RU169920U1 - Arctic snow-ice geographic information database system - Google Patents

Abstract

The utility model relates to the field of informatics and can be used in the geographic information systems of the Arctic snow-ice cover. The technical result is to increase the reliability and speed of the system by eliminating manual procedures performed by the operator when checking the data entered into the system and comparing them with the data previously entered geoinformation database. The technical result is achieved by the fact that the system contains a module for receiving user requests, a module for setting operating modes of the system volumes, a module for identifying addresses for recording and reading geo-information data, a module for verifying the identity of quantitative values of indicators of update data and stored values of indicators in a database, a module for issuing address data to the address input of a database server, a module for receiving current data for updating snow and ice conditions, a selection module time cycles for updating the database, a module for receiving data from the system server database, a module for issuing data to automated workstations of system users emy. 7 ill.

Description

The utility model relates to the field of computer science and can be used in systems of geoinformation databases of the snow-ice cover of the Arctic.

The problems of monitoring the Russian Arctic are becoming particularly relevant as shipping along the Northern Sea Route intensifies and the Arctic shelf develops. In recent years, economic activity in the Arctic is actively developing, which requires operational information services, constant access to relevant and reliable information about the ice situation.

Traditionally, all-weather operational radar satellite imagery products are used to assess ice conditions. Based on the monitoring results, maps of the ice situation, film pollution, and navigational situation are being prepared.

Among the most important problems to be solved is the problem of monitoring the thickness of the snow-ice cover in the Arctic.

Known technical solutions that could be used to solve the problem (1, 2).

The first known technical solution is based on determining the state of the ice cover, including obtaining satellite radar images in the optical wavelength range, analyzing and interpreting images, interactively extracting the boundaries of ice zones using mosaics from different images, in which tomographic imaging is performed to determine the age and cohesion of ice ice cover survey, and the thickness of the ice and the morphographic anomalies of the underwater part of the ice formation are determined by means of steam a metric sonar meter by sensing ice formation by linear frequency-modulated pulses (1).

A significant drawback of this technical solution is that to determine the boundaries of the ice zones requires a lot of manual labor in the analysis of mosaics of different images of ice coverings.

Another technical solution is known, containing a user terminal, which includes an information input unit and an indication unit, an input information control unit, a control unit, an information processing unit, an address information unit, a reference data unit, a geographical information unit and an information matching unit (2 )

The well-known system of geographic information database is closest to the proposed technical essence and, as a result, is taken as a prototype.

Its disadvantage is the low reliability and low speed of the system, due to the fact that the control functions of the input data and their comparison with previously entered data are carried out manually by the system operator, which sharply limits the reliability of the entire system and reduces the speed of its operation.

The purpose of the utility model is to increase the reliability and speed of the system by eliminating manual procedures performed by the operator in monitoring input data into the system and comparing them with data previously entered into the geographic information database.

This goal is achieved by the fact that in a known system containing a module for receiving user requests, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, respectively, while the information input of the module for receiving user requests is designed to receive user requests from workstations, and synchronizing the input of the user request receiving module is intended for receiving signals of entering user requests into the receiving module user requests from workstations, the address data output module, the information output of which is the address output of the system, intended for issuing read and write addresses to the address input of the database server, the data receiving module for updating snow and ice conditions, the information and timing inputs of which are the second information and synchronizing inputs of the system, respectively, while the information input of the module for receiving data from updating snow and ice conditions and it is intended for receiving snow-ice update data, and the synchronizing input of the snow-ice update data receiving module is for receiving signals for entering snow-ice update data into the snow-ice update data receiving module, server database data receiving module, the information and synchronization inputs of which are the third information and synchronization inputs of the system, respectively, while the information input of the data receiving module the server database is designed to receive data from the server database, and the synchronizing input of the server database data receiving module is designed to receive the data entering signals into the server database data receiving module, the data output module for workstations of users of the system whose address input is connected to the second information output of the module for receiving user requests from workstations, the information input of the module for issuing data to workstations using The system is connected to the information output of the server database data reception module, and the information outputs of the data output module to the automated workstations of system users are information outputs of the system output group, a module for identifying recording and reading addresses of geo-information data is introduced, one synchronizing input of which is connected to the first synchronizing system input, another synchronizing input of the module for identifying recording addresses and reading geographic information data connected to the second synchronizing input of the system, the address output of the module for identifying addresses of recording and reading of geo-information data is connected to the information input of the module for issuing address data, the synchronizing input of which is connected to the first synchronizing output of the module for identifying addresses of recording and reading geo-information data, the second synchronizing output of which is the first synchronizing system output intended for issuing control signals to the input of the first base server interrupt channel data, a module for setting the system operation modes, the first information input of which is connected to the first information output of the user request receiving module, the second information input of the system operating mode setting module, is connected to the first information output of the snow-ice actualization data receiving module, the third information input of the mode setting module system operation is connected to the information output of the server database data reception module, while the control input of the operation mode setting module s of the system is the control input of the system, the synchronizing input of the module for setting the operating modes of the system is connected to the third synchronizing input of the system, the first information output of the module for setting the operating modes of the system is connected to the information input of the module for identifying addresses for recording and reading geo-information data, and one clock output of the module for setting the operating modes the system is connected to the synchronizing input of the data output module to the automated workstations of the system users, the selection module and the time cycles of updating the database, the information input of which is connected to the second information output of the server database data receiving module, the information output of the database updating time cycles selection module is the information output of the system, the synchronizing output of the database updating time cycles selection module is the second synchronizing output of the system designed to issue control signals to the input of the second channel of the database server interrupt, and the first and second signal The outputs of the module for selecting the time cycles of updating the database are the first and second signal outputs of the system, while the second signal output of the module for selecting the time cycles of updating the database is connected to the installation input of the module for setting the operating modes of the system, and the module for verifying the identity of the quantitative values of the indicators of the data for updating values of indicators in the database, one information input of which is connected to the second information output of the module for setting operating modes with systems, another information input of the module for verifying the identity of the quantitative values of indicators of actualization data and stored values of indicators in the database is connected to the second information output of the module for receiving the identity of the quantitative values of indicators of actualization of snow and ice conditions, synchronizing the input of the module for verifying the identity of the quantitative values of indicators of actualization data and the stored values of indicators in the database data is connected to another clock output of the module for setting the system operation modes, and the first and second clock s identity checking module outputs quantitative values of performance data and updating stored values of parameters in a database connected to the first and second clock input module selection time database updating cycles respectively.

The invention is illustrated by drawings, where in FIG. 1 is a structural diagram of a system; FIG. 2 is a structural diagram of a module for setting operating modes of the system, FIG. 3 is a structural diagram of a module for identifying recording addresses and reading geo-information data, FIG. 4 is a block diagram of a module for selecting time cycles for updating the database; FIG. 5 is a structural diagram of a module for issuing data to workstations of users of the system, FIG. 6 - an example of the concentration of ice fields and their distribution boundaries is shown, and FIG. 7 shows an example of an ice map-diagram according to the class of ice patency of vessels.

The system (Fig. 1) contains a module 1 for receiving user requests, a module 2 for setting the operating modes of the system, a module 3 for identifying addresses for recording and reading geo-information data, a module 4 for outputting address data to the address input of the database server, a module 5 for receiving current snow and snow update data -glacial environment, module 6 for verifying the identity of quantitative values of indicators of actualization data and stored values of indicators in the database, module 7 for selecting time cycles of updating the database, module 8 for receiving data from the server database, module 9 for issuing data to automated workstations of system users.

The drawing shows the first 11, second 12 and third 13 information inputs of the system, the first 14, second 15 and third 16 synchronizing inputs of the system, controlling 17 system inputs, as well as address 20 and information 21 system outputs, a group of 22-24 information outputs of the system, the first 25 and second 26 are synchronizing, and the first 27 and second 28 signal outputs of the system.

Module 1 (Fig. 1) for receiving user requests is made in the form of a register 1 having information 11 and synchronizing 14 inputs, as well as the first 32 and second 33 information outputs.

Module 2 (Fig. 2) of setting the operating modes of the system contains a trigger 35, elements 36, 37 AND, groups 38, 39 and 40 of AND elements, and a group of elements 41 OR. The drawing shows the first 45, second 46 and third 47 information inputs, synchronizing 48 input, control 49 and installation 50 inputs, as well as the first 51 and second 52 information, the first 53 and second 54 clock outputs.

Module 3 (Fig. 3) of identifying write and read addresses of geoinformation data includes a decoder 56, a memory unit 57 made in the form of read-only memory, elements 58-60 AND, element 61 OR, elements 62-64 delay. The drawing shows the first 65 and second 66 clock and information 67 inputs, as well as address 68, first 69 and second 70 clock outputs.

Module 4 (Fig. 1) issuing address data to the address input of the database server is made in the form of a register 4 having information 71 and synchronizing 72 inputs, as well as information 20 output.

Module 5 (Fig. 1) for receiving current data for updating the snow-ice situation is made in the form of a register 5 having information 73 and synchronizing 74 inputs, as well as the first 75 and second 76 information outputs.

Module 6 (Fig. 1) verifies the identity of the quantitative values of the indicators of the actualization data and the stored values of the indicators in the database is made in the form of a comparator 6, having the first 77 and second 78 information and synchronizing 79 inputs, as well as the first 80 and second 81 clock outputs.

Module 7 (Fig. 4) of the selection of time cycles for updating the database contains a trigger 85, counter 86, register 87, comparator 88, a group of 89 AND elements, 90 OR element, delay elements 91, 92, and 110. The drawing shows information 82, first 83 and second 84 clock inputs, as well as information 93 and clock 94, first 95 and second 96 signal outputs.

Module 8 (Fig. 1) of receiving data from a server database is made in the form of a register 8 having information 97 and synchronizing 98 inputs, as well as information 99 output.

The module 9 (Fig. 5) for outputting data to workstations of users of the system contains a decoder 100, and groups 101-103 of elements I. The drawing shows information 104, address 105 and synchronizing 106 inputs, as well as a group 107-109 information outputs.

The geographic information database system operates as follows.

Information for the geoinformation database on sea ice is formed in the form of archives of raster, graphic and vector digital ice maps. They are designed to accurately display the spatial distribution and characteristics of the ice cover on the seas, namely, zones of different general cohesion, private cohesion of age-related stages of ice, forms of ice fields, channels, streaks and other phenomena and formations.

To download data on the state of ice cover, you only need to specify the date and coordinates of the site.

The state of the ice cover is described by the ICEC (ice concetration) variable, which takes values in the range from 0 (open water) to 1 (solid ice).

To form a map, data is converted into a format accessible to the ArcGIS geographic information system, in which thematic maps are created. Visualization of ice concentration is carried out in a raster format (Fig. 6). The color scale allows you to visually assess the concentration of ice fields and the distribution boundary of ice. A vector option for data visualization is the ice distribution scheme (Fig. 7).

Deciphering sea ice from satellite radar images involves the detection, recognition and interpretation of ice parameters. For detection and recognition, features such as the backscatter value and texture, as well as the structure, size and shape of objects are used.

The main direct decoding feature is the brightness of the radar image, which is determined by the coefficient of backscattering of water and sea ice.

Based on the differences in the backscattering coefficients, the main types of ice are determined. The dependence of the specific effective scattering area and image tone on the type of ice, its shape and surface roughness makes it possible to determine a number of parameters of sea ice, however, different types of ice can be represented by the same tone and texture. In typical radar images, many types of ice look the same at different polarizations and sensing angles.

Unlike the prototype, the geographic information database system has two operating modes:

- mode of loading and updating data on the snow-ice cover of the Arctic;

- the mode of issuing data from the database at the request of users.

In the initial state, the system is in the mode of loading and updating data on the snow-ice cover of the Arctic, in which trigger 35 of module 2 is in the “zero” state, in which element 37 I is opened from the inverse output of trigger 35 at one input, and also elements 39 and 40 groups of elements I.

In addition, in the register 87 of module 7, a predetermined quantitative value of the number of update codograms to be loaded into the database is set in advance. After that, at the informational 12 input of the system, codograms are sequentially received with the data of updating the geoinformation database, which, through the informational input 73, are entered into the register 5 by synchronizing pulses coming from the synchronizing 15 system input to the synchronizing 74 input of the register 5.

The actualization codograms have the following structure:

From the output 75 of register 5, the coordinate code X, Y of the discrete point of the snow-ice cover through the input 46 of module 2 is fed to one of the inputs of the elements 39 And of the group, the other inputs of which from the inverted output of the trigger 35 have a high resolution potential. As a result, the X, Y coordinate code of the selected discrete point sequentially passes the elements 39 AND groups, and then the elements 41 OR groups to the output 51 of module 2, and then through the input 67 of module 3 it enters the input of the decoder 56 of module 3, which decodes the incoming code and opens one input of one of the elements 58-60 AND, corresponding to the coordinate code X, Y of the selected discrete point. Assume that such an element is element 60 I.

In parallel, the synchronizing pulse from the input 15 of the system enters the input 66 of module 3, the OR element 61 passes, it is delayed by the delay element 62 entering the data updating codegram into register 5, and then it goes to the other inputs of elements 58-60.

Given the fact that only element 60 And will be open at one input, then passing this element And, the clock pulse, firstly, is fed to the read input of a fixed memory cell of read-only memory 57, where the address of the memory cell in which the recording of the quantitative value of the ice thickness indicators at the selected discrete point corresponding to the X, Y coordinate code.

The address code of the selected memory cell from the output 68 of the module 3 is read to the information input 71 of the register 4, where it is entered by the synchronizing pulse from the output 69 of the module 3 supplied to the synchronization input 72 of the register 4.

Simultaneously with this process, the synchronizing pulse from the output of the delay element 63 is additionally delayed by the element 64 for the time the address code is entered into register 4, and then through the first synchronizing output 25 of the system it enters the input of the first 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 specified address, issuing it to the information input 13 of the system and recording the contents of the database cell in register 8 with a synchronizing pulse from the server to input 16.

The structure of the codogram at the output 99 of register 8 will have the following form:

The quantitative value of the ICEC indicator at a discrete point with coordinates X, Y from the output 99 of register 8 is supplied to both the information input 47 of module 2 and the information input 105 of module 9.

From the input 47 of module 2, the code of the quantitative indicator ICEC arrives at one of the inputs of elements 40 And groups, the other inputs of which are open with high potential from the inverse output of trigger 35 of module 2.

As a result, the ICEC quantitative indicator code passes through the elements of the 40 And groups and, from the output 52 of module 2, enters the information input 77 of module 6, to the other information input 78 of which the ICEC quantitative indicator code is supplied from the informational 76 output of register 5.

In parallel, the synchronizing pulse from the input 16 of the system enters the synchronizing input 48 of module 2, is delayed by element 42 while the data are entered into register 8, and passes through element 37 AND, open at the other input with a high potential from the inverse output of trigger 35, to the output 53 module 2 and on to the synchronizing 79 input of the comparator 6.

The comparator 6 compares the input value of a quantitative indicator of the thickness of ice at a discrete point from the codogram of data updates, with a quantitative value of the index of thickness of ice read from the server database.

If the comparison of the input codes has not occurred, then the comparator 6 generates a synchronizing signal at the output 80, from which this signal passes through the input 83 of the module 7 to the single input of the trigger 85 and sets it to the single position, at which the high potential from the direct output of the trigger 85 opens elements 89 And groups to one input, thereby connecting the output 76 of register 5 through the input 82 of module 7 to the information output 93 of module 7 and further to the information output 21 of the system.

In parallel with this, the synchronizing pulse from the input 83 of the module 7 is, firstly, delayed by the delay element 91 for the duration of the trigger 85, and is issued to the output 94 of the module 7 and then through the output 26 of the system to the input of the second channel of the database server interrupt. By this signal, the database server goes to the subroutine for recording a new quantitative indicator of the ice thickness from the information output 21 to the address of the memory cell, the address of which is installed on the address 20 of the system output.

Secondly, the same clock signal from the output of the delay element 91 is again delayed by the delay element 92 for the duration of recording a new quantitative indicator of the ice thickness in the memory cell of the database, and arrives at the installation input of the trigger 85, returning it to its original state.

Thirdly, the same synchronizing signal from the output of the delay element 91 passes through the OR element 90, and enters the counting input of the counter 86, fixing the fact of updating the server database.

The code recorded by the counter 86 of module 7, from the output of the counter 86 is fed to one information input of the comparator 88, the other information input of which from the output of the register 87 is supplied with the specified code for the number of records of quantitative indicators to be updated.

In parallel, the synchronizing pulse from the output of the element 90 OR module 7 is delayed by the element 110 at the time of operation of the counter 86 and is supplied to the synchronizing input of the comparator 88.

According to the synchronizing signal received at its input, the comparator 88 compares the number of records made with a given number of records of quantitative indicators of ice thickness in the server database to be updated.

If the comparison of the codes did not happen, then the output 95 of module 7 generates a signal that is output to the output 27 of the system as a signal of readiness to receive the next codogram of updates received at the input 15 of the system.

If the comparator 6, comparing the input value of the quantitative indicator of the ice thickness at the discrete point from the data updating codegram, with the quantitative value of the ice thickness indicator read from the server database will record their coincidence, then the repeated recording of such an indicator in the database will be blocked.

In this case, a synchronizing signal is generated at the output 81 of the comparator 6, which is transmitted through the input 84 of the module 7 and then, through the element 90, is fed to the counting input of the counter 86, fixing the fact of receiving the next codogram for updating the server database.

The code recorded by the counter 86 of module 7, from the output of the counter 86 is fed to one information input of the comparator 88, the other information input of which from the output of the register 87 is supplied with the specified code for the number of records of quantitative indicators to be updated.

In parallel, the synchronizing pulse from the output of the element 90 OR module 7 is delayed by the element 110 at the time of operation of the counter 86 and is supplied to the synchronizing input of the comparator 88.

According to the synchronizing signal received at its input, the comparator 88 compares the number of records made with a given number of records of quantitative indicators of ice thickness in the server database to be updated.

If the comparison of the codes did not happen, then the output 95 of module 7 generates a signal that is output to the output 27 of the system as a signal of readiness to receive the next codogram of updates received at the input 15 of the system.

If the comparator 88 records the fact of viewing a given number of records of quantitative indicators of the ice thickness in the server database to be updated, then an output will be generated at the output 96 of the comparator 88, which will be output to the system 28 as a signal for the end of the database update procedure. In addition, the same pulse from the output 96 of the module 7 is fed to the input 50 of the module 2 and then goes to the installation input of the trigger 35, confirming its initial state.

The mode of outputting data from the database at the request of users is established by applying a pulse to the control input 49 of module 2, from where the pulse goes to the direct input of trigger 35 and sets it to a single state, in which element 36 will be open at one input at high potential from the direct output of trigger 35 And, and elements 38 And groups.

At the automated workstation, the user of the geographic information database generates a query codogram in which he requests a quantitative value of the ICEC indicator at a discrete point in the snow-ice cover indicating specific X, Y coordinates.

The user request codogram code is sent to the information input 11 of the system and then to the information 30 input of the module 1, where it is entered by the synchronizing pulse coming from the synchronizing 14 input of the system to the synchronizing 31 input of the module 1.

The user request codogram is as follows:

From the output 32 of register 1, the coordinate code X, Y of the discrete point of the snow-ice cover through the input 45 of module 2 is supplied to one of the inputs of elements 38 And of the group, the other inputs of which have a high resolution potential from the direct output of trigger 35.

As a result, the X, Y coordinate code of the selected discrete point sequentially passes the elements 38 AND groups, and then the elements 41 OR groups to the output 51 of module 2, and then through the input 67 of module 3 it enters the input of the decoder 56 of module 3, which decodes the incoming code and opens one input of one of the elements 58-60 AND, corresponding to the coordinate code X, Y of the selected discrete point. Assume that such an element is element 60 I.

In parallel, the synchronizing pulse from the input 14 of the system enters the input 65 of module 3, the OR element 61 passes, it is delayed by the time 62 the user request code is entered into register 1 by the delay element 62, and then it goes to the other inputs of elements 58-60.

Given the fact that only element 60 And will be open at one input, then passing this element And, the clock pulse, firstly, is fed to the read input of a fixed memory cell of read-only memory 57, where the address of the memory cell in which the recording is stored on the quantitative value of the ice thickness indicators at the selected discrete point corresponding to the X, Y coordinate code.

The address code of the selected memory cell from the output 68 of the module 3 is read to the information input 71 of the register 4, where it is entered by the synchronizing pulse from the output 69 of the module 3 supplied to the synchronization input 72 of the register 4.

Simultaneously with this process, the synchronizing pulse from the output of the delay element 63 is additionally delayed by the element 64 for the time the address code is entered into register 4, and then through the first synchronizing output 25 of the system it enters the input of the first channel of the database server interrupt.

By this signal, the server goes to the subroutine for reading the contents of the database cell at the specified address, issuing it to the information input 13 of the system and recording the contents of the database cell in register 8 with a synchronizing pulse from the server at input 16.

The structure of the codogram at the output 99 of register 8 will have the following form:

The quantitative value of the ICEC indicator at a discrete point with coordinates X, Y from the output 99 of register 8 is supplied to both the information input 47 of module 2 and the information input 105 of module 9.

In the first case, from the input 47 of module 2, the ICEC quantity indicator code is sent to one of the inputs of the 40 AND group elements, the other inputs of which in this mode are blocked by low potential from the inverse output of trigger 35 of module 2. As a result, the ICEC quantity indicator code cannot be issued to output 52 of module 2, as was done in the update mode.

In the second case, the code of the quantitative indicator ICEC from the information input 105 goes to one of the inputs of the AND elements of all groups 101-103.

The address code of the user's workstation from the output 33 of register 1 is sent to the address 104 input of module 9 and then to the input of the decoder 100, which decrypts the user address code and opens the And elements of one of the groups 101-103 at the second input. Suppose that such a group of elements AND was selected group 102.

In this case, the synchronizing pulse from the input 16 of the system enters the input 48 of module 2, is delayed by the delay element 42 for the time the code is entered in register 8, passes the 36 And element opened by high potential from the direct output of trigger 35, and from the output 54 of module 2 synchronizing 106 input of module 9, from where it is fed to the inputs of AND elements of all three groups 101-103.

Considering, however, that only AND elements of the group 102 will be open at two inputs, the synchronizing pulse ensures the issuance of the ICEC quantitative indicator code through the AND elements of the group 102 to the output 108 of module 9 and then from the output of the system 23 to the user's workstation.

Thus, the introduction of new modules and new design relationships has significantly improved the reliability and performance of the system by eliminating manual procedures performed by the operator when monitoring the data entered into the system and comparing them with data previously entered into the geographic information database.

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

1. RF patent No. 2449326 (02.24.2010)

2. RF patent No. 1 16 663 (11/08/2011) (prototype).

Claims (1)

The Arctic snow-ice coverage geo-information database system containing a user request receiving module, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, respectively, while the user request receiving module information input is designed to receive user requests from workstations, and synchronizing the input of the module for receiving user requests is intended for receiving signals of entering user requests in m a module for receiving user requests from workstations, an address data output module, the information output of which is an address output of the system intended for issuing data read and write addresses to the address input of a database server, a data receiving module for updating snow and ice conditions, information and timing inputs which are the second information and synchronization inputs of the system, respectively, while the information input of the module for receiving snow-ice update data howling is intended for receiving snow-ice update data, and the synchronizing input of the snow-ice updating data receiving module is for receiving signals for entering snow-ice updating data into the snow-ice updating data receiving module, server database data receiving module , the information and synchronizing inputs of which are the third information and synchronizing inputs of the system, respectively, while the information input of the module receiving data from a server database is intended for receiving data from a server database, and the synchronizing input of a server database data receiving module is intended for receiving data input signals into a server database data receiving module, a data output module for automated workstations of system users whose address input connected to the second information output of the module for receiving user requests from workstations, the information input of the module for issuing data to automated workstations A number of system users are connected to the information output of the server database data reception module, and the information outputs of the data output module to the computer workstations are information outputs of the system output group, characterized in that the system contains a module for identifying addresses for recording and reading geo-information data, one synchronizing the input of which is connected to the first synchronizing input of the system, another synchronizing input of the recording address identification module and reading geo-information data is connected to the second synchronizing input of the system, the address output of the module for identifying recording addresses and reading geo-information data is connected to the information input of the module for issuing address data, the synchronizing input of which is connected to the first synchronizing output of the module for identifying addresses of recording and reading geo-information data, the second synchronizing output of which is the first synchronizing system output intended for issuing control signals to the input of the first channel of interruption of the database server, the module for setting the system operation modes, the first information input of which is connected to the first information output of the module for receiving user requests, the second information input of the module for setting the system operation modes is connected to the first information output of the module for receiving data for updating the snow-ice situation, the third information input of the system operation mode setting module is connected to the information output of the server database data receiving module, while The main input of the system operation mode setting module is the control input of the system, the synchronizing input of the system operation mode setting module is connected to the third synchronizing input of the system, the first information output of the system operation mode setting module is connected to the information input of the module for identifying addresses for recording and reading geographic information data, and one clock the output of the module for setting the operating modes of the system is connected to the synchronizing input of the module for issuing data to automated work e places of users of the system, the module for selecting the time cycles of updating the database, the information input of which is connected to the second information output of the module for receiving data from the server database, the information output of the module for selecting time cycles for updating the database is the information output of the system, synchronizing the output of the module for selecting time cycles for updating the database data is the second synchronizing output of the system, designed to issue control signals to the input of the second interrupt channel the database server, and the first and second signal outputs of the module for selecting the time cycles of updating the database are the first and second signal outputs of the system, while the second signal output of the module for selecting the time cycles of updating the database is connected to the installation input of the module for setting the operating modes of the system, and the verification module the identity of the quantitative values of indicators of actualization data and the stored values of indicators in the database, one information input of which is connected to the second information the output of the module for setting the operating modes of the system, another information input of the module for verifying the identity of the quantitative values of the indicators of actualization data and the stored values of the indicators in the database is connected to the second information output of the module for receiving the data for updating the snow-ice situation, the synchronizing input of the module for verifying the identity of the quantitative values of the indicators of the update data and the stored values of indicators in the database is connected to another clock output of the installation module mode in the system, and the first and second timing outputs verify identity module quantitative values of performance data and updating stored values of indicators in a database connected to the first and second clock input module selection time database updating cycles respectively.

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