RU132907U1 - AUTOMATED INFORMATION SYSTEM OF PLANNING OF RE-GROWING OF TROOPS (FORCES) BASIC TYPES OF TRANSPORT - Google Patents

Abstract

An automated information system for planning the regrouping of troops (forces) by the main means of transport, containing a module for selecting the reference address for recording the data array in the server database, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, while the first information input of the system is designed to receive base records server data, the first synchronizing input of the system is designed to receive synchronizing pulses of recording database records with the server into the selection module for selecting a reference address for recording a data array in a server database, and the first information output of a module for selecting a reference address for recording a data array in a server database is an information output of the system, a module for integrating address signals for reading and writing data, the output of which is an address output of the system, a module for modifying the addresses for reading the calculated data, the information input of which is connected to the second information output of the module for selecting the reference address of the record of the data array in the database server, one synchronizing input of the module for calculating the read addresses of the calculated data is connected to the first synchronizing output of the module for selecting the reference address of the record of the data array in the server database, and the other synchronizing input of the module for modifying the addresses of reading of the calculated data is connected to the second clock data in the server database, while the information output of the module for modifying the addresses for reading the calculated data is connected to the same information

Description

The utility model relates to computing, in particular, to an automated information system for planning regrouping of troops (forces) by the main modes of transport.

The modern combined arms battle is characterized by decisiveness, high maneuverability, tension and transience, rapid and abrupt changes in the situation and the variety of methods of conducting it, the deployment of military operations on the ground and in the air, on a wide front, to a great depth and leading them at a high pace.

In this regard, a clear and quick maneuver by troops is required not only in areas of individual units and formations, but also on a larger scale. This maneuver by the troops will be facilitated by the quick, clear and organized movement of troops across. air, rail or water transport and march.

The following types of troop transport:

- transportation by rail;

- transportation by sea (river) transport;

- transportation by air;

- transportation on heavy road trains;

- transportation in a combined way.

The transportation of troops by rail is used mainly when moving units from the depths of the country to the war zone. When transported by rail, a high speed of movement is provided regardless of the weather, time of year or day. At the same time, personnel forces are saved, motor resources and fuel are saved.

At the same time, the great vulnerability of railways from modern enemy weapons limits their use, especially in the front-line zone.

By sea, troops are deployed along the coastal lines of war to isolated sections of the coast and islands. Difficulties of transportation by sea are mainly due to the complexity of organizing reliable security and escort of vessels to designated ports and unloading points, lack of equipment for loading (unloading) of heavy military equipment, and the possibility of destruction of ports.

Transportation by river is carried out in order to deliver troops from the depths of the country to the war zone or transfer them from one direction to another.

Air transportation can be used for the urgent transfer of motorized rifle units from the depths of the country to the war zone. By air, you can also transfer units in any direction and to areas that are practically inaccessible to other modes of transport (to the rear of the enemy, to mountainous and wooded areas, through areas with a high level of radiation).

The movement of troops in a combined way is carried out both with the simultaneous use of various modes of transport, and with their consistent use.

The results of the system’s work can be used by the command and headquarters of the association at all stages of the planning of troop regrouping: clarification of the task, assessment of the situation, elaboration of an idea and decision-making on regrouping, as well as in the process of organizing its reorganization.

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

The first of the known systems contains a modeling planning system, a management server, a database, automated workstations, a modeling monitoring system, a block of information and settlement tasks of combat control, a block of information and settlement tasks of planning, a block of regulated and formalized data exchange. (one).

A significant drawback of this system is the impossibility of solving the problem of updating data stored in memory in the form of relevant documents at the same time as solving the problem of delivering the contents of these documents to users in real time.

Another system is known that contains a module for selecting a reference address for writing a data array in a server database, a module for modifying addresses for reading calculated data, a module for integrating address signals for reading and writing data, a module for identifying cycles for generating annual intervals, a module

the formation of the current address for reading data of a time period, a selection module for a base address of a time period, a module for identifying boundaries of a time period. (2). The last of the above technical solutions is closest to the described.

Its disadvantage lies in the lack of the possibility of calculating the regrouping of troops (forces) with the main modes of transport.

The purpose of the utility model is to expand the functionality of the system by solving the problem of calculating the regrouping of troops (forces) in real time.

This goal is achieved by the fact that in a known system containing a module for selecting a reference address for recording a data array in a server database, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, while the first information input of the system is designed to receive server database records, the first synchronizing input of the system is designed to receive synchronizing pulses of recording server database records in the selection module of the reference address of the record array and the data in the server database, and the first information output of the selection module of the reference address of the record of the data array in the server database is the information output of the system, the integration module of the address signals for reading and writing data, the output of which is the address output of the system, the module for modifying the addresses for reading the calculated data, the information input of which is connected to the second information output of the selection module of the reference address of the record of the data array in the server database, one synchronizing input of the modif module quotations of readout addresses

connected to the first synchronizing output of the selection module of the reference address of the record of the data array in the server database, and the other synchronizing input of the module of the modification of the addresses of the reading of the calculated data is connected to the second synchronizing output of the selection module of the reference address of the record of the data array in the server database, while the information output of the modification module reading addresses of the calculated data is connected to one information input of the integration module of the address signals of reading and writing data, the first synchronization the synchronizing input of which is connected to the second synchronizing output of the selection module for the reference address of the record of the data array in the server database, and the synchronizing output of the module for modifying the addresses for reading the calculated data is the first synchronizing output of the system designed to provide control signals to the input of the first channel of the database server interrupt, the module the formation of the current data reading address of the time period of the regrouping of troops, the information output of which is connected to another information by the input of the module for integrating address signals for reading and writing data, one synchronizing output of the module for generating the current address for reading data of the temporary regrouping period is connected to the second synchronizing input for the module for integrating the address signals for reading and writing data, and the other for the synchronizing output of the module for generating the current address for reading data for the temporary regrouping Troops is the second synchronizing output of the system, designed to issue control signals to the course of the second channel database server interruption data generating unit cycles identification regrouping intervals

troops, the synchronizing input of which is connected to the first synchronizing input of the system, the clock input of the module for identifying the formation cycles of the regrouping intervals of troops is connected to the synchronizing output of the module for modifying the addresses for reading the calculated data, and the first output of the module for identifying the cycles of forming intervals of the regrouping of troops is connected to the clocking input of the module for generating the current address reading data of a temporary period of regrouping troops, a module for selecting the base address of a temporary period of regrouping troops, the information and synchronizing inputs of which are the second information and synchronizing inputs of the system, while the second information input of the system is designed to receive parameters of the intervals of regrouping troops, and the second synchronizing input of the system is designed to receive synchronizing pulses of entering parameters of the annual intervals of regrouping troops in the selection module base address of the temporary period of regrouping troops, information output of the base selection module of the address of the time period of the regrouping of troops is connected to the information input of the module for generating the current address for reading data of the time period of the regrouping of troops, and the synchronization output of the module for selecting the base address of the time period of the regrouping of troops is connected to the synchronizing input of the module for generating the current address for reading the data of the temporary period of regrouping, and the identification module the boundaries of the time period of the regrouping of troops, information and synchronizing inputs of which are on the third information and the synchronization input of the system, while

the third information input of the system is designed to receive the identifier of the initial interval of the time period of the regrouping of troops, and the third synchronizing input of the system is designed to receive the synchronizing pulses of the identifier of the initial interval of the time period of the regrouping of troops in the module for identifying the boundaries of the time period of the regrouping of troops, the clock input of the module for identifying the boundaries of the time period of the regrouping of troops troops connected to the second output of the module identifying cycles f troop regrouping intervals, the first output of the unit for identifying the boundaries of the troop regrouping time period is connected to the installation inputs of the modules for generating the current address for reading the data of the troop regrouping time, selecting the base address of the troop regrouping time period, identifying the formation cycles of troop regrouping intervals and selecting the record reference address an array of data in the server database, and the second output of the time period boundary identification module Yes, the regrouping of troops is the third synchronizing output of the system, intended for issuing control signals to the input of the third channel for interrupting the database server, a means that implements the planning process for regrouping troops (forces) by the main modes of transport, made in the form of a server using calculation programs to calculate the required values of indicators regrouping of military units, presented in the form of a table containing calculated data on the duration of the regrouping of troops (with l) in various ways.

The invention is illustrated by drawings, in which Fig. 1 shows a structural diagram of a system, Fig. 2 shows an example of a specific structural embodiment of a module for selecting a reference address of a record of a data array in a server database, Fig. 3 is an example of a specific structural embodiment of a module for modifying calculation read addresses 4, an example of a specific structural embodiment of an address signal integration module, FIG. 5 is an example of a specific structural embodiment of a form loop identification module Nia slots regrouping forces, 6 - an example of a specific structural embodiment of a module forming the current data read address time period rearrangement forces, 7 - an example of a concrete structural embodiment of the identification module boundaries time period rearrangement forces.

The system (Fig. 1) comprises a module 1 for selecting a reference address for recording a data array in a server database, a module 2 for modifying addresses for reading calculated data, a module 3 for integrating address signals for reading data, a module 4 for identifying cycles for generating time intervals for regrouping troops, and a module 5 for generating the current read addresses of the time period of the regrouping of troops, module 6 selection of the base address of the time period of the regrouping of troops, module 7 identifying the boundaries of the time period of the regrouping Application troops.

Figure 1 shows the first 10, second 11 and third 12 information inputs of the system, the first 13, second 14 and third 15 synchronizing inputs of the system, information 16 and address 17 outputs of the system, and the first 18, second 19 and third 20 synchronizing outputs of the system.

Module 1 (figure 2) selection of the reference address of the record of the data array in the server database contains register 25, trigger 26, elements 27 - 28 AND, memory unit 29, made in the form of read-only memory, element 30 OR, elements 31 - 32 delay . The drawing also shows information 34, synchronizing 35 and installation 36 inputs, as well as information 37, address 38, first 39 and second 40 synchronization outputs.

Module 2 (figure 3) modification of the addresses for reading the calculated data contains a register 42, a counter 43, an adder 44 and a delay element 45. The drawing shows information 47, first 48 and second 49 and synchronizing inputs, as well as information 50 and synchronizing 51 outputs.

Module 3 (figure 4) integration of address signals for reading data contains a trigger 53, elements 54, 55 AND groups, and elements 56 OR groups. The drawing also shows the first 57 and second 58 information inputs, clock 59, installation 60 inputs, and output 61.

Module 4 (Fig. 5) for identifying cycles of formation of time intervals for regrouping troops contains a counter 65, a register 66 and a comparator 67. The drawing shows a counting 68, installation 69 and synchronizing 70 inputs, as well as the first 71 and second 72 outputs.

Module 5 (FIG. 6) of forming the current data reading address of the time period of the regrouping of troops comprises a counter 75, an OR element 76, and a delay element 77. The drawing shows the installation 78, timing 78, information 80 and synchronizing 81 inputs, as well as information 82, and the first 83 and second 84 synchronizing outputs.

Module 6 selection of the base address for reading the data of the time period of the regrouping of troops (Fig.7) contains a counter 85, a decoder 86, a memory unit 87 made in the form of a permanent storage device, elements 88-90 OR, element 91 OR, elements 92 - 93 delay. The drawing shows the inputs of information 94, synchronizing 95 and counting 96 inputs, as well as information 97 and synchronizing 98 outputs

Module 7 identifying the boundaries of the time period of the regrouping of troops (Fig) contains a register 100, a counter 101, a comparator 102, and a delay element 103. The drawing also shows information 104, synchronizing 105 and counting 106 inputs, as well as the first 107 and second 108 outputs.

The system operates as follows.

The system database stores arrays of indicators characterizing the combat and numerical strength of the opposing sides, as well as the characteristics of typical military formations. (TVF). An element of the combat composition (military formation) is represented in the database by a set of attributes: {level, type, kind}, which uniquely determines the place of military formation in the general structure of military targets.

For each typical military formation in the system-wide database, the characteristics and normative data are defined:

- minimum and maximum number of railway directions;

- the required number of railway trains for transportation in full force;

- minimum and maximum number of loading / unloading stations;

- minimum and maximum rates of transportation;

- minimum and maximum number of routes;

- depth of the marching column in full force;

- the interval between adjacent columns;

- consumption of gasoline per 100 km in full force;

- diesel fuel consumption per 100 km in full force;

- depth of the marching column in a combined way;

- gasoline consumption per 100 km in a combined way;

- diesel fuel consumption per 100 km in a combined way.

When working with the system, an electronic map is used as an interface for maintaining the elements of the task of the senior boss and elements of the plan (solution), which are spatial data:

- the starting area and the position of troops in it;

- The final area of concentration and the position of troops in it;

- band (region) of regrouping;

- regrouping routes on their own;

- directions of rail transportation;

- regulatory and barrier lines.

The system allows the operator to evaluate the composition of his troops, the territory in the regrouping band (region), the routes of movement on his own, railway directions, and to calculate the duration of regrouping of troops on his own, using railway transport and in a combined way.

To solve the task of calculating the duration of the regrouping of troops, the operator at his automated workplace generates initial data for the task to be solved.

First, the operator must specify the parameters of the time period that determine the period of regrouping of troops. To do this, the operator from his workstation (not shown) through the information input 12 of the system enters this value into the register 100 of module 7, which is written to the register 100 with a synchronizing signal from the input 15 of the system.

Secondly, the operator must indicate the identifier code of the start date of the time period selected for analysis, the digital value of which from the information input 11 of the system is fed to the input of the counter 85 of module 6.

After a set of input data, the operator presses the “EXECUTE” key. Entering the input code into the counter 85 is carried out by the synchronizing signal supplied to the input 14 of the system.

From the output of the counter 85, the code is input to the decoder 86 (Fig.6). Decoder 86 decodes the identifier code of the start date of the time period, giving out one of its outputs high potential.

In parallel, the synchronizing pulse from the input 14 of the system through the input 95 of the module 6 is supplied to the input 91 OR, is delayed by the element 92 while the code is entered into the counter 85 and the decoder 86 is activated. Then the same pulse goes to the inputs of the elements 88 - 90 AND, interrogating their condition.

Considering the fact that only one of the elements 88 - 90 I will be open decoder 56 at one input, then after passing the corresponding element And, the clock pulse, firstly, is fed to the read input of the corresponding fixed memory cell of the permanent storage device 87.

In a fixed ROM cell, the base address of the server database memory cell is stored, starting from which the data array of the specified time period is stored in the server database, and reads the code of the base address of the time period to the output of module 97 97.

The base address code from the output 97 of the module 6 through the input 80 of the module 5 is fed to the information input of the counter 75 (Fig.6), where it is entered by the synchronizing pulse from the output 98 of the module 6, delayed by the delay element 93 while the code is being read from the memory module 87.

The base address code from the output 82 of the module 5 is fed to the information input 58 of the module 3, where it is fed to one of the inputs of the elements 55 AND groups. In parallel, the synchronizing pulse from the output 83 of the module 5 through the input 60 of the module 3 is supplied to the installation input of the trigger 53 and confirms its initial state, in which, with a high potential from the inverse output, the trigger 53 opens the elements 55 And groups on one input.

The code of the base address from the output of the counter 75 through the input 58 of module 3 is fed to the other inputs of the elements of the 55 AND group, the elements 56 OR of the group pass and issued to the address output 17 of the system.

In parallel with the described process of generating the server database read address, the synchronizing pulse from the input 78 of module 5 passes the OR element 76, is delayed by the element 77 for the time of operation of the counter 75, and then it is output to the system 19 as a read pulse received at the input of the first interrupt channel server.

By this signal, the server goes to the subroutine for reading the first record of the data array from the server database at the address generated at output 17.

The contents of the base address of the selected memory cell is issued by the database server through the system input 10 to the information input 34 of register 25 of module 1, where it is entered by the server synchronizing pulse coming from the system input 13. From the output of register 25, its contents are output to the output 16 of the system. In addition, the synchronizing pulse from the input 13 of the system through the input 68 of the module 4 is supplied to the counting input of the counter 65, counting the number of read records from the server database, and to the input of the elements 27, 28 I. Given that the trigger 26 is in the initial state, then with a high potential from the inverse output, the element 28 And will be opened, and the element 27 is closed with a low potential from the direct output.

As a result of this, the input pulse passes through element 28 AND to the read input of the memory module 29, made in the form of read-only memory, in a fixed memory cell of which the starting base address is stored, starting from which the data array necessary for solving the problem will be formed in the server database regrouping troops.

As a result of reading, the base address from the output 38 of module 1 through the input 47 of module 2 is fed to the information input of the register 42, where it is entered by the synchronizing pulse from the output 39 of module 1. From the output of the register 42, the base address of the recording of the array being generated is fed to one input of the adder 44, the other input of which receives the readings of the counter 43, which is in the initial state.

In addition, the synchronizing pulse from the output of the delay element 31 of module 1 is supplied both to the direct input of the trigger 26, setting it to a single state, in which the And element 28 for the next input pulse from the input 35 is closed, and the And element 27 is open, and to the input of the delay element 32, which delays the synchronizing pulse for the time the base address code is entered in the register 42 of module 2.

From the output of the delay element 32, the synchronizing pulse through the OR element 30 and the output 40 of the module 1, firstly, goes to the synchronizing input 49 of the adder 44 of the module 2, by which the adder 44 summarizes the readings of the register 42 with the zero readings of the counter 43, since the latter to date time is in the initial state.

Secondly, the same pulse from the output 40 of the module 1 through the input 59 of the module 3 is fed to the direct input of the trigger 53, setting it to a single state, in which the high potential from the direct output of the trigger 53 opens the elements 54 AND, connecting the output of the adder 44 through the elements 54 And groups and elements 56 OR to the address output 17. The address code is issued to the address output 17 of the system as the recording address of the generated data array of the analyzed time period.

Thirdly, the same pulse is delayed by the element 45 of module 2 for the duration of the operation of the adder 44 and the trigger 53 and is output to the output 51 of the module 2 as a synchronizing write pulse, which is output to the system 18 as a synchronizing pulse to write the contents of the register 25 of the module 1 s output 16 of the system to the database at the address generated at the output 17 of the system.

In addition, from the output 51 of module 2, the synchronizing pulse arrives at the counting input of the counter 43, increasing its readings by one, and fixing, thereby recording the fact of writing to the database the next record of the generated array, and to the synchronizing input 70 of module 4 and further to synchronizing input of the comparator 67.

At one input of the comparator 65 from the output of the register 66, a constant code equal to the number 12 is constantly supplied. This constant fixes the number of time series intervals in a year, and in this case it is 12 months. At the other input of the comparator 67, a code is supplied from the output of the counter 65, counting the monthly number of readings of the records of the data array of the next time period. Given that at this point in time, the counter 65 only records the first record of the data array, then its readings will be less than the readings of register 66.

As a result of this, the synchronization signal “less” is generated at the output 71 of the module 4, which, firstly, passes through the input 79 of the module 5 to the counting input of the counter 75, increasing the base read address by one.

Secondly, the same pulse passes through the OR element 76, and from the output 83 it enters the installation 60 input of the trigger 53, setting it to its original state, in which the group of 55 And elements will be open to transmit the address code from the counter output with high potential from the direct output of the trigger 82 to exit 7 of the system.

Thirdly, the same pulse is delayed by element 77 for the duration of the address code output to the system output 17, and then from the output of module 5 5 it is output to the system output 19 as a read pulse received at the input of the first server interrupt channel. By this signal, the server again switches to the subroutine for reading the next record of the data array of the selected time period from the server database at the address generated at output 17.

The contents of the next address of the selected memory cell is again issued by the database server through the system input 10 to the information input of the register 25 of module 1, where it is entered by the server synchronizing pulse received from the system input 13. From the output of register 25, its contents are output to the output 16 of the system. In addition, the synchronizing pulse from the input 13 of the system again goes to the counting input 68 of the counter 65 of module 4, counting the number of read records from the server database, and to the inputs of elements 27, 28 I.

Given that at this point in time, the trigger 26 of module 1 is set to a single state by the previous read pulse, then the low potential from the inverted output element 28 And will be closed, and the element 27 And open high potential from the direct output.

As a result of this, the input pulse passes through the AND element 27 and to the input of the OR element 30 and from the output 40 of module 1, firstly, it passes to the synchronizing input 49 of module 2, by which the adder 44 summarizes the readings of register 42 with the readings of counter 43.

Secondly, the same pulse from the output 40 of the module 1 through the input 59 of the module 3 is fed to the direct input of the trigger 53, setting it to a single state, in which the high potential from the direct output of the trigger 53 opens the elements 54 AND, connecting the output of the adder 44 through the elements 54 And groups and elements 56 OR to the address output 17. The address code is issued to the address output 17 of the system as the next record address of the generated data array of the analyzed time period.

Thirdly, the same pulse is delayed by the element 45 during the operation of the adder 44 and the trigger 53 and is issued to the output 51 of the module 2 as a synchronizing write pulse. This pulse is issued to the output 18 of the system as a clock pulse to write the contents of the register 25 of module 1 from the output 16 of the system.

In addition, from the output 51 of module 2, the synchronizing pulse arrives at the counting input of the counter 43 of module 2, increasing its readings by one, and thereby recording the fact of writing to the database the next record of the array being formed, as well as to the synchronizing input 70 of module 4 and further to the synchronizing input of the comparator 67

At one input of the comparator 67 from the output of the register 66, a constant code equal to the number 12 is constantly supplied. This constant fixes the number of time series intervals in a year and in this case it is 12 months. At the other input of the comparator 67, a code is supplied from the output of the counter 65, counting the monthly number of readings of the records of the data array of the next calendar period.

If the readings of the counter 65 are less than the code of the register constant 66. then the output of the comparator 67 generates a synchronization signal “less than or equal to”, which, firstly, through the input 79 of the module 5 is fed to the counting input of the counter 75, increasing the base read address by one .

Secondly, the same pulse passes through the OR element 76 and from the output 83 it enters the installation 60 input of the trigger 53 of module 3, setting it to its initial state, in which the group of 55 And elements will be open to transmit the address code with the high potential from the direct output of the trigger the output of the counter 75 to the output 17 of the system.

Thirdly, the same pulse is delayed by element 77 for the duration of the address code output to the system output 17, and then from the output of module 5 5 it is output to the system output 19 as a read pulse received at the input of the first server interrupt channel.

By this signal, the server again switches to the subroutine for reading the next record of the data array of the selected time period from the server database at the address generated at output 17.

The process of reading the troops regrouping data from the selected time period and writing them to the analyzed server database array continues as described above until the comparator 67 of module 4 fixes the fact of the equality of the input codes. In other words, at the moment of equality of the constant code stored in register 66 with the number of records recorded by the counter 65, a signal is generated at the output 72 of the comparator 67 of module 4 by the clock pulse supplied to the clock input of the comparator 67, indicating the end of the data sampling of the first interval time period. This signal from the output 72 of module 4 through the input 106 of module 7, firstly, enters the counting input 106 of the counter 100 intervals, increasing its readings by one.

Secondly, the same signal is delayed by the delay element 103 for the response time of the counter 100, and is fed to the synchronizing input of the comparator 102. A code for the numerical value of the time period is constantly applied to one input of the comparator 102 from the output of register 100. At the other input of the comparator 100, the readings of the counter 101 intervals of the time period. The comparator 102 of module 7 compares the codes on the clock pulse from the output of the delay element 103.

If the readings of the counter 101 are less than the value of the specified time period of the register 100, then a signal is generated at the output 107 of the comparator 102, which, firstly, goes to the counting input 96 of module 6 and then to the counting input of the counter 85 and increases the quantity by one.

Secondly, the same pulse is supplied to the installation input 69 of module 4 and then to the installation input of counter 65, through the input 81 of module 5 it enters the installation input of counter 75, and through input 36 of module 1 it enters the installation input of trigger 26, returning them to the initial state.

Thirdly, the same pulse through the input 96 of module 6 goes to the input of the OR element 91, is delayed by the element 92 for the duration of the operation of the counter 85 and the decoder 86. Then the same pulse goes to the inputs of the elements 88 - 90 AND, interrogating their state.

Given the fact that the open decoder 56 at one input will now be another of the elements 57-59 AND, corresponding to the next interval, then after passing the corresponding element And, the clock pulse, firstly, is fed to the read input of the corresponding fixed memory cell of the permanent storage device 87.

In a fixed ROM cell, the base address of the server database memory cell is stored, starting from which the data array of the specified period is stored in the server database and reads the code of the base address of this period to the output of module 97.

The base address code from the output 97 of the module 6 through the input 80 of the module 5 is fed to the information input of the counter 75 (Fig. 5), where it is entered by the synchronizing pulse from the output 98 of the module 6.

The base address code from the output 82 of the counter 75 of the module 5 is fed to the information input 58 of the module 3, where it is fed to one of the inputs of the 55 And group elements. In parallel, the synchronizing pulse from the output 83 of the module 5 through the input 60 of the module 3 is supplied to the installation input of the trigger 53 of the module 3 and confirms its initial state, in which the high-potential from the inverse output of the trigger 53 opens the elements 55 And groups on one input. The code of the base address from the output of the counter 75 through the input 58 of module 3 is fed to the other inputs of the elements of the 55 AND group, the elements 56 OR of the group pass and issued to the address output 17 of the system.

In parallel with the described process of generating the server database read address, the synchronizing pulse from the input 78 of module 5 passes the OR element 76, is delayed by the element 77 for the time of operation of the counter 75, and then it is output to the system 19 as a read pulse received at the input of the first interrupt channel server. By this signal, the server switches to the reading routine of the first record of the next data array from the server database at the address generated at output 17.

The contents of the base address of the selected memory cell is issued by the database server through the system input 10 to the information input of the register 25 of module 1, where it is entered by the server synchronizing pulse coming from the system input 13. From the output of register 25, its contents are output to the output 16 of the system. In addition, the synchronizing pulse from the input 13 of the system goes both to the counting input 68 of the counter 65 of module 4, which counts the number of read records from the server database, and to the inputs of the elements 27, 28 I. Considering that at this point in time, the trigger 26 continues to be in a single state, then the low potential from the inverse output element 28 And will be closed, and the element 27 And open high potential from the direct output.

As a result of this, the pulse from input 35 passes through element 27 AND to the input of element 30 OR and from output 40 of module 1, firstly, it goes to the synchronizing input 49 of adder 44 of module 2, by which adder 44 summarizes the readings of register 42 with the readings of counter 43 .

Secondly, the same pulse from the output 40 of the module 1 through the input 59 of the module 3 is fed to the direct input of the trigger 53, setting it to a single state, in which the high potential from the direct output of the trigger 53 opens the elements 54 AND, connecting the output of the adder 44 through the elements 54 And groups and elements 56 OR to the address output 17. The address code is issued to the address output 17 of the system as the next record address of the generated data array of the analyzed time period.

Thirdly, the same pulse is delayed by the element 45 for the duration of the operation of the adder 44 and the trigger 53 and is output to the output 51 of the module 3 as a synchronizing write pulse. This pulse is issued to the output 18 of the system as a synchronizing pulse recording the contents of the register 25 from the output 16 of the system.

In addition, from the output 51 of module 3, the synchronizing pulse arrives at the counting input of the counter 43 of module 2, increasing its readings by one, and thereby recording the fact of writing to the database the next record of the array being formed, as well as to the synchronizing input 70 of the comparator 67 module 4. At one input of the comparator 67 from the output of the register 66, a constant code is constantly applied, fixing the number of time series intervals. At the other input of the comparator 67, a code is supplied from the output of the counter 65, which counts the number of readings of the records of the data array of the next calendar period.

If the readings of the counter 65 will be less than the code of the constant of the register 66. then the output of the comparator 67 generates a synchronizing signal "less than or equal to", which, firstly, through the input 79 goes to the counting input of the counter 75, increasing the base address of reading by one.

Secondly, the same pulse passes through the OR element 76 and from the output 83 it enters the installation 60 input of the trigger 53 of module 4, setting it to its initial state, in which, with a high potential from the direct output of the trigger, the group of 55 And elements will be open to transmit the address code with the output of the counter 75 to the output 17 of the system.

Thirdly, the same pulse is delayed by element 77 for the duration of the address code output to the system output 17, and then from the output of module 5 5 it is output to the system output 19 as a read pulse received at the input of the first server interrupt channel. By this signal, the server again switches to the subroutine for reading the next record of the data array of the selected time period from the server database at the address generated at output 17.

The described process of forming the analyzed data array continues until the comparator 102 of module 7 fixes the equality of the numerical values in the counter 101 and the register 100 by issuing a synchronizing signal at the output 108.

This synchronizing signal, firstly, is output to the system 20 and then to the input of the third channel of the server interrupt. With the arrival of this signal, the server switches to a program for calculating the desired values of the regrouping indicators of military units.

Secondly, the same synchronizing signal arrives at the installation inputs of the nodes and elements of the system, returning them to their original state.

The results of solving the problem of estimating the duration of a regrouping in the main ways are presented in the form of a table containing the calculated durations of the regrouping in various ways.

Thus, the introduction of a tool that implements the planning process for regrouping troops (forces) with the main means of transport, made in the form of a server using calculation programs to calculate the desired values for the regrouping of military formations, presented in the form of a table containing calculated data on the duration of the regrouping of troops (forces) in various ways, it allowed to significantly expand the functionality of the system.

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

RF patent No. 2449367 (04/28/2011)

RF patent No. 77 470 (04.16.2008) - (prototype).

AUTHORS                                    Vypasnyak V.I.

                                             Gouralnik A.M.

                                             Kotenev M.E.

                                             Larionov M.Yu.

                                             Makartsev L.V.

                                             Protasov A.A.

                                             Skachko P.G.

                                             Skachko A.P.

                                             Ushakov V.I.

Claims (1)

An automated information system for planning the regrouping of troops (forces) by the main means of transport, containing a module for selecting the reference address for recording the data array in the server database, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, while the first information input of the system is designed to receive base records server data, the first synchronizing input of the system is designed to receive synchronizing pulses of recording database records with the server into the selection module for selecting a reference address for recording a data array in a server database, and the first information output of a module for selecting a reference address for recording a data array in a server database is an information output of the system, a module for integrating address signals for reading and writing data, the output of which is an address output of the system, a module for modifying the addresses for reading calculated data, the information input of which is connected to the second information output of the module for selecting the reference address of the record of the data array in the database yes server, one synchronizing input of the module for calculating the read addresses of the calculated data is connected to the first synchronizing output of the module for selecting the reference address of the record of the data array in the server database, and the other synchronizing input of the module for modifying the addresses of reading of the calculated data is connected to the second clock data in the server database, while the information output of the module for modifying the addresses for reading the calculated data is connected to the same information the input input of the module for integrating address signals for reading and writing data, the first synchronizing input of which is connected to the second synchronizing output of the selection module for the reference address of the recording of the data array in the server database, and the synchronizing output of the module for modifying the addresses for reading the calculated data is the first synchronizing output of the system control signals to the input of the first channel of the interruption of the database server, the module generating the current address for reading data temporarily of the period of the regrouping of troops, the information output of which is connected to another information input of the module for integrating the address signals of reading and writing data, one synchronizing output of the module for generating the current address for reading data from the time period of the regrouping of troops is connected to the second synchronizing input of the module for integrating the address signals for reading and writing data, and the other synchronizing output of the module for generating the current data reading address of the time period of the regrouping of troops is the second synchronizing system output intended for issuing control signals to the input of the second channel of the database server interruption, the troop regrouping interval identification cycle identification module, the synchronizing input of which is connected to the first synchronizing system input, the clock input of the troop regrouping interval identification cycle identification module is connected to the synchronizing the output of the module for modifying the addresses for reading the calculated data, and the first output of the loop identification module troop regrouping intervals are connected to the clock input of the module for generating the current address for reading the data of the temporary regrouping of troops, the module for selecting the base address of the temporary period of troop regrouping, the information and synchronizing inputs of which are the second information and synchronizing inputs of the system, while the second information input of the system is designed to receive parameters of the intervals of regrouping troops, and the second synchronizing input of the system is intended for receiving synchronizing pulses of entering parameters of annual intervals of the regrouping of troops into the selection module of the base address of the temporary period of troop regrouping, the information output of the selection module of the base address of the temporary period of troop regrouping is connected to the information input of the module for generating the current read address of the data of the temporary regrouping of troops, and the synchronizing output of the base module of selection of the troop addresses of the time period of the regrouping of troops connected to the synchronizing input a module for generating a current address for reading data of a time period of a regrouping of troops, and a module for identifying the boundaries of a temporary period of regrouping of troops, the information and synchronizing inputs of which are the third information and synchronizing inputs of the system, while the third information input of the system is designed to receive the identifier of the initial interval of the time period of the regrouping of troops, and the third synchronizing input of the system is designed to receive synchronizing impulses I am the identifier of the initial interval of the time period of the regrouping of troops in the module for identifying the borders of the time period of the regrouping of troops, the clock input of the module for identifying the borders of the time period of the regrouping of troops is connected to the second output of the module for identifying the cycles of the formation of the intervals of the regrouping of troops, while the first output of the module for identifying the boundaries of the time period of the regrouping of troops is connected with the installation inputs of the modules for forming the current address for reading temporary data the period of regrouping troops, selecting the base address of the time period of regrouping troops, identifying cycles for the formation of intervals for regrouping troops and selecting the reference address for recording a data array in the server database, and the second output of the module for identifying the boundaries of the time period for regrouping troops is the third synchronizing output of the system for signaling control on the input of the third channel of the database server interrupt, characterized in that the system comprises means, The process of planning the regrouping of troops (forces) by the main means of transport, made in the form of a server using calculation programs to calculate the desired values of the regrouping of military formations, presented in the form of a table containing calculated data on the duration of the regrouping of troops (forces) in various ways.

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