RU117664U1 - AN OPPOSITION INFORMATION AND ANALYTICAL PLANNING SYSTEM FOR FIRE DAMAGE OF AN OPPONENT - Google Patents

Abstract

An information-analytical system for planning fire engagement of a group of forces, containing a module for identifying the reference address of a selected group of forces in the database of the system server, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, respectively, while the information input of the identification module for the reference address of the selected group of forces in the system server database is designed to receive monitoring codograms, and the synchronizing input of the identification module of the reference address of the selected group of forces in the system server database is intended to receive signals for entering monitoring codograms into the identification module of the reference address of the selected group of forces in the system server database, the module for generating read addresses database data of the system server, the information input of which is connected to the first information output of the identification module of the reference address of the selected group of forces in the database system server, and the synchronizing input of the module for generating addresses for reading data from the system server database is connected to the synchronizing output of the module for identifying the reference address of the selected group of forces in the system server database, the module for integrating address signals for reading data from the system server database, the first address input of which is connected to the address output of the module for generating addresses for reading data from the system server database, the first synchronizing input of the module for integrating address signals for reading data from the system server database is connected to synchronization

Description

The utility model relates to computer technology, in particular, to the information-analytical system for planning fire destruction of a force grouping.

It is known that groupings of troops, like group objects, are systems of one or another complexity (1).

As systems, they are largely similar: they have centralized management; have a certain independence in solving assigned tasks; have internal reserves to restore the affected elements and the system as a whole; open to external influences from their supersystem, interacting systems and the enemy; their composition can be distinguished by its own subsystems

At the same time, the methods of fire destruction of groups and objects differ significantly (2).

The main method of fire destruction of the latter is areal, when almost all manpower and military equipment is exposed to simultaneous fire (the exception is observed objects that are hit by guided ammunition).

As a result, as a rule, an object completely loses combat effectiveness for the entire period of hostilities or temporarily, i.e. destroyed or suppressed. Note that in both cases, it is not provided for a partial loss of combat effectiveness or its reduction (the object’s action is part of the forces) - this is achieved only when solving the problem of its disorganization. Therefore, the main criterion for assessing the result of fire impact on an object is its condition (combat readiness).

When a group of forces is defeated with conventional weapons, selective influence is characteristic (object, structural, in directions, etc.), since in modern conditions it is more advantageous to “knock out” certain important units in the enemy’s group of fire than to try to hit many objects in the entire band action.

Being, as a rule, systems with redundancy, groups, while maintaining operational (combat) integrity, do not lose the ability to conduct armed struggle, i.e. they cannot be destroyed or suppressed. For their destruction or suppression by means of fire destruction, there simply may not be enough strength.

As the experience of wars and military conflicts of recent decades shows, the completion of the destruction (defeat) of groups can be carried out only by subsequent blows of ground troops (forces).

The significant difference in the value of critical losses for objects and groupings of troops is explained by the fact that when groups are defeated, not all of their composition is exposed to fire, but only certain, most important objects.

In this case, the so-called operational (combat) stability centers (command posts, ground-based aviation control centers, elements of reconnaissance systems, air defense, electronic warfare systems, etc.), whose functional importance is great, are primarily affected. The degree of their defeat can reach 20-30% when suppressed and 50-60% when destroyed (3).

The same losses are suffered by combined-arms formations of the first echelon operating in the main directions, and, of course, fire weapons. Since the numerical composition of these objects is small compared with the total number of groups, its total losses are negligible. It follows that the direct transfer of the degrees of destruction established for group targets to groupings of troops leads to a significant overestimation of the degree of defeat of the latter.

Any troop grouping is a combination of various subsystems (4), the definition of tasks and the required degree of fire destruction of which is a special problem, the proposed technical solution of the task is aimed at solving it.

Known systems that could be used to solve the problem (5, 6).

The first of the known systems contains the first and second system units, comprising central processor modules, the first and second unified workstations connected to data storage and display units, a local computer network, communication and data switching equipment (5).

A significant drawback of this system is its structural complexity.

Another system is known that contains a data input unit, a significance vector generation unit, a system configuration formalization unit, a distribution matrix generation unit, the inputs of which are connected to the outputs of the data processing units, and the outputs are connected to the input of the result output unit (6).

The last of the above technical solutions is closest to the described.

Its disadvantage lies in the low speed of the system, due to the fact that the calculation procedure for the required degree of defeat of the enemy’s combat and numerical strength is implemented by searching for calculation data across the entire system server database and their subsequent processing by the central processor, which inevitably leads to large amounts of data to a large investment of time, and, as a result, leads to low efficiency of use of this system.

The purpose of the utility model is to increase the system’s speed when planning the engagement of enemy troops by fire by localizing the addresses of database records by group identifiers of both own forces and assets, and forces and means of enemy forces.

This goal is achieved by the fact that in the known system containing the identification module of the reference address of the selected troop group in the system server database, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, respectively, while the information input is the identification module of the reference address of the selected troop group in the system server database is designed to receive monitoring codograms, and the synchronizing input of the reference address identification module to a combat force grouping in the system server database is designed to receive signals for entering monitoring codograms into the identification module of the reference address of the selected force grouping in the system server database, a module for generating read addresses of the system server database data, the information input of which is connected to the first information output of the reference identification module addresses of the selected troop grouping in the system server database, and the synchronizing input of the module for generating addresses for reading database data data of the system server is connected to the synchronizing output of the identification module of the reference address of the selected troop group in the system server database, the integration module of the address signals for reading data from the database of the system server, the first address input of which is connected to the address output of the module for generating read addresses of the system server database data read the synchronizing input of the integration module of the address signals for reading data from the database of the system server is connected to the synchronizing output of the ident module fiction of the reference address of the selected group of troops in the system server database, while the address output of the integration module of the address reading signals of the system server database data is the address output of the system designed to provide the read addresses to the address input of the system database server, the first synchronizing output of the integration module address signals of reading data from the database of the system server is the first synchronizing output of the system designed to issue control signals to the first interrupt input of the system database server, and the second synchronizing output of the integration module of the address reading signals of the system server database data read is the second. the system’s synchronizing output, intended for issuing control signals to the second input of the system database server interrupt, a module for fixing the boundaries of the troop grouping data is introduced, the information input of which is connected to the second information output of the identification module of the reference address of the selected troop group in the system server database, and the synchronizing the input of the module for fixing the boundaries of the sample of data of the grouping of troops is connected to the synchronizing output of the module for identifying the reference address of the selected troop testing in the system server database, while the first output of the module for fixing the boundaries of the data of grouping of troops is connected to the counting input of the module for generating the read addresses of the database data of the system server and with the first clock input of the module for integrating the address signals for reading the data from the system server database, and the second the output of the module for fixing the boundaries of the sample of data of the grouping of troops is connected to the second clock input of the module for integrating the address signals of reading the data from the database of the system server l determine the direction of data monitoring, the information input of which is connected to the third output of the identification module of the reference address of the selected troop group in the system server database, and the synchronizing input of the module for determining the direction of data monitoring is connected to the second synchronizing input of the system, the module for identifying the share of participation of military equipment in fire destruction , the first information input of which is connected to the fourth information output of the identification module of the reference address of the selected group troops in the system server database, the identification module of the specified monitoring parameter, one information input of which is the second information input of the system designed to receive data from the system server database, the other information input of the identification module of the specified monitoring parameter is connected to the fifth information output of the reference identification module addresses of the selected force grouping in the system server database, synchronizing the input of the identification module of the specified monitoring parameter is the second synchronizing input of the system intended for receiving the synchronizing signals of entering the input data into the identification module of a given monitoring parameter, and the clock input of the identification module of a given monitoring parameter is connected to the clock output of the module for determining the direction of data monitoring, while one information output of the identification module of the specified monitoring parameter is information output of the system intended for the issuance of the final results of the battle monitoring of the composition of the groupings, another information output of the identification module of the specified monitoring parameter is connected to the second information input of the identification module of the participation share of the combat weapon in the fire defeat, the clock output of the identification module of the specified monitoring parameter is connected to the first clock input of the module for fixing the boundaries of the sample data of the force grouping, and the synchronizing output identification module of a given monitoring parameter is connected to one synchronizing input of the identification module dol the participation of a combat weapon in a fire defeat, the other synchronizing input of which is connected to the synchronizing output of the module for determining the direction of data monitoring, the module for modifying the data write and read addresses, the information input of which is connected to the information output of the module for determining the direction of data monitoring, the synchronizing input of the module for writing and reading address modification the data is connected to the first output of the identification module of the share of participation of a military weapon in a fire defeat, and the timing input the data recording and reading address modification module is connected to a clock output of the system server database data reading address integration signal integration module, wherein one information output of the data writing and reading address modification module is connected to the second information input of the address server data reading signal integration module of the system server database data, and the first clock output of the module for modifying write and read addresses is the third clock output of the system, while the second the output of the identification module of the share of participation of the combat weapon in fire engagement is connected to the second clock input of the module for fixing the boundaries of the sample data of the group of troops, and the first synchronizing output module for modifying the write and read addresses is connected to the third clock input of the module for fixing the borders of the sample of data of the group of troops, and the control module the issuance of data, the information input of which is connected to the second information output of the module for modifying the addresses of writing and reading data, synchronizing input One of the data output control module is connected to the second synchronizing output of the data write and read address modification module, the first output of the data output control module is connected to the third clock input of the integration module of the address read signals of the system server database data, and the second output of the data output control module is the signal output the system, while the first output of the module identifying the share of participation of the weapon in fire engagement is connected to the fourth clock input of the integ module ation address signals database server data reading system.

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 constructive implementation of a module for identifying a reference address of a selected group of troops in the system server database, Fig. 3 shows an example of a specific constructive implementation of a fixation module the boundaries of the sample data of the grouping of troops, figure 4 - shows an example of a specific constructive implementation of the module integration of the address signals of reading data from the database server system, figure 5 - shows an example of a specific constructive implementation of an identification module of a given monitoring parameter, FIG. 6 is an example of a specific constructive implementation of a module for determining a direction for monitoring data, FIG. 7 is an example of a specific constructive implementation of a module for modifying data recording and reading addresses, and FIG. 8 is an example. specific constructive implementation of the module identifying the participation share of a military weapon.

The system (Fig. 1) comprises a module 1 for identifying the reference address of the selected troop group in the system server database, a module 2 for fixing the boundaries of the troop group data, module 3 for generating the read addresses of the system server database data, module 4 for integrating the address signals for reading the database data system server, module 5 for identifying a given monitoring parameter, module 6 for determining the direction of data monitoring, module 7 for modifying write and read addresses, module 8 for identifying a share I am a combat weapon in fire engagement, module 9 data output.

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

Module 1 (figure 2) identification of the reference address of the selected grouping of troops in the system server database contains a register 30, a memory unit 31, made in the form of read-only memory, a decoder 32, elements 33-35 And, elements 36-37 delay.

The drawing also shows information 11 and synchronizing 13 inputs, as well as the first 21, second 22, third 23, fourth 24, fifth 25 information and synchronizing 26 outputs.

Module 2 (figure 3) fixing the boundaries of the sample data of the grouping of troops contains a register 45, a counter 46, a comparator 47, an element 48 OR, and an element 49 delay. The drawing shows information 51, synchronizing 52, and the first 53, second 54, third 55 clock inputs, as well as the first 56 and second 57 outputs.

Module 3 (Fig. 1) of generating the read addresses of the database data of the server of the system is made in the form of a counter having an information 38, synchronizing 39 and counting 40 inputs, as well as the output 41 of the module.

Module 4 (Fig. 4) of the integration of the address signals for reading data from the database of the system server contains a trigger 60, elements 61-63, 69 OR, groups 64-65 elements AND, group 66 elements OR, and elements 67, 68 delay. The drawing shows the first 71 and second 72 address inputs, the first 73, second 74, third 75, fourth 76 and fifth 77 clock inputs, as well as address 16, first 17, second 18 and third 19 clock outputs.

The module 5 (figure 5) for identifying a given monitoring parameter contains a register 42 and a comparator 43. The drawing shows the first 12 and second 44 information inputs, the first 14 and second 45 clock inputs, as well as the first 15, second 79 information, the first 80 and second synchronizing outputs.

Module 6 (Fig. 6) for determining the direction of data monitoring comprises a memory unit 85 made in the form of read-only memory, a decoder 86, a register 87, AND elements 88-90, an OR element 91, a delay element 92. The drawing also shows information 93 and synchronizing 94 inputs, information 95 output, and synchronizing 96, 97 outputs.

Module 7 (Fig. 7) of the modification of write and read addresses contains an adder 100, a counter 101. An OR element 102, delay elements 103, 104. The drawing shows the information input 106, synchronizing 107 and counting 108 inputs, as well as the first 109 and second 110 information and the first 111 and second 112 synchronizing outputs.

Module 8 (Fig. 8) for identifying the participation share of a combat weapon in a fire engagement contains a comparator 125 and an OR element 126. The drawing shows the first 128 and second 129 information inputs, the first 130 and second 131 clock inputs, as well as the first 132 and second 133 outputs.

The module 9 (Fig. 1) for controlling the data output is made in the idea of a comparator having information 134 and 135, and synchronizing 136 inputs, as well as outputs 135 and 136.

The software package of the system uses the information and calculation tasks to ensure the overall planning of fire destruction, in particular:

- the task of clarifying the required degree of damage;

- the task of conditional distribution;

- the task of determining the degree of defeat achieved and the equity participation in it of various means.

The order of the system when planning enemy fire damage is determined by the following algorithm of the system:

1) Input of the initial data in the format in which they are received in the guidelines and working documents, without converting them into arbitrary units, saving the initial data in the local database of the system;

2) Refinement of the results of calculations of the required degree of damage (in terms of details on the types of targets) coming from other software (if necessary);

3) Solving the optimization problem of conditional target distribution, storing the results in a local database, issuing data on the magnitude of the degree of defeat achieved and the share of the means of destruction in the AKI;

4) Detailing the results of solving the problem of conditional target allocation according to the conditions of the organization of the stages of the operation in terms of the distribution of the resource according to the tasks of the operation and the lines of action of the troops and the distribution of weapons in directions

5) Saving the results of solving problems in the local system database for their further use in the formation of screen forms and output documents.

To solve the problem, the monitoring parameters of the database of the combat and numerical strength of the opposing groupings are determined, which determine the specific values of the indicators that influence the formation of the required value of the degree of defeat of the combat and numerical strength of the enemy groupings.

For this purpose, monitoring codograms are formed having the following structure:

The identifier of the group of combat and numerical strength The required value of the degree of defeat of the combat and numerical strength of the enemy Grouping identifier code is entered The value code of the selected indicator is entered

This codogram is fed to the information input 11 of the system and with a clock pulse from input 13, the codogram of the request is entered in the register 30 of module 1.

From the first output of the register 30, the grouping identifier code is input to the decoder 32. The decoder 32 determines the sign of the selected troop grouping, giving out one of its outputs high potential.

For definiteness, we assume that a high potential is received at one input of element 34 I. In parallel with this, the synchronizing pulse from input 13 is delayed by element 36 for the duration of operation of decoder 32, and then polls the states of elements 33-35 I.

Considering the fact that only the And element 34 will be open at one input, then, having passed this And element, the clock pulse arrives, firstly, at the read input of a fixed memory cell of the permanent storage device 31.

This cell stores the code of the base address of the system server’s memory zone (not shown in the drawing), which is assigned to this grouping, and the code of the total number of records of combat and numerical strength in the database of the selected grouping.

The structure of the data record in the memory cell of the permanent storage device is as follows:

The code The code The base address of the memory zone of the system server that is assigned to this grouping The total number of records of the combat and strength of the troops in the database of the selected group Output 21 of module 1 Output 22 of module 1

The code of the reference address of the memory zone of the database of the server of the system is read to the information input 38 of the counter 3, where it is entered by the synchronizing read pulse, delayed delay element 37 during the reading of the contents of the fixed ROM cell, and from the output 26 of module 1 coming to the synchronizing output of counter 3. V as a result, the counter of the memory zone address code coming from the output 21 of module 1 will be recorded in counter 3. From the output 41 of the counter 3, the address code through the input 71 of module 4 is fed to one of the inputs of the group of elements 65 I.

The code of the total number of records of the combat and numerical strength of forces and equipment that is part of the selected group from output 22 of module 1 goes to the information input 51 of module 2 and then goes to the information input of register 45 of module 2, to the synchronizing input of which there is a pulse from output 26 of the module 1 and enters into it the code of the total number of records of the combat and numerical strength of the forces and equipment that is part of the selected grouping.

At the same time, the same synchronizing pulse from the output 26 of module 1 passes through the input 69 of module 4 through the input 73 of module 4 and arrives at the installation input of trigger 60, setting the latter to its original state, in which a group of 65 elements will be opened from the inverse output of trigger 60 And, through which the output of the counter 3 will be connected to the output 16 of the system.

In parallel with this process, the same clock pulse from module 26 output 1 through module 73 input 73 passes OR element 61, is delayed by element 67 while the base address code is entered into counter 3, and then from the system output 17 it enters the input of the first base server interrupt channel data.

By this signal, the server goes to the subroutine for reading the contents of the database cell at the address specified on the system output 16, issuing the read record to the information input 12 of the system and recording the contents of the record in the register 42 of module 5 with the synchronizing server pulse received at the system input 14.

The structure of the codogram of a read record from the system database will have the following form:

The code The code The code The current value of the indicator of combat potential The maximum value of combat potential achieved by this tool Other record attributes, including performance data

The code of the current value of the indicator of the combat potential of this weapon from the first output of the register 42 of module 5 is fed to one input of the comparator 43, the other input 44 of which from the output 25 of module 1 is constantly supplied with a code for the value of the indicator of the achieved weapon by this weapon.

At the same time, the synchronizing pulse from the input 14 of the system goes to the input 94 of the module 6, the information input of which from the output 23 receives the code of the maximum value of the combat potential achieved by this tool.

From the input 93 of module 6, the code of the maximum value of the combat potential achieved by this weapon is supplied to the input of the decoder 86. The decoder 86 decodes the code of the maximum value of the combat potential, giving out one of its outputs a high potential.

For definiteness, we assume that a high potential is received at one input of the 88 I element. At the same time, a synchronizing pulse from input 94 enters the other inputs of the 88-90 I elements, interrogating their state. Given the fact that only one element And will be open at one input, then, having passed this element And, the clock pulse arrives, firstly, at the read input of a fixed memory cell of the permanent storage device 85.

In this cell, the reference address of the server memory zone is reserved for storing the generated record file according to the results of data sampling of the given troop grouping. The reference address code of this memory zone is read into the information input of register 87.

Secondly, the same read pulse about the input 94 of the module 6 is delayed by the delay element 92 for the time of reading the contents of the fixed cell ROM 85 and then goes to the synchronizing input of the register 87, fixing the base address code in it.

Thirdly, the same clock pulse from the output of element 88 AND passes through the element 91 OR, and from the output 96 of module 6 it enters the synchronizing input 45 of the comparator of module 5, which compares the quantitative values of the achieved magnitude of the defeat with this weapon and the set value of the magnitude of the defeat of the troop group in whole.

If the quantitative values of the indicator of the magnitude of the defeat by this weapon are higher than or equal to the established indicator of the magnitude of the defeat, then the comparator 43 of the module 5 generates a signal at the output 80 of the module 5, which passes through the element 53 of the module 3 OR element 48, and enters the counting input of the counter 46, counting the number of records read.

The output code of the counter 46 is fed to one input of the comparator 47, the other input of which from the output of the register 45 is constantly supplied with the code of the total number of records stored in the database of the system server.

In parallel, the synchronizing pulse from the output of the 48 element OR is delayed by the element 49 for the duration of the counter operation and arrives at the synchronizing input of the comparator 47. The comparator 47 compares the number of scanned records with a fixed number in the register 45 using the synchronizing signal received at its information input.

If the comparison of numbers did not happen, then at the output 56 of module 2 a signal is generated, which, firstly, is fed to the counting 40 input of the counter 3, increasing its readings by one. As a result of this, the newly formed address for reading the next record will be issued to the system output 16.

Secondly, the synchronizing pulse from the output 56 goes to the input 74 of the module 4, where, firstly, it passes through the OR element 69 and goes to the installation input of the trigger 60, confirming its initial state, and secondly, the OR element 61 passes , is delayed by element 67 for the duration of counter 3 and trigger 60 operation, and then from the output 17 of the system it is fed back to the input of the first channel of the database server interrupt.

Based on this signal, the server again goes to the subroutine for reading the contents of the next cell of the system server database at the address specified on output 16, issuing it to the information input 12 of the system and recording the contents of the read in register 42 of module 5 with the synchronizing server pulse received at the system input 14 described above way.

If the comparator 43 of module 5 fixes the fact that the numerical value of the achieved defeat is less than the set value for the grouping of troops, then the output 81 of module 5 displays a signal fed to the input 131 of module 8, where the OR element 126 passes and goes to the synchronizing input of the comparator 125, to the input 79 of which the code of the readable value of the defeat from the read record is received, and to the input 128 the code of the set achievable value of the defeat from the output 24 of the module 1 is received.

By a synchronizing signal from the output of the OR element 126, the comparator 125 compares the incoming input codes. If the values of the codes of the achieved values did not match, then the output 133 of module 8 generates a synchronization signal, which is fed to the input 54 of module 2, where element 48 OR again passes, and fed to the counting input of the counter 46, fixing the fact of viewing the next record of data of the readable troop group.

The output code of the counter 46 is fed to one input of the comparator 47, the other input of which from the output of the register 45 is constantly supplied with the code of the total number of grouping entries stored in the system server database.

In parallel, the synchronizing pulse from the output of the 48 element OR is delayed by the element 49 for the duration of the counter operation and arrives at the synchronizing input of the comparator 47. The comparator 47 compares the number of scanned records with a fixed number in the register 45 using the synchronizing signal received at its information input.

If the comparison of numbers did not happen, then at the output 56 of module 2 a signal is generated, which, firstly, is fed to the counting 40 input of the counter 3, increasing its readings by one. As a result of this, the newly formed address for reading the next record will be issued to the system output 16.

If the comparator 125 of module 8 fixes the equality of the codes of the achieved damage value at its inputs, then this fact will be confirmed by issuing a synchronizing pulse to the output 132 of module 8. From where this pulse goes to the input 77 of module 4 and to the input 107 of module 7.

From the input 77 of module 4, the synchronizing pulse through the element 63 OR is supplied to the direct input of the trigger 60 and sets it to a single state, in which the high potential from the direct output of the trigger 60 will open the elements 64 And groups through which the address code from the input 72 passes through the elements 66 And groups to exit 16 of the system.

From the input 107 of module 7, the synchronizing pulse, firstly, passes through the OR element 102 to the synchronizing input of the adder 100, to one information input 106 of which from the output 95 of module 6 the base address of the documentation of the read database record with a given allowable lesion value is supplied, and another, the readings of the counter 101 are given, which at this point in time was in the initial state. As a result, at the output 109 of the adder 100 of module 7, an address code will be generated that is equal to the code of the base address of the documentation of the data of the group’s combat weapons having a given defeat value.

The document base address code from the output 109 of the module 7 through the input 72 of the module 4 is issued to the address output 16 of the system as described above.

In parallel, the synchronizing pulse from the input 107 of the module 7 is delayed by the delay element 104 for the time of the operation of the adder and the trigger 60 of the module 4, and from the output 111 of the module 7 goes to the output 19 of the system and then to the input of the third channel of the database server interrupt.

Based on this signal, the database server switches to the subroutine for documenting the groupings read from the database with a fixed defeat value, according to which the entire read record from the output 15 of module 5 is sent to the server information input and is written to the address set on the address output 16 of the system.

Secondly, the pulse from the output of the delay element 104 is supplied to the summing input of the counter 101, which records the fact of writing to the buffer memory of the documentation, and the readings of the counter 102 increased by one go to one of the inputs of the adder 100.

Thirdly, the synchronizing pulse from the output 111 of the module 7 is fed to the input 55 of the module 2 and then through the element 48 OR to the counting input of the counter 46, and to the input of the delay element 49.

Further, the system continues to work as described above until the comparator 47 fixes the fact of viewing all the records, the number of which is determined by the readings of the register 45 of module 2, by issuing a synchronizing signal to the output 57 of module 2. This signal is fed to the input 75 of module 4, where both through the OR element 63 to the single input of the trigger 60, setting it to a single state, and through the OR element 62 to the system output 18 and then to the input of the second channel of the database server interrupt.

Based on this signal, the database server switches to the data reading subroutine of the opposing group in the manner described above, and then the program for distributing resources according to tasks and directions is launched to ensure the specified value of the enemy’s defeat.

Thus, the introduction of new nodes and modules and new constructive connections made it possible to significantly increase the system’s speed by eliminating the search for analytical processing data across the entire system server database and localizing the search only to the reference addresses of the database of opposing force groupings ..

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

1. Bonin A.S. Quantitative-qualitative correlation of forces of the groupings of the parties. Ministry of Defense of the Russian Federation, 2001.

2. Methodology for assessing the combat potentials of weapons and military equipment and military units of the armed forces of the Russian Federation and foreign states. - M .: CVSI, 2001.

3. Anisimov VG, Anisimov EG et al. Fundamentals of the theory of the effectiveness of combat missile forces and artillery. - M .: Military Publishing, 2003 .-- 168 p.

4. Grebenyuk V.I., Galkin F.A. A methodological approach to solving the problems of the rational distribution of RV&A fire weapons over enemy targets. - S-Pb .: SEC “Morintech”, Thematic collection, issue No. 15, 2004. - 246 p.

6. RF patent No. 101554 (05/27/2010).

7. RF patent No.80604 (08/06/2008) (prototype).

Claims (1)

An information-analytical system for planning the engagement of a grouping of troops, containing a module identifying the reference address of the selected grouping of troops in the system server database, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, respectively, while the information input is the identification module of the identification of the reference address of the selected grouping of troops in the system server database is designed to receive monitoring codograms, and the synchronizing input of the id module The identification of the reference address of the selected group of troops in the system server database is intended for receiving signals to enter monitoring codes into the identification module of the reference address of the selected group of troops in the system server database, the module for generating addresses for reading data from the system server database, the information input of which is connected to the first information output identification module of the reference address of the selected force grouping in the system server database, and the synchronizing input of the formation module system for reading the data from the database of the server of the system is connected to the synchronizing output of the identification module of the reference address of the selected troop group in the system server database, the integration module of the address signals of reading the data from the database of the system server, the first address input of which is connected to the address output of the module for generating the addresses of reading the database data system server, the first synchronizing input of the integration module of the address signals of reading data from the database of the system server is connected to the synchronization the output output of the identification module of the reference address of the selected troop group in the system server database, while the address output of the integration module of the address signals read data from the database of the system server is the address output of the system designed to provide the read addresses to the address input of the system database server, the first synchronizing the output of the integration module of the address signals of reading data from the database of the system server is the first synchronizing output of the system intended for issuing control signals to the first interrupt input of the system database server, and the second synchronizing output of the integration module of the address reading signals of the system server database data is the second synchronizing output of the system, intended for issuing control signals to the second interrupt input of the system database server, characterized in that the system contains a module for fixing the boundaries of the sample data of the force grouping, the information input of which is connected to the second information output of the identification module the reference address of the selected troop grouping in the system server database, and the synchronizing input of the module for fixing the borders of the sample troop grouping data is connected to the synchronizing output of the identification module of the reference address of the selected troop grouping in the system server database, while the first output of the module for fixing the boundaries of the sample troop grouping data is connected with the counting input of the module for generating addresses for reading data from the database of the server of the system and with the first clock input of the module for integrating address signals with data of the system server database, and the second output of the module for fixing the boundaries of the data of the troop grouping is connected to the second clock input of the module for integrating the address signals for reading data from the database of the system server, the module for determining the direction of data monitoring, the information input of which is connected to the third output of the reference address identification module selected grouping of troops in the system server database, and the synchronizing input of the module for determining the direction of data monitoring is connected to the second to the system’s synchronizing input, a module for identifying the share of participation of a military weapon in fire engagement, the first information input of which is connected to the fourth information output of the identification module of the reference address of the selected group of troops in the system server database, the module for identifying a specified monitoring parameter, one information input of which is the second information input system intended for receiving data from the system server database, another information input of the backend identification module of this monitoring parameter is connected to the fifth information output of the identification module of the reference address of the selected troop group in the system server database, the synchronizing input of the identification module of the specified monitoring parameter is the second synchronizing input of the system designed to receive synchronizing signals entering the input data into the identification module of the specified monitoring parameter, and the clock input of the identification module of the specified monitoring parameter is connected to the clock output of the mod To determine the direction of data monitoring, one information output of the identification module of the specified monitoring parameter is an information output of the system designed to provide the final results of monitoring the combat composition of the groupings, another information output of the identification module of the specified monitoring parameter is connected to the second information input of the identification module of the participation share of the weapon in fire damage, the clock output of the identification module of a given monitoring parameter n it is connected to the first clock input of the module for fixing the boundaries of the sample data of the force grouping, and the synchronizing output of the identification module of the specified monitoring parameter is connected to one synchronizing input of the identification module of the participation share of the weapon in the fire, the other synchronizing input of which is connected to the synchronizing output of the module for determining the direction of monitoring data, a module for modifying data recording and reading addresses, the information input of which is connected to the information output m a muzzle for determining the direction of data monitoring, the synchronizing input of the module for modifying the write and read addresses is connected to the first output of the module for identifying the share of the participation of military equipment in fire damage, and the clock input of the module for modifying the addresses for writing and reading data is connected to the clock output of the module for integrating the address signals of reading the database data data of the system server, while one information output of the module for modifying write and read addresses is connected to the second information at the input of the integration module of the address signals for reading data from the database of the server of the system, and the first synchronizing output of the module for modifying the addresses of writing and reading data is the third synchronizing output of the system, while the second output of the module for identifying the share of participation of the weapon in fire engagement is connected to the second clocking input of the fixation module the boundaries of the sample data of the force grouping, and the first synchronizing output of the module for modifying the addresses of writing and reading data is connected to the third clock the module for fixing the boundaries of the sample data of the force grouping, and the data output control module, the information input of which is connected to the second information output of the data write and read address modification module, the synchronizing input of the data output control module is connected to the second synchronizing output of the data write and read address modification module, the first output of the data output control module is connected to the third clock input of the integration module of the address signals for reading data from the database server and the system, and the second output of the data output control module is the signal output of the system, while the first output of the module for identifying the share of participation in the weapon of fire is connected to the fourth clock input of the module for integrating address signals of reading data from the database of the system server.