SU1290218A1 - Method of calibration checking of instrument equipment - Google Patents

Abstract

This invention relates to the field of metrology. It can be used when calibrating measuring channels of information-measuring systems. The aim of the invention is to reduce the volume and simplify the verification process. For this purpose, an unambiguous measure is connected to the instrument being tested, and at its entrance equal values of the non-sample test signal are formed. The results of their measurements are recorded and compared with the result of measurement of an unambiguous measure. Two results of the test signal closest to it are selected, and (Considering the real conversion-to-test device function between them is linear, a system of equations is derived from which the error of the device is determined. One method of forming equidistant values of the signal is to sum the test signal A signal whose value is determined by the comparison unit. To do this, use the set-up, containing the controlled key element 1, the comparison unit 2, the testable device 3. The proposed method ozvol is to minimize the number of cross sections of power metal emogo measurement range of the instrument z.p.f 4-yl ly.Z For a (A 1 -.. © .l

Description

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The invention relates to metrology and can be mainly used in the metrological verification of measuring channels of information-measuring systems (process measuring instruments), as well as for checking other types of measuring instruments, especially in cases when reproducing exemplary signals in a wide range of values poses a certain complexity.

The aim of the invention is to reduce the volume and simplify the verification process.

The scope of verification is characterized by the number of units of physical quantity transmitted (reproducible) by a more accurate means (measure, standard), and the simplicity of verification is characterized by the possibilities of its automation and performance directly at the site of operation of the device being tested in a relatively short time.

The implementation of the claimed method is as follows. The basis of verification is the method of comparing the results of a measure of measure with their known values. To perform the verification, a rather unambiguous measure is used, the value of which is chosen for reasons of convenience, simplicity and reliability, or the possibility of implementing the measure

A unique measure is connected to the instrument being tested, it is measured and the measurement result is memorized.

Then connect to a test, instrument test signal. The initial value of the signal must be known, for example, equal to zero. Nachi

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The value of the test signal is changed from this known X value. The change in the signal is carried out in such a way as to ensure the fixation of the measurement results corresponding to the disparate values of the test signal. Specific examples of the formation of such equal values and their corresponding measurements are discussed below and are explained in the test signal wiring diagrams shown in Figures 1 - 3.

Assume that the equal values of the input signal are realized and the corresponding results are obtained.

Tats measurements X, X ,. . .X, X ,,

where n is the number of increments of the test signal required for by

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obtaining measurement results in the whole range of indications of the device being turned; K is the serial number of the increment.

The formation of equidistant values of the test signal at the input must be carried out in such a way that any subsequent value of the signal differs from the previous one, including the initial value X, by the same value. Essential for the realization of this condition and the whole verification in general is that during these operations with the input signal, knowledge of the actual values of the signal or the value of its increment A is not required.

The result is a series of test signal measurements.

 2) The measurement result of the unambiguous measure Xjj was obtained earlier.

When one of the measurement results of the test signal coincides with the measurement result of the measure Xg, the actual value of the constant increment A X Xa (X + KA) + ao Xd + a is determined,

where a, 3 (j are the parameters of the linearized portion of the real function of the conversion of the device being turned on; Ud is the initial known value of the test signal; 0 is the real value

measures;

K is the sequence number of the increment A of the input signal. Then at X Xg,

A - c. .

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in the more general case, the results of measurements of X and X, are closest to Xd. It is quite strictly possible to consider and provide the corresponding technical implementation (the latter is confirmed by the implementation of the known test methods for measuring measurement accuracy) that all three results X, Xd, X "belong to the linear part of the conversion function with parameters a and a (a) characterizes the slope of the linear plot, and a - the point of his pe312902

section with the axis of ordinates). Then the system of equations

X,., A, (Hy n-ka) + a „

XQ + ao

HK4. 2.0+ KA) + a, A + a, 5 whose solution allows to calculate the actual value of the increment A of the test signal:

X

K4-t

- X. A.A.

XQ - X, (b - X "- KA) a, Determine the ratio of the second difference to the first

a - x-ka „

X, -X, A, A Add the obtained result with the sequence number K of the increment of the test signal

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X, „- X, A V

Then the error of the measuring device at the Kth point of the measurement range (K is the incremental number of the test signal increment) is estimated as

LK X - KA.,

Let us consider the implementation of the operations of connecting a test signal to the input of a rotating device and forming its equidistant values.

One of the methods consists in that equal signal values are formed by sequentially summing the test signal connected to the input of the device under test with a signal whose value is determined by the comparison unit, for example, by a measuring instrument.

For this purpose, for example, (Fig. 1), an adjustable test signal is connected via a series-connected controlled key element 1, a comparator unit 2 and an adder, connected to the input of a rotating device 3. At its input, some known value of the X signal is applied.

Comparison unit 2 can be a measurement tool, an indicator tool, or a threshold element adjusted to some given value X ,,,. test signal.

The value of the signal X is changed. At the moment when X is equal with some given value X ad (the ad determines the number of verified sections of the measurement range), the test signal X is disconnected and a signal is formed.

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increment A into the adder, which for the given circuit simultaneously performs the role of a signal accumulator and ensures that it is not connected to the input of the device being scanned 3. At its output, record the measurement Xi of the signal XQ + A, Repeat this operation until the output of the checked instrument 3 of the measurement result X, which is close to the limiting value of its range. Conduct the previously specified processing of the measurement results of the test signal X and the unambiguous measure 0.

The operation of connecting to the calibrated instrument 3 of measure 6 in FIG. I and the following figures is not shown, since its technical implementation is practically the same as in the known methods and can be performed in any sequence with respect to other verification operations.

The peculiarity of the adder as a signal accumulator is related to the type of signal X. Thus, the circuit shown in Fig. 1 is the most convenient (simplifies calibration) of a certain group of measuring devices for which the implementation of the objective functions of the above operations by known devices does not present much difficulty.

The formation of equidistant test signal values is feasible in cases where the signal type does not allow a simple (natural) summation at the input of the device being turned on or existing adders (signal accumulators) can affect the accuracy of the calibration. Sequential addition of the executive signal, for example, an electrical device connected to the input of a turnable device, with a signal whose value is determined by the comparison device, can be carried out according to the circuit shown in FIG. 2

In this case, the test signal X | at the input of the instrument being checked

4 are obtained as a result of summation of signals from controlled sources

5 and 6. The signal from source 6 determines the initial value of the test signal X, which may be zero or coincide with the beginning (end) of the measurement range of device 4. Equal increments A are generated by signal source 5, block 7, comparison, and key element 8. Block 7 Comparison controls the change in the signal at the output of the source 5 and compares its value with a predetermined increment value

The real accuracy of the implementation of the increment A to the given value X, Q, is not significant. From the above mentioned settings, the average value of X and the predictions and operations, it is only necessary to ensure the condition of equality of each subsequent increment A to all previous ones, which for a relatively short calibration period can be achieved due to the natural stability of the parameters and characteristics of the source 5 of the block 7, the signal source 5 and Comparison unit 7 can be replaced with a constant signal source X ,,. , which for the period of calibration provides some unknown, but stable signal value.

Managed key element 8 implements the connection of increment A to the adder according to a specific algorithm. The sequence of operations for this example implementation (Fig. 2) is as follows.

The measuring device 4 measures the initial value of the test signal, the result obtained is recorded in the control block 9, which opens the key element 8, and thereby provides an increment A connection to the adder. The initial value of the signal X from the source 6 is summed up with the increment A and simultaneously affects the input of the test instrument, the output of which receives the measurement result.

This result is remembered in control block 9, which closes key element 8 (turns off increments of increment A. The last equality is quite strictly ensured, since it does not depend on the metrological characteristics of checked device 4 and is determined by the stability of its conversion coefficient at the same point range for a short, short period of time between the previously mentioned operations.

Further, the sequence of operations is similar.

The sum of the signal from source 6 can be performed with a negative

5 value of the increment A, if the initial value of the X signal corresponds to the immediate value of the range of indications of the instrument being checked. Deist20

significant X value in this case

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It may be unknown if one of the measurement results corresponds to the zero value of the signal from source 6.

It is possible to further simplify the proposed method of verification in terms of the formation of equilibrium values of the test signal by successively summing the signal connected to the input of the device under test with equal: increment values. For this, the increment value is determined directly by a measuring instrument.

As an example, a verification scheme, shown in FIG. 3, is shown. To calibrate the meter. 10 (FIG. 3) use two adjustable sources of 1 G and 12 signals and two control blocks 13 and 14, key elements 15 and 16. Formation of constant increments A is performed by signal source 12, key element 16, measuring device 10 and control unit 14.

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A from the adder) and provides a comman - regulating output values for a change in the signal from the source of X from the source 12 of the signal. For 6. The measured values of this signal in control block 9 are compared with the previous X measurement result.

the total value of the signal X and the increment A. At the moment of equality of these values (according to the indications of the checked instrument), the control unit 9 gives commands to stop the change in the magnitude of the signal from source 6 and to open the key element 8. The increment A and the signal from the source are summed up 6 equal to sum50

55

This in the control unit 14 is entered the value of the constant increment of the measurement result. corresponding to a certain increment of signal A. Control unit 14

when the element 15 and the open 16 are closed, it controls the change in the signal at the output of the source 12 until the measurement result coincides with the set value Xgg. Then, at the command of the control unit 14, the signal change from the test station 12902186 is stopped.

, the initial value of X and the previous increment A. The last equality is provided fairly strictly, since it does not depend on the metrological characteristics of the device being turned 4 and is determined by the stability of its conversion coefficient at the same point of the range for the co -, short period of time between previously indicated operations.

Further, the sequence of operations is similar.

The sum of the signal from source 6 can be performed with a negative

the increment value A, if the initial value of the X signal corresponds to the actual value of the range of indications of the instrument being checked. Act0

significant X value in this case

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It may be unknown if one of the measurement results corresponds to the zero value of the signal from source 6.

It is also possible to further simplify the proposed method of verification in terms of the formation of equidistant values of the test signal by successively summing the signal connected to the input of the device being checked with equal: increment values. For this, the increment value is determined directly by a measuring instrument.

As an example, a 5 May verification scheme is shown, shown in FIG. To calibrate the meter. 10 (FIG. 3) use two adjustable sources of 1 G and 12 signals and two control blocks 13 and 14, key elements 15 and 16. Formation of constant increments A is performed by signal source 12, key element 16, measuring device 10 and control unit 14.

0

- regulating the values of the output signal X from the source 12 of the signal. For

50

55

This in the control unit 14 is entered the value of the constant increment of the measurement result. corresponding to a certain increment of signal A. Control unit 14

when the element 15 and the open 16 are closed, it controls the change in the signal at the output of the source 12 until the measurement result coincides with the set value Xgg. Then, at the command of the control unit 14, the signal change from the operation is stopped.

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point 12 and the key element 15 is opened. At the input of the measuring device 10, a total value of the initial value X, a signal from source 11 and an increment A from source 12 are formed.

The result of measuring this total value enters the control unit 13, which stores it and issues commands to close the key element 16 and change the signal from the source 11. This signal is continuously fed to the input of the measuring device 10 and its measurement results are compared in the control unit 13 measurement result. At the moment these measurement results coincide, the control unit 13 issues commands to stop the signal from the source 11, transfer the control to the unit 14 to form increment A and open the key element 16.

The control unit 14, regulating the signal change from the source 12 according to the readings of the device 10, generates an increment signal A. Then issues a command to the source 12, prohibiting the signal change, and opening the key element 15. Thus, at the input of the measuring device 10 a new test signal value is generated, which differs from the one previously stored in block 3 by a constant value. The result of the measurement is stored and similar operations are performed to change the signal from source 11 until the result of its measurement coincides with the new value in the memory of block 13. In this way, the sequential summation of signals from source 11 with increment A from signal source 12 is formed equally The values of the signals at the input of the tested instrument 10 in the whole range of its indications. The connection operation of the unambiguous measure and the measurement of its value are carried out before or after performing operations with test signals. The measurement results are processed according to the previously specified algorithm.

The formation of equal values of the test signal at the input of the instrument being tested is also possible in another way. To do this, an adjustable signal source is connected to the input of the instrument to be tested and, starting with not

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which is known, for example -. measures of zero uniformly increase (decrease) the magnitude of the signal. At the output of the device being checked, the measurement results are recorded at the time of the start of the signal measurement and at equal intervals of time.

In this case, a means of measuring time and realizing time is necessary. matching the time reference and the beginning of the signal change, which is practical for any information-measuring system.

A method of verification based on the formation of equal values of the test signal at the input of the device being tested and the measurement of an unambiguous measure is also realized when a known initial value of the signal (for example, an electric one) is connected through known signal dividing devices; model) level of accuracy of dividers. This is due to the fact that it is not necessary to determine the actual value of the increment of the signal generated by the divider, but only the constancy of these increments for each subsequent value of the input signal.

Similarly, equidistant values of the test signal are formed by multiplying the initial value of the signal by certain coefficients in the scale amplifier. The processing operations of the measurement results of the test signals and the signal generated by the unambiguous measure do not differ from the previously considered variants.

The positive effect is proposed; This method of verification consists in reducing the volume and simplifying the process of verification. The scope of verification is determined in this case by the number of sections of the measurement range of the instrument being tested, for which it reproduces the reference value of the signal. In the proposed method, it is the minimum possible. In analogs and prototypes, this number fully determines the accuracy of the results of verification and in practice depends on the specific types of measuring instruments and their measurement ranges. The number of verified sections and its connection with reliability are characteristic of other methods of verification, with the exception of limited

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groups of measuring instruments for which methods of autonomous verification are implemented.

Claims (5)

Invention Formula 1, Method of calibration of measuring devices, based on connecting a unique measure to a calibrated instrument, measuring its value and fixing the obtained result, so that, in order to reduce the volume and simplify calibration, start with some known, for example, zero X value, at the input of the device being tested, form the uniformity of the non-sample test signal, record the results of their measurements, compare these results with the XQ result, measure unambiguously measure 0, choose the closest to it results H. and measuring the test signal, counting their corresponding real function portion converting power metal emogo linear device, and determining an error measuring instru pa L to the system of equations LR X "Spoken-X y- .Ho X K + 1 where a, a X - KA - a, (X „-KA) h-a, + ao aLH„ + KA) + a.A + a And about 7 parameters of the linearized portion of the real transformation function; increment test signal; . 0 five 8 10 K is the serial number of the increment of the test signal. 2. Method POP1, characterized in that equal values of the test signal are generated by summing the test signal connected to the input of the device under test with a signal whose value is determined by a comparison unit, for example, a measuring instrument. 3. The method according to claim 2, excluding the fact that the magnitude of the increment of the test signal is first determined directly with a testable device, and then summed with the test signal connected to its input. 4 "Method according to claim 5, characterized in that the formation of equal values of the test signal is carried out by connecting to the input of the test instrument a uniformly increasing (decreasing) test signal and fixing the measurement results at regular intervals of time. 5. The method of clause} is also distinguished by the fact that the equal values of the test signal are carried out by dividing (multiplying) the initial value of the test signal applied to the input of the test signal using dividers or scalers of the input signal. .З