RU2571614C1 - Analogue voltage integrating unit - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: analogue voltage integrating unit comprises sources of input and reference voltage, two keys, an integrating amplifier, a summing up chronometer, a control unit, a differentiating RC-circuit, at that the main and auxiliary keys are made as switches.

EFFECT: increased integrating accuracy for input voltage due to the maximum elimination of breakups in integrating of an input voltage source.

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Description

The invention relates to electronic measuring equipment and analytical instrumentation. It can be used to integrate slowly varying signals, in particular, when determining the basic substance by coulometry at a controlled potential.

Known electronic voltage integrator containing sources of input and reference voltages, connected in series and counter, a key, structurally made in the form of a switch, including a source of reference voltage, an integrating amplifier, summing up the chronometer and control unit of the switch, and the same output terminals of both sources through normally closed contacts switches are connected to the input of the integrating amplifier, and the other output terminal of the reference voltage source is connected to normally open contact of the switch (USSR Author's Certificate No. 374618, class G06G 7/18. Bull. No. 15, 1973).

In this integrator, the voltage of the input source is integrated in cycles - first only the signal of the input voltage source, then after switching on the source of the reference voltage, the algebraic sum of the signals of the sources of input and reference voltages is integrated. Switching the source of the reference voltage on and off is carried out by the switch according to the commands of the control unit functioning as a two-threshold comparator. The value of the integral is estimated by the total duration of the inclusion of the source of the reference voltage, measured by a summing chronometer.

The drawback of the integrator is the integration error caused by interruptions in the voltage supply of the input source to the input of the integrating amplifier. These interruptions are caused by the final time of the switch operation (the time of the "flight" of the switching contact).

Closest to the proposed invention (prototype) is an electronic voltage integrator containing input and reference voltage sources connected in series and counterclockwise, a key structurally made in the form of a switch, including a reference voltage source, an integrating amplifier, summing up the chronometer and a control unit, the output of the same name the terminals of both sources are connected through the normally closed contacts of the switch to the input of the integrating amplifier, and the other output terminal is The reference voltage source is connected to a normally open contact of the switch. The integrator also contains a “storage” capacitor and a pulse transformer connected in series between the input voltage source and the input of the integrating amplifier, the transformer secondary winding connected to the control input of the chronometer (USSR Author's Certificate No. 538373, class G06G 7/18. Bull. No. 18 , 1992).

When this integrator is operating, the voltage of the input source (as well as that of the well-known integrator) is integrated in cycles - first, only the signal of the input voltage source, then the key (switch) turns on the source of the reference voltage and integrates the algebraic sum of the signals of the sources of input and reference voltages. Switching on and off the reference voltage source is carried out according to the commands of the control unit. The functions of the control unit in this integrator are performed by an electromagnetic relay connected to the output of the integrating amplifier. The contacts of this relay operate as a key (switch) of the reference voltage source, and the relay drive coil acts as a two-threshold comparator due to the difference in the values of the response and release currents of the relay. The value of the integral is estimated by the total duration of the inclusion of the source of the reference voltage, measured by a summing chronometer.

The disadvantage of this integrator (as well as the well-known analog integrator) is the integration error caused by interruptions in the connection of the input source voltage to the input of the integrating amplifier. The error is due to the final response time of the switch (time of "flight" of the switching contact). The presence of a “memory” capacitor in this integrator, connected between the input voltage source and the input of the integrating amplifier, somewhat reduces the value of this error, but does not completely eliminate it.

The objective of the present invention is to improve the accuracy of integrating the input voltage due to the maximum possible elimination of interruptions in the integration of the voltage of the input source.

The problem is solved by the fact that in the analog voltage integrator containing sources of input and reference voltages connected in series and counterclockwise, the main key, an integrating amplifier, summing the chronometer and control unit, an additional key and a differentiating RC circuit are introduced, while the main and additional keys made in the form of switches, one of the conclusions of the main key is connected to the pole of the reference voltage source connected to the input of the integrating amplifier, and the other is connected to the source Khodnev voltage input pole of the same name and reference voltage sources are connected via an additional key. A differentiating RC circuit is connected to the input of the integrating amplifier, and its output is connected to the control input of the summing chronometer, while the output of the integrating amplifier is connected to the input of the control unit, the outputs of which are connected to the main and auxiliary keys.

In the manufacture of the integrator, the primary and secondary keys can be made in the form of high-speed integral keys based on complementary MOS transistors. The control unit, the output signals of which control the operation of the main and auxiliary keys, can be built on the basis of a two-threshold comparator using a Schmitt trigger or on the basis of a regenerative comparator.

In FIG. 1 shows a block diagram of a proposed analog voltage integrator. To simplify the drawing, power supplies are not shown. Information and command communications are highlighted by thickened lines.

In FIG. 2 shows the timing diagrams of signals in individual nodes of the integrator:

a) input voltage;

b) the voltage at the input of the integrating amplifier;

c) the voltage at the output of the integrating amplifier;

d) pulses at the output of the differentiating RC circuit;

e) switching pulses of the summing chronometer;

f) the sequence of the main key (notes mean: “on” - the contacts are closed, “off” - the contacts are open);

g) the sequence of operation of the additional key (marks mean: “on” - the contacts are closed, “off” - the contacts are open).

The analog voltage integrator includes sources of input voltage 1 and reference voltage 2. The voltage of the source of reference voltage 2 exceeds the maximum voltage of the source of input voltage 1. For definiteness, the drawing shows the negative polarity of the source of input voltage 1 and the change (decrease) in the voltage of this source during time.

Sources 1 and 2 are connected in series and opposite, their poles of the same name are connected through an additional key 3. One output of the main key 4 is connected to a source of reference voltage 2 and the input of an integrating amplifier 5, the other terminal is connected to a source of input voltage 1.

A differentiating RC circuit 6 is connected to the input of the integrating amplifier 5, consisting of a resistor 7 and a capacitor 8. The output of the differentiating RC circuit 6 is connected to the control input of the summing chronometer 9. The output of the integrating amplifier 5 is connected to the input of the control unit 10, made in the form of a two-threshold comparator . The latter is based on the Schmitt trigger and controls the main 4 and additional 3 keys.

The work of the analog voltage integrator is as follows.

At the initial moment, the contacts of the additional key 3 are open, the contacts of the main key 4 are closed (Fig. 1). The voltage of negative polarity from the input voltage source 1 (Fig. 2-a) is supplied to the input of the integrating amplifier 5 through the contacts of the main switch 4. At the output of the integrating amplifier 5, the voltage of positive polarity increases linearly in time (Fig. 2-c). When the voltage value at the output of the integrating amplifier 5 reaches the threshold value of the comparator of the control unit 10, two control signals are issued by the commands of the latter: one opens the contacts of the main key 4 (Fig. 2-e), the other closes the contacts of the additional key 3 (Fig. 2- g) and, thus, the reference voltage source 2 is connected to the circuit. At this moment, the algebraic sum of the voltage of the input voltage source 1 and the reference voltage source 2 (Fig. 2-b) is applied to the input of the integrating amplifier 5, and from the output differentiating RC circuit 6 to the control input of the summing chronometer 9 receives the first (start) pulse (Fig. 2-g), including the summing chronometer 9 (Fig. 2-d).

Further, the output voltage of the integrating amplifier 5 begins to decrease (Fig. 2-c). At the moment when it decreases to the release threshold of the comparator of the control unit 10, the commands of the latter close the contacts of the main key 4 (Fig. 2-e) and open the contacts of the additional key 3 (Fig. 2-g). The reference voltage source 2 is turned off, and the second pulse (Fig. 2-g) stops the summing chronometer 9 (Fig. 2-d) from the output of the differentiating RC circuit 6 to the control input of the summing chronometer 9. Now, the input of the integrating amplifier 5 through the contacts of the main switch 4 receives only the voltage of the input voltage source 1 (Fig. 2-b). Further, all the mentioned processes are cyclically repeated (Fig. 2-c).

From the description of the proposed integrator, it is obvious that during each integration cycle, since the primary and secondary switches work simultaneously and there is no switching process in the input 1 and reference 2 voltage source circuits, there is no interruption in the integration of the input voltage (as is the case with the prototype )

The parameters of the proposed analog voltage integrator were checked by computer simulation as applied to the peculiarities of using integrators as part of precision installations designed to determine the basic substance by coulometry at a controlled potential. During verification, a double integral key of the type K590KN25 (manufactured by the Russian Federation) containing complementary MOS transistors was used as the primary and secondary keys. The key has two separately controlled contact pairs with a response time of 100 ns. The voltage of the input source is selected to decrease exponentially from 10 V to 10 mV. The time constant of the capacitive feedback of the integrating amplifier is chosen equal to 1 s. The voltage of the reference voltage source was 15.0 V (agreed with the switch parameters). The operation of the integrator and keys was controlled by a digital oscilloscope.

As a result of the check, it was found that the use of two switches (main and additional) to turn on the source of the reference voltage instead of the switch key as in the prototype, ensured the almost complete absence of interruptions in the supply voltage of the input source to the input of the integrating amplifier and, therefore, the error for losses of part of the input voltage during integration - according to the estimate, the value of the loss of part of the input voltage is less than 10 ^-7 %.

To compare the accuracy parameters of the proposed voltage integrator with the prototype, the prototype integrator was studied using the same method of computer simulation. The prototype had the same basic characteristics, and a high-speed electromagnetic relay with magnetically switching contacts was used as a key (switch) (RF production, type of contacts - MCU, switching time 1 ms).

Evaluation of the error of the prototype associated with the finite switching time of the electromagnetic relay showed that, despite the presence of a "storage" capacitor in the prototype, the specified error of the prototype was many times greater than the error of the proposed integrator and amounted to at least 3 · 10 ^-2 %. This error value can significantly limit the scope of use of the prototype integrator in precision coulometry with a controlled potential.

Claims (3)

1. An analog voltage integrator containing input and reference voltage sources connected in series and counterclockwise, a main key, an integrating amplifier, a summing chronometer and a control unit, characterized in that an additional key and a differentiating RC circuit are introduced into the integrator, while the main and additional the keys are made in the form of switches, one of the conclusions of the main key is connected to the pole of the reference voltage source connected to the input of the integrating amplifier, and the other is connected to the input source voltage, the same poles of the input and reference voltage sources are connected via an additional switch, the differentiating RC circuit is connected to the input of the integrating amplifier, and its output is connected to the control input of the summing chronometer, the output of the integrating amplifier is connected to the input of the control unit, the outputs of which are connected to the main and auxiliary keys. 2. The analog voltage integrator according to claim 1, characterized in that the primary and secondary switches are made in the form of integrated switches based on complementary MOS transistors. 3. The analog voltage integrator according to claim 1, characterized in that the key control unit is built on the basis of a two-threshold comparator using a Schmitt trigger.

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