RU2054819C1 - Optical-electronic space system for remote monitoring - Google Patents

Abstract

FIELD: radio engineering. SUBSTANCE: photo detecting circuits of optical-electronic converter 5, which is a part of optical-electronic receiving unit of low-orbit earth satellite, are separated into several stages. Digital information that is read from each stage is recorded to corresponding magnetic tape storage unit 9. information from storage units 9 is transmitted in series to radio transmitter 11 through commutator 10. Speed of reading is lesser than that of writing. additional decrement of information flow is achieved by additional reduction of redundancy in information flow compression unit 7. Low-orbit earth satellite transmits information through relay station of earth-stationary satellite to earth station. Satellite antenna and relay station antennas are designed as scanning phased antenna grills. EFFECT: increased reliability. 3 cl, 4 dwg

Description

 The invention relates to electronic equipment, in particular to systems for observing the Earth’s surface from space, and can be used to obtain a video signal of an optical or infrared image from an aircraft, for example, an artificial Earth satellite (AES) of an airplane, helicopter, when solving problems of researching natural resources Land and other economic tasks.

 Known optoelectronic digital space remote sensing system, placed on board the satellite and containing a series-connected unit for receiving video data, including a lens and an optoelectronic converter in the form of a photodetector, analog-to-digital converter (ADC), an information frame forming unit, and a storage device , a synchronizing pulse generator, a terminal device made in the form of a recorder with recording analog information on photographic film, then analyzed on the ground m processing station.

 The disadvantages of the known system include the impossibility of directly transmitting information to ground objects, which significantly reduces the speed of obtaining information by users, their high cost and low reliability of data acquisition. In addition, the use of the analog method of direct recording on board is not always justified due to the need for subsequent analog-to-digital conversion of information when processing data at a ground processing station.

 The closest in technical essence to the proposed one is the optoelectronic space remote sensing system, including a low-orbit satellite, having on its board an optoelectronic receiving part containing an optical input device, an optoelectronic converter with photodetector circuits, an ADC, an information frame forming unit, and a storage device (ZU), and the transmitting part, including a radio transmitter with an antenna, as well as a ground receiving station with an antenna.

 The known system allows to increase the efficiency of receiving and processing data in connection with the possibility of direct transmission of information to ground processing points, as well as to improve the quality of information transmitted in digital form.

 Its disadvantage is due to the fact that the remote sensing areas from which direct transmission of information to ground-based points is possible are limited to the satellite visibility zones from these points. An increase in the satellite orbit in order to expand these zones leads to a deterioration in resolution. The possibility of remote sensing outside the direct line of sight is significantly limited by the capacity of the memory, while the efficiency of the information received at the ground receiving points is also significantly reduced.

 The purpose of the invention is the increase in productivity (daily volume of information received from the satellite) for sections of the orbits lying outside the zones of direct visibility of the satellite from ground receiving points, as well as an increase in the speed of receipt of information from these sections of the orbits.

 The essence of the invention lies in the fact that in the optoelectronic space system of remote sensing, including a low-orbit satellite, having on board an optoelectronic receiving part containing an optical input device, an optoelectronic converter with photodetector circuits, an ADC, an information frame shaper, a memory and transmitting a part including a radio transmitter with an antenna, as well as a ground receiving station with an antenna, an additional repeater located at stationary satellite containing a receiving antenna in series, a low noise amplifier, a first frequency converter, an intermediate frequency amplifier, a bandpass filter, a second frequency converter, an output amplifier, a transmitting antenna, and also the first and second frequency drivers, the outputs of which are connected respectively to the second input of the first converter frequency and with the second input of the second frequency converter, and the inputs, respectively, with the first and second outputs of the master oscillator, in the optoelectronic reception a large part of the low-orbit satellite has a data stream compression unit, the inputs of which are connected to the ADC outputs and the outputs to the inputs of the information frame former, and the memory is made in the form of several magnetic tape drives containing tape speed switches, and the photodetector circuits of the optoelectronic converter are divided into several identical groups, the number of which is equal to the number of drives and the output of each of which is connected through the ADC, the information flow compression unit and the information frame shaper with the corresponding yuschim drive, and drives the outputs are connected to switch channels, the output of which is connected to the input of a radio transmitter, a ground receiving station is configured as a series-connected to an antenna radio flow information restoring unit and the playback unit and the registration information.

 In this case, the low-orbit satellite can be equipped with a direction finding receiver, which is connected to the transmitting antenna of the radio transmitter via the directional orientation control unit.

 In addition, the receiving and transmitting antennas of the repeater of the geostationary satellite can be made in the form of scanning active phased antenna arrays (AFAR).

 The introduction into the composition of the onboard equipment of a low-orbit satellite satellite a data stream compression unit and a set of magnetic tape-switched drives with outputs that can be switched with a tape speed can significantly reduce the information stream to be transmitted to the ground receiving station about the probed areas of the Earth’s surface, which allows the geostationary repeater to be introduced into the system AES and expand the zone with which it is possible to quickly transmit information to the line of sight low-orbit AES from geostationary go satellite. At the same time, the performance limitation due to the limited capacity of the memory is also removed.

 The implementation of the receiving and transmitting antennas on the low-orbit and geostationary satellite in the form of scanning AFARs can significantly improve the reliability of the system.

 Figure 1 shows the space system of remote sensing, General view; figure 2 is a structural diagram of the paired optoelectronic receiving and transmitting parts placed on board the low-orbit satellite; figure 3 is an electrical block diagram of the reception and processing of information from a ground station; figure 4 is an electrical block diagram of a repeater placed on board a geostationary satellite.

 Optoelectronic space remote sensing system (see figure 1) contains nikzoorbital satellite 1, ground receiving station 2 and geostationary satellite 3, which is located in the visibility zone of ground station 2.

 Optoelectronic receiving and transmitting parts (see figure 2), placed on board the satellite 1, contain an optical input device 4, an optical-electronic Converter 5, the photodetector circuit which is located in the focal plane of the optical input device 4 and is divided into N groups, ADC 6, information flow compression unit 7, information frame former 8, N tape drives 9, whose inputs are connected to N outputs of information frame former 8, a switch on N channels with a common output 10, radio transmitter 11 and transmitting antenna 12.

 The ground receiving station 2 (see FIG. 3) comprises a receiving antenna 13, a radio 14, a data flow recovery unit 15 and an information reproducing and recording unit 16.

 The repeater of the geostationary satellite 3 (see figure 4) contains a series-connected receiving antenna 17, a radio 18 including a low-noise amplifier 19 and a first (input) frequency converter 20, an intermediate frequency amplifier 21, a bandpass filter 22, a radio transmitter 23, including a second (output) ) a frequency converter 24 and an output amplifier 25, and a transmitting antenna 26. The repeater also includes a heterodyne frequency generating unit 27, including a master oscillator 28 and a first 29 and a second 30 frequency drivers. The outputs of the first 29 and second 30 shapers are connected respectively to the second input of the first converter 20 and to the second input of the second converter 24, and the inputs, respectively, to the first and second outputs of the master oscillator 28.

 In addition, the receiving 17 and transmitting 26 antenna of the repeater are made in the form of scanning AFAR.

 In addition, the satellite 1 is equipped with a receiver-direction finder 31 with an antenna 32, which is connected through the orientation pattern control unit 33 to the transmitting antenna 12 of the radio transmitter 11 (see Fig. 2).

 Space remote sensing system operates as follows.

When moving a low-orbit satellite 1, which performs the function of observation, above the Earth's surface, images of the observed objects move in the focal plane of the input optical device 4, where the photodetector circuits of the optoelectronic converter 5 are divided into N sections. From the elements of the photodetector circuits of each of the N sections, analogue signal samples are simultaneously taken and sent through parallel channels to the ADC 6. After conversion from the output of the ADC 6, the digital samples are sent to the compression unit of the information stream 7, where the digital information stream decreases by a factor of ₁ . From the information compression unit 7, the signals are sent to the information frame former 8, where overhead information is added to the observation information. From the output of the imaging frame information 7 information on N channels is fed to the corresponding drives on magnetic tape 9.

In the intervals between sessions of monitoring objects, digital information is sequentially read from drives 9 and directed through the switch 10 and radio transmitter 11. At the same time, reading is performed at a lower tape speed than writing, which allows to reduce the information flow in n ₂ Vap / read. times, where V _app write speed; V _count read speed.

In general, the flow of information from the optoelectronic converter 5 to the radio transmitter 11 decreases n ₁ .n ₂ .N times.

 In the radio transmitter 11, the received information is used to modulate the carrier frequency of the signal, then the required power gain, filtering, and corresponding matching with the antenna 12 are made. Antenna 12 emits a signal in the direction of the geostationary satellite with a repeater. To fine-tune the direction of the axis directional pattern of the transmitting antenna 12 of the satellite 1 in the conditions of movement of the satellite 1 and satellite 3 in the satellite 1 use the block 33 control the orientation of the radiation pattern and the receiver-direction finder 31 with the antenna 32 in the form of an active phased antenna array located in the same plane as transmitting antenna 12. According to the control signal of the receiver-direction finding device 31, a change in the direction of the axis of the radiation pattern of the transmitting antenna 12 is provided during the guidance and transmission of signals, which ensures a maximum the reliability of the signal transmission pir minimum power of the radio transmitter 11 with a highly directional transmitting antenna 12. The receiving antenna 17 of the repeater receives the signal, after which the signal passes through the low-noise amplifier 19, the first frequency converter 20, which is used to lower the carrier frequency, the intermediate frequency amplifier 21, a bandpass filter 22, the second frequency converter 24, the output amplifier 25, and enters the transmitting antenna 26, which emits a signal in the direction of the ground station 2. Reception The ground station antenna 13 receives a signal, which then passes sequentially through the receiver 14 and the information stream recovery unit 15, which performs the operation that is inverse to the compression of the information stream, after which it is output to the playback and recording unit 16.

In a specific example of the implementation of the remote sensing system, the photodetector circuits of the optoelectronic converter are divided into 8 groups, respectively, N 8 magnetic tape drives are used, differential pulse code modulation is used in the information flow compression unit, which compresses the information stream n ₁ 3 times, and the speed of reading information from tape drives is less than the write speed n ₂ 3 times. The total decrease in the flow of information from the ADC to the transmitter is 72 times.

Claims (3)

 1. OPTICAL-ELECTRONIC SPACE SYSTEM OF REMOTE SENSING, including a low-orbit artificial satellite (AES), having on its board an optoelectronic receiving part containing an optical input device, an optoelectronic converter with photodetector circuits, an analog-to-digital converter (information converter, ADC) , a storage device, and a transmitting part, including a radio transmitter with an antenna, as well as a ground receiving station with an antenna, characterized in that it is additionally introduced geostationary satellite placed in the visibility range of the ground station with a repeater containing a receiving antenna in series, a low-noise amplifier, a first frequency converter, an intermediate frequency amplifier, a bandpass filter, a second frequency converter, an output amplifier, a transmitting antenna, and also the first and second frequency drivers, outputs which are connected respectively to the second inputs of the first and second frequency converters, and the inputs, respectively, to the first and second outputs of the master oscillator ora, a data stream compression unit is introduced into the optical-electronic receiving part of a low-orbit satellite, the inputs of which are connected to the ADC outputs, and the outputs - to the information frame shaper inputs, and the storage device is made in the form of several magnetic tape drives containing tape speed switches, and the photodetector circuits of the optoelectronic converter are divided into several identical groups, the number of which is equal to the number of drives and the output of each of which is connected through the ADC, the compression unit of the information flow information and a shaper of the information frame with the corresponding drive, the outputs of the drives being connected to a channel commutator, the output of which is connected to the input of the radio transmitter, and the ground receiving station is made in the form of a receiver connected in series with the antenna, a data stream recovery unit, and an information playback and recording unit.  2. The system according to claim 1, characterized in that the low-orbit satellite is equipped with a direction-finding receiver with an antenna, which is connected through the directional orientation control unit to the transmitting antenna of the radio transmitter.  3. The system according to claim 1, characterized in that the receiving and transmitting antennas of the repeater are made in the form of scanning active phased antenna arrays.

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