SU1709262A1 - Calibrator of periodic signals - Google Patents

Abstract

The invention is intended to form calibrated periodic signals in a calibration apparatus, the purpose of the invention is to improve the accuracy of forming the output voltage of the calibrator. The periodic signal calibrator contains a block of 1 constant memory, a calculator 2, an alphanumeric display 3, a block 4 of RAM, a DAC 5, a frequency grid former 6, gates 7, a register 8 of memory, a scale converter 9, multiplying digital-analog converters 10 and 19, reversible counters 11 and 18, formers 12 and 16, comparator 13, adder 14, source 15 of exemplary voltage and switch 17. 1 or ill. feVJO H) U Oy

Description

The invention relates to electrical measuring equipment and can be used to form calibrated in terms of the root-mean-square value of periodic oscillations with a given spectral and weight composition in a wide frequency range for certification of voltmeters, spectrum analyzers and other devices.

The known calibrator of periodic signals of infrasonic frequencies contains a permanent storage device connected to the first input of the calculator (control, interface and synchronization unit, alphanumeric display) and the first input of a random access memory, the second input of which is connected to the second output of the calculator, the third input which is connected to the frequency grid former, the fourth input is connected to the external control bus, the first input is connected to the nefj input of the control low-pass filter, and the second output is perv1m input converter output scale. The output of the random access memory is connected to the input of a digital-to-analog converter, the output of which is connected to the second input of the control low-pass filter. The second input of the output scale converter is connected via a switch to the output of a digital-to-analog converter or a low-pass control filter.

The specified calibrator generates signals with a given spectral and weight composition, however, it is characterized by such disadvantages as limiting the spectrum of output signals to the infrasound range and low accuracy of the output voltage by the mean square value determined by the accuracy of the digital-analog converter.

Closest to the present invention is a periodic signal calibrator containing a permanent memory unit connected to the first input of the calculator, the second input of which is connected to an alphanumeric display, and the first output connected to the input of the first RAM block, the output of which is connected to the input the first digital-to-analog converter; the second output of the calculator is connected to the first input of the C0% frequency controller, the second input of which is the VST input and the frequency, and the third output with the control input of the output mass the head converter, the frequency grid generator outputs through gates, the control inputs of which are connected to the fourth output of the calculator through the memory register, are connected to the first inputs of all N RAM blocks, the second inputs of which from the second to the Nth are connected to the first output of the calculator, and their outputs - with the inputs of digital-to-analog converters from the second to the N-th, the outputs of all digital-to-analog converters are connected to the inputs of an analog adder, the output of which is connected to the first input of the multiplying digital-analogue 0 g About the converter, the fifth output of the calculator is connected via a reversible counter to the second input of the multiplying digital-analog converter, the output of which is connected to the second input of the output scale converter and the first input of the comparator, the second input of which is connected to the output of the source of the 9th voltage, and the output through the driver, control input which

0 is connected to the sixth output of the calculator. connected to the summing and subtracting inputs of the reversible counter, with the calibrator output being the upstream output of the scaler.

5 The well-known calibrator allows generating and calibrating output signals with different specified spectral weights in the sound and ultrasonic frequency range by root-mean-square, however, the accuracy of the root-mean-square value of the output voltage in the calibrator depends on the time and temperature characteristics of the comparator.

The purpose of the invention is to improve the accuracy of the formation of the output voltage of the calibrator.

0 The goal is achieved by the fact that a periodic signal calibrator 8, containing a constant memory block, is connected to the first input of the calculator, the second input of which is connected to the alphanumeric display, and the first input is connected to the first inputs of the operational memory blocks, the outputs of which connected to the inputs of digital-to-analog converters, the second output of the calculator is connected to the first input of the frequency grid former, the outputs of which are connected via a wave to the second inputs of the RAM, the control inputs Chains connected to the outlets

A memory register 5, the input of which is connected to the third output of the calculator, the fourth output of which is connected to the control input of the output scaler, whose information input is connected to the output of the multiplying digital-analog converter, and the output is the output of the calibrator, the fifth output of the calculator is connected to the first input reversible counter, the sixth output - with the first input of the imager, the second input of which is connected to the output of the comparator, 3 outputs - with the second and third inputs of the reversible counter, the output to The second input is connected to the first input of a multiplying digital-to-analog converter, the second input of which is connected to the output of an adder, whose inputs are connected to the output of digital-to-analog converters, as well as a source of exemplary voltage, a switch, a calculator, a voltage source, an additional multiplying digital-analog converter, a reversible counter are introduced and a driver, the first input of which, connected to the control input of the switch, is connected to the seventh output of the calculator, the second input of the auxiliary the former is connected to the output of a comparator, the first input of which is connected via a switch to a source of reference voltage or to the output of a multiplying digital-analog converter, the outputs of an additional driver are connected to the inputs of an additional reversible counter, the output of which is connected to the first input of an additional multiplying digital-analog converter, the second input of which is connected with the first input of the calculator, connected to the output of the voltage source, the output of the additional multiplying A digital-analog converter is connected to the second input of the subtractor, output 1 is expensively connected to the second input of the comparator.

In a known calibrator, the accuracy of maintaining the rms value of the output signal is determined by the accuracy of the comparator, the stability of the characteristics of the multiplying digital-to-analog converter, the source of the reference voltage and the output scale converter. The largest error is introduced by the RMS comparator, containing a non-linear square element.

Improving the accuracy of the output signal of the calibrator is based on the periodic correction of the operating point of the comparator, which is carried out by the blocks entered into the calibrator. Such a correction reduces the stability requirements in time and the temperature dependence of the characteristics of the multiplying D / A converter and the comparator, which improves the accuracy of the calibrator as a whole.

The comparator is corrected during the synthesis of the input signal and not 5 requires a significant investment of time. If the output signal does not change in shape for a long time, correction can be made by the operation of the internal timer of the calculator.

0The drawing shows a functional diagram of the proposed periodic signal calibrator.

The periodic signal calibrator contains a block of 1 permanent memory connected to the first input of the calculator 2, the second input of which is connected to the alphanumeric display 3, and the first output connected to the first inputs of the 4 memory blocks, the outputs of which are connected to the inputs of digital-analogue converters 5, the second output of calculator 2 is connected to the first input of a 6 frequency grid, the outputs of which are connected via gates to the second inputs of RAM 4, the control inputs of gates 7 are connected to the outputs p memory 8, the input of which is connected to the third output of calculator 2, the fourth output of which is connected to the control input of the output scaler 9, whose information input is connected to the output of the multiplying digital-analogue converter 10, and the output of the calibrator, item 5 the output of the calculator 2 is connected to the first input of the reversible counter 11, the sixth output is connected to the first input of the driver 12, the second input is connected to the output of the comparator 13, and the outputs to the second and third inputs of the reversible counter 11, the output of which is connected to the first input of the multiplying digital-analog converter 10, the second input of which is connected to the output of the adder 14, the inputs 5 of which are connected to the outputs of the digital-analog converters 5, the source 15 of the reference voltage, the additional driver 16, the first input of which is connected to the control input of the switch 17 is connected to the seventh output of the transmitter 2, the second input of the additional driver 16 is connected to the output of the comparator 13, the first input of which through the switch 17 is connected to and The sample voltage of the reference voltage 15 or to the output of the multiplying digital-analog converter 10, the outputs of the additional driver 16 are connected to the inputs of the additional reversible counter 18, the output of which is connected to the first input of the additional multiplying digital-analog converter 19, the second input of which is connected to the first input of the subtractor 20 is connected with an output of a voltage source 21, the output of an additional multiplying digital-to-analog converter 19 is connected to a second input of a subtractor 20, the output of which one with the second input of the comparator 13,

The practical implementation of the calibrator is provided by the possibility of using standard assemblies of measuring computer technology, as well as the known technical solutions of individual units.

Permanent memory 1 can be performed on K573RF5 chips.

As a calculator 2, it is possible to use a standard single-board microcomputer of the type Electronics NMS 11100.1 in which the Q-bus and IRPR interfaces are involved. Alphanumeric display 3 types 15-0003.

Operational storage devices 4 can be built on chips like КР132РУ6.

Digital to analogue converters 5 can be implemented on the chip K1118PA1. K594PA1, K572PA2.

Shaper b of the frequency grid is a frequency divider on K555IE6, K155YE2 chips with a switch on K155KP1 chips.

Valves 7 can be made on K555LAZ microcircuits.

Memory register 8 can be built on K155TM2 microcircuits.

Output scaler 9 can be implemented on a K572PA2A chip or on an R-2R resistive grid of type 313HP20B and RES55A, as well as on operational amplifiers K574UD1A and resistors C2-29. The multiplying digital-to-analog converter 10 (19) can be built on the K572PA2A chips. K572PA1A or on a resistive grid R-2R type 313НР20В and relay RES55A; Reversible counters 11 and 18 can be performed on K155IE7 microcircuits, driver 12 (16) -K155LAZ, K155L4, K155IE7 microcircuits.

The comparator 13 of the mean voltage values can be implemented similarly to that used in the John Fluke (USA) type 9500A voltmeter. To construct a comparator, thermal transducers of the TMK, PNTE-6 TVB-2 types and amplifiers of the K574UD1A, K140UD17, K140UD14 type can be used. Adder

14 can be performed on resistors C229 and operational amplifier K475UD1A.

An exemplary voltage source 15 can be built on the basis of a constant voltage source with a KS191F stabilizer and a modulator, for example, on KR590KN7, K555LAZ, K555TM2 microcircuits.

Switch 17 can be implemented on a KR590KN4 chip or on a RES55A relay.

The subtractor 20 can be implemented on resistors C2-29 and chips K140UD14, K140UD17.

5 The voltage source 21 may be either a constant voltage source or a source of alternating voltage, for example, a square wave type. A constant voltage source can be built on a stabilizer base based on KS191F, and a square wave type voltage can be obtained by modulating a constant voltage.

The modulator, as-and for the source 15, can be performed on chips KR590KN7, K555LAZ, K555TM2,

Calibrator periodic signals works as follows.

In block 1, the permanent memory is recorded in 0 codes of the ordinate of the model sinusoidal signal and the program of operation of the calibrator.

The synthesis of the ordinates of the output signal is carried out using the Fourier number of factors specified by the operator according to the formula

F (x) A + Sislnx + Sisln2x-i-S3Sln3x + ... + Cicosx + + C2cos2x + C3cos3x + ..., where A is a constant component; 0 Si is the amplitude of the 1st harmonic component of the 1st harmonic;

Ci is the amplitude of the cosine component of the 1st harmonic.

In the proposed calibrator, the synthesis of ordinates of a complex signal is carried out not by one but by several channels. In this case, the sum of the Fourier series for each of the channels can be written as follows:, 0 for the first channel.

Fi (x) A + Sistnx + Cicosx + S2Sln2x + C2Cos2x + ... + + Snsln nx + CnCOS nx,

therefore, the first channel generates a signal at the output, in which the components can be constant and the harmonics from the first to the nth;

for the second channel F2 (x) Sn-nsln (n + 1) x + Cn + lcos (n + 1) x + (n + 2) x + Cn + 2COs (n + 2) ... + + SmSln mx + CmCOS mx.

The second and subsequent channels form at the output a signal in which there can be harmonics by a number one more than the last given in the previous channel, up to the tth or thth one in the next channel.

The constant component, the harmonic number and the Fourier row coefficients with a sign are entered into the calculator 2 from the alphanumeric display 3. This subroutine starts with the command Entering data A, S, C. The input data and the operation Enter are displayed in alphabetical digital display 3.

After completion of the data input from the alphanumeric display 3, the subprogram “Synthesis of a complex Signal” is entered. Operation Synthesis is indicated on display 3.

The entered Fourier transform coefficients, depending on the harmonic number, are formed in the calculator 2 into groups according to the channels in which they must form fragments of a complex signal.

Then, in the calculator 2, the ordinates of the output signal fragments for the corresponding channels are synthesized sequentially, beginning with the lowest frequency harmonics, one after the other.

In this synthesis, unit sinus and cosine ordinates are derived from block 1 of constant memory, which multiply the harmonics of the complex output signal by multiplying by the corresponding input coefficient S or C.

Next, the addition takes place, taking into account the sign of the ordinates of the harmonics in each channel, so that a fragment of a complex signal is obtained containing the harmonic components specified in it.

After the synthesis, the amplitude (extreme value) of the total signal of all channels and fragments of the signal in the channels is jointly normalized (without operator commands) so that the experimental value of the total output signal does not exceed the dynamic range of the output signal of the analog adder 14, and the signals in channels in their extreme values did not exceed the dynamic range of the used digital-to-analog converters 5.

After normalizing the total signal and its fragments in amplitude, the ordinates of these signals are rounded off according to the size of the used digital-to-analog converters 5.

In accordance with this rounding, the amplitudes of the input harmonics of the composite signal are rounded off.

As a result of the operation of synthesizing a complex signal, the calculator 2 calculates the approximate rms value of the output signal Cd-s over the period based on the rounded amplitudes of the harmonics of the output signal, taking into account all its fragments using the formula

UcK.3 V Uo + Ul2 + U2 + U3 + ... + UK

ten

where Uo is a constant component:

UI-UK - complex amplitude harmonics

output signal.

Then, using the value UCK.S, the calculator 2 calculates the approximate code value

UH for multiplying digital-analog

converter 10 according to the formula

G

. (2-1) iv.kh.n.

gun:

UcK.3

where OVIHN is the output rms voltage of the converter 10, which, for any form of the output signal, should be close to the constant value specified by the source 15 of the reference voltage;

y is the number of bits of the binary code of the converter 10.

The multiplying digital-to-analog converter 10 is a precision low-speed ratio converter, the output voltage of which must be set and saved

given constant rms value for any output waveform. Digital to analogue converters 5 must have a high speed, so their size

is limited.

NH code. calculated by the size of the used converters 5, is approximate and then refined to

multiplier of the digital-to-analog converter 10.

Entering the approximate value of the NH code into the reversible counter 11 shortens the time for setting the updated code value to

block 10 and does not create conditions overload of the comparator 13.

Adjustment code multiplying the digital-to-analog converter 10, coming from the reversing counter 11,

carried out using a comparator 13 and a former 12 controlled from the sixth output of the transmitter 2.

The adjustment continues for a predetermined correction time, which is determined by the counter in the driver 12.

The adjustment of the input code of the unit 10 is necessary for accurate operation of the calibrator. The correction time of the reversible counter 11 takes into account the end of the transient processes in the multiplying digital-to-analog converter 10, therefore, after the end of this time the value of the NH code can be used to operate the calibrator with a given accuracy.

The correction code of the reversible counter 11 is carried out in the first position of the switch 17. In the second position, the switch 17 turns on the seventh output of the calculator 2 for the entire duration of the calibrator operation, except for the code correction time in the reversible counter 11.

In the second position of the switch 17, the source 15 of the reference voltage is connected to the first input of the comparator 13, and the output of the subtractor 20 to the second input of the comparator 13.

From the voltage source 21, the first input of the subtractor 20 receives a voltage exceeding the root-mean-square value of the voltage of the source 15 of the reference voltage and the possible voltage of the drift of the comparator 13. The same voltage from the source 21 is fed to the input of the additional (multiplying) digital-analog converter 19 the output of which removes the signal to the second input of the subtractor 20. The converter 19 is controlled by a code from the additional reversible counter 18, controlled by the additional driver 16. From the output computer The aarator 13 receives the feedback signal to the second input of the additional generator 16. The drift self-tuning system of the characteristics of the comparator 13 is implemented using the reference source 15 as the reference source.

In the case of auto-tuning of the reversible counter code 11, the output voltage of the subtractor 20 is used as a reference source, in which, after correction, the drift of the characteristics of the comparator 13 is taken into account. This improves the accuracy of the calibrator.

After calculating the rounded values of the ordinates of the output signal fragments, the calculator 2 outputs the information about the ordinates of the output signal fragments to the operational storage devices 4, outputs the code of the operational storage devices 4 to the memory register 8, the normalization code of the signal by the mean square value NH in the reversible counter 11, the Start-up signal in blocks 4, which is used to output information from blocks 4 to blocks 5, and then the revision counter code correction enable signal 11 start |) 0рмиро The transmitter 12, and on the frequency grid former 6, the maximum output frequency code is then set.

From the outputs of digital-to-analog converters 5, the analog signals of the output signal fragments are output to the output of the adder 14, at which the output signal is formed. From the adder 14, the signal is fed to a multiplying digital-to-analog converter 10.

The switch 17 is switched to the first position by a command from the calculator 2, and depending on the reaction

The comparator 13 shaper 12 generates a counting pulse to the summing or subtracting input of the reversible counter 12.

It closes the feedback loop,

which allows to obtain at the output of converter 10 a predetermined analog root-mean-square value of voltage, which is fed to output scale converter 9.

After passing a predetermined number of correction cycles of the reversible counter code 11, the correction termination signal is input to the calculator 2 from the generator 12 and then the corrected code E) FROM the reversible counter 11 is entered into the calculator 2.

In the calculator 2, the amplitude coefficient Ka of the output signal is calculated by the formula

1 / ivyh.extr. TO

and

sk.z

where i.ext.expression is the voltage of the extreme value of the total complex output signal obtained after normalizing it in amplitude;

UcK.3 - rms value

output signal value corresponding to the corrected code value of the reversible Counter 11.

The completion of the Synthesis operation is an indication of the magnitude of the amplitude coefficient K on the alphanumeric display 3.

The operator, having received on the alphanumeric display 3 information about the completion of the synthesis of a complex signal, enters into the calculator 2 from the display 3 a command to start the operation Enter the output signal parameters {the start address of the input subroutine for the output signal of the complex signal - the root-mean-square value of the output signal and frequency) .

The input parameters are displayed on an alphanumeric display 3.

The calculator 2 stores this information and brings it to a form convenient for sending commands to the output scale converter 9 for writing to the frequency grid generator 6.

The frequency grid generator 6 generates frequencies that are proportional to the frequency of the calibrator output complex signal, with frequencies coming to the valves 7c that differ from each other by so many times. what is the difference in low harmonics provided for by the design of each channel?

Gates 7 are controlled through memory register 8, which serves to shut them off and not to create additional interference from switching the channel, the harmonics of which are not specified and do not participate in the formation of the output signal.

In order to obtain a signal with a parameter entered into the calibrator, the command Change output waveform is entered. Under this command, a subroutine starts, which displays the output parameters of the output signals, Pout, and also displays the codes on the grid generator 6 and on the output scale converter 9, which set the specified output signal parameters. The Changeform command blocks the calibrator output from erroneous voltages that can overload the input of the instrument under test.

To change the shape of the output signal, it is necessary to change the information about the values of A, SK, Cc, previously received by the Data Input command, carry out the procedure for synthesizing a complex signal, normalize it in amplitude and root-mean-square value, calculate the amplitude coefficient of the resulting signal, enter new values of the output voltage signal frequency and output from calculator 2 all received data about the signal to external devices.

The proposed device makes it possible to generate and calibrate with high accuracy on the root-mean-square value of the voltage output signals of different levels with different predetermined spectral and weight composition in the field of sound and ultrasonic frequencies.

The accuracy of the formation, the rms value of the output signal in the proposed device is improved by eliminating the drift characteristics

comparator rms voltage, which occurs over time and from the effects of ambient temperature. five

The form of the invention The periodic signal calibrator comprising a block of permanent memory connected to the first input of the calculator.

0 whose second input is connected to an alphanumeric display, and the first output is connected to the first inputs of N RAM blocks, the outputs of which are connected to the inputs of N digital-analog converters, the second output of the calculator is connected to the first input of the frequency grid former. The N outputs of which are connected to the second inputs of the N memory blocks through the corresponding N valves, the control inputs of the N valves are connected to the corresponding outputs of the memory register, the input of which is connected to the third output of the calculator, the fourth output of which is connected to the control

5 is an input to a scale converter, whose information input is connected to the output of a multiplying digital-to-analog converter, and the output is a calibrator output, the fifth output of the calculator

0 is connected to the first input of the reversible counter, the sixth output is connected to the first input of the imager, the second input of which is connected to the output of the comparator, and the outputs to the second and third inputs of the reversible

5 counter, the output of which is connected to the first input of the multiplying digital-analog converter, the second input of which is connected to the output of the adder, whose inputs are connected to the outputs of the N digital-analog converters, the source of exemplary voltage, in order to improve the accuracy of formation of the output voltage, A switch, a subtractor, a voltage source, as well as an additional multiplying D / A converter, a reversible counter and a driver, the first second input coupled to a control input

0 switch and the seventh output of the calculator, the second input of the additional driver is connected to the output of the comparator, the first input of which is connected to the output of the switch, the first input of which is connected to the output of the multiplying digital-analog converter, and the output of the additional driver is connected to the inputs of the additional reversive counter, vy15170926216

the course of which is connected to the first input to the tatel and the output of the voltage source, and

complementary digital-output-output - with the second input of the subtractor, output

A second converter, the second input of which is connected to the second input of the compact one which is connected to the first input of the calculator.

Claims (1)

Claim A periodic signal calibrator comprising a read-only memory block connected to the first input of the calculator, the second input of which is connected to an alphanumeric display, and the first output is connected to the first inputs of N RAM blocks, the outputs of which are connected to the inputs of N digital-to-analog converters, the second output of the calculator is connected with the first input of the frequency grid driver, the N outputs of which are connected through the corresponding N gates to the second inputs of N RAM blocks, the control inputs of the N gates are connected with the corresponding outputs of the memory register, the input of which is connected to the third output of the calculator, the fourth output of which is connected to the control input of the scale converter, the information input of which is connected to the output of the multiplying digital-analog converter, and the output is the output of the calibrator, the fifth output of the calculator is connected to the first input of the reversible counter, the sixth output - with the first input of the shaper, the second input of which is connected to the output of the comparator, and the outputs - with the second and third inputs of the reverse with a meter, the output of which is connected to the first input of the multiplying digital-to-analog converter, the second input of which is connected to the output of the adder, the inputs of which are connected to the outputs of N digital-to-analog converters, a reference voltage source, characterized in that, in order to increase the accuracy of generating the output voltage, the calibrator additionally introduced a switch, a subtractor, a voltage source, as well as an additional multiplying digital-to-analog converter, a reversible counter and a shaper, the first input otorrhea connected to the control input of the switch and the seventh output of the calculator. the second input of the additional driver is connected to the output of the comparator, the first input of which is connected to the output of the switch, the first input of which is connected to the output of the multiplying digital-to-analog converter, and the second to the output of the reference voltage source, the outputs of the additional driver are connected to the inputs of the additional reverse counter, output15 which is connected to the first input of an additional multiplying digital-to-analog converter, the second input of which is connected to the first input of the subtractor and the output voltage source house, and an output - to a second input of a subtractor whose output is connected to the second input of the comparator.