communication lines 21, while excluding transmission of fiber-optic signals 21 (decrease in energy potential), with a small distance between subscribers (power adaptation), with an increase in energy potential when the subscriber is in sectors where adjacent hemispheres intersect (diagrams ION adjacent bead group wide-range antenna 17).

The input signal processing paths 42 for d onboard wide-range radio frequency receiving and transmitting modules 16 are shown for simplicity in the example of the sequence of operations in the fourth group. The signals are processed in each of the d optical modulators 36 of the fourth group, the second input of which, through the optical splitter 35 of the fourth group, receives the optical signals of the laser 34 of the fourth group. From output 43, the control signals of laser 34 of the fourth group are removed. Optical signals are combined and distributed in the optical switch 37 to the transmission of the fourth group and through the corresponding fiber optic cable 21 are sent to the second optical switch 27. Switches 37 and 27 are controlled using the commands 47 ₄ and 41 ₄ from the onboard computer 5. Then, after passing through a series from d low-pass filters 29 _{4 of the} fourth group, d photodetectors 28 _{4 of the} fourth group in the form of a video signal arrive at the outputs 40 ₄ for phase shifters.

In the first, second and third groups, operations similar to those specified in the fourth group are carried out. The output signals 38 n of the phase shifters are modulated in each optical modulator 25, the second input of which through the second optical splitter 24 receives the optical signals of the second laser 30. From the output 39, control signals of the second laser 30. and through the corresponding fiber-optic links 21 arrive at the optical switches 31 to receive four groups. The switches 31 are controlled by commands 44, 45, 46, 47 from the onboard computer 5. Then, after passing a serial chain consisting of d photodetectors 32, low-pass filters 33 in the form of a video signal arrive at the outputs 48

The ground complex 1 of the system for operation with the on-board communication complex 3 may contain, for example [4], terrestrial antennas MB and DKMV bands associated with terrestrial radio stations MB and DKMV bands and connected by two-way communications through the ground data transmission equipment to the first transmitter / workplace (AWP). The second input / output of the ARM calculator is connected to input / output 4 of NC 1 for information consumers, the third input / output is connected to the shaper of the type of relayed messages, the fourth and fifth inputs / outputs are connected to the second inputs / outputs of ground radio stations MB and DCMB, respectively. The first input of the ARM calculator is connected to the ground receiver of global navigation satellite signals, the second input is connected to the AWP control console, and the output is connected to the AWS monitor.

The proposed system of radio communication with software using radiophotonic elements provides data transmission in the MB range in relay mode from NC 1 using onboard communication complexes 3 along the chain of the first software connected in series, the second software and further to the Nth software, and data transmission from N- This software on NC 1 carried out in reverse order. Data transmission in the HF range from the on-board communication complex 3 of the software is carried out to that ground complex 1, the reception quality of which is the best or acceptable for a given mobile object. Terrestrial network 2 data transmission is connected by two-way interfaces to each of the M distributed geographically NK1. Thus, the terrestrial network 2 of the data communication via information interaction unites all NK 1 with each other and ensures the connection of each NK 1 with the terrestrial users of the radio communication system.

In the absence of interference, the data exchange algorithm, for example, in the simplex mode in accordance with the TDMA protocol in the inventive system of radio communication with software, consists in the following operations:

- each NC 1 is assigned to the time interval of 1-2 hours, the active HMW frequency from the set of allowed frequencies of the HF communication from the general list of frequencies, optimal for radio propagation conditions and electromagnetic compatibility for this time interval, different from the active frequencies of all other NC 1 communication systems . Bring the number of the active frequency together with the time interval of its activation to each NC 1 via the terrestrial network 2 data transmission, thus implementing the frequency division multiple access protocol (FDMA) (frequency adaptation);

- each time-resolved HF frequency is determined by its own time shift of the first frame of the Multiple Access Protocol with Time Division (TDMA) relative to the leading frame, bound, for example, by 00:00: 00 sec: universal coordinated UTC time in order different frequencies were radiated by NC 1 in spaced apart time slots to reduce the time of the quality analysis of the markers conducted by each airborne communication complex 3 of the moving object;

- develop the MB and DCMB communication system tables, in which they indicate the list of M ground communication complexes 1 with their addresses, coordinates, modes of operation supported by them and a set of allowed frequencies with the indicated shifts of the first frame of each frequency;

- bring the system tables MB and HF communication to all NK 1 and all airborne communication complexes 3 of the mobile object via the terrestrial data network 2 and radio channels of communication;

- carry out on each NC 1 packet data exchange through the terrestrial network 2 data transmission with users of the system, as well as with other (M-1) NC 1;

- implement in NK 1 data exchange protocols in the HF and MB channels of the physical layer (modems-codecs), channel and network layer, for example, in accordance with ARINC 618, ARINC 631, ARINC 635, ARINC 750, DO-224, ED-108 in modes HFDL, VDL-1 (ACARS), VDL-2, VDL-4 and others;

- split to provide HF communication due to the use time of each HF frequency channel into time frames for the implementation of the Protocol multiple access channel with time division (TDMA). In the first slot of each frame, a marker signal is emitted, containing, for example, receipts for all messages received by NK 1 from different on-board communication systems 3 in the previous two frames, the active frequencies of two adjacent NK 1, the database version (system table), the slot usage assignments from the 4th to the 13th of the current frame and slots of the 2nd and 3rd next frame, as well as the channel busy flag. At the end of each frame, for each slot of the next frame, for example, the assignment of its use is performed for transmission from NK 1 or for transmission from a specific on-board communication complex 3 of a mobile object upon its preliminary request to an access slot, or for transmission from any side of software in random access ;

- carry out the exchange of packet data "Air-Earth" on each active MB and HF channel channel with multiple access at a given intensity of the message flow;

- choose the best communication frequency and register the on-board communication complex 3 of the moving object at selected frequencies MB and DCMB channels at each mobile object according to the results of quality assessment of received signals of markers of different NC 1 for each frequency range;

- initiate in the MB and DCMB range on each moving object a frequency search procedure when the equipment is turned on or after the line is disconnected, if the onboard communication complex 3 cannot detect markers from ground complex 1 at the current frequency anymore. After auto frequency selection and registration on the new channel, packet data is exchanged, for example, in the TDMA mode with NK 1, on which the on-board communication complex 3 of the mobile object is registered, until the quality of the MB and DCF of the radio channel exceeds the allowable level. When the quality of MB and HF radio channel is deteriorating below the permissible level, a new MB and HF radio channel and the corresponding NC 1 are selected, regardless of the location of NC 1, and the on-board communication complex 3 of the mobile object is registered on the new MB and DCMV radio channel (adaptation over space);

- implement in the on-board complex 3 communications of the movable object and NC 1 the following procedures for managing the MB data link connectivity;

- form in the onboard end systems of the on-board communication complex 3 of the mobile object (5-18) a packet message containing the recipient's address and the sender's address (software address), and is transmitted through the interface module 12 to the onboard module 13 of the router, where it is packaged as, for example ISO 8208 packet and then transmitted to the module 14 of the data link layer, where it is converted into a data link layer packet of the data transmission network containing the check sequences calculated using the cyclic redundancy check code (CRC). The received messages are transmitted to the module 15 of the physical layer, where, for example, adaptation operations with time are carried out [4].

A radio signal formed for transmitting a HF or MB, for example, multipositional phase shift keying (M-PSK, M = 2, 4 or 8) from the output of the physical layer module 15 with the required phase specified by the corresponding nodes 19, using control signals from the onboard computer 5 through no distorting the shape and spectrum of radio signals, nodes 20, 21, 22 are fed to the inputs of pieces of SM DMSPPM 16 in the first group, b pieces in the second group, from pieces in the third group, d pieces in the fourth group, where it is amplified to the required level power, then through the corresponding airborne broadband azone antenna 17 to MB 23 or HF radio channels are transmitted to the ground complex 1, which is registered on-board communication complex 3 of the movable object. Several simultaneously operating nodes 16 and 17 in each group are necessary, for example, in order to form a desired pattern in a given direction using an onboard computer 5 and to eliminate the influence of interference on data transmission.

In the presence of interference, the following procedures are performed:

- determine the direction to the source of interference by scanning the space using the control signals of the onboard computer 5, nodes 19, 16 and 17 in the time intervals when there is no data exchange;

- the coordinates of the mobile object are determined by the previously known location and motion parameters of the source of interference using methods known in radiolocation [7] and the corresponding messages are transmitted to NC 1 (through it and the ground network 2 data transmission to other NC 1 and mobile objects);

- if the situation allows, then the transfer of nodes 15 to another reserve operating frequency is carried out or the mode of forming a pseudo-random tuning of the operating frequency is activated;

- at the same time using the control signals of the onboard computer 5, nodes 19, 26, 27, 31, 37, the shape of the radiation pattern in space is corrected to ensure minimal gain in the direction of the interferer;

- to increase the reliability of data transmission with the help of nodes 5, 11, 16, 17, 19, 26, 27, 31, 37, a narrow beam (needle) beam is formed in the corresponding hemisphere of space in the direction of the subscriber with whom the session is being conducted or to be conducted.

On NC 1, by analogy with [4], a CKBB or MB radio signal through the corresponding antenna, ground station, data transmission equipment, is fed to the input of the transmitter ARM, where it is packaged into a packet intended for transmission, for example, using the X.25 protocol over the ground network 2 data transmission and NK 1 to consumers of information. When transmitting a packet, for example, according to the X.25 protocol via the terrestrial network 2, data transmission in the opposite direction (from the information consumer) via NC 1 to the software is first processed in the computer workstation, transmitted through the data transmission equipment, the corresponding radio stations and antennas on the air.

The radio signal formed on NK 1 is transmitted via radio channel 23 to the on-board communication complex 3 of the mobile object, where it passes through SD 17 and SD 194, non-distorting the shape and spectrum of radio signals, nodes 20, 21, 22 the corresponding input of the MFP 15, where it is demodulated, descrambled, de-interlaced, decoded with forward error correction, and given to MKU 14, where it is checked for the presence of errors not corrected by the decoder; input MM 13 for p eobrazovaniya a packet destined for transmission via MI 12 for airborne users (blocks 5, 8, 9) or to the bus 18.

In the process of exchanging packet data in the MB range with ground users on each on-board communication complex 3 of the mobile object, the packet message is formed in the on-board final system, for example, the computer navigation system [8, 9], and operations similar to that discussed above are performed.

The MB band communication frequencies specified in the frequency support list are active. On each NC 1, at the active communication frequency, the signals of the markers emit at a specified interval, according to the system operation protocol. Signals of the system table (database version), active frequencies of two neighboring NK 1, slot assignments for the new frame, receipt for all messages from the on-board communication unit 3 of the moving object received in the previous frame, channel busy flag are entered into the signals of the CKMV markers. . The first slot is retracted to the radiation of the marker with NC 1.

In the radio communication system, navigation and other data are transmitted on the MB radio link between the ground complex 1 and the on-board communication complex 3 of the mobile object, which are located within the radio horizon NK 1. Upon request, the location information motion parameters of the moving object selected for communication. In the absence of data exchange, control signals from the onboard computer 5 and nodes 16, 17, 20, 21, 22, and 19 are provided by scanning beams in the working frequency band with the rays of the pattern of nodes 17 in the required hemisphere of space to determine the direction to sources of signals and interference. When interference is detected using control signals from the onboard calculator 5 and nodes 16, 17, 20, 21, 22, and 19, a minimum of the gain of the total pattern is formed in this direction, organized with the help of the onboard calculator 5 and nodes 20, 21, 22 and 19 In the simplex communication mode in node 16, the receiving device is blocked for the duration of the transmission, and in the duplex communication mode, the system operates at different frequencies. In the ground complex 1, the tasks of providing constant stable radio communication with all N on-board communication complexes 3 of the mobile object are performed, and based on the information about the exact location of all the on-board communication complexes 3 of the mobile object and the parameters of their movement, they carry out the memory and storage of transmitted and received messages.

When going beyond the NK 1 radio horizon, at least one airborne communication complex 3 of a mobile object or approaching it to the border of a stable radio communication zone, the ground complex 1 determines programmatically one of the software that is assigned by the first message transponder by the address part of the encodonogram transmitted to it. With a constant change in range between software and NK 1, any of N N software whose location is known and optimally relative to NK 1 and all other software can be assigned as a repeater for a certain time. By analyzing the location and motion parameters of the remaining software, the optimal ways of delivering messages to a mobile object remote from NK 1 beyond the radio horizon are determined — the recipient of the message using the narrow form of the radiation pattern formed by group 16, 17 of the i-th group using the onboard computer 5 and the corresponding phase shifters 19 A message from NC 1 through a sequential chain, consisting, if necessary, of several (from 1 to (N-1)) software, can be delivered to the required on-board communication complex 3 of the mobile object - tter information. To do this, on NC 1, in the predefined bits of the transmitted codogram, the address of the software assigned by the first repeater is laid, if necessary, the addresses of other mobile objects — repeaters providing the specified message traffic, and the address of the recipient. Received and processed on the software in the devices 17, 16, 20, 21, 22, 19, 15, 14, 13, 12 and 5 messages are passed to the block 9 analysis of the type of messages. If the message is intended for this on-board communication complex 3 of the mobile object, then after analysis, the issue of sending data on the bi-directional bus 18 to the software control system or transmitting the message in the relay mode to the neighboring software is solved by generating the corresponding pattern in space by transmitting from phase shifters 19 through nodes 25, 26, 21, 31, 32, 33 to nodes 16 and 17 of the radio signals of the required form. To avoid collisions, the number of bits in the transmitted message is minimized and the data is retransmitted sequentially in time.

For each onboard complex 3 of the connection of a moving object, the trajectory of movement of neighboring software, if necessary, is displayed on the screen of the onboard block 8 of the data recording. The trajectories of oncoming or associated software with which a potentially conflicting situation is possible, with the help of marks characterizing the previous location of moving objects, are also displayed on the screen of the onboard data recording unit 8. As software moves, obsolete marks are erased. During the pre-flight preparation of each moving object, using the interface 18, the necessary data is loaded into the onboard computer 5 in the form of a system table containing lists of addresses, coordinates of ground complexes and their assigned communication frequencies. In NC 1, the system tables are loaded via the terrestrial network 2 data transmissions.

The information received on the on-board communication unit 3 of the moving object is displayed on the screen of the data recording unit 8 in the form of alphanumeric characters or in the form of points and vectors. Messages in accordance with the exchange protocol are queued to the appropriate urgency category. In the on-board computer 5, the time of "aging" of information is determined, and if the message was not transmitted to the communication channel for a period of time equal to the "aging", then it is "erased" and a request to send a new message is sent.

In order to minimize the likelihood of collisions of random access, not to interfere with the current transmission of the message, procedures are used, for example, as in VDL-2 mode, Multiple Access to Carrier Listening Channel (CSMA). To do this, in the physical layer modules 15 and the data link layer 14 of the on-board communication complex 3 of the moving object, before transmitting each message, the channel is monitored (carrier busy monitoring) to detect the preamble, header, or useful part of the messages. The prepared message with the software is transmitted only when the radio channel is free. In order to postpone the time of communication of different mobile objects and NK 1 in time, when, after the channel is busy, all correspondents found that the radio channel is free, in module 14 of the channel level of the software they create pseudo-random delays in the transmission of messages from moving objects (for each software has its own) and from NC 1. On each of the software, the end time of the carrier frequency signal in the radio channel and synchronization pulses are used to initialize the calculation in the module 14 of the channel level of the own transmission time interval and within this interval using the physical layer module 15, nodes 19, 20, 21, 22, 16, and 17 of the airborne software complex 3, transmit their own data packet.

Messages about the location of the software and its movement parameters from the receiver outputs of 7 signals of global navigation satellite systems, for example, GLONASS / GPS, are recorded in the memory of the onboard computer 5 with reference to the global time [8, 9, 10]. The exact synchronization of slots used for data exchange between subscribers of the system, and their planned use for transmission is known to each user in relation to surrounding users with known coordinates. The control of the channel access protocol on each moving object is performed in the data link layer module 14.

In the calculator 5, the location data of the software is used to calculate the navigation characteristics and motion parameters of the moving object selected for communication. Depending on the specified time interval for issuing software position messages to NC 1, the transmitter 5 in the calculator 5 generates a corresponding message with reference to the global time when the coordinates of the software are measured. This time is used in NC 1 for the well-known operation of constructing extrapolation marks from software [7]. Thanks to the ground network 2 data transmissions, which unites all M NK 1, information from remote over long distances (up to 4-6 thousand km and more) software, equipped with devices 14, 15, 16, 17, 19 20, 21, 22 , with the control function of the HF radio link and radiation patterns in the corresponding hemisphere of space, even in a difficult interfering environment, all NK 1 radio communication systems are communicated, although remote software communicates with only one NK 1, the quality of markers is the best for the software at a given time. During the execution of a moving object maneuver (roll, pitch, etc.) using on-board computer 5, taking into account the location of the software and the called subscriber, control signals are generated that allow you to hold the main lobe of the directional pattern of the onboard communication complex 3 on the called subscriber, thus preventing loss of communication.

On the software in module 15, the onboard computer 5 and modules 14, 13, 12 of the computer communication module 11, the received marker signals from all ground complexes 1 are automatically analyzed at all frequencies and the best frequency is selected, for example, by the maximum criterion measured by the demodulator when receiving the entire ratio packet signal / disturbance. According to the signal-to-interference ratio measured at the selected frequency in the module 15 in the module 14 of the computational communication module 11, the maximum allowable data transfer rate is chosen, as well as the type of modulation and coding. The signal-to-interference ratio is estimated by all NK 1 and the system software each time a message packet is received. The value of the selected maximum allowable data transfer rate is reported to the opposite side in the form of the recommended data transfer rate. In the onboard modules 15, 14 software, known algorithms of high-speed adaptive modems designed to work in multipath channels can be used, for example, a demodulation algorithm using an equalizer with a decisive feedback, a suboptimal receive Viterbi algorithm as a whole with elementwise decision making under multipath conditions, maximum likelihood algorithm with identification of current channel parameters (channel impulse response) based on stochastic approximation methods and others. All used noise immunity reception algorithms must meet the requirements specified, for example, in ARINC 635 [11].

Thus, each of the onboard communication systems 3 software can communicate on several operating frequencies, known to all participants in the movement. The lists of selected frequencies vary depending on the season, and the working frequency for each NC 1 of the list of selected frequencies is activated every hour or two hours of the day. When moving, a moving object makes contact, choosing for communication that NC 1, the propagation conditions of radio waves for communication with which at a given time are optimal. At the same time, it is not necessary that the selected NC 1 was the nearest. The communication channel between the software and the ground-based consumer (source) of information compiled in this way will usually include the on-board software of the software, NK 1 and the terrestrial data network 2. As soon as the quality of the communication channel 23 degrades below the permissible level, on board using the 5, 14 and 15 software nodes, a new probabilistically optimal working frequency is selected based on the analysis of radio propagation conditions and a new NK 1 corresponding to it. ) communication reliability when exchanging data with software located at NK 1 at distances from several hundred to (4-6) thousand kilometers.

The system is synchronized based on the use of a single global universal time coordinated time (UTC) by all participants of the movement, received from the existing objects of the global navigation satellite system using receivers 7.

For the interfacing of ground complexes 1, end users and software, the ground data network 2 and inputs / outputs 4 of NC 1 are used. It can be implemented by known methods, for example, during network interconnection of NC 1 through packet switching centers in accordance with the X.25 protocol [ four]. Connections between NC 1 and X.25 packet switching centers (routers) can be provided via dedicated or leased communication channels. They will allow broadcasting a message addressed by a terrestrial user of a specific software to that ground complex 1 on which this software is “registered” and where the optimal conditions for receiving HFKW are provided at a given time. The radio communication system with the software operates in an automatic mode without operator intervention on the selected frequencies from the list of frequencies assigned during communication planning. When transmitting data via the HF link, each frequency channel is used, for example, using a time division multiple access protocol. The access time to the frequency channel is divided into frames, each of which, in turn, is divided into intervals (slots). Uses short message packets with a duration shorter than a slot. The transmission of NK 1 broadcast marker at each active frequency has its offset relative to the beginning of the lead frame indicated in the system table.

The main advantage of using the introduced on software nodes 25, 26, 21, 31, 32, 33 together with devices 19, 17, 16, 15, 14, 13, 12, 5, based on the principles of integrated modular avionics, presented, for example, in [12 -14] and the programmable radio method, consists in the highest level of configurability and flexibility of protection against interference provided by the architecture. The highest level of configurability implemented in the proposed equipment of a moving object is fully flexible modulation types, line level protocols, networks, algorithms for determining the direction to the source of interference and control of radiation patterns in four hemispheres of space and user functions, the ability to change the modulation type, signal bandwidth and center frequency, the directivity pattern of nodes 17 according to the program in a wide range [9]. Thanks to the claimed system, it becomes possible to create (using the onboard computer 5 and the corresponding modules 15, 14 with a wide-band radio frequency receiving and transmitting module 16) a wide-range programmable adaptive communication complex of a new type, working in conjunction with radiophoton nodes 20, 21, 22 and optimally assembled in to the sides of the movable object onboard wide-band antennas 17, forming a circular radiation pattern in azimuth, both in the MB and in the KFW bands. The software physical layer module 15 contains high-speed ADCs and DACs with a large dynamic range and is based on high-performance signal processors that digitally implement most of the functions of the physical layer, for example, frequency conversion, filtering, frequency synthesis, radio reception. The MFP 15 is designed to generate and process radio signals at the physical layer (encoding / decoding, interleaving / deinterleaving, scrambling / descrambling data, modulating / demodulating, implementing adaptive methods for transmitting and receiving signals, band-pass filtering, frequency conversion, etc.). Module 14 of the data link layer provides protocols for selecting communication frequencies, drawing up a communication link, exchanging line level data and accessing the Air-to-Earth subnetwork, exchanging software routing module 13, ensuring fail-safe operation, and other procedures. Routing module 13 provides for the distribution of Air-to-Earth messages received via the MB and DCMB channels, for example, in the form of ISO 8208 packets, to end users on board and in the opposite direction. Module 12 of the interfaces provides all the necessary interfaces with the onboard equipment, for example, using the ARINC 429, ARINC 664, ARINC 646 and other protocols.

When operating in the interfering environment with the help of phase shifters 19, controlled by the onboard computer 5, several separate narrowly directed (needle) shapes are formed in each of the four hemispheres of space (when transmitting data through the repeater) and several frequencies are used simultaneously in each beam in the direction of the subscribers: NK 1 or the selected mobile object with which to conduct a communication session. Then, depending on the location of the subscriber (ground complex with known coordinates or information received on the Earth-Air or Air-Air radio channels about the location and motion parameters of the corresponding software), this beam is due to the application of control signals from the onboard computer 5 to phase shifters 19 and the nodes 26, 27 and 31, 37 in the corresponding side wide-band antennas 17, placed on all sides along the surface of the moving object, form the main lobe of the radiation pattern towards the subscriber. The number of nodes 16 and 17 in each hemisphere of space is selected taking into account the formation of the required shape of the radiation pattern in a given sector or with the possibility of transferring the rays in azimuth to the repeater. Due to this, new capabilities of the radio communication system appear and several advantages are achieved at once:

1. It is possible to increase the range of stable communication by reducing the power losses of radio signals in the "long" onboard antenna-feeder paths when introducing nodes on radio photon elements controlled by an onboard computer, and distributing n onboard wide-band antennas 17 and n on-board wide-band radio-frequency receivers transmitting modules 16 into four groups (hemispheres of space), each of which forms its own radiation pattern in the corresponding hemisphere shifted relative to the beam them by 90 °, and forming a total for the two hemispheres directivity pattern for concentrating energy capacity in the selected direction.

This is due to the fact that by increasing the antenna gain in the direction of the selected subscriber, much less energy is needed to form and emit radio signals in one beam, since a conventional omnidirectional antenna radiates energy in a wide sector.

2. Improving the noise immunity of the system is ensured by the fact that when there are more than two serially connected nodes 16 and 17, and excluding distortions of the form of radio signals and their spectra during transmission over radiophotonic elements, it becomes possible to autocompensate (separate) the interference by programmatic methods of spatial-time signal processing by changing the shape directivity patterns in the direction of the jammer, namely, reducing its gain to zero [15].

3. There are no communication losses due to shading of the onboard antennas in the direction of the called subscriber by the metal glider of air objects during roll and pitch, since the onboard wide-range antennas and the onboard wide-range radio frequency receiving and transmitting modules are located on all four sides of the movable object.

4. Taking into account the broadband radio photon nodes 20, 21, 22, the range of transmitted radio signals can be extended, not only in the meter and decameter range, but also in the centimeter and millimeter, for which the radio-electronic part and the design of nodes 16 and 17 can be changed by analogy with [16] .

5. The concept of separating the equipment for synthesizing frequencies, generating radio signals and receiving-transmitting modules, antennas allows reducing the degree of the impact of climatic conditions and increasing the stability of the system characteristics.

Nodes, channels and tires 1-19, 23 are the same with the prototype. SD 17 and modules 16, 19, 20, 21, 22, 15, 14 together with the onboard computer 5 integrate the functions of MB and DCMB radio adaptive stations, data transmission equipment (codec, modem) with software coding) with the possibility of introducing new modes of operation of the modules programmatically via the bus 18, the onboard computer 5 and the corresponding serially connected modules 12 and 13 included in the computing module 11 of the communication. Computational communication module 11 (can be performed, for example, on the ADSP-21060 chip), which is part of the software, provides functional interaction with on-board devices 5, 7, 8, 9, 10 and 15 and on-board sensors 6 (events). Devices 20, 21, 22 and their nodes 24-37 can be performed on serial samples [5, 6, 16].

As antennas 17, for example, light flat ribbon antennas glued through a dielectric to a “grounded” metal surface of the fuselage or a conductive plate can be used, which will reduce the number of protruding surfaces retracted to the antenna on the moving object, and therefore improve its aerodynamic characteristics increase speed and reduce fuel consumption. The brand of tape and dielectric materials for antennas is determined by the characteristic impedance, frequency range, and other requirements [17, 18].

At the time of filing of the application, algorithms of functioning and software fragments of the claimed radio communication system have been developed.

Literature:

1. RF patent №44907.

2. RF patent №52290.

3. RF patent №68211.

4. RF patent №2518014 (prototype).

5. https://fpi.defence.ru/article/fpi-sozdaet-radiofotonnie-raclari-kotorie-smogut-obnaruzhit-bespilotniki/

6. MB Mityashev. To the implementation of radiophotonic technologies in AFAR radar systems. // Bulletin of SibSUTI. 2015. №2. Pp. 178-190.

7. D.S. Kontorov, Yu.S. Golubev-Novozhilov. Introduction to radar systems engineering. - M .; Ow. Radio, 1971, 367 p.

8. B.I. Kuzmin. “Digital telecommunication networks and systems”, part 1 ICAO CNS / ATM. Moscow St. Petersburg: NIIER OJSC, 1999, 206 p.

9. A.V. Keystovich, V.R. Milov. Types of radio access in mobile communication systems. Textbook for universities - M .: Hotline - Telecom, 2015. - 278 p.

10. GPS - global positioning system. - M .: PRIN, 1994, 76 p.

11. Guide to the HF data link (Doc9741 - AN / 962). First edition. - ICAO, 2000, 148 p.

12. RTCA / DO-297. IMA design guidelines and review of its certification. 2005.

13. ARINC 651. Guidelines for the development of integrated modular avionics. 1991

14. ARINC 653-1. Standard avionics application software interfaces. 2003

15. S.A. Metelev, Yu.V. Shishkin. The principle of construction of a two-channel spatial signal separator and interference with preliminary orthonormalization of input processes // Izv. universities. Radio Physics. - 2000. - T. 43. - №2. - p. 130-143.

16. Belousov A.A., Volkhin Yu.N., Gamilovskaya A.V., Dubrovskaya A.A., Tikhonov E.V. On the application of methods and means of radiophotonics for processing signals of the decimeter, centimeter and millimeter wavelength ranges // Applied photonics. 2014. №1. Pp. 65-86.

17. RF patent №2516868.

18. RF patent №2627686.

Claims (2)

1. Radio communication system with mobile objects using radiophotonic elements, consisting of M territorially separated ground communication complexes and N mobile objects interconnected by the Air-Air communication channels of the MB range, and the Air-Earth radio communication channels of the MB and DKMV bands with M terrestrial complexes, which are interconnected and with external subscribers through a terrestrial data network, each mobile object contains n onboard wide-band antennas, n on-board wide-band radio-frequency n Receiving-transmitting module, a physical layer module connected by two-way communications through a serially connected channel-level module, a router module and an interface module to an onboard computer that has a bidirectional interface of an on-board mobile control system, n phase shifters connected by two-way communications to the physical module I / O level, while the control inputs / outputs of n phase shifters are connected by two-way connections to the corresponding n inputs / outputs of the onboard computation the module interface inputs are connected to the onboard sensors, the global navigation satellite system receiver, the interface module output is connected to the data acquisition unit, the second input / output of the interface module is connected to the onboard analyzer of the type of received messages, the third input / output is connected to the onboard driver of the relayed type messages, characterized in that it introduced an optical transceiver connected by two-way communications on the one hand to the inputs / outputs of n phase shifters, and on the other hand - to the inputs / outputs of 2n fiber-optic communication lines, which are connected by two-way communications, respectively, to four group optical transceivers, the inputs / outputs of which are connected through four groups of n onboard wideband radio frequency receiving and transmitting modules to the inputs / outputs of four groups of n onboard wideband antennas, control inputs / outputs of the optical transceiver and four group n optical transceivers are connected by two-way connections to the corresponding inputs / outputs of the boards second calculator, the number n of nodes is selected based on the destination system. 2. Radio communication system with mobile objects using radiophotonic elements according to claim 1, characterized in that in an optical transceiver, the radiation of the first laser through the first optical splitter enters the inputs for the carrier frequency n of the first optical modulators, to the information inputs of which the output signals of the n phasers are fed and the outputs of the first optical modulators are connected to the corresponding inputs of the first optical switch, the outputs of which are connected to the inputs n of the first fiber optic cable, the outputs of the n second fiber optic cable through The second optical switch is connected to the inputs of four parallel branches of the optical transceiver, each of which consists of series-connected photodetectors of the i-th group and low-pass filters (LPF) of the i-th group, the outputs of the low-pass filter of the i-th group are connected to the inputs of n phase shifters, and outputs n the first FOLs are connected to the corresponding inputs of four parallel branches of a group of optical transceivers, each of which consists of series-connected optical switches for receiving the i-th group, photo-detectors of the i-th group ppy, i-th group low-pass filter, low-pass-band output of group optical transceivers are connected to the corresponding inputs of four groups of on-board wide-range radio-frequency transceiver modules, the outputs of which are connected through the corresponding optical modulators of the i-th group of each optical transceiver to the corresponding inputs of the optical switch for transmission i group, the outputs of which are connected to the inputs of the n second fiber, the laser radiation of the i-th group of each optical transceiver through the optical splitter of the i-th group The sensor enters the inputs for the carrier frequency of the optical modulators of the i-th group, the control outputs of the first laser and the l-th group lasers are connected to the corresponding inputs of the on-board computer, the control signals of the first and second optical switches, optical switches for receiving and transmitting the i-th group connected to the corresponding control outputs of the onboard computer, the number of groups i is equal to four, the total number of nodes in four groups is equal to n, and the number of nodes in each group is determined by the assignment of bortovog complex communication.

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