RU194497U1 - A device for solving the problem of determining the predicted values of the states of complexes of automation equipment for air defense control centers - Google Patents

Abstract

The utility model relates to computing. The technical result consists in automating the process of determining the forecast values of the KSA state of the air defense control points. The device contains a control and monitoring unit, a database with current values of KSA states, a database of possible values of KSA states, a database with technical characteristics of KSA samples, a data selection block, a comparison unit, a calculator, working memory, a block for determining the occurrence of the KSA limit state, a block selection of the value of the KSA state, a unit for recording and displaying the results of prediction 1 ill.

Description

A device for solving the problem of determining the predicted values of the states of automation complexes of air defense control centers relates to computing and can be used to automatically solve the problem of determining the forecast values of the states of automation systems of automation systems (KSA) of air defense control centers in a promising military automation complex.

The known system [1], which is a prototype, which includes a control unit, two squaring blocks, two cube root recovery blocks, three multiplication blocks, a sum block, and the input P of the device connected to the control input of the control unit 1, input K0 of the device connected to the first information input of the multiplication block 9, the input r1 of the device is connected to the information input of the squaring block 2 and to the second information input of the multiplication block 5, the input r2 of the device is connected to the information input of the block 3 adrat and with the second information input of the multiplication unit 4, the first output of the control unit 1 is connected to the control input of the squaring unit 2, the second output of the control unit 1 is connected to the control input of the squaring unit 3, the third output of the control unit 1 is connected to the control input of the unit 4 multiplications, the fourth output of the control unit 1 is connected to the control input of the multiplication unit 5, the fifth output of the control unit 1 is connected to the control input of the cubic root extraction unit 6, the sixth output of the control unit 1 is connected to the control input of the cubic root extraction unit 7, the seventh output of the control unit 1 is connected to the control input of the sum unit 8, the eighth output of the control unit 1 is connected to the control input of the multiplication unit 9, the output of the squaring unit 2 is connected to the first information input of the multiplication unit 4, the output the squaring unit 3 is connected to the first information input of the multiplication unit 5, the output of the multiplying unit 4 is connected to the information input of the cubic root extraction unit 6, the output of the multiplying unit 5 is connected to the information m the input of the cubic root extraction unit 7, the output of the cubic root extraction unit 6 is connected to the first information input of the sum unit 8, the output of the cubic root extraction unit 7 is connected to the second information input of the sum unit 8, the output of the sum unit 8 is connected to the second information input of the multiplication unit 9 , the output of the multiplication unit 9 is connected to the output device E.

A disadvantage of the known system [1] is the impossibility of its use for the automated solution of the problem of determining the forecast values of KSA states of air defense control centers in a promising military automation system, due to the narrow functionality for determining the forecast values of KSA states of air defense control centers in a promising automation system military purposes taking into account the values of the KSA state at the time of forecasting period, KSA service life, KSA resource, KSA service life margin, periodicity of KSA service.

The objective of the utility model is to eliminate the shortcomings of the known system [1], namely, expanding the functionality of the prototype to solve the problem of determining the predicted values of the KSA of the air defense control points in a promising military automation system.

The technical result, which provides a solution to the problem, is to automate the process of determining the forecast values of the KSA state of the air defense control points in a promising military automation complex taking into account the values of the KSA state at the time of the beginning of forecasting, KSA service life, KSA resource, KSA service life reserve, periodicity Carrying out service of KSA.

The achievement of the claimed technical result and, as a result, the solution of the problem is ensured by the fact that the device for solving the problem of determining the predicted values of the KSA of the air defense control points, in order to expand its functionality to solve the problem of determining the predicted values of the KSA of the air defense control points in a promising complex of military automation equipment, additionally contains a control and monitoring unit (1), a database x with current values of KSA states (2), a database of possible values of KSA states (4), a database with technical characteristics of KSA samples (6), a data selection block (3), a comparison block (5), a computer (8), a working memory (9), a block for determining the occurrence of the limiting state of the KSA (7), a block for selecting the value of the state of the KSA (10), a block for recording and displaying the results of forecasting (11), and two blocks of squaring, three blocks of multiplication, two blocks of extraction of the cubic root were removed , the sum block, and the input-output 1.1 of the control unit and counter For (1) it is connected to the input-output 2.3 of the database with the current values of the KSA states (2), the input-output 3.3 of the data selection block (3), the input-output 4.1 of the database of possible values of the KSA states (4), the input-output 5.7 comparison unit (5), input-output 6.2 of the database with the technical characteristics of the KSA samples (6), input-output 7.3 of the unit for determining the onset of the limiting state of the KSA (7), input-output 8.3 of the calculator (8), input-output 9.2 of the working memory (9), input-output 10.5 of the unit for selecting the value of the KSA state (10), input-output 11.2 of the registration unit and displaying the prediction results (11), the input 2.1 of the database with the current values of the states of the KSA (2) is connected to the output 10.4 of the block for selecting the values of the KSA (10), the input-output 2.2 of the database with the current values of the states of the KSA (2) is connected to input-output 3.1 of the data selection unit (3), output 3.2 of the data selection unit (3) is connected to input 5.1 of the comparison unit (5), output 4.2 of the database of possible values of the state of the KSA (4) is connected to input 5.4 of the comparison unit (5), the output 4.3 of the database of possible values of the KSA states (4) is connected to the input 10.6 of the selection block I state KSA (10), the input 5.2 of the comparison unit (5) is connected to the output 6.1 of the database with the technical characteristics of the samples of the KSA (6), the output 5.5 of the comparison unit (5) is connected to the input 7.1 of the unit for determining the occurrence of the limit state of the KSA (7), the output 5.6 of the comparison unit (5) is connected to the input 8.1 of the calculator (8), the input 5.3 of the comparison unit (5) is connected to the output 8.5 of the calculator (8), the output 7.2 of the unit for determining the occurrence of the limit state of the CSA is connected to the input 10.3 of the block for selecting the value of the CSA state ( 10), output 7.4 of the block determining the occurrence of the ultimate state KSA is connected to the input 8.6 of the calculator (8), the input-output 8.2 of the calculator (8) is connected to the input-output 9.1 of the working memory (9), the output 8.4 of the calculator (8) is connected to the input 10.1 of the block for selecting the value of the KSA state (10), the output 10.2 of the KSA state value selection unit (10) is connected to the input 11.1 of the registration and display unit of the prediction results (11).

This, in turn, allows us to solve the problem, namely, to increase the level of automation when determining the predicted values of the KSA state of air defense control points in a promising military automation system.

Graphic materials explaining the essence of the utility model are presented in FIG. 1.

In FIG. Figure 1 shows a block diagram of a device for solving the problem of determining the predicted values of KSA states of air defense control points in a promising military automation system.

In FIG. 1 adopted the following notation:

1 - control and monitoring unit;

2 - a database with current values of the KSA states;

3 - data selection unit;

4 - a database of possible values of the KSA states;

5 - block comparison;

6 - a database with the technical characteristics of the KSA samples;

7 - block determining the onset of the ultimate state of the KSA;

8 - calculator;

9 - working memory;

10 - block selection of the value of the state of the KSA;

11 - block registration and display of forecasting results.

The control and monitoring unit (1) is intended for the automated generation of control actions at the operator’s command to turn the device on, input the necessary input data, adjust intermediate results, followed by the automatic generation of control actions on the respective blocks in the interest of initiating their work, as well as display and control results obtained from the results of the operation of the device. The inputs and outputs of the control and monitoring unit (1) are connected to the corresponding inputs and outputs of the database with the current values of the KSA states (2), the database of possible values of the KSA states (4), the database with the technical characteristics of the KSA samples (6), the selection block data (3), a comparison unit (5), a calculator (8), working memory (9), a unit for determining the occurrence of the limiting state of the KSA (7), a unit for selecting the value of the state of the KSA (10), a unit for recording and displaying forecast results (11) .

A database with current values of KSA states (2) is intended for storing in the corresponding tables information on the current technical condition of KSA samples, which for each KSA sample includes data on the year of manufacture, location, expended resource, service life, date and type of performed maintenance measures, etc. The input 2.1 of the database with the current values of the state of the KSA (2) is connected to the output 10.4 of the block for selecting the value of the KSA (10), the input-output 2.2 is connected to the input-output 3.1 of the data selection unit (3) , in d-output 2.3 is connected to control input-output of 1.1 management and control unit (1).

The data selection block (3) is designed to generate the necessary information about the current technical condition of the KSA samples from the database with the current values of the KSA states (2) in accordance with the parameters of the control signal from the control and monitoring unit (1). The essence of the unit is to automatically select from the database with the current values of the KSA state (2) information on the year of release, location, expended resource, service life, date and type of service activities carried out, the value of the KSA technical condition at the time the forecast was started, necessary for further processing and its transmission to the comparison unit (5) or to the computer (8) depending on the parameters of the control signal from the control and monitoring unit (1), input-output 3.1 of the data selection unit (3) nen with input / output 2.2 of the database with the current values of the KSA states (2), output 3.2 of the data selection unit (3) is connected to input 5.1 of the comparison unit (5), input / output 3.3 of the data selection unit (3) is connected to input / output 1.1 control and monitoring unit (1).

The database of possible values of KSA states (4) is intended for storing all possible values of technical conditions of KSA with the corresponding parameters specific to each value of the technical condition of typical KSA samples, such as resource, service life, frequency of service events. The input-output 4.1 of the database of possible values of the KSA states (4) is connected by the input-output 1.1 of the control and monitoring unit (1), the output 4.2 is connected to the input 5.4 of the comparison unit (5), the output 4.3 is connected to the input 10.6 of the block for choosing the value of the KSA ( 10).

The comparison unit (5) is designed for automated military-technical analysis of the current state of the KSA, the service life of the KSA samples, the stock of the service life of the KSA samples, the frequency of servicing of the KSA samples from the Air Defense Forces group. The essence of the unit is in the automated military-technical analysis of data on the current state of the KSA, the service life of the KSA samples, the reserves of the service life of the KSA samples, the frequency of servicing KSA samples. Based on the parameters of the control signal from the control and monitoring unit (1) received at the input 5.7 of the comparison unit (5), an automated analysis of the sequences takes place: data on the current state of the CSA coming from input 5.1 from the data selection block (3) and possible values of technical conditions KSA, data about which come from input 5.4 from a database of possible values of KSA states (4); data on the current service life of the KSA samples coming from input 5.1 from the data selection block (3), the established service life for a specific KSA sample and the warranty life for a specific KSA sample coming from input 5.2 from the database with the technical characteristics of the KSA samples (6 ); data on the current reserves of the service life of the KSA samples coming from input 5.1 from the data selection block (3); data on the current moments of the maintenance activities coming from input 5.1 from the data selection block (3) and data on the necessary frequency of the maintenance activities coming from input 5.2 from the database with the technical characteristics of the KSA samples (6). The input 5.1 of the comparison unit (5) is connected to the output 3.2 of the data selection unit (3), the input 5.2 of the comparison unit (5) is connected to the output 6.1 of the database with the technical characteristics of the KSA samples (6), the input 5.4 of the comparison unit (5) is connected to the output 4.2 database of possible values of KSA states (4), output 5.5 of the comparison unit (5) is connected to the input 7.1 of the unit for determining the occurrence of the limit state of the KSA (7), the output 5.6 of the comparison unit (5) is connected to the input 8.1 of the calculator (8), the input is the output 5.7 of the comparison unit (5) is connected to the input-output 1.1 of the control and monitoring unit (1), the input is 5.3 unit and comparisons (5) are connected to the output 8.5 of the calculator (8).

The database with the technical characteristics of the KSA samples (6) is intended for storing the tactical, technical and economic characteristics of the KSA samples, which for each type of KSA includes data on the name and code of the sample, the purpose of the sample, indicators of combat capabilities, mass and overall characteristics, warranty service life, the designated service life before cancellation, the frequency and volume of measures for maintenance, the cost of production, the cost of service, etc. Exit 6.1 connection inen with the input 5.2 of the comparison unit (5), the input-output 6.2 is connected to the input-output 1.1 of the control and monitoring unit (1).

The unit for determining the onset of the ultimate state of the KSA (7) is designed to determine the possibility of the onset of the ultimate state of the KSA samples. At the onset of the limiting state, the KSA sample ceases to fulfill its intended purpose and goes into an inoperative state. The essence of the unit is to automatically determine the possibility of the onset of the limiting state of the KSA samples. Based on the results of an automated analysis of data on the current life span of KSA samples and data on the frequency of servicing KSA samples, a control signal may occur from input / output 7.3 from the control and monitoring unit (1), upon receipt of which in the determination unit the occurrence of the limiting state of KSA (7) based on the current values of the coefficient of readiness of KSA samples, the possibility of transition of KSA samples to an inoperative state is determined. Input 7.1 is connected to output 5.5 of the comparison unit (5), output 7.2 is connected to input 10.3 of the KSA state value selection block (10), input-output 7.3 is connected to input-output 1.1 of the control and monitoring unit (1), output 7.4 is connected to input 8.7 calculators (8).

The computer (8) is designed to calculate the predicted values of the military-technical characteristics of the KSA samples. The essence of the unit is to automatically calculate the service life of the KSA samples, the reserves of the service life of the KSA samples, the resources of the KSA samples, the availability factors of the KSA samples. Upon receipt of the control signal from input-output 8.3 from the control and monitoring unit (1) in the computer (8), the service lives of the KSA samples, the reserves of the service life of the KSA samples, the resources of the KSA samples, the availability factors of the KSA samples are calculated on the basis of the data received on the information input 8.6 from the data selection block (3). Input 8.1 is connected to output 5.6 of the comparison unit (5), input-output 8.2 is connected to input-output 9.1 of the working memory (9), input-output 8.3 is connected to input-output 1.1 of the control and monitoring unit (1), output 8.4 is connected to the input 10.1 of the KSA state value selection block (10), the output 8.5 is connected to the input 5.8 of the comparison unit (5), the input 8.6 is connected to the output 7.4 of the block determining the occurrence of the KSA limit state (7).

Working memory (9) is intended for storage of data necessary for calculations: initial data on the technical condition of each KSA sample of the considered air defense group, tactical, technical and economic characteristics of KSA samples. Input-output 9.1 is connected to input-output 8.2 of the calculator (8), input-output 9.2 is connected to input-output 1.1 of the control and monitoring unit (1).

The KSA state value selection block (10) is designed to determine the predicted value of the state of the KSA air defense group. The essence of the unit is to automatically select the value of the state of the KSA samples based on the data on the predicted tactical, technical and economic characteristics received at the input 10.1 from the computer (8) and information about the occurrence of the limiting state of the KSA sample, coming to the input 10.3 from the block determining the occurrence of the limit KSA state (7), delivery of selected predicted values of the state of KSA samples to output 10.4 for writing to the database with the current values of KSA states (2) and to output 10.2 to the registration unit and selecting prediction results. The input 10.1 is connected to the output 8.4 of the calculator (8), the output 10.2 is connected to the input 11.1 of the registration and display unit of the forecasting results, the input 10.3 is connected to the output 7.2 of the unit for determining the occurrence of the limit state of the KSA (7), the output 10.4 is connected to the input of the database 2.1 with the current values of KSA states (2), input-output 10.5 is connected to input-output 1.1 of the control and monitoring unit (1), input 10.6 is connected to output 4.3 of the database of possible values of KSA states (4).

The unit for recording and displaying forecasting results (11) is intended for displaying and recording the results obtained during the operation of the device and during the adjustment of intermediate results in accordance with the input data. Input 11.1 is connected to the output 10.2 of the KSA state value selection block (10), input-output 11.2 is connected to the input-output 1.1 of the control and monitoring unit (1).

Control and monitoring unit (1), a database with current values of KSA states (2), a data selection block (3), a database of possible values of KSA states (4), a comparison block (5), a database with technical characteristics of KSA samples ( 6), a block for determining the occurrence of the ultimate state of the KSA (7), a computer (8), working memory (9), a block for selecting the value of the KSA state (10), a unit for recording and displaying the results of forecasting (11) are made in the form of software and hardware modules on expansion board PC with architecture type x86, which is constructive It is mounted on a stand rack for the design of automation systems for military use.

The operation of the device to solve the problem of determining the predicted values of the states of complexes of automation means of control centers for air defense is as follows.

At the preliminary stage of the device’s operation, input / output 2.3 of the database with the current values of the KSA states (2), input-output 4.1 of the database of possible values of the KSA states (4), input-output 6.2 of the database with the technical characteristics of the KSA samples (6) through input-output 1.1 of the control and monitoring unit (1) information is entered to fill in the corresponding databases.

After that, in the control and monitoring unit (1), the operator automatically generates a command to turn on the device into operation and from input / output 1.1 of the control and control unit (1) to input / output 2.3 of the database with the current values of the KSA states (2), input-output 3.3 of the data selection block (3), input-output 4.1 of the database of possible values of the KSA states (4), input-output 5.7 of the comparison unit (5), input-output 6.2 of the database with the technical characteristics of the KSA samples (6), input-output 7.3 of the unit for determining the onset of the limiting state of the KSA (7), input-output 8.3 a computer (8), input-output 9.3 of the working memory (9), input-output 10.5 of the KSA state value selection unit (10), input-output 11.2 of the registration and display unit of forecasting results (11), a control signal is transmitted to initiate their operation. This signal from output 2.2 of the database with the current values of the KSA states (2) to the input 3.1 of the data selection block (3) gives information on the current tactical, technical and economic characteristics of the first sample of the KSA from the database with the current values of the states of the KSA (2). Based on this information, the block automatically chooses data characterizing the current state of the KSA sample, the current service life of the KSA sample, the current life reserve of the KSA sample, the current resource of the KSA sample, and the moment of service maintenance of the KSA sample. The result of the block is a formed sample of the current values of the characteristics of the KSA sample. The obtained values from the output 3.2 of the data selection block (3) go to the input 5.1 of the comparison block (5) and from the output 3.4 of the data selection block (3) go to the input 8.6 of the calculator (8).

Simultaneously with the output 4.2 of the database of possible values of the KSA states (4), the input 5.4 of the comparison unit (5) receives information about the possible values of the states of the KSA sample.

Simultaneously with the release of 6.1 database with the technical characteristics of the KSA samples (6), the input 5.2 of the comparison unit (5) receives information on the tactical-technical-economic characteristics of the KSA sample established by the manufacturer.

In the comparison block (5), an automatic comparison of the possible values of the state of the KSA sample and the current state of the KSA sample, the current life of the KSA sample, the current life reserve of the KSA sample, the current resource of the KSA sample, the moment of servicing the KSA sample, the current sample availability factor is performed KSA with the relevant values of these characteristics set by the manufacturer and automated analysis of the results of the comparison. The result of the unit’s work is the formed sequence of the device’s further functioning, which can be as follows: if it is necessary to check for the possibility of the ultimate state of the KSA sample, data on the current coefficient of reliability of the KSA sample is received from output 5.5 of the comparison unit (5) to input 7.1 of the determination unit the onset of the ultimate state of CSA (7); if there is no need to check for the possibility of the ultimate state of the KSA sample, data on the current service life of the KSA sample, the current life reserve of the KSA sample, the current resource of the KSA sample, and the current availability factor of the KSA sample are received from output 5.6 of the comparison unit (5) to the input 8.1 calculators (8).

When a signal arrives at input 7.1 of the block determining the occurrence of the limiting state of the KSA (7), a simulation of the possibility of the occurrence of the limiting state of the KSA sample occurs in the block. According to the result of simulation, the value of the current coefficient of readiness of the KSA sample comes from output 7.4 of the block determining the occurrence of the limiting state of KSA (7) to input 8.7 of the calculator (8), from the output 7.2 of the block determining the occurrence of the limiting state of KSA (7) to input 10.3 of the block for selecting the state value KSA (10) receives information about the need to change the value of the state of the KSA sample to “inoperative” or the absence of the need to change the current state of the KSA sample.

In the computer (8), when a signal arrives from information inputs 8.1 from the output 5.6 of the comparison unit (5) and 8.7 from the output 7.4 of the unit for determining the onset of the limiting state of the KSA (7), the predicted values of the service life of the KSA sample, the service life of the KSA sample, and the resource are calculated KSA sample, KSA sample availability coefficient. The intermediate results of the calculations are transmitted through the input-output 8.2 of the calculator (8) to the input-output 9.1 of the working memory (9). At the end of the block operation, the calculated predicted values of the KSA sample service life, the KSA sample service life reserve, the KSA sample resource, and the KSA sample availability coefficient are transmitted through output 8.4 of the computer (8) to input 10.1 of the KSA state value selection block (10).

The working memory (9) stores the results of intermediate calculations of the service life of the KSA sample, the service life of the KSA sample, the resource of the KSA sample, the availability factor of the KSA sample coming from input-output 9.1 from input-output 8.2 of the computer (8). At the request of the calculator (8), the results of intermediate calculations are output through the input-output 9.1 to the input-output 8.2 of the calculator (8).

Simultaneously with the output 4.3 of the database of possible values of the KSA states (4), the input 10.6 of the block for choosing the value of the KSA state (10) receives the parameters of the possible values of the states of the KSA sample. In the block of selection of the value of the KSA state (10), the state value of the KSA sample is selected based on the information received from the information input 10.1 from the output 8.4 of the calculator (8). If there is a signal at input 10.3 from output 7.2 of the KSA limit state determination unit (7) about the need to change the value of the KSA sample to “inoperative” information received from the information input 10.1 from output 8.4 of the calculator (8) when choosing the value of the KSA sample state is ignored . After changing the state value of the KSA sample, information about the predicted state of the KSA sample through the information output 10.4 of the KSA state value selection block (10) is fed to database input 2.1 with current KSA state values (2) for writing to the database, from the output of 10.2 value selection block the state of the KSA (10) to the input 11.1 of the registration and display unit of the forecasting results (11).

Information is received from the output 10.2 of the KSA state value selection block (10) about the predicted value of the KSA sample state, the KSA sample service life, the KSA sample service life reserve, and the resource KSA sample, KSA sample availability coefficient. If necessary, input-output 11.2 receives a signal at input 1.1 of the control and monitoring unit (1) for adjustment.

Further, the process of determining the predicted values of the states of the KSA continues according to the signal from the input-output 1.1 of the control and monitoring unit (1) for the next KSA sample from the database with the current values of the KSA states (2).

Information about the end of the process of solving the problem of determining the predicted values of the state of the KSA samples of the air defense control points and recording this fact from the input-output 11.2 of the registration and display unit of forecasting (11) is transmitted to the input-output 1.1 of the control and monitoring unit (1). In the control and monitoring unit (1) a control signal is generated to stop the database with the current values of the KSA states (2), the data selection block (3), the database of possible values of the KSA states (4), the comparison block (5), the database with the technical characteristics of the KSA samples (6), the block for determining the onset of the limiting state of the KSA (7), a computer (8), working memory (9), a block for selecting the value of the KSA state (10), a unit for recording and displaying prediction results (11). This completes the operation of the device.

The utility model is made in the form of an operator's automated workstation, a control and monitoring unit (1), a database with current values of the KSA states (2), a data selection block (3), a database of possible values of KSA states (4), a comparison block (5 ), a database with the technical characteristics of the KSA samples (6), a block for determining the onset of the limit state of the KSA (7), a computer (8), working memory (9), a block for selecting the value of the KSA state (10), a unit for recording and displaying forecast results ( 11) made in the form of software and hardware x modules on the expansion board PC x86 type architecture.

The utility model is developed at the level of a modeling algorithm and a computer program. The test results of the model showed an increase in the level of automation in solving the problem of determining the predicted values of the states of complexes of automation equipment for control centers of air defense in a promising complex of automation equipment for military purposes by 65-70%.

Sources taken into account in the preparation of the description and claims:

1. RU 86769, G06F 7/38, 2009.

2. Strogalev V.P., Tolkacheva I.O. Simulation modeling. - MSTU them. Bauman, 2008.

Claims (1)

A device for solving the problem of determining the predicted values of the states of complexes of automation equipment for air defense control centers, containing a control and monitoring unit (1), a database with current values of KSA states (2), a database of possible values of KSA states (4), a database with technical characteristics of the KSA samples (6), a data selection block (3), a comparison block (5), a computer (8), working memory (9), a block for determining the occurrence of the limiting state of the KSA (7), a block for selecting the value of the KSA state (10), registration unit and displaying the results of forecasting (11), characterized by the introduction of new blocks, the organization of communication between the blocks, and the input-output 1.1 of the control and monitoring unit (1) is connected to the input-output 2.3 of the database with the current values of the KSA states (2), the input is output 3.3 of the data selection block (3), input-output 4.1 of the database of possible values of the KSA states (4), input-output 5.7 of the comparison unit (5), input-output 6.2 of the database with the technical characteristics of the KSA samples (6), input- output 7.3 of the block determining the occurrence of the limiting state K A (7), input-output 8.3 of the calculator (8), input-output 9.2 of the working memory (9), input-output 10.5 of the block for selecting the value of the KSA state (10), input-output 11.2 of the block for registering and displaying the results of forecasting (11) , the input 2.1 of the database with the current values of the states of the KSA (2) is connected to the output 10.4 of the block for selecting the value of the KSA (10), the input-output 2.2 of the database with the current values of the states of the KSA (2) is connected to the input-output 3.1 of the block of the data selection ( 3), the output 3.2 of the data selection unit (3) is connected to the input 5.1 of the comparison unit (5), the output 4.2 of the database is possible KSA state values (4) is connected to the input 5.4 of the comparison unit (5), output 4.3 of the database of possible KSA state values (4) is connected to the input 10.6 of the KSA state value selection block (10), input 5.2 of the comparison unit (5) is connected to the output of the database 6.1 with the technical characteristics of the KSA samples (6), the output 5.5 of the comparison unit (5) is connected to the input 7.1 of the unit for determining the occurrence of the limit state of the KSA (7), the output 5.6 of the comparison unit (5) is connected to the input 8.1 of the calculator (8), input 5.3 of the comparison unit (5) is connected to the output 8.5 of the calculator (8), the output 7.2 of the block for the occurrence of the limit state KSA connection is connected to the input 10.3 of the KSA state value selection block (10), the output 7.4 of the KSA limit state determination unit is connected to the input 8.6 of the computer (8), the input-output 8.2 of the computer (8) is connected to the input-output 9.1 of the working memory (9), the output 8.4 of the calculator (8) is connected to the input 10.1 of the KSA state value selection unit (10), the output 10.2 of the KSA state value selection unit (10) is connected to the input 11.1 of the registration and display unit of forecasting results (11).

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