RU2691759C1 - Information transmission system using radio and optoelectronic channels - Google Patents

Abstract

FIELD: radio equipment.SUBSTANCE: invention relates to radio engineering and can be used to transmit information to subscribers moving on trajectories in the area of direct visibility from each other. Information transmission system includes a GLONAS signal receiver, which output is connected to the motion parameter reception / transmission unit input, the first output of which is connected to the omnidirectional radio channel antenna, and the second output to the digital decision unit input, which output is parallel connected to control inputs of transmitting controlled phased antenna array and control unit of optical radiation direction of infrared laser, information input of which is connected to output of infrared laser unit, wherein output of UHF signal generation unit is connected to information input of transmitting controlled phased antenna array, receiving part includes receiving controlled phased antenna array and unit of controlled lenses, control inputs of which are combined and connected to output of digital decision unit, wherein input of photodetectors unit is connected to output of controlled lenses unit, and input of converter is connected to output of receiving controlled antenna array.EFFECT: technical result consists in expansion of functional capabilities of a system for transmitting command or communication information to a group of subscribers.1 cl, 1 dwg

Description

The invention relates to information transmission systems using electromagnetic radiation, whose parameters are modulated according to the law of transmitted information, and the simultaneous use of radio and opto-electronic transmission channels of information signals.

The closest analogue of the proposed information transmission system is a device that includes the transmitting and receiving part of the patent RU 2188510, 2002.

The transmitting part contains: a microwave (centimeter or millimeter) signal shaping unit loaded on a horn, an optical bandwidth generating unit loaded on an optical emitter (for example, a semiconductor IR laser). In addition, the transmitting part includes a combined (microwave optical) antenna constructed according to the Kasy-Kgren scheme. The antenna contains: a dichroic element, a microwave mirror, a combined (microwave - optical) mirror with a hole in the center, and an optical mirror. The combined mirror, on the one hand, has a coating with a maximum of the reflection coefficient at the frequency of the microwave transmitter, and on the other hand, a coating with a maximum of the reflection coefficient at the wavelength of the IR laser. A horn, dichroic element, three mirrors installed coaxially. A dichroic element is installed so that the optical radiation of the emitter passes through the holes in the mirrors.

The receiving part of the device consists of separate microwave and optical paths. The microwave path includes a receiving antenna constructed according to the Cassagren scheme, and formed by two mirrors, a microwave converter, a receiver and a device for extracting information. The optical path of the receiving part contains a lens lens, a photodetector and a device for extracting information.

This device effectively functions in the case of stationary placement on fixed objects. If it is necessary to work in the driving mode, it is very difficult to search and track a subscriber.

Therefore, in order to increase the functionality for organizing communication between objects in motion at different trajectories and speeds, an omnidirectional low-frequency radio channel is introduced into the system, through which navigation information is transmitted between subscribers, which allows targeting the directional patterns of narrow-beam antennas and the IR laser radiation to a mobile an object.

Each subscriber of the system includes in its structure: receiving and transmitting part. The receiver of the GLONASS signals, the motion parameters receiving / transmitting unit, the digital solver unit, the transmitting controlled antenna array, the control unit for the direction of optical radiation of the IR laser are entered into the transmitting part. The receiving controlled phased antenna array and the unit of controlled lens lenses are introduced into the receiving part.

The block diagram of the system is shown in FIG. one.

The transmitting part contains: the source of transmitted information (1), the output of which is connected in parallel to the inputs of the microwave signal conditioning unit (2) and the IR laser unit (3), the block (4) of the GLONASS signal receiver, the output of which is connected to the input of the unit (5) reception / transmission of motion parameters, the first output of which is connected to the antenna of the omnidirectional radio channel, and the second output to the input of the digital decision unit (6). The output of the microwave shaper unit (2) is connected to the information input of the transmitting controlled phased antenna array (UFAR) (7), the control input of which is combined with the control input of the IR radiation direction control unit (8), the information input of which is connected to the output of the unit ( 3) IR-laser and connected to the output of the digital decision unit (6).

The receiving part contains: receiving UFAR, block (10) a converter, the output of which is connected to the first input of the block (11) of information extraction.

The optical path of the receiving part contains a block (12) of controlled lens lenses, the controlled input of which is combined with the controlled input of the UVAR (9) and connected to the output of the digital decision unit (6). The information output of the ULO (12) is connected via the block (13) of photodetectors and the receiver (14) of optical signals to the second input of the block (11) of information extraction.

The system operates as follows. From the source (1), the transmitted information is fed simultaneously to the inputs of the block (2) of the microwave signal generation and the block (3) of the IR laser of the optical range. From the block (4) of the GLONAS receiver, the navigation information is fed to the input of the block (5) of the motion parameters from where it is transmitted from the transmitting output to the frequency known to the subscribers of the system, and from the information output goes in digital form to the crucial block (6).

It is assumed that the frequency of the microwave generator in the radio range is tens of GHz. The output of the microwave signal conditioning unit (2) is connected to the information input of the transmitting UFAR (7).

In turn, to form a transmission through the optical channel, the input of the IR laser unit is connected to the output of the information source unit (1), and the output to the information input of the IR laser direction control unit (8).

In order to form the direction of the UVAr radiation patterns (7, 9) and set the direction of emission and reception of the optical signal from the output of the decision block (6), the generated command information is sent to the control inputs of blocks 7, 8, 9, 12.

The received microwave signal is fed through UFAR (9) to the converter, from where to the first input of the device (10) the signal extraction. The received optical signal enters the unit (12) of the controlled lens lenses, from where the photo detector unit (13) and the optical signal receiver (14) are fed to the second input of the signal extractor (10), where a comparison and corresponding processing is carried out to accept about the correctness of the adopted information decisions.

The search for technical solutions in related fields of technology did not allow the authors to identify the distinctive features of the proposed technical solution, which meets the criterion of "inventive step".

Thus, from the above it follows that the proposed system of information transmission using radio and opto-electronic channels ensures the achievement of a positive technical effect - the possibility of reliable information transfer between objects operating on different trajectories and speeds under the condition of direct visibility.

Literature:

1. Patent RU 2188510, 2002.

Claims (1)

The system of information transmission using radio and opto-electronic channels, containing in the transmitting part a source of transmitted information, the output of which is connected in parallel to the inputs of the microwave signal conditioning unit and the IR laser unit, while in the receiving part a converter whose output is connected to the first input block information selection, the second input of which is connected to the output of the receiver of optical signals, the input of which is connected to the output of the block of photodetectors, characterized in that the receiver signal is entered in the transmitting part in GLONASS, motion parameters receiving / transmitting unit, digital deciding unit, transmitting controlled antenna array, IR radiation laser optical direction control unit, the output of the GLONASS receiver is connected to the input of the motion parameters receiving / transmitting unit, the first output of which is connected to the omnidirectional antenna radio channel, and the second output to the input of the digital decision unit, the output of which is connected in parallel to the control inputs of the transmitting controlled phased antenna array and the control unit is directed Optical radiation of the IR laser, whose information input is connected to the output of the IR laser unit, while the output of the microwave signal conditioning unit is connected to the information input of the transmitting controlled phased antenna array, the receiving controlled phased antenna array and the unit of controlled lens lenses are inserted into the receiving part, control inputs of which are combined and connected to the output of a digital solver unit, while the input of the photodetector unit is connected to the output of the unit of controlled lens lenses, and the input The converter is connected to the output of the receiving controlled antenna array.

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