RU86769U1 - DEVICE FOR SOLVING THE PROBLEM OF FORECASTING THE TECHNICAL LEVEL OF A COMPLEX TECHNICAL SYSTEM - Google Patents

Abstract

A device for solving the problem of predicting the technical level of a complex technical system, comprising a control unit, two squaring blocks, two cube root recovery blocks, three multiplication blocks, a sum block, characterized by the introduction of new blocks, organizing communication between the blocks, and the device’s input P is connected to control input of control unit 1, input K0 of the device is connected to the first information input of multiplication unit 9, input r1 of the device is connected to the information input of squaring unit 2 and to the second and the information input of the multiplication unit 5, the input r2 of the device is connected to the information input of the squaring unit 3 and to the second information input of the multiplying 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 the input of the squaring unit 3, the third output of the control unit 1 is connected to the control input of the multiplication unit 4, 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 it 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 unit 9 multiplication, the output of the squaring unit 2 is connected to the first information input of the multiplication unit 4, the output of the squaring unit 3 is connected to the first information input of the multiplying unit 5, the output of the multiplication unit 4

Description

The device relates to computer technology and can be used to predict the technical level of a complex technical system.

The closest in technical essence to the proposed (prototype) is a device for solving the problem of assessing the quality of rocket and artillery weapons (Utility Model Certificate No. 31012, 2003/1 /), containing a control unit, four memory units, a switching unit, 2m units memory, m comparison blocks (at a minimum), n + 3 total blocks, one subtraction block, one division block, m multiplication blocks, one comparison block (at a maximum).

However, this device does not allow to solve the problem of forecasting the technical level of a complex technical system.

The purpose of the utility model is to expand the functionality of the prototype for predicting the technical level of a complex technical system depending on the values of dimensionless individual indicators of the properties of the STS.

This goal is achieved by the fact that in the device for solving the problem of assessing the quality of rocket and artillery weapons, containing a control unit, four memory units, a switching unit, 2m memory units, m comparison units (minimum), n + 3 total units, one subtraction unit , one division block, m multiplication blocks, one comparison block (to the maximum), characterized in that in order to expand its functionality in predicting the technical level of a complex technical system, two additional erection blocks are introduced into it vadrat, three blocks of multiplication, two blocks of extraction of a cubic root, a block of sum and four blocks of memory are removed, a switching block, 2m blocks of memory, m blocks of comparison (at a minimum), n + 3 blocks of sum, one block of subtraction, one block of division, m multiplication units, one comparison unit (to the maximum), the input P of the device connected to the control input of the control unit 1, the input K _{0 of the} device connected to the first information input of the multiplication unit 9, the input r _{1 of the} device connected to the information input of the squaring unit 2 and with the second information the input of the multiplication unit 5, the input r _{2 of the} device is connected to the information input of the squaring unit 3 and to the second information input of the multiplying 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 the input of the squaring unit 3, the third output of the control unit 1 is connected to the control input of the multiplication unit 4, 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 the squaring unit 2 is connected to the first information input of the multiplication unit 4, the output of the squaring unit 3 is connected to the first information input of the multiplying unit 5, the output of the multiplying unit 4 is connected to the information by the input of the cubic root extraction unit 6, the output of the multiplication unit 5 is connected to the information 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 unit 8 the sum, the output of the sum block 8 is connected to the second information input of the multiplication block 9, the output of the multiplication block 9 is connected to the output device E.

The device implements the following theoretical provisions.

The goals of forecasting the technical level of a complex technical system (STS) are met to the greatest extent by methods based on obtaining a generalized indicator by aggregating individual indicators with corresponding weighting factors. The most common such estimate is an additive function of the form

where N is the number of individual indicators characterizing the ANO of the Republic of Kazakhstan;

K _i - weight coefficient of a single indicator of the i-th property.

In addition, each property of the STS sample is characterized by one or more individual indicators.

The task is to express in a generalized indicator certain quantities of properties that are essentially different. In order to compare different amounts of heterogeneous indicators, they must be reduced to a dimensionless scale, i.e. each indicator a _i, having a dimension and its own measurement scale, must be associated with a dimensionless indicator r _i . Such a transition is not difficult to carry out, given the following reasoning.

During the operation of the STS, each i-th unit indicator can remain constant (patentability indicators), take a number of discrete values (maintainability indicators), or change continuously (power on the motor shaft)

where m is the number of discrete values that a single indicator takes during operation;

- limit values of a single indicator, determined by technical conditions (capabilities);

a _ij is the j-th value of the i-th unit indicator.

In the range each j-th value of the i-th unit indicator corresponds to the probability that it is realized during the operation of the ANO of the Republic of Kazakhstan. This probability is described by the probability density function φ _i (a _ij ).

In general, the range of variation of the i-th unit indicator may be less than the range , i.e. a _iн > a _imin , a _iв <a _imax ,

where a _iн , a _iв - limit (lower and upper) values of individual indicators of the i-th property of the STS.

Then the dimensionless unit indicator r _i expressing the ratio of the achieved value to the necessary will be determined from the expression

.

It is obvious that the range of variation of the dimensionless unit indicator is in the range from zero to unity

0≤r _i ≤1.

In the case of a uniform distribution, the methods of transition to dimensionless unit indicators have the form

In determining K _i, it should be considered that the weight coefficient of any i-th unit indicator reflects the relative importance of one unit r _i with respect to other dimensionless unit indicators. The product under the sign of the sum of a generalized indicator shows the quantitative contribution of each property to a complex property. Any property becomes a reality, being reflected in a single indicator. Therefore, the weight characterizing the importance of the i-th property in relation to the totality of other properties depends on the indicators of these properties, i.e. we can write that

K _i = F (r ₁ , r ₂ , ... r _N ).

Naturally, for a specific STS, the product K _i r _i is a constant value. The multipliers of the product (K _i r _i ) take any values depending on the choice of the coordinate system, but such that for any transformations the relation will always be true

where j _k is the coordinate system number or transformation number.

Expression (1.1) illustrates the invariance of a quantitative estimate of the property K _i r _i relative to the introduced transformations.

If we consider from the standpoint of the invariance of formula (1.1) the contribution of each of the two properties included in the complex property, then it is obvious that this contribution will be different in the general case. The disparity of the contribution ΔR is also invariant with respect to the transformation equations

As you can see, it is due to one of three combinations of individual indicators and weightings, in particular, combinations of the form

It seems appropriate to study expression (1.3) in each of the three cases. For this purpose, it is necessary to take the coordinate system (K, r), in which the generalized indicator R ₀ is determined by the sum of the indicators r _j0 having weight K ₀ . Then we can write the well-known equality

From the invariance condition follows the formula for determining K _i , i.e.

To find the relationship between equilibrium r _i and having equal weights r _i0 and further determine K _i from expression (1.5), it is necessary to consider one particular case. Let N = 2, a ∆R> 0, i.e. r ₁ <r ₂ and r ₁₀ <r ₂₀ , then equality (1.2) takes the form

The disparity expressed in the difference in the weights of each of the properties described by the indices r ₁₀ and r ₂₀ is determined using the following relationships

The disparity of equilibrium indicators is determined by the expression

Substituting the value of ΔR from formula (1.6) in dependence (1.7) and (1.8), we obtain two elementary equalities of the form

Comparing formulas (2.19) and (2.20), we can obtain the elementary equation

from which, by virtue of condition (1.7), the obvious equalities

Since all the coefficients and indicators are related by invariance (1.1), the determination of the indicators r ₁₀ and r ₂₀ reduced to the weight K ₀ should be carried out by solving a system of four equations

Solving system (1.13) with respect to r ₁₀ and r ₂₀ , it is easy to obtain relations for their calculation, in particular, they look as follows

Equations (1.12) in this case will have a fairly simple form

In (1.15), the weights K ₁ and K ₂ are expressed in terms of the dimensionless unit parameters of the STS properties r ₁ and r ₂ , which are known by the condition, and the unknown constant K ₀ , which is set by the developers when predicting the technical level of the STS. Then the generalized indicator is written as the product of K ₀ and the corresponding sum of cubic equations

where R ₀ is the predicted technical level of the STS;

r ₁ and r ₂ are the values of dimensionless individual indicators of the properties of the STS;

K ₀ - unknown constant (set by developers when predicting the technical level of STS)

The device implements the presented theoretical provisions and is presented in figure 1.

It contains a control unit, two squaring blocks, two cubic root extraction blocks, three multiplication blocks, a sum block.

A device for solving the problem of forecasting the technical level of complex technical systems operates as follows.

The operation of the device is carried out in a certain sequence specified by the clock pulses of the control unit 1.

The initial installation of the device blocks occurs when a pulse is applied to the input “P”, as a result of which the control unit 1 is started, the device blocks are zeroed and the values of the characteristics r ₁ , r ₂ , K ₀ are sent to the information inputs of the device.

The first clock pulse from the first output of the control unit 1 is supplied to the control input of the squaring unit 2 and initiates its operation. As a result, the value r _{1 is} supplied to the information input of the squaring unit 2, the value is formed at the output of the squaring unit 2 ,

The second clock pulse from the second output of the control unit 1 is supplied to the control input of the squaring unit 3 and initiates its operation. As a result, the r ₂ value is inputted to the information input of the squaring unit 3, a value is generated at the output of the squaring unit 3 .

The third clock pulse from the third output of the control unit 1 is supplied to the control input of the multiplication unit 4 and initiates its operation. As a result, the first information input of the multiplication block 4 receives the value from the output of the squaring block 2 , the value r ₂ is supplied to the second information input of the multiplication unit 4, the value is generated at the output of the multiplication unit 4 r ₂ .

The fourth clock pulse from the fourth output of the control unit 1 is supplied to the control input of the multiplication unit 5 and initiates its operation. As a result, at the first information input of the multiplication block 5, the value from the output of the block 3 of erection in the cavitrate receives the value , the value r ₁ is supplied to the second information input of the multiplication unit 5, the value is generated at the output of the multiplication unit 5 r ₁ .

The fifth clock pulse from the fifth output of the control unit 1 is supplied to the control input of the cubic root extraction unit 6 and initiates its operation. As a result, the information input of block 6 of extracting the cubic root from the output of block 4 of the multiplication receives the value r ₂ , at the output of block 6, a value is formed .

The sixth clock pulse from the sixth output of the control unit 1 is supplied to the control input of the cubic root extraction unit 7 and initiates its operation. As a result, the information input of block 7 of extracting the cubic root from the output of block 5 of the multiplication receives the value r ₁ , at the output of block 7, a value is formed .

The seventh clock pulse from the seventh output of the control unit 1 is supplied to the control input of the sum unit 8 and initiates its operation. As a result, the first information input of block 8 of the sum from the output of block 6 of extracting the cubic root receives the value , the second information input of block 8 of the sum from the output 7 of the extraction of the cubic root receives the value , at the output of block 8 of the amount the value is formed

The eighth clock pulse from the eighth output of the control unit 1 is supplied to the control input of the multiplication unit 9 and initiates its operation. As a result, the value K ₀ is supplied to the first information input of the multiplication unit 9, the value is supplied to the second information input of the multiplication unit 9 from the output of the sum unit 8 thus, the value K ₀ calculated in the multiplication block 9 arrives at the output device E.

Thus, the use of the device will avoid routine computational work associated with solving problems of predicting the technical level of complex technical systems.

List of sources used

1. Filyustin A.E., Filatov I.N., Rossoshansky P.V., et al. A device for solving the problem of assessing the quality of rocket and artillery weapons // Utility Model Certificate No. 31012. - M .: RAPTZ, 2003.

2. Filyustin A.E., Gasyuk D.P., Bochkov A.P. Models and methods for managing the development of technical systems. Textbook: - St. Petersburg: Soyuz Publishing House, 2003. - 288 p. (Graduate School)

Claims (1)

A device for solving the problem of predicting the technical level of a complex technical system, comprising a control unit, two squaring blocks, two cubic root recovery blocks, three multiplication blocks, a sum block, distinguished by the introduction of new blocks, the organization of communication between the blocks, the input P of the device being connected to the control input of the control unit 1, the input K _{0 of the} device is connected to the first information input of the multiplication unit 9, the input r _{1 of the} device is connected to the information input of the squaring unit 2 and to the second the information input of the multiplication unit 5, the input r _{2 of the} device is connected to the information input of the squaring unit 3 and the second information input of the multiplying 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 multiplication unit 4, 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 The connection 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 block 9 multiplication, the output of the squaring unit 2 is connected to the first information input of the multiplication unit 4, the output of the squaring unit 3 is connected to the first information input of the multiplying unit 5, the output of the multiplication unit 4 is connected inen with the information input of the cubic root extraction unit 6, the output of the multiplication unit 5 is connected to the information 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.