SU1228021A1 - Meter of complex impedance parameters - Google Patents

Abstract

This invention relates to the field of electrical measurements. The purpose of the invention is. increased measurement accuracy. The device contains a power source 1, a measuring circuit 2 with an output 3, which includes a discretely-adjustable sample 4, a measurement object 5 and an amplifier 6. A controllable divider 7-voltage, a comparator 8, a voltage source 9, counter 10 of the division factor, counter of the P ranges, switch 12 with a changeover contact 13 and fixed contacts 14 and 15, respectively, synchronous detector 16, analog-digital converter 17, oscillator 18 of rectangular pulses, controlled frequency divider 19 and out An electronic digital block 20. The introduction of a controlled frequency divider allows the conversion scale of an analog-digital converter to be synchronized and proportional to the division ratio of the controlled voltage divider, whereby the conversion channel ratio remains constant. The division ratio counter controls the dividers. voltage and frequency in accordance with the level of the output voltage of the measuring circuit. 1 il. (Lü you 00 about with

Description

The invention relates to electrical measuring equipment and can be used in the construction of measuring impedance parameters.

The purpose of the invention is to increase the measurement accuracy by stabilizing the voltage level applied to the input of a synchronous detector and an analog-to-digital converter.

The drawing shows a structural diagram of the measuring instrument parameters of complex resistances.

The device contains a power source 1 (a sinusoidal signal generator), a measuring circuit 2 having an output 3 and including a discretely adjustable model resistance measure 4, a measuring object 5 and an amplifier 6, a voltage divider 7, a comparator 8 voltage, source 9 reference voltage, counter 10 division factor, counter P ranges, switch 12 with change-over contact 13 and fixed contacts 14 and 15 respectively, synchronous detector 16, analog-to-digital converter 17, generator 18 pr. s pulse, is controlled - emsh frequency divider 19, the digital readout unit 20.

The power source 1 ((generator, sinusoidal voltage) is connected to measuring circuit 2, which has output 3 and includes a discrete-regulated exemplary measure 4 of resistance, object of measurement 5 and amplifier 6, performing conversion of the measured value and resistance of sample measures and alternating voltage, a common channel, including a series-connected synchronous detector 16, an analog-to-digital converter 17 and a digital reading unit 20, a switch 12, the flip contact of which is connected to the input an synchronous detector, and one of the fixed contacts together with the input of the measuring circuit and the control input of the synchronous detector is connected to the output of the power source, the comparator 8 is unloaded, one input is connected to another fixed contact of the switch, and the other input is to the reference voltage source 9, The range counter 1 output is connected to the control circuits of the discrete-adjustable measure 4 resistance

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of the measuring circuit 2 and with the control circuits of the indication and the symbols of the dimension of the measured value of the readout digital unit 20, the control voltage divider 7 is connected between the output of the measurement circuit and the fixed contact of the switch controlled by the voltage comparator 19 frequency, the output of which is connected to the reference (pulse) input of the analog-digital converter, the signal input - to the pulse generator and the counter 10 of the division factor, the counting input of which is connected to the output with the voltage comparator 8, the overflow output is connected to the counting input of the counter 11 diazazons, and the code output to the circuits of the controlled voltage and frequency dividers.

Switching on a controlled voltage divider between the output of the measuring circuit and the input of the synchronous detector allows stabilizing the voltage level applied to the input of the synchronous detector and then to the input of the analog-digital converter, which reduces the measurement error due to the nonlinearity of the transfer characteristic of the common channel.

The introduction of a controlled frequency divider allows the conversion scale of the analog-digital converter to be synchronized and proportional to the division ratio of the controlled voltage divider, whereby the common channel conversion coefficient remains constant.

The division factor counter controls the voltage and frequency dividers in accordance with the output voltage level of the measuring circuit.

Measuring parameters of complex resistance works as follows.

When the power source 1 is connected to the measuring circuit 2. At its output 3, a voltage occurs that is proportional to the impedance of the measurement object 5. This voltage is applied to the controlled voltage divider 7, and from its output to the input of 1emparator 8 voltage. If the voltage taken from the output of the divider 7 is different from the voltage of the source 9

the reference voltage, at the output of the comparator 8, pulses appear, which are fed to the counting input of the counter 10 of the division factor.

The operation of the meter is synchronized so that at the initial moment the counter 10 of the division factor and the counter of the 1I ranges are in the initial zero state, the discrete-adjustable standard resistance measure 4 has a minimum value, and the division ratio of the controlled voltage divider is 1. As it arrives counting pulses to the input of the counter 10, the latter changes its state, due to which the division ratio of the divider 7 also changes. If at the maximum value of the division factor of the voltage divider 7 to the output The divider 7 exceeds the voltage of the source 9 of the reference voltage, the counter 10 overflows, and a full impulse occurs, which, acting on the counting input of the range counter 11, changes its state, resulting in a ten-fold change in the value of the discrete-adjustable an exemplary measure 4 and to the corresponding change in voltage taken from output 3 of measuring circuit 2. If, in this case as well, the voltage supplied to the comparator 8 exceeds the voltage of source 9 of the reference voltage, you The measurement range boron will be repeated until the gain is satisfied, where Ug and iUo are the voltage at the output of the divider 7 and the voltage of the source 9 of the reference voltage, respectively.

In the impedance parameter meter, any decimal range is divided into a number of subbands, the number of which is equal to the number of counter states 10 of the division factor. If, for example, the number of states of the counter 10 is taken to be 10, the transfer coefficients of the voltage divider 7 are 0.1; 0.2; 0.3; 0.4; 0.5; 0.6; 0.7; 0.8; 0.9. In this case, the output voltage of the measuring circuit corresponding to the measured impedance represented, for example, counting 1.000 (after the procedure of selecting the limit and setting the appropriate case of the division factor of divider 7 equal to 0.9) is fed to the common channel input as the voltage corresponding to counting 9.000.

If the measured impedance corresponds to a count of 3.000, the counter 10 assumes a state in which the division factor of the divider is 7

becomes 0.3, and the input of the common channel is supplied with a voltage corresponding to a count of 9.000, etc.

By virtue of the fact that the voltage and

the measurement range selection process becomes quite close to the voltage and, and the latter is chosen equal to the output voltage of the power source 1 or the voltage used

as a dividend, measuring voltages of the same level are supplied to the common channel input, which is equivalent to a decrease in the error resulting from the nonlinearity of the common channel transfer characteristic.

Due to the fact that the reference frequency, taken from the output of the generator of 18 square-wave pulses, is fed to the reference (impulse) input of the anapic-digital converter 17 through a controlled frequency divider 19, the division factor of which changes synchronously and proportionally with the division factor of the controlled divider

7 voltage the process of normalization of measuring voltages does not affect the measurement result.

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Claims (1)

Invention Formula An impedance parameter meter containing a series-connected switch, a synchronous detector, an analog-to-digital converter and a digital readout unit, a power source whose first output is connected to a common bus, and the second to the second input of the synchronous detector and to the first inputs. A switch and a measuring circuit consisting of a discrete-regulated exemplary measure of resistance, the first terminal of which is connected to the first input of the measuring circuit, 0 and the second output - to the first square to connect the measured object and the first input of the amplifier, the second input of which connected to the second terminal to connect the measured 5 of the object and the second input of the measuring circuit connected to the common length, and the output of the amplifier is connected to the output of the measuring circuit, a comparative voltage, the first input of which is connected to the second input of the switch, and the second input to the source of the reference voltage, a square pulse generator, a range counter, the output of which is connected to the control input of a discrete-adjustable exemplary measure of resistance of the measuring circuit and to the control input of the reading digital unit, so that, in order to improve the accuracy, it includes a controlled frequency divider, a division factor counter and a controlled voltage divider, enabled between the output of the measuring circuit and the second input of the switch, the output of the controlled divider is connected to the pulse input of the analog-digital converter, and the signal input is connected to the output of the square pulse generator, the count input of the division factor is connected to the voltage comparator, the output of the overflow counter the division is connected to the counting input of a range counter, and the code output is connected to the control inputs of a controlled voltage divider and a controlled frequency divider.