RU2445687C1 - Device to determine functions of value of single assessment parameters of complicated technical systems - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: device comprises a group of input registers, three input registers, a group of commutators, a unit of involution, a delay element, two units of subtraction, a commutator, two units of multiplication, a square-ware generator, three groups of summators with accumulation, a group of subtraction units, two groups of division units, three groups of delay elements, a group of registers, two groups of keys, a group of square-ware generators, an OR element, a comparison unit, a division unit, two groups of indication units, a clock pulse generator and a pulse distributor.

EFFECT: increased accuracy of complex technical system technical level assessment due to detection of preference of a single numerical parameter.

11 dwg, 32 tbl

Description

The invention relates to computer technology and can be used to determine the value functions of individual indicators that characterize their impact on the quality of complex technical systems (STS).

Applicants do not know that such a technical problem should be solved. This is because in specific practical problems this factor is often neglected.

The technical result of the claimed solution is to identify the preferences of a single numerical indicator on a scale from zero to one to increase the reliability of assessing the technical level of STS. This makes it possible to assess the degree of influence of this and other individual indicators on the performance of the main functions of the STS in a normalized form (i.e., regardless of the dimension of the estimated indicator) when determining the technical level of the STS.

In addition, it becomes possible to determine the boundary values of the estimated unit indicators, i.e. ranges of permissible changes in the values of indicators. A single indicator should be understood as a parameter or characteristic that determines the main properties of the STS and significantly affects its functioning.

Thus, a function is formed that takes part in determining the technical level of the STS.

The determination of the value functions of the individual STS indicators is carried out in the following order:

1. The definition of a list of individual indicators.

2. Determination of the type of value function for each unit indicator.

3. The establishment of boundary values of individual indicators.

4. Selection of the value function by each expert.

5. Verification of the degree of consistency of expert assessments.

The initial information for these procedures is the polling matrix of the k-th expert, presented in table 1 (stages 1 through 4).

Table 1 Interview matrix of the expert Indicators Indicator values U _iк1 (g _i ) = 0.10 U _iк2 (g _i ) = 0.20 U _iк3 (g _i ) = 0.50 U _iк4 (g _i ) = 0.70 U _iк5 (g _i ) = 0.90 g ₁

g _i

g _n

The number of these tables is determined by the number of experts participating in the survey.

In table 1, the following notation:

U _icc (g _i ) is a value function that establishes a correspondence between the values of an indicator and a scale from 0 to 1.

g _i - a single indicator that affects the quality of the STS.

The value function sets priorities between the different values of a single indicator. For each type of indicator, in principle, a kind of value function can be assigned.

The value function for logical indicators is binary and takes values 0 or 1, depending on whether this property is desirable or not. In the future, we will consider numerical indicators that provide for the introduction of five points.

The numerical values in each row of Table 1 determine the nature of the change in the value function: it can be monotonically decreasing or increasing, linear, convex or concave, S-shaped, triangular and trapezoidal, etc.

It is advisable to obtain averaged indicators g _ij for each j-th point according to the following dependence for all experts:

where g _iкj is the value of the indicator from table 1;

j = 1, ..., 5; k = 1, ..., m; i = 1, ..., n;

m is the number of experts participating in the survey;

n is the number of unit indicators.

These averaged indicators can be presented in table 2.

table 2 Matrix of averaged indicators Indicators Indicator values U _i1 (g _i ) = 0.10 U _i2 (g _i ) = 0.20 U _i3 (g _i ) = 0.50 U _i4 (g _i ) = 0.70 U _i5 (g _i ) = 0.90 g ₁

g _i

g _n

The numerical values in each row of table 2 determine the appearance of the desired value function.

However, there is a need to verify the degree of consistency of expert assessments (stage 5). This can be done using the concordance coefficient W _j , which is estimated for each of the five points of the value function according to the following formula:

i = 1, ..., n; k = 1, ..., m; j = 1, ..., 5;

where d _ijк is the normalized deviation of the current value of the indicator g _iкj from its average value, determined by the formula (1).

The value of d _ijк is estimated by the following formula:

If inequality holds

where W _∂ is the acceptable value of the concordance coefficient, then the results of the survey of experts can be considered consistent.

Otherwise, it is necessary to adjust the results of the expert survey by re-conducting it.

To illustrate, consider a specific example. Define the value function of the individual indicators of the truck. We distinguish six of its functional unit indicators:

1) speed (U, km / h);

2) capacity (V, m ³ );

3) the mass of the transported cargo (m _G , t);

4) the mass of the equipped car (m _a , t);

5) turning angle (α, degrees);

6) engine power (P, hp).

In FIG. From 1 to 6, the value functions for these indicators are presented, and the opinions of each of the seven experts are taken into account. The numbers of the curves in each figure correspond to the numbers of the corresponding experts.

The numerical values of indicators taken from these curves are presented in Table 3-9 for each expert. Tab. 10 contains information on average values of indicators based on expert testimony. Table 11-17 shows the differences between the average values of a single indicator and the values of this indicator according to each expert for each j-th point of the value function. Since there will be a squaring in the future, the sign in front of these differences does not matter and therefore the difference modules are given in these tables.

Table 18-24 contains the normalized values of these differences obtained in accordance with formula (3).

Table 25-31 shows the squares of these normalized values for each expert for all points of the curves of value functions. Table 32 summarizes the summation of the squares of the normalized differences and the estimates of W _j according to formula (2). From this table it can be seen that each value of W _{j is} greater than 0.99. This indicates a good coordination of the actions of experts, and even with W _∂ = 0.80, the obtained average values of the value function of the individual truck indicators (Table 10) can be taken as a basis. The obtained value functions of these indicators are presented in figures 1-6 in the form of dashed lines.

The technical result is achieved by the fact that the device for determining the value functions of the individual estimated indicators of complex systems contains a group of input registers, including m matrices, each of which consists of 5 × n elements, the first, second and third input registers, a group of switches, including m matrices, each of which consists of 5 × n elements, exponentiation block, delay element (EI), first and second subtraction blocks, commutator, first and second multiplication blocks, quadrator, first and second groups of accumulators with accumulation Each of which is composed of 5 × n elements, the third group of adders consisting of five elements, a group of the subtraction blocks comprising m of matrices, each of which

Table 3 Numerical values of indicators for Expert Advisor No. 1 Indicator number Indicator values U _i11 (g _i ) = 0.10 U _i12 (g _i ) = 0.20 U _i13 (g _i ) = 0.50 U _i14 (g _i ) = 0.70 U _i15 (g _i ) = 0.90 one 17.34 32.00 80.00 111.00 142.66 2 1.96 4.65 12.80 24.30 45.00 3 5.00 7.00 9.00 9.60 9.94 four 1.20 2.90 7.25 10,20 13.15 5 2.40 3.60 14.40 28.80 67.20 6 96.00 132.00 174.00 198.00 246.00

Table 4 Numerical values of indicators for Expert Advisor No. 2 Indicator number Indicator values U _i21 (g _i ) = 0.10 U _i22 (g _i ) = 0.20 U _i23 (g _i ) = 0.50 U _i24 (g _i ) = 0.70 U _i25 (g _i ) = 0.90 one 16.18 30.05 77.34 108.00 134.68 2 0.27 1.33 6.65 13,99 31.33 3 1,60 2.80 6.10 8.00 9.24 four 1.00 2,30 6.00 8.60 11.20 5 5.60 9.60 28.80 45.60 84.00 6 90.00 120.00 157.00 180.00 240.00

Table 5 Numerical values of indicators for Expert Advisor No. 3 Indicator number Indicator values U _i31 (g _i ) = 0.10 U _i32 (g _i ) = 0.20 U _i33 (g _i ) = 0.50 U _i34 (g _i ) = 0.70 U _i35 (g _i ) = 0.90 one 9.54 18.00 52.00 73.35 96.00 2 1.12 2.98 10.00 20.00 38.67 3 2.60 4.10 7.60 8.80 9.52 four 1.30 3.20 8.95 11.40 14.70 5 4.00 6.60 20.40 38.40 74.40 6 36.00 60.00 102.00 132.00 198.00

Table 6 Numerical values of indicators for Expert Advisor No. 4 Indicator number Indicator values U _i41 (g _i ) = 0.10 U _i42 (g _i ) = 0.20 U _i43 (g _i ) = 0.50 U _i44 (g _i ) = 0.70 U _i45 (g _i ) = 0.90 one 12.66 22.10 61.33 90.00 117.34 2 4.48 9.66 22.65 41.33 60.00 3 2.00 3.40 6.80 8.40 9.38 four 1.10 2.60 6.60 9.30 12,20 5 7.20 12.50 36.00 57.60 93.60 6 135.00 165.00 204.00 234.00 270.00

Table 7 Numerical values of indicators for Expert Advisor No. 5 Indicator number Indicator values U _i51 (g _i ) = 0.10 U _i52 (g _i ) = 0.20 U _i53 (g _i ) = 0.50 U _i54 (g _i ) = 0.70 U _i55 (g _i ) = 0.90 one 8.00 20.10 46.65 66.62 86.65 2 2.80 6.32 18.10 30.00 54.00 3 1.20 2.40 5.40 7.38 9.10 four 1.40 3,50 8.70 12.30 16.50 5 10.40 18.60 48.00 72.00 103,20 6 114.00 150.00 188.00 216.00 258.00

Table 8 Numerical values of indicators for Expert Advisor No. 6 Indicator number Indicator values U _i61 (g _i ) = 0.10 U _i62 (g _i ) = 0.20 U _i63 (g _i ) = 0.50 U _i64 (g _i ) = 0.70 U _i65 (g _i ) = 0.90 one 14.22 24.00 63,20 98.20 125.40 2 3.64 7.99 22.10 36.00 57.34 3 3.00 4.80 8.20 9.15 9.68 four 1,50 3.80 9.60 13.50 17.70 5 12.00 21.60 55,20 79.30 108.00 6 72.00 102.00 144.00 165.00 234.00

Table 9 Numerical values of indicators for Expert Advisor No. 7 Indicator number Indicator values U _i71 (g _i ) = 0.10 U _i72 (g _i ) = 0.20 U _i73 (g _i ) = 0.50 U _i74 (g _i ) = 0.70 U _i75 (g _i ) = 0.90 one 11.10 19.80 57.34 98.67 125.30 2 5.32 11.33 30.00 45.30 61.38 3 3.60 6.00 8.80 9.40 9.80 four 0.90 2.00 5.40 7.95 10,20 5 8.80 15.60 40.00 64.80 100.80 6 54.00 81.00 123.00 150.00 222.00

Table 10 Average values based on information from seven experts Indicator number Average Values U _i1 (g _i ) = 0.10 U _i2 (g _i ) = 0.20 U _i3 (g _i ) = 0.50 U _i4 (g _i ) = 0.70 U _i5 (g _i ) = 0.90 one 12.72 23.72 62.69 92.26 118.29 2 2.80 6.32 17.47 30.15 49.67 3 2.71 4.36 7.41 8.68 9.38 four 1.20 2.90 7.50 10.46 13.66 5 7.20 12.59 34.69 55.21 90.17 6 91.00 115.72 156.00 182.14 238.29

Table 11 Differences between the average values of a single indicator and the values of this indicator according to expert No. 1 Indicator number Difference values U _i11 (g _i ) = 0.10 U _i12 (g _i ) = 0.20 U _i13 (g _i ) = 0.50 U _i14 (g _i ) = 0.70 U _i15 (g _i ) = 0.90 one 4.62 8.28 17.31 18.74 24.37 2 0.84 1,67 8.47 5.85 4.67 3 2.29 2.64 1,59 0.92 0.56 four 0.00 0.00 0.25 0.26 0.51 5 4.80 8.99 10.29 26.41 22.97 6 5.00 16.28 18.00 15.86 7.71

Table 12 The differences between the average values of a single indicator and the values of this indicator according to expert No. 2 Indicator number Difference values U _i21 (g _i ) = 0.10 U _i22 (g _i ) = 0.20 U _i23 (g _i ) = 0.50 U _i24 (g _i ) = 0.70 U _i25 (g _i ) = 0.90 one 3.46 6.33 14.65 15.74 16.39 2 2,53 4.99 10.82 16.16 18.34 3 1,11 1,56 1.31 0.68 0.14 four 0.20 0.60 1,50 1.86 2.46 5 1,60 2.99 5.89 9.61 6.17 6 1.00 4.28 1.00 2.14 1.71

Table 13 Differences between the average values of a single indicator and the values of this indicator according to expert No. 3 Indicator number Difference values U _i31 (g _i ) = 0.10 U _i32 (g _i ) = 0.20 U _i33 (g _i ) = 0.50 U _i34 (g _i ) = 0.70 U _i35 (g _i ) = 0.90 one 3.18 5.72 10.69 18.91 22.29 2 1.68 3.34 7.47 10.15 11.00 3 0.11 0.26 0.19 0.12 0.14 four 0.10 0.30 1.45 0.94 1,04 5 3.20 5.99 14.29 16.81 15.77 6 55.00 55.72 54.00 50.14 40.29

Table 14 Differences between the average values of a single indicator and the values of this indicator according to expert No. 4 Indicator number Difference values U _i41 (g _i ) = 0.10 U _i42 (g _i ) = 0.20 U _i43 (g _i ) = 0.50 U _i44 (g _i ) = 0.70 U _i45 (g _i ) = 0.90 one 0.06 1,62 1.36 2.26 0.95 2 1.68 3.34 5.18 11.18 10.33 3 0.71 0.96 0.61 0.28 0.00 four 0.10 0.30 0.90 1.16 1.46 5 0.00 0.09 1.31 2,39 3.43 6 44.00 50.28 48.00 51.86 31.71

Table 15 Differences between the average values of a single indicator and the values of this indicator according to expert No. 5 Indicator number Difference values U _i51 (g _i ) = 0.10 U _i52 (g _i ) = 0.20 U _i53 (g _i ) = 0.50 U _i54 (g _i ) = 0.70 U _i55 (g _i ) = 0.90 one 4.72 3.62 16.04 25.64 31.64 2 0.00 0.00 0.63 0.15 4.33 3 1.51 1.96 2.01 1.30 0.28 four 0.20 0.60 1.20 1.84 2.84 5 3.20 6.01 13.31 26.79 13.03 6 23.00 34.28 32.00 33.86 19.71

Table 16 Differences between the average values of a single indicator and the values of this indicator according to expert No. 6 Indicator number Difference values U _i61 (g _i ) = 0.10 U _i62 (g _i ) = 0.20 U _i63 (g _i ) = 0.50 U _i64 (g _i ) = 0.70 U _i65 (g _i ) = 0.90 one 1,50 0.28 0.51 5.94 7.11 2 0.84 1,67 4.63 5.85 7.67 3 0.29 0.44 0.79 0.47 0.30 four 0.30 0.90 2.10 3.04 4.04 5 4.80 9.01 20.51 ' 24.09 17.83 6 19.00 13.72 12.00 17.14 4.29

Table 17 Differences between the average values of a single indicator and the values of this indicator according to expert No. 7 Indicator number Difference values U _i71 (g _i ) = 0.10 U _i72 (g _i ) = 0.20 U _i73 (g _i ) = 0.50 U _i74 (g _i ) = 0.70 U _i75 (g _i ) = 0.90 one 1,62 3.92 5.35 6.41 7.01 2 2,52 5.01 12.53 15.15 11.71 3 0.89 1,64 1.39 0.72 0.42 four 0.30 0.90 2.10 2,51 3.46 5 1,60 3.01 5.31 9.59 10.63 6 37.00 34.72 33.00 32.14 16.29

Table 18 Normalized difference values for expert No. 1 Indicator number Normalized Difference Values U _i11 (g _i ) = 0.10 U _i12 (g _i ) = 0.20 U _i13 (g _i ) = 0.50 U _i14 (g _i ) = 0.70 U _i15 (g _i ) = 0.90 one 0.363 0.349 0.276 0,203 0.206 2 0,300 0.264 0.485 0.194 0,094 3 0.845 0.606 0.215 0.106 0,060 four 0,000 0,000 0,033 0,025 0,037 5 0.667 0.714 0.297 0.478 0.255 6 0,055 0.141 0.115 0,087 0,032

Table 19 Normalized difference values for expert No. 2 Indicator number Normalized Difference Values U _i21 (g _i ) = 0.10 U _i22 (g _i ) = 0.20 U _i23 (g _i ) = 0.50 U _i24 (g _i ) = 0.70 U _i25 (g _i ) = 0.90 one 0.272 0.267 0.234 0.171 0.139 2 0.904 0.790 0.619 0.536 0.369 3 0.410 0.357 0.176 0,078 0.015 four 0.167 0,207 0,200 0.178 0.180 5 0.222 0.237 0.170 0.174 0,068 6 0.011 0,037 0.006 0.012 0.007

Table 20 Normalized difference values for expert No. 3 Indicator number Normalized Difference Values U _i31 (g _i ) = 0.10 U _i32 (g _i ) = 0.20 U _i33 (g _i ) = 0.50 U _i34 (g _i ) = 0.70 U _i35 (g _i ) = 0.90 one 0.250 0.241 0.171 0.205 0.188 2 0,600 0.528 0.428 0.337 0.221 3 0,041 0,060 0,026 0.014 0.015 four 0,083 0.103 0.193 0,090 0,076 5 0.444 0.476 0.412 0,304 0.175 6 0.604 0.482 0.346 0.275 0.169

Table 21 Normalized difference values for expert No. 4 Indicator number Normalized Difference Values U _i41 (g _i ) = 0.10 U _i42 (g _i ) = 0.20 U _i43 (g _i ) = 0.50 U _i44 (g _i ) = 0.70 U _i45 (g _i ) = 0.90 one 0.005 0,068 0,022 0.024 0.008 2 0,600 0.528 0.297 0.371 0.208 3 0.262 0.220 0,082 0,032 0,000 four 0,083 0.103 0,120 0,111 0.107 5 0,000 0.007 0,038 0,043 0,038 6 0.484 0.434 0,308 0.285 0.133

Table 22 Normalized difference values for expert No. 5 Indicator number Normalized Difference Values U _i51 (g _i ) = 0.10 U _i52 (g _i ) = 0.20 U _i53 (g _i ) = 0.50 U _i54 (g _i ) = 0.70 U _i55 (g _i ) = 0.90 one 0.371 0.153 0.256 0.278 0.267 2 0,000 0,000 0,036 0.005 0,087 3 0.557 0.450 0.271 0.150 0,030 four 0.167 0,207 0.160 0.176 0.208 5 0.444 0.477 0.384 0.485 0.145 6 0.253 0.296 0.205 0.186 0,083

Table 23 Normalized difference values for expert No. 6 Indicator number Normalized Difference Values U _i61 (g _i ) = 0.10 U _i62 (g _i ) = 0.20 U _i63 (g _i ) = 0.50 U _i64 (g _i ) = 0.70 U _i65 (g _i ) = 0.90 one 0.118 0.012 0.008 0,064 0,060 2 0,300 0.264 0.265 0.194 0.154 3 0.107 0,101 0.107 0,054 0,032 four 0.250 0.310 0.280 0.291 0.296 5 0.667 0.716 0.591 0.436 0.198 6 0.209 0.119 0,077 0,094 0.018

Table 24 Normalized difference values for expert No. 7 Indicator number Normalized Difference Values U _i71 (g _i ) = 0.10 U _i72 (g _i ) = 0.20 U _i73 (g _i ) = 0.50 U _i74 (g _i ) = 0.70 U _i75 (g _i ) = 0.90 one 0.127 0.165 0,085 0,069 0.059 2 0,900 0.793 0.717 0.502 0.236 3 0.328 0.376 0.188 0,083 0,045 four 0.250 0.310 0.280 0.240 0.253 5 0.222 0.239 0.153 0.174 0.118 6 0.411 0,300 0.212 0.176 0,068

Table 25 The squares of the normalized values of the difference for expert No. 1 Indicator number Squares of normalized difference values U _i11 (g _i ) = 0.10 U _i12 (g _i ) = 0.20 U _i13 (g _i ) = 0.50 U _i14 (g _i ) = 0.70 U _i15 (g _i ) = 0.90 one 0.1318 0.1218 0,0762 0.0412 0,0424 2 0,0900 0,0697 0.2350 0,0376 0.0088 3 0.7141 0.3666 0,0460 0.0112 0.0036 four 0.0000 0.0000 0.0011 0,0006 0.0014 5 0.4444 0.5099 0.0880 0.2288 0,0649 6 0.0030 0.0198 0.0133 0.0076 0.0010

Table 26 The squares of the normalized values of the difference for expert No. 2 Indicator number Squares of normalized difference values U _i21 (g _i ) = 0.10 U _i22 (g _i ) = 0.20 U _i23 (g _i ) = 0.50 U _i24 (g _i ) = 0.70 U _i25 (g _i ) = 0.90 one 0,0740 0,0712 0,0546 0,0291 0.0192 2 0.8164 0.6234 0.3836 0.2873 0.1363 3 0.1678 0,1280 0,0313 0.0061 0,0002 four 0,0278 0.0428 0,0400 0,0316 0,0324 5 0,0494 0,0564 0.0288 0,0303 0.0047 6 0.0001 0.0014 0.00004 0.0001 0.00005

Table 27 The squares of the normalized values of the difference for expert No. 3 Indicator number Squares of normalized difference values U _i31 (g _i ) = 0.10 U _i32 (g _i ) = 0.20 U _i33 (g _i ) = 0.50 U _i34 (g _i ) = 0.70 U _i35 (g _i ) = 0.90 one 0.0625 0,0582 0,0291 0.0420 0,0355 2 0.3600 0.2793 0.1828 0.1133 0.0490 3 0.0016 0.0036 0,0007 0,0002 0,0002 four 0,0007 0.0107 0,0374 0.0081 0.0058 5 0.1975 0.2264 0.1697 0.0927 0,0306 6 0.3653 0.2318 0.1198 0,0758 0.0286

Table 28 The squares of the normalized difference values for expert No. 4 Indicator number Squares of normalized difference values U _i41 (g _i ) = 0.10 U _i42 (g _i ) = 0.20 U _i43 (g _i ) = 0.50 U _i44 (g _i ) = 0.70 U _i45 (g _i ) = 0.90 one 0.00002 0.0047 0,0005 0,0006 0.00006 2 0.3600 0.2793 0.0879 0.1375 0,0436 3 0,0686 0,0485 0.0068 0.0010 0.0000 four 0.0069 0.0107 0.0144 0.0123 0.0114 5 0.0000 0.00005 0.0014 0.0019 0.0014 6 0.2338 0.1888 0.0947 0.0811 0.0177

Table 29 The squares of the normalized values of the difference for expert No. 5 Indicator number Squares of normalized difference values U _i51 (g _i ) = 0.10 U _i52 (g _i ) = 0.20 U _i53 (g _i ) = 0.50 U _i54 (g _i ) = 0.70 U _i55 (g _i ) = 0.90 one 0.1377 0,0230 0,0655 0,0772 0,0715 2 0.0000 0.0000 0.0013 0.00002 0.0076 3 0.0964 0.2021 0,0736 0.0224 0,0009 four 0,0278 0.0428 0,0256 0,0309 0.0432 5 0.1975 0.2279 0.1472 0.2355 0,0209 6 0.0639 0.0878 0.0421 0,0346 0.0068

Table 30 The squares of the normalized difference values for expert No. 6 Indicator number Squares of normalized difference values U _i61 (g _i ) = 0.10 U _i62 (g _i ) = 0.20 U _i63 (g _i ) = 0.50 U _i64 (g _i ) = 0.70 U _i65 (g _i ) = 0.90 one 0.0139 0.0001 0,00007 0.0041 0.0036 2 0,0900 0,0698 0,0702 0,0376 0,0238 3 0.0115 0.0102 0.0114 0.0029 0.0010 four 0.0625 0.0963 0,0784 0.0845 0.0875 5 0.4444 0.5122 0.3496 0.1904 0,0391 6 0,0436 0.0141 0.0059 0.0089 0,0003

Table 31 The squares of the normalized values of the difference for expert No. 7 Indicator number Squares of normalized difference values U _i71 (g _i ) = 0.10 U _i72 (g _i ) = 0.20 U _i73 (g _i ) = 0.50 U _i74 (g _i ) = 0.70 U _i75 (g _i ) = 0.90 one 0.0162 0,0273 0.0073 0.0048 0.0035 2 0.8100 0.6284 0.5144 0.2525 0,0556 3 0.1079 0.1415 0,0352 0.0069 0.0020 four 0.0625 0.0963 0,0784 0,0576 0,0642 5 0,0494 0,0572 0,0234 0,0302 0.0139 6 0.1690 0,0900 0,0447 0,0311 0.0047

Table 32 Summation and Estimation Results W _j Intermediate values Impression number
body Sum of squared normalized difference values U _i1 (g _i ) = 0.10 U _i2 (g _i ) = 0.20 U _i3 (g _i ) = 0.50 U _i4 (g _i ) = 0.70 U _i5 (g _i ) = 0.90 one 0.4361 0.3063 0.2332 0,1990 0.1757 2 2,5264 1.9499 1,4752 0.8658 0.3247 3 1,1679 0,9005 0.2050 0,0507 0.0079 four 0.1882 0.2996 0.2753 0.2256 0.2459 5 1.3826 1,5900 0.8081 0.8098 0.1755 6 0.8787 0.6337 0.3205 0.2392 0.0591 Σ 6.5799 5,6800 3.3173 2,3901 0.9888 W _j 0,9923 0,9938 0,9961 0,9972 0,9988

consists of 5 × n elements, the first group of division blocks, consisting of 5 × n elements, the second group of division blocks, including m matrices, each of which consists of 5 × n elements, the first group of EZ, including five subgroups, each of which consists of n elements, the second and third groups of EZ, consisting of four elements, a group of registers, consisting of 5 × n elements, the first group of keys, consisting of 5 × n elements, the second group of keys, consisting of five elements, register, group of quadrators, including m matrices, each of which consists of 5 × n ele events, OR element, comparison unit, division unit, the first group of indication blocks, consisting of 5 × n elements, the second group of indication blocks, consisting of n elements, a clock generator and a pulse distributor (RI), the clock input of which is connected to the output of the generator clock pulses, the first output of the RI - with the recording inputs of the first group of input registers, the second, third and fourth outputs - with the recording inputs of the first, second and third input registers, the fifth output - with the read inputs of the group of input registers , the sixth output - with the control inputs of the group of switches, the seventh output - with the write inputs of the register group, the eighth output - with the read input of the second register, the ninth output - with the control input of the switch, the tenth and eleventh outputs - with the read inputs of the first and third input registers, respectively , from the twelfth to sixteenth outputs - with control inputs, respectively, from the first to fifth elements of the second group of keys, the seventeenth output - with the read inputs of the group of registers, eighteenth and nineteenth Exit - with inputs respectively write and read register data inputs of the group of input registers are input reference source information, which are supplied with the values g _ikj characterizing the i-th unit indicator for the kth expert j-th point of its value function, data inputs of the first , the second and third input registers are the input of the initial information, which receives the values n, m and W _∂ , respectively, characterizing the number of individual indicators, the number of experts and the admissible value of the concordance factor, the output of each element from the first to the mth matrix of the input register is connected to the information input of the corresponding element from the first to the mth matrix of the group of switches, the first output of each of which is connected to the first by the mth inputs of the corresponding elements of the first group of adders with accumulation, and the second output is to the input of the subtracted corresponding element of each of the m matrices of the group of subtraction blocks, the output of each of which is connected to the input of the divisible corresponding element of each of the m matrices of the second group b locks, and the input of each matrix being reduced - with the output of the corresponding element of a single matrix of the first group of division blocks, the dividend of each of which is connected to the output of the corresponding element of the first group of adders with accumulation, and the input of the divider - to the first output of the switch, the second output of which is connected to the quadrator input, and the information input with the output of the second input register, the output of the first input register is connected to the inputs of the exponentiation block and the EZ, the outputs of which are connected to the inputs respectively of a substantially reduced and subtracted first subtraction block, the output of which is connected to the first input of the first multiplication block, the second input of which is connected to the quadrator output, and the output is to the register information input, the output of which is connected to the input of the divider of the division block, the dividend of which is connected to the output of the second multiplication unit, and the output with the input of the subtracted second subtraction unit, the output of which is connected to the information input of the comparison unit, the threshold input of which is connected to the output of the third input register, in the progress of each element of the first group of division blocks is connected to the information input of the corresponding element of the group of registers and to the input of the corresponding element of the first group of EZs, the output of each of which is connected to the input of the divisor of the corresponding element of each of the m matrices of the second group of division blocks, the output of each of which is connected to the input each corresponding element of the group of quadrators, the output of each of which is connected to the first by the mth input of the corresponding elements of the second group of adders with accumulation, the output of each of the first element of a certain column of which is connected to the first through the n-th inputs of the corresponding elements of the third group of adders with accumulation, the output of the first element of which is connected to the first input of the OR element, and the input of each of the following elements, from second to fifth, with the input of the corresponding element, from the first to fourth, second groups of EZs, the output of each of which is connected to the corresponding inputs of the OR element, from the second to fifth output of which is connected to the input of the second multiplication block, the output of the comparison block is connected to the info the input of each element of the second group of keys, the output of the last, fifth, from which is connected to the control input of each element of the last, fifth, column of the first group of keys, the output of each of the other elements, from the first to the fourth, second group of keys is connected to the input of the corresponding element of the third EZ groups, the output of each of which is connected to the control input of each element of the corresponding column, from the first to the fourth, the first group of keys, the information input of each element of which is connected to the output an ode to the corresponding element of the group of registers, and the output to the input of the corresponding element of the first group of display units, while the outputs of the elements of a certain row, from the first to the n-th, the first group of keys are connected to the first to fifth inputs of the corresponding elements, from the first to the n-th , the second group of display units.

1-6 depict value functions for six unit evaluation indicators characterizing a truck. The numbers of the curves in each figure correspond to the numbers of the corresponding experts (from the first to the seventh).

Figures 7, 8, 9 and 10 show a functional diagram of a device for determining the value functions of individual evaluative indicators of complex technical systems (to eliminate the cumbersome communication between RI and control inputs of the corresponding blocks and elements are not shown completely, but are indicated by numbering the inputs and outputs) .

Figure 11 presents the sequence diagram of the operation of the claimed device (the ordinates indicate the numbers of the outputs of the RI, and the abscissa indicates the number of objects). Moreover, the durations of various operations (addition and subtraction - one clock cycle, multiplication and squaring - six clock cycles, cubing and division - twelve clock cycles) in the upper part of Fig. 11 (for the possibility of execution of the sequence diagram, m = 7, n = 6, although these values can take arbitrary values).

A device for determining the value functions of individual estimated indicators of complex technical systems (Figs. 7, 8, 9 and 10) contains a group of 1 input registers, including m matrices, each of which consists of 5 × n elements, the first 2, second 3 and third 4 input registers, a group of 5 switches, including m matrices, each of which consists of 5 × n elements, an exponentiation block 6, EZ 7, the first 8 and second 9 subtraction blocks, commutator 10, first 11 and second 12 multiplication blocks, a quadrator 13, the first 14 and second 15 groups of accumulative adders, each of which x consists of 5 × n elements, the third group of 16 adders with accumulation, consisting of five elements, a group of 17 subtraction blocks, including m matrices, each of which consists of 5 × n elements, the first division group 18, consisting of 5 × n elements , the second group of 19 division blocks, including m matrices, each of which consists of 5 × n elements, the first group of 20 EZ, including five subgroups, each of which consists of n elements, the second 21 and third 22 groups of EZ, consisting of four elements , a group of 23 registers consisting of 5 × n elements, the first group of 24 cells whose, consisting of 5 × n elements, a second group of 25 keys, consisting of five elements, register 26, a group of 27 quadrators, including m matrices, each of which consists of 5 × n elements, an OR element 28, a comparison unit 29, a block 30 division, the first group of 31 display units, consisting of 5 × n elements, the second group of 32 display units, consisting of n elements, a clock generator 33 and RI 34.

It should be noted that blocks 6, 9, and 12 have only one input. This is explained by the following. In block 6 of raising to a power, an exponent of three is “wired” in advance. In the second subtraction block 9, the decremented equal to unity is already “sewn up”. In the second block 12 of the multiplication one of the factors is “sewn up” (coefficient equal to twelve).

A device for determining the value functions of individual evaluation indicators of complex technical systems works as follows. The value g _iкj , characterizing the i-th unit indicator for the k-th expert of the j-th point of his value function, is sent to the information input of each element of group 1 of the input registers. In this case, the control signals to the recording inputs of group 1 are supplied from the first output of the RI 34, the pace of which is set by the generator 33 clock pulses. The information inputs of the first 2, second 3, and third 4 input registers are fed with the values n, m, and W _∂ , which characterize the number of individual indicators, the number of experts, and the admissible value of the concordance coefficient. In this case, the control signals to the recording inputs of blocks 2, 3 and 4 are sent respectively from the second, third and fourth outputs of RI 34.

в соответствии с формулой (1). Этот показатель засылается на информационный вход каждого соответствующего элемента группы 23 регистров. При этом управляющий сигнал на запись подается с седьмого выхода РИ 34. Кроме того, осредненный показатель направляется на вход уменьшаемого каждого соответствующего элемента группы 17 блоков вычитания, на вход вычитаемого каждого из которых поступает с выхода соответствующего элемента группы 1 входных регистров через группу 5 коммутаторов величина g_iкj. Поскольку эта величина подается со второго выхода каждого элемента группы 5, управляющий сигнал на эту группу с выхода РИ 34 не подается. Осредненный показатель

с выхода каждого элемента первой группы 18 блоков деления засылается также на вход соответствующего элемента первой группы 20 ЭЗ. С выхода каждого элемента этой группы этот показатель подается на вход делителя каждого соответствующего элемента второй группы 19 блоков деления, на вход делимого каждого из которых с входа каждого соответствующего элемента группы 17 блоков вычитания направляется значение

.According to the signal from the fifth output of RI 34, to the reading inputs of each of the elements of group 1 of the input registers, the quantities g _{ij are} sent through the corresponding elements of group 6 of the switches to the corresponding inputs of the elements of the first group of 14 adders with accumulation. In this situation, a signal from the sixth output of RI 34 is supplied to the control input of each element of the group of 5 switches, which ensures the appearance of a signal at the first output of each element of group 5 and, therefore, at the inputs of the elements of the first group 14 of accumulators. In each element of this group, the sum of g _iкj values is _determined for all m experts for the i-th unit indicator of the j-th point of its value function. The value of this sum from the output of each element of group 14 is directed to the input of the dividend of each corresponding element of the first group 18 of division blocks, the value of m is sent to the input of the divider of each of which from the output of the second input register 3 through switch 10. The signals to the read input of block 3 and the control input of block 10 are supplied respectively from the eighth and ninth outputs of RI 34. This ensures that a signal appears at the first output of the switch 10. Thus, an average indicator will be generated at the output of each element of the first group 18 of division blocks

in accordance with the formula (1). This indicator is sent to the information input of each corresponding element of the group of 23 registers. In this case, the control signal for recording is supplied from the seventh output of RI 34. In addition, the averaged indicator is sent to the input of each corresponding element of group 17 of the subtraction units being reduced, the input of each of which is deducted from the output of the corresponding element of group 1 of the input registers through group 5 of switches g _iкj . Since this value is supplied from the second output of each element of group 5, a control signal is not supplied to this group from the output of RI 34. Average

from the output of each element of the first group of 18 division blocks is also sent to the input of the corresponding element of the first group of 20 EZ. From the output of each element of this group, this indicator is fed to the input of the divider of each corresponding element of the second group of 19 division blocks, to the input of the dividend of each of which the value is sent from the input of each corresponding element of the group 17 of subtraction blocks

.

Group 19 carries out normalization, i.e. calculates the value of d _ijк in accordance with formula (3), which is sent to the input of each corresponding element of the group of 27 quadrators.

According to the signal from the tenth output of RI 34, to the read input of the first input register 2, the value n is supplied through the power raising unit 6 and the EZ 7 to the inputs of the first subtracting unit 8, which are reduced and subtracted, respectively. From the output of block 8, the quantity (n ³ -n) is sent to the first input of the first block 11 of multiplication, the second input of which is sent from the output of the second input register 3 through the switch 10 and quadrator 13 value m. In this situation, a signal for reading from block 3 is supplied from the eighth output of RI 34, and no signal is supplied to the control input of switch 10, because the value of m is transmitted from its second output. From the output of block 11, the value of m ³ (n ³ -n) is sent to the information input of register 26. In this case, the control signal for recording is supplied from the eighteenth output of RI 34. The signal from the nineteenth output of RI 34 sends this value to the input of the divider of division block 30.

A group of 27 quadrants, a second 15 and a third 16 groups of accumulators, the second group 21 of the EZ, the OR element 28, the second subtraction block 12, the division block and the second subtraction block 9 evaluate the concordance coefficient W _j for each jth point of the value function in according to the formula (2). This coefficient is fed to the information input of the comparison unit 29, the threshold input of which is sent from the output of the third input register 4 to the valid value of the coefficient of concordance W _∂ . The control signal to the read input of this input register is supplied from the eleventh output of the RI 34.

If inequality (4) is observed, then at the output of the comparison unit 29 a signal will appear that is sent to the elements of the second group of 25 keys.

Since the values of W _j (j = 1, ..., 5) for all five points of the value function are determined sequentially, the control signals to the element of the second group of 25 keys from the twelfth, thirteenth, fourteenth, fifteenth and sixteenth outputs of RI 34 are received with a certain interval in accordance with the cyclogram of the device. From the output of each element, except for the last (fifth), second group of 25 keys, the control signal is fed to the input of the element of the third group 22 EZ, which ensures the simultaneous receipt of the control signal at the control input of each element of the first group of 24 keys.

According to the signal from the seventeenth output of RI 34 to the read input of each element of the group of 23 registers, the average value of the i-th unit index of the j-th point of the value function is sent to the information input of each corresponding element of the first group of 24 keys. In case inequality (4) is observed for the jth point of the value function, the control signal will ensure the passage of the parameter value characterizing this point for the i-th indicator through the elements of the first group of 24 keys to the inputs of the corresponding elements of the first 31 and second 32 groups of display units. Moreover, in the elements of group 31, the numerical values of the value function are displayed in five columns (points) for each unit indicator, and in the elements of group 32, the curves constructed by five points for each i-th indicator are displayed.

Thus, the technical result of the claimed invention is achieved not due to the mathematical apparatus, but using the technical means (blocks and elements) mentioned in the description of the operation of the device. This device allows you to identify the preference of a single numerical indicator on the scale of measurements from zero to unity, which makes it possible to assess the degree of influence of indicators on the performance of the main functions of STS.

The industrial applicability of the invention is justified by the fact that it can be used in different areas (industries) of production in assessing the degree of influence of indicators on the performance of STS.

Claims (1)

A device for determining the value functions of individual estimated indicators of complex technical systems contains a group of input registers, including m matrices, each of which consists of 5 × n elements, first, second and third input registers, a group of switches, including m matrices, each of which consists of 5 × n elements, exponentiation block, delay element (EI), first and second subtraction blocks, commutator, first and second multiplication blocks, quadrator, first and second groups of accumulators, each of which consists of 5 × n elements, the third group of adders, consisting of five elements, a group of subtraction blocks, including m matrices, each of which consists of 5 × n elements, the first group of division blocks, consisting of 5 × n elements, the second group of division blocks, including m matrices, each of which consists of 5 × n elements, the first group of ESs, including five subgroups, each of which consists of n elements, the second and third groups of ESs, consisting of four elements, a group of registers, consisting of 5 × n elements, the first key group consisting of 5 × n elements, second the fifth group of keys, consisting of five elements, a register, a group of quadrators, including m matrices, each of which consists of 5 × n elements, an OR element, a comparison block, a division block, the first group of indication blocks, consisting of 5 × n elements, the second a group of indication blocks, consisting of n elements, a clock generator and a pulse distributor (RI), the clock input of which is connected to the output of the clock generator, the first RI output - with the recording inputs of the first group of input registers, the second, third and fourth outputs - with the inputs and records of the first, second, and third input registers, respectively, the fifth output — with the read inputs of the group of input registers, the sixth output — with the control inputs of the group of switches, the seventh output — with the inputs of the write of the group of registers, the eighth output — with the read input of the second register, the ninth output - with the control input of the switch, the tenth and eleventh outputs - with read inputs of the first and third input registers, respectively, from the twelfth to sixteenth outputs - with control inputs, respectively, from the first about the fifth elements of the second group of keys, the seventeenth output - with the inputs of reading the group of registers, the eighteenth and nineteenth outputs - with the inputs respectively of the writing and reading of the register, the information inputs of the group of input registers are the input of the job of the initial information, to which the values of g _iк characterizing i- th unit indicator for the k-th expert of the j-th point of his value function, the information inputs of the first, second and third input registers are the input of the input of the initial information to which are respectively the values of n, m and W _d, characterizing the number of unit figures, the number of experts and the allowable value of the coefficient of concordance, the output of each element of the first to m-th matrix input register connected to the data input of the corresponding element of the first to m-th switch group matrix , the first output of each of which is connected to the first by the mth inputs of the corresponding elements of the first group of adders with accumulation, and the second output is to the input of the subtracted corresponding element of each of the m matrices of the block subtractions, the output of each of which is connected to the input of the divisible corresponding element of each of the m matrices of the second group of division blocks, and the input of the reduced each matrix to the output of the corresponding element of the unique matrix of the first group of division blocks, the input of the dividend of each of which is connected to the output of the corresponding element of the first groups of adders with accumulation, and the input of the divider to the first output of the switch, the second output of which is connected to the input of the quadrator, and the information input to the output of the second input register a, the output of the first input register is connected to the inputs of the exponentiation block and the EZ, the outputs of which are connected to the inputs of the correspondingly reduced and subtracted first subtraction block, the output of which is connected to the first input of the first multiplication block, the second input of which is connected to the quad output, and the output is with the information input of the register, the output of which is connected to the input of the divider of the division unit, the input of the dividend of which is connected to the output of the second multiplication unit, and the output - with the input of the subtracted second subtraction unit, the output of which о is connected to the information input of the comparison unit, the threshold input of which is connected to the output of the third input register, the output of each element of the first group of dividing units is connected to the information input of the corresponding element of the group of registers and to the input of the corresponding element of the first group of EZ, the output of each of which is connected to the input of the divider the corresponding element of each of the m matrices of the second group of division blocks, the output of each of which is connected to the input of each corresponding element of the group of quadrators, the output each of which is connected to the first by the mth input of the corresponding elements of the second group of adders with accumulation, the output of each element of a certain column of which is connected to the first by the n-th inputs of the corresponding elements of the third group of adders with accumulation, the output of the first element of which is connected to the first input of the element OR, and the input of each of the following elements, from the second to the fifth, with the input of the corresponding element, from the first to the fourth, second groups of EZs, the output of each of which is connected to the corresponding electronic inputs OR, the output of which is connected to the input of the second multiplication unit, the output of the comparison unit is connected to the information input of each element of the second group of keys, the output of the last, fifth, from which is connected to the control input of each element of the last, fifth, column of the first group of keys, the output of each of the remaining elements, from the first to the fourth, second groups of keys connected to the input of the corresponding element of the third group of EZ, the output of each of which is connected to the control input of each element of the corresponding column , from the first to the fourth, the first group of keys, the information input of each element of which is connected to the output of the corresponding element of the group of registers, and the output to the input of the corresponding element of the first group of display units, while the outputs of the elements of a certain row, from the first to the nth, first groups of keys are connected to the first through fifth inputs of the corresponding elements, from the first to the nth, second group of indication blocks.

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