RU117665U1 - SYSTEM OF SUPPORT OF DECISION MAKING ON FIRE DEFEAT OF GROUP OF AN ENEMY - Google Patents

Abstract

Decision support system for fire engagement of an enemy grouping, containing a block for receiving records of typical plans for fire engagement of combat assets of an enemy grouping, information and synchronizing inputs of which are the first information and synchronizing inputs of the system, while an information input for receiving records of standard plans for fire engagement of combat assets of an enemy grouping is designed to receive records of standard plans from the information outputs of automated workstations of users, and the synchronizing input of the block for receiving records of standard plans for fire engagement of combat assets of an enemy grouping is intended to receive synchronizing pulses from automated workstations of users, the first output of the block for receiving records of standard plans of engagement of combat assets enemy grouping is the information output of the system, intended for issuing data to the information input of the system database server, the receiving unit user requests, the information and synchronization inputs of which are the second information and synchronization inputs of the system, while the information input of the block for receiving user requests is designed to receive user requests from automated workstations of users, and the synchronizing input of the block for receiving user requests is intended to receive synchronizing pulses from automated workers places of users, a block for receiving standard plans for fire destruction of combat assets of an enemy grouping of a system database server, information and sync

Description

The utility model relates to computer technology, in particular, to a decision support system for fire destruction of enemy groups.

In the aggregate of management tasks, a large group consists of poorly structured tasks, the solution of which is associated with the determination of quantitative and qualitative variables, and often the qualitative aspects of the solution dominate.

This circumstance necessitates the creation of software systems based on both traditional methods of algorithmic data processing and methods for creating and using knowledge bases.

The most fruitful methodology for building software systems to solve such problems is the use of information technologies related to the development of expert systems and decision support systems.

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

The first of the known systems contains data reception and storage units connected to control and data processing units, search and selection units connected to data storage and display units, the synchronizing inputs of which are connected to the outputs of the control unit (1).

A significant drawback of this device 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, comprising data receiving units whose outputs are connected to a memory unit and to a data processing unit, a time interval selection unit whose outputs are connected to a data receiving unit, to a user request receiving unit and to a memory unit and to a data processing unit, the outputs of which are connected to one of the inputs of the switching unit of the data output channels, the other inputs of which are connected to the selection of time intervals, and the outputs are the outputs of the system (2).

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

Its disadvantage is the low speed of the system, due to the fact that all the data received by the system is first written to the database of the system, and only then the procedure for processing them begins, which leads to unjustified delays in the time for obtaining the final results.

The purpose of the invention is to increase the system’s speed by eliminating data retrieval across the entire system server database and localizing data retrieval only by the identifiers of the situational situation of opposing force groupings.

This goal is achieved by the fact that in a known system containing a unit for receiving records of typical plans for fire destruction of combat assets of an enemy grouping, the information and synchronizing inputs of which are the first information and synchronizing inputs of the system, while the information input for receiving records of typical plans for fire destruction of combat assets of an enemy group it is intended for receiving records of standard plans from information outputs of user workstations, and synchronizing the first input of the unit for receiving records of typical plans for fire destruction of combat weapons of the enemy group is designed to receive synchronizing impulses from the user's workstations, the first output of the unit for receiving records of typical plans of fire destruction of combat weapons of the enemy’s group is the information output of the system designed to send data to the server’s information input system database, the unit for receiving user requests, the information and synchronizing inputs of which are second with information and synchronizing inputs of the system, while the information input of the user request receiving unit is designed to receive user requests from user workstations, and the synchronizing input of user request receiving unit is designed to receive synchronizing pulses from user workstations, the receiving unit of typical fire destruction plans combat means grouping the enemy server database system information and synchronizing cat inputs Rogues are the third information and synchronizing inputs of the system, while the information input of the receiving unit of typical plans for fire destruction of the enemy group’s weapons of the system database server is designed to receive plans records from the system server’s database, and the synchronizing input of the receiving unit of typical plans of fire fighting of the grouping weapons the adversary of the system database server is designed to receive server synchronizing pulses, the selection block of the user address, information the first input of which is connected to one output of the user request receiving unit, the synchronizing input of the user address selection unit is connected to the third synchronizing input of the system, the data output unit, one information input of which is connected to the information output of the user address selection unit, the other information input of the data issuing unit the output of the reception unit of records of typical plans for fire destruction of combat assets of enemy groupings, the synchronizing input of the data output unit is connected to the output of the selection block of the user address, and the outputs of the data output block are the information outputs of the system group, intended for the issuance of records of fire plans at the information inputs of the corresponding automated places of the system users, the control unit for writing and reading data from the server database, the address output of which is the address output system designed for issuing write and read addresses to the address input of the system database server, the first synchronizing in the stroke of the control unit for writing and reading data from the server database is the first synchronizing output of the system designed to issue synchronizing signals to the input of the first channel for interrupting the database server, and the second synchronizing output for the control unit for writing and reading data from the server database is the second synchronizing output of the system for issuing synchronization signals to the input of the second channel of the database server interrupt, a block for selecting the reference address of the fire plan is introduced the first defeat of the combat weapons of the enemy grouping, the information input of which is connected to the second output of receiving typical fire plans of the combat weapons of the enemy grouping of the system database server, and the synchronizing input of the selection block of the reference address of the plan of fire destruction of the enemy grouping combat weapons is connected to the first synchronizing input of the system, block the formation of the current address of the plan of fire destruction of combat assets of an enemy grouping, the control inputs of which are connected to the controlling outputs of the selection block of the reference address of the plan of fire destruction of the enemy grouping’s combat weapons, the reading inputs of the block of the formation of the current address of the plan of fire of the enemy’s group of weapons are connected to the corresponding outputs of the readout of the block of the selection of the reference address of the plan of combat engagement of the enemy grouping, the first adder, one the input of which is connected to the information output of the selection block of the reference address of the combat fire defeat plan enemy grouping means, another information input of the first adder is connected to the output of the unit for generating the current address of the fire plan of the enemy group’s combat weapons, the synchronizing input of the first adder is connected to the synchronizing output of the selection block of the reference address of the fire plan of the enemy group’s combat weapons, the unit for generating the time period address, the information input of which is connected to the third output of the reception unit of records of typical plans for fire destruction of combat weapons enemy grouping unit, the synchronizing input of the time period address generating unit is connected to the synchronizing output of the selection block of the reference address of the fire plan of the combat weapons of the enemy grouping, and the synchronizing output of the time period address forming unit is connected to the first synchronizing input of the control unit for writing and reading system server database data , the second adder, the information inputs of which are connected to the information outputs of the first adder and block of the time period address, the synchronizing input of the second adder is connected to the synchronizing output of the time period address generation unit, and the output of the second adder is connected to one information input of the server database recording and reading control unit, the selection of the reference reading address, the information input of which is connected to another the output of the block for receiving user requests, the synchronizing input is connected to the second synchronizing input of the system, one information output of the village block the reference reading address is connected to another information input of the system server database data recording and reading control unit, the synchronizing output of the reading reference address selection unit is connected to the second synchronizing input of the server database writing and reading data control unit, and the system server database address generation unit , the information input of which is connected to another information output of the selection block of the reference reading address, synchronizing the input of the forming unit a of the server database of the system is connected to the synchronizing output of the selection block of the reference read address, the control inputs of the server database address generation unit are the system control inputs, while one output of the server database address generation unit is connected to the third synchronizing input of the database data writing and reading control unit server data, and the other output of the server database address generation unit is connected to the fourth synchronizing input of the write control unit and aniem database server database.

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 selection block of a reference address of a plan of fire engagement of combat weapons of an enemy grouping, Fig. 3 shows an example of a specific constructive implementation of a support selection block read addresses of the plan of fire destruction of combat assets of the enemy’s grouping, Fig. 4 shows an example of a specific constructive implementation of the selection block of the user address, Fig. 5 shows An example of a specific constructive implementation of the unit for generating the current address of the plan of fire destruction of the enemy group’s combat assets is shown, FIG. 6 is an example of a specific constructive implementation of the unit for generating the address of a temporary period, and FIG. 7 is an example of a specific constructive implementation of the unit for generating the addresses of the database system server, Fig. 8 shows an example of a specific constructive implementation of a control unit for writing and reading data from a database of a system server; Fig. 9 shows an example of a specific constructive implementation of the data output unit.

The system (Fig. 1) contains a block 1 for receiving records of typical plans for fire destruction of combat weapons of an enemy grouping, block 2 for receiving user requests, block 3 for receiving typical plans for fire destruction of combat weapons for enemy grouping of a system database server, block 4 for selecting a reference address for a plan of fire destruction combat means of the enemy’s grouping, block 5 selection of the reference reading address, block 6 selection of the user’s address, block 7 of the formation of the current address of the plan of fire destruction of military means of grouping anti Vnik, the first 8 and second 9 adders, the block 10 generating the address of the time period, the block 11 generating the addresses of the server database, the block 12 for writing and reading data from the server database and the block 13 for outputting data.

Figure 1 shows the first 15, second 16 and third 17 information inputs of the system, the first 18, second 19 and third 20 synchronizing inputs of the system, the first 21 and second 22 control inputs of the system, information 23 and address 24 system outputs, the first 31 and second 32 synchronizing system outputs, and a group of information 33-35 system outputs.

Block 1 of the reception of records of typical plans for the engagement of combat weapons of an enemy grouping (Fig. 1) is made in the form of a register having information 15 and synchronizing 18 inputs and outputs 36-38.

Block 2 receiving user requests (figure 1) is made in the form of a register having information 16 and synchronizing 19 inputs and outputs 39-40.

Block 3 of the reception of typical plans for fire destruction of combat weapons of an enemy grouping of the system database server (Fig. 1) is made in the form of a register having information 17 and synchronizing 20 inputs, and an output connected to input 168 of block 13.

Block 4 selection of the reference address of the plan of fire defeat of the combat weapons of the enemy grouping (figure 2) contains a memory unit 41, made in the form of read-only memory, a decoder 42, register 43, elements 44-49 And, elements 50-53 delay. The drawing shows information 54 and synchronizing 18 inputs, as well as information 55 and synchronizing 56 outputs, a group of 57-59 control outputs and a group of 60-62 reading outputs.

Block 5 (figure 3) selection of the reference read address contains a memory block 64 made in the form of read-only memory, a decoder 65, elements 66-68 AND, element 69 OR, and element 70 delay. The drawing also shows the information 72 and synchronizing 19 inputs of the block, as well as synchronizing 73 and information 74, 75 outputs.

Block 6 (figure 4) selection of the user address contains a memory block 76, made in the form of read-only memory, a decoder 77, elements 78-80 AND, element 81 OR, and elements 82-83 delay. The drawing also shows information 84 and synchronizing 20 inputs, as well as information 85 and synchronizing 86 outputs.

Block 7 (figure 5) of the formation of the current address of the plan of fire destruction of combat weapons of the enemy grouping contains counters 87-89, groups 90-92 AND elements, a group of elements 93 OR. The drawing also shows a group of 94-96 control inputs, and a group of 97-99 read inputs, as well as information 100 output.

The first adder 8 has information inputs 101, 102, a clock input 103 and an output 104.

The second adder 9 has information inputs 105, 106, a clock input 107 and an output 108.

The time period address generating unit 10 (FIG. 6) comprises a memory unit 110 configured as read-only memory, a decoder 111, a register 112, AND elements 113-115, delay elements 116, 117. The drawing also shows information 118 and synchronizing 119 inputs, information 120 and synchronizing 121 outputs.

The system server database address generation unit 11 of the system (FIG. 7) comprises a register 122, a reverse counter 123, comparators 124, 125, first 126, second 127 and third 128 OR elements, first 129, second 130 and third 131 delay elements, and element 138 OR. The drawing also shows the information 132 and synchronizing 133 inputs of the block, the first 134 and second 135 control inputs of the block, as well as the control outputs 136 and 137 of the block.

Block 12 for writing and reading data from the database of the server of the system (Fig. 8) contains a reversible counter 140, trigger 141, groups 144-145 of AND elements, group 146 of OR elements, elements 142-143 AND, elements 147-148 OR, and elements 149 -151 delays. The drawing shows information 152, 153 inputs, the first 154, second 155, third 156 and fourth 157 synchronization inputs, as well as information 158 outputs and outputs of the record 159 and read 160. In this case, the information output 158 of block 12 is the address input of the system, output 159 block 12 is the first clock output of the system, and the output 160 of the read block 12 is the second clock output of the system.

The data output unit 13 (Fig. 9) contains a register 161, a decoder 162, a first 163, a second 164 and a third 165 of a group of AND elements, a delay element 166. The drawing also shows the first 167 and second 168 information and synchronizing 159 inputs, as well as information 170-173 outputs of the group of outputs of the block.

The system proposed as a utility model is made in the form of a software and hardware complex that includes a technical basis (basic computers of officials and an information exchange server) and a set of software tools.

The software package includes basic software (operating system, graphic and text editors) and elements of a decision support system consisting of:

- the user-system interface part;

- block analysis of problems;

- block forming solutions;

- database (knowledge);

- The base of objective and subjective models.

In addition, in order to reduce the load on the operator’s person, a block was introduced into its structure to determine the need to involve the operator in the decision-making process.

The system will reduce the time it takes to make decisions in cases where this can be done without human intervention and reduce the burden on the human operator in the process of managing complex technical systems.

For this purpose, for each case of the possible composition of the combat assets of opposing groups, a specific plan for the engagement of enemy forces is developed based on typical options for the use of weapons of engagement.

A typical use of fire weapons consists of a number of sections. Each section (subsection) may consist of subsections or points of the plan.

The division of the plan into subsections is mainly related to the perception of the plan by the operator on the screen of the display facilities.

Each item of the plan contains the name of a specific event, indicating the type (type) of forces, means, resources necessary for its implementation and the identifier of the item of the plan, which must be fulfilled before its implementation.

Implementation methods are developed for each point of the plan, and methodologies (design tasks) are developed for each method, which allow to determine (estimate) the time of its implementation and the quantitative characteristics of the forces, means, resources involved to fulfill the plan item, depending on the specific parameters of the enemy’s grouping. In addition, methods are being developed for determining the lead time and values of performance indicators of specific ways to carry out activities, sections of the plan and the plan as a whole.

The set of all the parameters for assessing the enemy’s grouping, which is required to calculate the necessary forces, means, resources, time, determining the plan’s performance indicators and ways to carry out specific actions of the plan, is the set of parameters that should be taken into account when planning the engagement of the enemy grouping

At the same time, the structure of the fire plan of the enemy grouping must clearly determine the sequence and time standards for the receipt of specific parameters, and the set of all other information indicators used for calculations will make a list of information indicators for conditionally constant information of the system’s database.

Thus, the system ensures the completeness of the information necessary for making management decisions.

The software and hardware of the system allows storing, processing, and displaying corresponding plans for collective display facilities. In this case, the plan is displayed with a given degree of detail.

The decisive role in the development of the plan belongs to the decision maker. In the process of developing the plan, exercising visual control over the development of the plan, it can, based on the current situation, give instructions on the development of new sections of the plan, on adjustments to the already prepared ones, and choose ways to implement the sections of the plan and the plan as a whole.

The proposed method of planning the engagement of a group of forces on the basis of standard plans will reduce the time it takes to make a decision by transferring the main intellectual efforts to develop a goal setting and decision plan to the stage of everyday activity, when there are no strict time limits, and automation of the process of preparing a draft plan will reduce time by preparation of a draft management decision.

Software and hardware should allow for the adjustment of the relevant section of the plan to responsible persons directly from their workplace.

The system operates as follows.

In the process of developing standard plans for fire destruction of enemy forces and means, the input of the system from the user's workstations receives input data in the form of a codogram having the following structure:

THE CODE THE CODE THE CODE The identifier of the situational situation of opposing groups Date of readiness of the plan of fire destruction The contents of the sections of the plan of fire destruction

After the receipt of this codogram to the information input 15 of the system, this codogram is entered into register 1 by a synchronizing pulse supplied to the synchronizing input 18 of the system. From the first output 36 of register 1, the full content of the codogram is issued to the information output 23 of the system.

From the second output 37 of register 1, the code of the identifier of the situational situation of the opposing groups goes to the information input 54 of module 4, from where it is fed to the decoder 42, which decrypts the code of the identifier of the situation situation of the opposing groups and gives out one of its outputs a high potential supplied to the corresponding inputs of the elements 44-49 I.

For definiteness, suppose that the high potential from the first output of the decoder 42 will open elements 44 and 47 And, and in addition, the high potential from the first output of the decoder will be directly issued to the output 57.

The clock pulse from the input 18 of the system, delayed by the element 50 during the operation of the decoder 42, is supplied, firstly, through the element 44 AND to the input of the fixed cell ROM 41, which stores the reference address of the memory zone of the database allocated for recording all plans related to to a given plan of fire destruction of the enemy group, and reads its contents to the input of the register 43.

Secondly, the same pulse delayed by the element 51 while reading the base address from the ROM 41 is supplied to the synchronizing input of the register 43 and enters the code of the base address, which from the output 55 of the register 43 goes to the input 102 of the adder 8.

Another input 101 of the adder 8 from the output 100 of block 7 receives a code from the output of the counter 87 through the elements And, open at the second output with high potential from the output 57 of block 4.

The same synchronizing pulse of block 4, delayed by element 52 while the base address code was entered in register 43, firstly, through the output 56 of block 4 is fed to the synchronizing input 103 of adder 8, providing the sum of the reference address and counter code 87 of block 7. Considering however, that by now the counter 87 was in the initial state and its readings are equal to zero, as a result of the summation, the code of the reference address at the output 104 of the adder 8 will remain unchanged and from the output 104 will go to the input 105 of the adder 9.

Secondly, the synchronizing pulse from the output of element 52 of block 4 is delayed by element 53 for the duration of the adder 9, and then, passing element 47 AND, as well as output 60 of block 4, is fed to input 97 of block 7 and then to the counting input of counter 87 , increasing its readings by one and thereby forming the readings of the counter 87 for the next cycle of work.

In parallel with the process described above, the plan creation date code from the output 38 of register 1 enters the information input 118 of block 10 and then goes to the input of the decoder 111, which decrypts the date code and outputs a high potential to one of its outputs, which arrives at the corresponding inputs of elements 113-115 AND.

For definiteness, let us assume that element 113 I will be opened with high potential from the first output of decoder 111.

The synchronizing pulse from the output 56 of block 4 is fed, firstly, to the input 119 of block 10 and then through element 113 And is fed to the input of a fixed cell in ROM 110, which stores the address of the memory zone of the database allocated for recording all plans in the specified period time, and reads its contents to the input of register 112.

Secondly, the clock pulse from the input 119 of the block 10 is delayed by the element 116 for the time of reading the code of the time period and goes to the clock input of the register 112 and enters the code of the time period, which from the output 120 of the register 112 goes to another information input 106 of the adder 9. Recall that the first input 105 of the adder 9 from the output 104 of the adder 8 receives the code of the reference address of the given plan of fire destruction.

The synchronizing pulse from the output of element 116, delayed by element 117 for the time the code of the time period is entered in register 112, from the output 121 of block 10 is supplied to the synchronizing input 107 of the adder 9, fixing the total address of the record, which from the output 108 of the adder 9 goes to the input 152 of the block 12 In addition, the clock pulse from the output 121 of the block 10 is supplied to the clock input 154 of the block 12.

From the input 152 of block 12, the generated write address goes to one of the inputs of the And 144 elements of the first group, which will be opened by high potential from the inverse output of the trigger 141. The state of the trigger 141 is determined by the synchronizing write pulses arriving at the input 154 of the block 12, and the synchronizing read pulses arriving input 155 of block 12.

Considering that at the given moment, the input 154 of the block 12 received a synchronizing write pulse, then passing to the installation input of the trigger 141, this pulse will confirm it to its original state, in which high potential from the inverse output of the trigger 141 will be opened as elements 144 And groups, so is element 142 I.

The code of the recording address from the output of the 144 AND group elements passes through the OR elements 146 of the group to the information input of the counter 140, to the synchronizing input of which there is a pulse from the input 154 of the block 12, which has passed through the chain: the OR element 147 and the delay element 149, delaying the pulse for the duration of the operation adder 9.

In addition, the same pulse from the output of the delay element 149 passes through the And element 142, is delayed by the element 150 for the time the address code is entered into the counter 140, and then from the output 159 through the system output 31 it enters the input of the first channel of the database server interrupt.

With the arrival of this signal, the database server switches to the routine for recording the readings of register 1 from the output 23 of the system at the address generated at the output 24 of the system.

The procedure for recording subsequent model plans for other plans for fire destruction of enemy groups is carried out in a similar way.

To obtain relevant information from the server database, each user who has access to the appropriate sections of the database of standard plans, at his automated workstation generates a query codogram and presses the "View" button.

The structure of the codogram formed at the user's workstations has the following structure:

THE CODE THE CODE The identifier of the situational situation of opposing groups User Workstation Identifier

In this case, the codes of the identifier of the situational situation of the opposing groups and the identifier of the user's workstation through input 16 go to register 2, where they are entered by a synchronizing pulse from input 19.

From the first output 39 of register 2, the identifier code of the situational situation of the opposing groups comes through the input 72 of module 5 to the input of the decoder 65.

The decoder 65 decrypts the code of the identifier of the situational situation of the opposing groups, giving out one of its outputs high potential. For definiteness, we assume that a high potential is received at one input of element 67 I.

In parallel with this, the synchronizing pulse from input 19 is delayed by element 70 for the time the code is entered in register 2 and the decoder 65 is triggered, and then it polls the states of elements 66-68 I.

Given the fact that only one element And will be open at one input, then passing through this element And, the clock pulse arrives, firstly, at the read input of a fixed memory cell of read-only memory 64.

In a fixed memory cell, the code of the reference address of the first memory cell of this situational situation of opposing groups is stored in the server database and the code of the number of plans in the server database, according to which it is supposed to act in the conditions of this crisis situation.

The structure of the codogram in the memory cell has the following structure:

THE CODE THE CODE Reference Address Code Number of plans code the first memory cell of a given situational situation of opposing groupings in the server database actions for a given situational situation of opposing groups in the server database

The code of the reference address of the first memory cell and the code of the number of plans are read from a fixed memory cell and fed to the outputs 74, 75 of block 5, respectively.

In parallel with this, the read pulse of the fixed memory cell of block 5, having passed the element 69 OR, immediately leaves the output 73 of block 5 through the input 155 of block 12 to the single input of trigger 141 and sets it to a single state, in which it opens one input of elements 145 And groups, as well as element 143 And, while at the same time closing low-potential elements 144 And groups together with element 142 I from their inverse output.

The code of the reference address of the first memory cell from the output 74 of the block 5 through the input 153 of the block 12 and the elements 145 And, as well as the elements 146 OR group goes to the information input of the reverse counter 140.

The same clock pulse from the input 155 of block 12 passes through the OR element 147, is delayed by the delay element 149 for the time of reading the code from the memory block 64 and the trigger 141, and arrives at the clock input of the reverse counter 140, fixing the reference address code of the first memory cell in the counter the given situation of opposing groups in the server database.

In addition, the same pulse from the output of the delay element 149 passes through the AND element 143, the OR element 148 and is delayed by the delay element 151 for the time that the reference address code was entered into the counter 140, and through the output 160 of the block 12 and the output 32 of the system it enters the input of the second interrupt channel server.

According to this signal, the server goes to the subprogram for interrogating the contents of the memory cell at the address generated on the address output of the system 24 and issuing the read data through the input 17 of the system to the information input of register 3, where they are entered by the synchronizing pulse of the server entering the input 20 of the system.

Simultaneously with this process, the code for the number of records of plans for this situational situation of opposing groups from the output 75 of block 5 enters through the input 132 of block 11 to the information input of register 122, which is also recorded by the pulse from the output 73 of block 5 through the input 133 of block 11.

At the same time, the user workstation identifier code from the output 40 of register 2 enters through the input 84 of block 6 to the input of the decoder 77. The decoder 77 decodes the user workstation identifier code, giving high potential to one of its outputs. For definiteness, we assume that a high potential is received at one input of element 78 I.

In parallel with this, the synchronizing pulse from the input 20 is delayed by the element 82 for the duration of the operation of the decoder 77, and further, it polls the states of the elements 78-80 I.

Considering the fact that only the And element 78 will be open at one input, then passing through this And element, the clock pulse arrives, firstly, at the read input of a fixed memory cell of the permanent storage device 76, where the address code of the user workstation is stored, and reads it through output 85 of block 6 to the information input 167 of block 13.

Secondly, the same read pulse, having passed the OR element 81, is delayed by the delay element 83 for the reading time of the contents of the fixed ROM cell. Further, from the output 86 of block 6, this pulse enters through the input 169 of block 13 to the synchronizing input of the register 161, fixing the address code of the user's workstation in the register.

The decoder 162 decrypts the address code of the user's workstation and with high potential at one of its outputs opens the And elements of one of the groups 163-165. At the same time, the pulse from the input 169 of block 13, the delayed delay element 166 for the duration of the decoder 162, the code of the first read write from the output of register 3, passing through the input 168 of block 13 and the corresponding group of elements And 163-165, through the corresponding output 170- 173 of the module 13 and, accordingly, the outputs 35-37 of the system are issued to the user's workstation.

The user is given the opportunity to view all plans for the engagement of enemy forces in the server database and get the information he needs.

To do this, the user uses the "Forward" and "Back" keys, the signals from which are fed to the control inputs 21, 22 of the system, respectively.

When the Forward key is pressed, the pulse from the input 21 of the system passes through the input 134 of block 11 to the counting input of the counter 123, which fixes the number of plans viewed. This number of plans is compared by the comparator 124 with the number of plans related to the given situation of opposing groups recorded in the register 122, according to the signal coming from the output of the delay element 129, which delays the pulse from the input 134 for the duration of the counter 123 operation.

If the number of plans viewed is less than the specified number of plans in the register 122, then an output 175 is generated from the comparator 124, which passes through the element 127 OR to the output 136 of the block 11 and then through the input 156 of the block 12 to the summing input of the reverse counter 140, forming the next read address on exit 24.

In addition, the same pulse, passing through the OR element 148 and the delay element 151, delaying this pulse for the duration of the operation of the reverse counter, passes to the output 160 of the block 12 and then to the output 32 and again goes to the input of the second channel of the server interrupt.

By this signal, the server again switches to the subprogram for interrogating the contents of the memory cell at the address generated at the address output of the system 24 and issuing the read data through the input 17 of the system to the information input of register 3, where they are entered by the synchronizing pulse of the server entering the input 20 of the system.

The described process of reading plans from the server database and issuing them to the user's workstation continues until the number of records in register 122 of block 11 is equal to the number of plans read from the database recorded by counter 123. The indicated moment will be recorded by issuing an impulse the output of 176 comparator 124.

The pulse from the output 176 of the comparator 124, firstly, through the element 128 OR enters the output 137 of the block 11 and then to the input 157 of the reversible counter 140, reducing its readings by one. In addition, the same pulse, passing through the OR element 148 and the delay element 151, which holds this pulse for the duration of the operation of the reverse counter, passes to the output 160 and the output 32 of the system and then again goes to the input of the second channel of the server interrupt.

By this signal, the server again switches to the subprogram for interrogating the contents of the memory cell at the address generated at the address output of the system 24 and issuing the read data through the input 17 of the system to the information input of register 3, where they are entered by the synchronizing pulse of the server entering the input 20 of the system.

Secondly, the same pulse from the output 176 of the comparator 124 is delayed by the delay element 130 for the duration of the pulse and through the OR element 126 is fed to the subtracting input of the counter 111, reducing its readings.

After that, the user can go back to the standard plans by pressing the "Back" button. The pulse from the input 29 through the OR element 116, firstly, is fed to the subtracting input of the counter 123, and, secondly, after the passage of the OR element 138 and delayed by the element 131 for the time the counter 123 operates, it goes to the synchronizing input of the comparator 125.

At this signal, the comparator 125 compares the readings of the counter 123 with "zero". If the counter 123 is greater than zero, then a signal is generated at the output 177 of the comparator 125, which, through the OR element 128, is output to the output 137 of the block 11 and then to the subtracting input of the reverse counter 140.

If the readings of the counter 123 are equal to zero, then a pulse is generated at the output 178 of the comparator 125, which, through the OR element 127, is similar to the output 136 of the block 11. Then the same pulse through the input 156 of the module 12 is fed to the summing input of the reverse counter 140, transferring the user to direct viewing mode of typical plans in the server database.

In other words, the user is given the opportunity to repeatedly view all the typical plans and reasonably select the data of interest to him.

Thus, the introduction of new nodes and blocks made it possible to significantly increase the system’s speed by eliminating the search for the optimal plan for fire defeat of the enemy grouping in the situational situation of opposing groupings throughout the server database and localizing the search only by temporary distinguishing features of the given grouping.

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

1. RF patent No.80604 (08/06/2008)

2. RF patent No. 2419140 (11/26/2008) - prototype

Claims (1)

The decision support system for the engagement of enemy groupings containing the unit for receiving records of typical plans for the engagement of combat weapons of the enemy group, the information and synchronization inputs of which are the first information and synchronization inputs of the system, while the information input for the reception of records of the typical plans for the engagement of combat weapons of the enemy designed to receive records of standard plans from the information outputs of the user's workstations oil, and the synchronizing input of the reception unit of records of typical plans for fire destruction of combat weapons of the enemy group is designed to receive synchronizing impulses from the user's workstations, the first output of the reception unit of records of typical plans of fire destruction of combat weapons of the enemy’s group is the information output of the system designed to issue data to information input of the system database server, block for receiving user requests, information and synchronizing inputs to otorogo are the second information and synchronizing inputs of the system, while the information input of the user request receiving unit is designed to receive user requests from user workstations, and the synchronizing input of user request receiving unit is designed to receive synchronizing pulses from user workstations, the unit receiving standard plans fire destruction of combat assets of the enemy grouping server database system, information and sync the onizing inputs of which are the third information and synchronizing inputs of the system, while the information input of the reception unit of typical plans for fire destruction of combat weapons of the enemy grouping of the system database server is designed to receive plans records from the system server database, and the synchronizing input of the reception unit of typical plans of fire destruction of combat means of grouping the enemy server database system is designed to receive synchronizing pulses of the server, the block selection address users, the information input of which is connected to one output of the user request receiving unit, the synchronizing input of the user address selection unit is connected to the third synchronizing input of the system, the data output unit, one information input of which is connected to the information output of the user address selection unit, the other information input of the data output unit connected to the output of the reception unit of records of typical plans for fire destruction of combat assets of enemy groupings, synchronizing the input of the issuing unit yes connected to the synchronizing output of the selection block of the user address, and the outputs of the data output block are the information outputs of the system group, intended for issuing records of fire plans to the information inputs of the corresponding automated places of the users of the system, the control unit for writing and reading data from the server database, the address output of which is the address output of the system intended for issuing write and read addresses to the address input of the system database server, per the second synchronizing output of the control unit for writing and reading data from the server database is the first synchronizing output of the system intended for issuing synchronizing signals to the input of the first channel for interrupting the database server, and the second synchronizing output of the control unit for writing and reading data from the server database is the second synchronizing output of the system designed to issue synchronizing signals to the input of the second channel of the database server interrupt, characterized in that the systems and it contains a selection block for the reference address of the plan of fire destruction of combat assets of the enemy grouping, the information input of which is connected to the second output of the reception of typical plans for the fire destruction of combat weapons of the enemy group of the system database server, and the synchronizing input of the block of selection of the reference address of the plan of fire destruction of the enemy group of weapons is connected to the first synchronizing input of the system, the unit for generating the current address of the plan of fire destruction of combat weapons An IK whose control inputs are connected to the corresponding control outputs of the selection block of the reference address of the fire plan of the combat weapons of the enemy group, the reading inputs of the block forming the current address of the fire plan of the combat weapons of the enemy group are connected to the corresponding outputs of the read of the selection block of the selection of the reference address of the plan of fire destruction of the enemy group enemy, the first adder, one information input of which is connected to the information output of the village block of the reference address of the fire defeat plan of the combat weapons of the enemy group, another information input of the first adder is connected to the output of the unit for generating the current address of the fire plan of the combat weapons of the enemy group, the synchronizing input of the first adder is connected to the synchronizing output of the selection block of the reference address of the plan of fire destruction of the combat group of the enemy , a unit for generating an address of a time period, the information input of which is connected to the third output of the receiving unit records of typical plans for fire destruction of combat assets of enemy groupings, the synchronizing input of the unit for generating the address of the temporary period is connected to the synchronizing output of the selection block of the reference address of the plan of fire destruction for combat weapons of the enemy, and the synchronizing output of the formation of the address block for the temporary period is connected to the first synchronizing input of the recording control unit and by reading the database data of the system server, the second adder, the information inputs of which are connected to inform with the output outputs of the first adder and the time period address generation unit, the synchronization input of the second adder is connected to the synchronization output of the time period address generation unit, and the output of the second adder is connected to one information input of the server database data recording and reading control unit, the selection of the reference reading address, the information input of which is connected to another output of the block for receiving user requests, the synchronizing input is connected to the second synchronizing the input of the system, one information output of the selection block of the reading reference address is connected to another information input of the recording and reading control unit of the server database of the system, the synchronizing output of the selection block of the reading reference address is connected to the second synchronizing input of the control block of writing and reading server database data, and a system server database address generation unit, the information input of which is connected to another information output of the reference address selection unit with The clock input of the system server database address generation unit is connected to the synchronization output of the reading reference address selection unit, the control inputs of the server database address generation unit are the system control inputs, and one output of the server database address generation unit is connected to the third synchronization input of the unit control of writing and reading server database data, and the other output of the server database address generation unit is connected to the fourth sync the input of the control unit for writing and reading server database data.