RU121613U1 - SYSTEM OF INTELLECTUAL PROCESSING OF DATA OF A TEAM-MEASURING COMPLEX - Google Patents

Abstract

The system of intelligent data processing of the command and measuring complex, containing a module for receiving data from a spacecraft, the information and synchronization inputs of which are the first information and synchronization inputs of the system, while the information input of the data reception module of the spacecraft is designed to receive data from sounding outer space or the earth's surface, and the synchronizing input of the spacecraft data receiving module is intended to receive synchronizing signals for entering space or earth surface sensing data into the spacecraft data receiving module, the module for integrating signals for recording and reading data from the system database server, the address output of which is the system address output, the first synchronizing output the module for integrating signals for writing and reading data from the system database server is the first synchronizing output of the system, designed to issue control signals on the input of the first interrupt channel of the system database server, and the second synchronizing output of the module for integrating the signals for writing and reading data from the system database server is the second synchronizing output of the system intended for issuing control signals to the input of the second interrupt channel of the system database server, the first modification module addresses of writing and reading data from the database of the system server, the control input of which is the first control input of the system, intended for receiving signals for issuing data, the information output of the first module is modified

Description

The utility model relates to the field of computer engineering, in particular, the system of intelligent data processing of the command-measuring complex.

Space sensing, which has been developing rapidly in recent decades, has provided the earth sciences with new opportunities for exploring the earth's surface. Intelligent analysis of measurement information is used to identify hidden patterns or patterns between variables that characterize the results of any processes in technical or natural systems, including when measurements are represented by large amounts of data.

Sensing methods can be passive when using natural reflected or secondary thermal radiation of objects on the Earth’s surface due to solar activity, and active methods using stimulated radiation of objects initiated by an artificial source of directed action.

The sounding data obtained from the spacecraft are characterized by a high degree of dependence on the transparency of the atmosphere. Therefore, spacecraft use multichannel equipment of passive and active types that record electromagnetic radiation in various ranges.

The quality of data obtained as a result of remote sensing depends on their spatial, spectral, radiometric and temporal resolution. To create accurate maps based on remote sensing data, a transformation that eliminates geometric distortion is needed. A snapshot of the Earth’s surface with an apparatus pointing exactly down contains an undistorted image only in the center of the image. With a shift to the edges, the distances between the points in the image and the corresponding distances on the Earth are increasingly different.

Known technical solutions to the problem (1, 2).

The first known technical solution includes a spacecraft, a space segment and a ground segment, performing the tasks of the space program and connected to the onboard control complex, the flight control center is connected by two-way communication with the data reception and transmission system (1).

The disadvantage of this solution is the low speed of the system, due to the fact that the processing of all measurement information is carried out in the flight control center, which leads to a large investment of time.

Another technical solution is known, containing a space segment consisting of three orbital constellations, a command-measuring system included in the ground segment, including ground-based technical means, means of a communication system and data transmission of flight control centers (2).

The last of the above technical solutions is closest to the described technical solution. Its disadvantage also lies in the insufficiently high speed, due to the fact that the search for data necessary to identify sensing objects is carried out throughout the database system.

The purpose of the utility model is to increase the system performance by eliminating the need to search for reference digital descriptions of sensing objects throughout the system database.

This goal is achieved by the fact that in a known system containing a module for receiving data from a spacecraft, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, while the information input of a module for receiving data from a spacecraft is designed to receive sounding data from outer space or the surface of the earth, and the synchronizing input of the data receiving module of the spacecraft is designed to receive synchronizing signals for entering data of undulating outer space or the surface of the earth into a module for receiving data from a spacecraft, a module for integrating write and read signals from a system database server, the address output of which is an address output of the system, the first synchronizing output of a module for integrating write and read signals from a system database server is the first synchronizing system output intended for issuing control signals to the input of the first interrupt channel of the system database server, and the second sync the lowering output of the integration module of the write and read data signals of the system database server is the second synchronizing output of the system designed to issue control signals to the input of the second interrupt channel of the system database server, the first module to modify the addresses of the write and read data of the system server database database, the control input of which is the first control input of the system designed to receive signals for data output, the information output of the first address modification module is written and reading the database data of the system server is connected to the first information input of the module for integrating the write and read data of the system database server, the first and second synchronizing inputs of which are connected to the first and second synchronizing outputs of the first module for modifying the write and read addresses of the system server database data, and a second module for modifying the write and read addresses of the database data of the system server, the control input of which is the second control input of the system, In order to receive signals for data output, the information output of the second module for modifying the write and read addresses of the system server database data is connected to the second information input of the system for recording and reading data integration module of the system database server, the third and fourth synchronizing inputs of which are connected to the first and second the synchronizing outputs of the second module for modifying the addresses of writing and reading data from the database of the server of the system, the module for receiving data from reference digital descriptions of objects sensing, the information output of which is the information output of the system, intended for issuing digital descriptions of sensing objects to the information input of the system server, a module for selecting reference addresses of recordings of reference digital descriptions of sensing objects is introduced, the information input of which is connected to the first information output of the spacecraft the synchronizing input of the module for selecting reference addresses of records of reference digital descriptions of sensing objects is connected to the first synchronizing input of the system, the module for maintaining the database of reference digital descriptions of sensing objects, the information input of which is connected to the first information output of the module for selecting reference addresses of recordings of the reference digital descriptions of sensing objects, the synchronizing input of the module for maintaining the database of reference digital descriptions of sensing objects is connected to the synchronizing output of the module selection of reference addresses of recordings of reference digital descriptions of sensing objects, information mode output For maintaining a database of reference digital descriptions of sensing objects, it is connected to the information input of a module for receiving data of reference digital descriptions of sensing objects, the synchronizing input of which is connected to the synchronizing output of a module for maintaining a database of reference digital descriptions of sensing objects, a module for identifying data of sensing objects, one information input of which is connected with the second information output of the spacecraft data receiving module, another information input of the ide module The data identification of sensing objects is connected to the information output of the module for receiving data of reference digital descriptions of sensing objects, and the synchronizing input of the module for identifying data of sensing objects is connected to the synchronizing output of the module for maintaining the database of reference digital descriptions of sensing objects, and the knowledge base data sampling control module, whose information input is connected to the second information output of the module for selecting reference addresses of records of reference digital descriptions of objects sounding, the synchronizing input of the knowledge base data sampling control module is connected to the synchronizing output of the reference selection module of reference addresses of records of reference digital descriptions of sensing objects, the counting input of the knowledge base data sampling control module is connected to the first clock output of the sensing objects data identification module, the first output of the data sampling control module the knowledge base is connected to the counting input of the module for maintaining the database of reference digital descriptions of sensing objects, and the second output d, the knowledge base data sampling control module is connected to the first installation input of the module for maintaining the database of reference digital descriptions of sensing objects, the second installation input of which is connected to the second clock output of the module for identifying data of sensing objects, and the installation output of the module for maintaining the database of reference digital descriptions of sensing objects is connected with the installation inputs of the modules for receiving data from the spacecraft and controlling the selection of data from the knowledge base, respectively, while the clock output of the sensing object data identification module is connected to the synchronizing input of the first module for modifying the write and read addresses of the system server database data, and the second output of the knowledge base data sampling control module is connected to the synchronizing input of the second module for modifying the write and read addresses of the system server database data .

The invention is illustrated by drawings, where Fig. 1 is a structural diagram of a system, Fig. 2 is a structural diagram of a module for selecting reference addresses of records of reference digital descriptions of sensing objects, Fig. 3 is a structural diagram of a control module for fetching knowledge base data, Fig. 4 is a block diagram of a module for maintaining a database of reference digital descriptions of sensing objects, FIG. 5 is a block diagram of a module for identifying data of sounding objects, and FIG. 6 is a block diagram of modules for modifying recording addresses and counts data scavenging of the system server database, Fig. 7 is a structural diagram of a driver of a reference address of a database of a system server; Fig. 8 is a structural diagram of a module for integrating write and read signals of a system database server data.

The system (Fig. 1) contains a module 1 for receiving data from a spacecraft, a module 2 for selecting reference addresses of records of reference digital descriptions of sensing objects, a module 3 for managing sampling data of a knowledge base, a module 4 for maintaining a database of reference digital descriptions of sensing objects, a module 5 for identifying object data sensing, module 6 for receiving data of reference digital descriptions of sensing objects, the first 7 and second 8 modules for modifying the addresses of writing and reading data from the database of the system server, module 9 for integrating catch recording and reading data server database system.

Figure 1 shows the information 10, synchronizing 11, the first 12, and 13 control inputs of the system, as well as information 14, address 15, the first 16 and second 17 synchronizing outputs.

Module 1 (Fig. 1) of receiving data from a spacecraft is made in the form of a register having information 10, synchronizing 11 and installation 20 inputs, as well as first 21 and second 22 information outputs.

Module 2 (figure 2) identification of reference addresses of selection of reference addresses of records of reference digital descriptions of sensing objects contains a memory unit 40 made in the form of read-only memory, a decoder 41, elements 42-44 And, the first 46 and second 47 delay elements. The drawing shows informational 48 and synchronizing 49 inputs, as well as informational 50.51 and synchronizing 52 outputs.

Module 3 (FIG. 3) of the knowledge base data sampling control comprises a register 52, a counter 53, a comparator 54, a delay element 55. The drawing shows the information input 56, the synchronizing input 57, the counting input 58 and the installation input 59, as well as the first 60 and second 61 clock outputs.

Module 4 (Fig. 4) for maintaining a database of reference digital descriptions of sensing objects comprises a memory unit 30, a counter 31, OR elements 32, 33, delay elements 34, 45. The drawing shows information 64, synchronizing 65, counting 66 and installation inputs 67, 68, as well as information 23, synchronizing 24 and installation 25 outputs.

Module 5 (Fig. 5) for identifying data of sensing objects comprises a comparator 72 and a delay element 73. The drawing shows information 74, 75 and synchronizing 76 inputs, as well as the first 77 and second 78 outputs.

Module 6 (Fig. 1) of receiving data of reference digital descriptions of sensing objects is made in the form of a register having information 26 and synchronizing 27 inputs, as well as information 14 output.

Modules 7, 8 (Fig. 6) of the modification of the write and read addresses of the system server database data comprise the system server database address forming unit 119, a counter 120, a comparator 121, an adder 122, a trigger 123, a group of 124 AND elements 125- 129 OR, delay elements 130-135. The drawing shows the synchronizing 114 and control 115 inputs, as well as information 139, the first 140 and second 141 synchronizing outputs.

Shaper 119 of modules 7 and 8 (Fig. 7) of the reference address of the system server database contains a memory unit 105 made in the form of read-only memory, registers 106, triggers 107, elements 108-109 AND, element 110 OR, elements 111-113 delays . The drawing shows a synchronizing input 114, as well as information 118 and synchronizing outputs 116, 117.

Module 9 (Fig. 8) of the integration of the write and read signals of the system database server data contains a group of 36 OR elements and elements 37-38 OR. The drawing shows the first 81 and second 82 information, the first 83, second 84, third 85 and fourth 86 clock inputs, as well as address 15, first 16 and second 17 clock outputs.

We will consider the operation of the system by the example of its use for processing the data received at the input of the ground command-measuring complex when receiving data from spacecraft.

The data of the spacecraft enter the information input 17 of the system in the form of a codogram having the following structure:

THE CODE THE CODE Sensing object identifier of the selected type Digital description of the sensing object of the selected type

This codogram is entered into the register of module 1 by a synchronizing pulse supplied to input 22 from the synchronizing output of the ground-based data receiving complex. From the output 170 of module 1, the sensing object identifier code is sent to the information input 48 of module 2, from where it is issued to the input of the decoder 41.

The decoder 41 decodes the code of the identifier of the sensing object and prepares the signal path from input 49, opening one of the elements 42-45 I. For definiteness, we assume that a high potential is received at one input of the element 42 I.

In parallel with this, the synchronizing pulse from the input 22 of the system enters the input 49 of module 2, where it is delayed by element 46 for the duration of entering the input codogram into module 1 and the operation of decoder 41, and then polls the states of elements 42-45 I.

Given the fact that only one AND element 42 will be open at one input, then passing through this And element, the clock pulse is fed to the read input of a fixed memory cell of a read-only memory (ROM) 40, where the reference address code of the recordings of reference digital descriptions of sensing objects is stored and the number similar entries in module 4 of the system knowledge base.

The structure of the codogram stored in a fixed memory cell of the ROM has the following form:

THE CODE THE CODE Reference address for knowledge of reference digital descriptions of sensing objects of the selected type The number of records of reference digital descriptions of sounding objects of the selected type

The code of the reference address of the records of the reference digital descriptions of sensing objects of this type from the ROM 40 is read out 50 and then through the input 64 of the module 4 it goes to the information input of the counter 31, and the code of the number of records is read to the output 51 and then through the input 56 of the module 3 register input 52.

In parallel with the described process, the same read pulse from the output of element 46 of module 2 is delayed by the delay element 47 for the duration of reading the contents of a fixed cell in ROM 40 and then from output 52 it goes to the synchronizing input 65 of the counter 31 of module 4 and to the synchronizing input 57 of the register 52, fixing they have the corresponding read codes.

The address code from the output of the counter 31 is issued to the address input of the memory unit 30. Simultaneously with entering the reference address code of the records of reference digital descriptions of sensing objects of this type into the counter 31 of module 4, the synchronizing pulse from input 65 passes through the OR element 33, is delayed by the element 34 while the address code is being entered into the counter 31, and then it goes to the reading input of the memory block .

This signal reads the first record from the cell of the reference address of the records of the reference digital descriptions of sensing objects of this type and through the output 23 of the module 4 it enters the information 26 input of the module 6, into which it is entered by the synchronizing pulse from the output 24 of the module 4 to the input 27 of the module 6 .

Thus, in module 6 there will be the content of the first record of the reference digital descriptions of sensing objects of this type, and in module 1 at this point in time there is already a digital description of the sensing object received at the system input.

The digital description of the sensing object, received at the input of the system, from the output 22 of module 1 goes to the information input 74 of module 5, and the content of the first record of the reference digital descriptions of sensing objects of this type from the output of module 6 goes to another information input 75 of module 5.

In parallel with this process, the synchronizing pulse from the output 24 of the module 4 is fed to the synchronizing 76 input of the module 5, where it is delayed by the element 73 while the code is entered into the module 6, and then it goes to the synchronizing input of the comparator 72.

According to this clock pulse, the comparator 72 compares the input codes and if the digital description of the sensing object located in module 6 does not coincide with the digital description of the sensing object of module 1, then a signal appears at the output 77 of module 5, which is fed to the input 58 of module 3, where -first, it passes to the counting input of the counter 53, which counts the number of scanned records from the knowledge base of module 4.

Secondly, the same impulse is delayed by the element 55 for the duration of the counter 53 operation, and then it goes to the synchronizing input of the comparator 54, on one information input of which from the output of register 52 a code of the number of records of reference digital descriptions of sensing objects of this type is supplied, and on the other information input code of the number of scanned records from the output of the counter 53.

If the number of scanned records recorded by the counter 53 is less than the number of records in the knowledge base of module 4, then an impulse appears at the output 60 of module 3. This pulse through the input 66 of module 4 passes to the counting input of the counter 31, increasing by one the reference address of the knowledge base of module 4.

In addition, the same pulse passes through the OR element 33, is delayed by the element 34 for the response time of the counter 31, and is again fed to the read input of the memory unit 30. This signal again reads the contents of the next memory cell at the newly formed address, issues it to the information input 26 of module 6 and enters into module 6 with a synchronizing pulse from output 24 of module 4 to synchronization input 27 of module 6.

The described process of reading the reference digital descriptions of the sensing objects of this type from module 4 and comparing them with the digital description of the sensing objects of this type in module 1 will continue until all entries in the knowledge base of module 4 are viewed. This fact will be recorded by the comparator 54 module 3 by issuing a signal to output 61.

From the output 61 of module 3, the signal, firstly, enters the input 67 of module 4, where the OR element 32 passes, and then it goes both to the installation input of the counter 31, resetting it to its original state, and through the output 25 of module 4 to the installation inputs modules 1 and 3.

If module 5 fixes the fact that the input codes are equal, which will indicate that the input digital description of the sensing object corresponds to the reference digital description of sensing objects of this type, then a signal appears at the output 78 of module 5, which, firstly, is fed to the clock input 114 module 7, starting the procedure for documenting a data array with a digital description of the sensing object.

To this end, the input signal is fed to one of the inputs of the elements 108, 109 AND, the other inputs of which are controlled by the potentials coming from the direct and inverse outputs of the trigger 107. However, only the element 108 And will be open on one input, since one of its inputs is supplied high potential from the inverse output of the trigger 107, which is in the initial state.

As a result, a synchronizing pulse from input 114 passes through the element 108 AND, and is fed to the input of a fixed memory cell in ROM 105, where the reference address of the buffer zone of the server’s memory reserved for storing records with a digital description of the sensing object is stored. The same clock pulse from the output of the element 108 And is delayed by the element 111 for the time of reading the code from the ROM 105, and, firstly, it goes to the clock input of the register 106, entering the reference address of the record into it.

Secondly, the same pulse is applied to the single input of trigger 107 and sets it to a single state, in which the And element 108 will be closed and the And element 109 will be open. Thereby, the circuit for the passage of the next synchronizing pulse from the input 114 will be prepared.

And, finally, thirdly, the pulse from the output of the delay element 111 passes through the OR element 110, is again delayed by the element 112 for the time the address code is entered in the register 106 and then goes to the output 116 of the driver 119.

The write address code from the output 118 of the shaper 119 is issued to one input of the adder 122, to the other input of which is connected the output of the counter 120, which is also connected to one input of the comparator 121, the “zero code” is constantly applied to the other input.

The synchronizing pulse from the output 116 of the shaper, firstly, immediately through the OR element 125, is fed to the synchronizing input of the adder 122, which sums the reference address code from output 118 with the zero code of the counter 120, which is in the initial state at this point in time and outputs change the code of the address of the entry to the input of elements 124 AND groups.

Secondly, the same pulse passes through the OR element 128 and arrives at the direct input of the trigger 123, setting the latter to a single state, in which the high potential from the direct output opens the elements of 124 AND groups on the other input, thereby connecting the output of the adder 122 to the output 139 As a result, the reference address of the record from the input 81 of the module 9 through the elements 36 OR group is issued to the address 15 output of the system.

Thirdly, the synchronizing pulse from the output of the delay element 112 of the shaper 119 is delayed by the element 113 during the formation of the final code at the address 15 of the system output and through the output 140 of the module 7 is fed to the input 83 of the module 9, the OR element 37 passes and is output to the system 16 recording control signal quality.

This signal is fed to the input of the second channel of the database server interrupt, through which the server goes to the subroutine for recording the contents of module 6 through the information output 14 of the system to the database of the system server at the address generated at the output of the system 15.

In addition, the pulse from the output 117 of the delay element 130 of the module 7 is supplied to the counting input of the counter 120, fixing the first record, and also after the delay by the element 135 while recording data in the system database, this pulse passes the input of the OR element 129 by setting the trigger 123 to the initial state. Returning to its initial state, the trigger 123 closes the elements AND of the group of one input and, thereby, disconnects the output of the adder 122 from the address 15 of the system output.

If, in the process of data identification, module 5 nevertheless fixes the inequality of the input codes after viewing all the reference records with the data of the probed object, which will be detected by the appearance of the signal at the output 61 of module 3, this signal is fed to the input 114 of module 8 and starts the procedure for documenting the input data the probed object into the memory zone of the server database, reserved for documenting all cases associated with errors in the data. The documentation procedure is implemented exactly as it was described in the previous case.

After the end of the communication session for receiving data from the sounding object from the spacecraft, the generated data arrays are ready for delivery for further processing.

For this purpose, a control signal is received at the input 12 of the system, which, through the input 115 of module 7, first, through an element 128 OR, is fed to the single input of the trigger 125, setting it to a single state, in which the elements 124 open with a high potential from the direct output And groups on another input, thereby connecting the output of adder 122 to output 139. As a result, the address of the last record stored in adder 122 from input 139 of module 7 goes to input 81 of module 9 and then, through elements 36 of the OR group, it is output to address 15 output system.

Secondly, the clock from the input 115 is delayed by the element 133 for the duration of the trigger 123 and through the element 127 OR is output 141 of the module 7, from where it passes to the input 85 of the module 9, the OR element 38 passes and issued to the output 17 as a control signal reading data. From the output 17 of the system, the signal goes to the input of the third channel of the database server interrupt.

By this signal, the server switches to the subroutine for reading the contents of the database cell at the address specified on output 15, and issuing the first database record.

In addition, the synchronizing pulse from the output of the OR element 127 is delayed by the element 134 for the duration of reading data from the database, and, firstly, through the OR element 126 it enters the installation input of the adder 122, resetting it to its original state.

Secondly, this pulse is fed to the subtracting input of the reverse counter 120, reducing its readings by one. Thirdly, this pulse is delayed by the element 131 for the duration of the operation of the reversible counter 120 and is supplied to the synchronizing input of the comparator 121.

The comparator 121 compares the readings of the reversing counter 120 with a zero code supplied to its other input, and while the readings of the counter 120 are greater than the zero code, a signal is generated at the output A of the comparator 121, which, firstly, passes through the OR element 125 to the synchronizing input of the adder 122, which, by this signal, sums the code of the reference address from input 118 with the readings of the reverse counter 120 reduced by one and gives the final address to the address 15 of the system output.

Secondly, the same pulse is delayed by the delay element 132 for the operation time of the adder 122, the OR element 127 passes and is output 141, from where it passes to the input 85 of the module 9, the OR element 38 passes, and is issued to the output 17 as the next read control signal data. By this signal, the server again switches to the subroutine for reading the contents of the database cell at the address specified on output 15, and issuing the next record of the citizens database.

In addition, the synchronizing pulse from the output of the OR element 127 is again delayed by the element 134 for the time of reading data from the database, and, firstly, again through the OR element 126 it is supplied to the installation input of the adder 122, resetting it to its original state. Secondly, it again enters the subtracting input of the reversible counter 120, reducing its readings by one. And, thirdly, it is delayed by element 131 for the duration of operation of the counter counter 120 and arrives at the synchronizing input of the comparator 121.

The comparator 121 again compares the readings of the reversible counter 120 with a zero code supplied to its other input, and while the readings of the counter 120 are greater than the zero code, a signal is generated at the output A of the comparator 121, which, through the OR element 125, is supplied to the synchronizing input of the adder 122, which this signal summarizes the code of the reference address from input 118 with the readings of the reverse counter 120 reduced by one and gives the final address to the address 15 of the system output.

The described process of reading the data of the database of citizens continues until the comparator 121 fixes the fact that the readings of the reverse counter 120 are equal to zero, indicating that all the lines of the data record of the database of citizens who have gone abroad have been sent to display and print media.

This fact will be confirmed by issuing a pulse to the output of the comparator 121, which is supplied to the installation inputs of the reversible counter 120, the adder 122 and the trigger 123.

Thus, the introduction of new modules and new design relationships has significantly improved the system’s speed by eliminating the need to search for reference digital descriptions of sensing objects throughout the system’s database.

Sources of information taken into account when drawing up the description of the application:

1. RF patent No. 111836 (06/01/2011).

2. RF patent No. 2349513 (04/13/2007) - prototype.

Claims (1)

An intelligent data processing system for the command-measuring complex, containing a spacecraft data receiving module, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, while the information input of the spacecraft data receiving module is designed to receive sounding data from outer space or the earth’s surface, and the synchronizing input of the spacecraft data receiving module is intended for receiving the synchronizing signal in recording the sounding data of outer space or the earth’s surface in the data receiving module of the spacecraft, the module for integrating the write and read data signals of the system database server, the address output of which is the address output of the system, the first synchronizing output of the module for integrating the write and read signals of the system database server data is the first synchronizing system output intended for issuing control signals to the input of the first interrupt channel of the sys database server the second synchronizing output of the module for integrating the signals of writing and reading data of the system database server is the second synchronizing output of the system, intended for issuing control signals to the input of the second interrupt channel of the system database server, the first module for modifying the addresses of writing and reading data of the system server database , the control input of which is the first control input of the system, designed to receive signals for data output, the information output of the first modi The system of writing and reading addresses of the database data of the system server is connected to the first information input of the module for integrating the write and read signals of the data of the database server of the system, the first and second synchronizing inputs of which are connected to the first and second synchronizing outputs of the first module for modifying the addresses of writing and reading database data the system server, and the second module for modifying the write and read addresses of the database data of the system server, the control input of which is the second control input ohm of the system intended for receiving signals for data output, the information output of the second module for modifying the write and read addresses of the database data of the system server is connected to the second information input of the module for integrating the write and read data signals of the database server of the system, the third and fourth clock inputs of which are connected to the first and second synchronizing outputs of the second module for modifying the addresses of writing and reading data from the database of the server of the system, the module for receiving data from the reference digital x descriptions of sensing objects, the information output of which is the information output of the system, intended for issuing digital descriptions of sensing objects to the information input of the server of the system, characterized in that, in order to improve system performance, it contains a module for selecting reference addresses of recordings of reference digital descriptions of sensing objects, the information input of which is connected to the first information output of the spacecraft data receiving module, and the synchronizing input of the selection module of reference addresses of records of reference digital descriptions of sensing objects connected to the first synchronizing input of the system, a module for maintaining a database of reference digital descriptions of sensing objects, the information input of which is connected to the first information output of a selection module of reference addresses of records of reference digital descriptions of sensing objects, a synchronizing input of a module for maintaining a database reference digital descriptions of sensing objects connected to the synchronizing output of the reference address selection module of records of reference digital descriptions of sensing objects, the information output of the module for maintaining a database of reference digital descriptions of sensing objects is connected to the information input of a data receiving module for reference digital descriptions of sensing objects, the synchronizing input of which is connected to the synchronizing output of the module for maintaining a database of reference digital descriptions of sounding objects, the module identification data of sensing objects, one information input of which is connected to the second information during the spacecraft data receiving module, another information input of the sensing object data identification module is connected to the information output of the sensing object data digital data module receiving module, and the synchronizing input of the sensing object data identification module is connected to the synchronizing output of the module for maintaining the database of digital reference sounding object data, and a knowledge base data sampling control module, the information input of which is connected to the second information the output of the selection module for selecting reference addresses of recordings of reference digital descriptions of sounding objects, the synchronizing input of the module for selecting the reference addresses of recordings of reference digital descriptions of sensing objects, the counting input of the control module for sampling data of the knowledge base is connected to the first clocking output of the module identification of sensing object data, the first output of the knowledge base data sampling control module is connected to the counting input of the database of reference digital descriptions of sensing objects is maintained, and the second output of the knowledge base data sampling control module is connected to the first installation input of the database module of reference digital descriptions of sensing objects, the second installation input of which is connected to the second clock output of the sensing object data identification module, and installation output of the module for maintaining the database of reference digital descriptions of sensing objects is connected to the installation inputs of the modules for receiving data hardware and control the selection of knowledge base data, respectively, while the second clock output of the module for identifying data of sensing objects is connected to the synchronizing input of the first module for modifying the write and read addresses of the database data of the system server, and the second output of the control module for sampling the data of the database of the system is connected to the synchronizing input the second module for modifying the addresses of the write and read data of the database server system.