RU2461011C1 - Bridge circuit for measuring parameters of two-terminal devices - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: bridge circuit for measuring parameters of two-terminal devices has series-connected feed pulse generator, a four-arm bridge circuit and a null indicator. The four-arm bridge circuit consists of two parallel-connected branches, the first of which has two series-connected resistor, and the second branch has series-connected single resistor, a two-element circuit consisting of a capacitor and a resistor and two terminals for connecting two-terminal circuits of the measuring object. The free lead of the resistor of the two-element circuit is earthed. The common lead of the two resistors of the first branch of the bridge form the first output lead of the bridge circuit. The common lead of the single resistor and the first terminal for connecting the measuring object form the second output lead of the bridge circuit. Both outputs of the four-arm bridge circuit are connected to the differential input of the null indicator whose clock input is connected to the output of the generator and the common bus is earthed. The second terminal for connecting the measuring object is also earthed.

EFFECT: reduced measurement error owing to elimination of the effect of spurious capacitance.

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Description

The invention relates to industrial electronics, automation, information-measuring equipment and can be used to control and determine the parameters of two-terminal devices.

Known bridge meter parameters of multi-element passive two-terminal [USSR AS No. 1157467, G01R. Bridge meter of parameters of multi-element passive two-pole / G.I. Peredelsky. - Publ. in Bull., 1985, No. 19], containing a pulse generator with series voltage change over their duration according to the law of power functions, a four-arm bridge circuit and a zero indicator.

Its disadvantage is the inability to ground both existing multi-element bipolar. All other things being equal, in practice, preference is given to bridge circuits, where all available multi-element bipolar terminals are grounded. An ungrounded multi-element bipolar forms a parasitic capacitance relative to the ground, which causes a corresponding additional component of the measurement error due to this parasitic capacitance. In addition, this parasitic capacitance is unstable and, as is known, varies significantly over time and especially with temperature. In the particular case of an ungrounded bipolar with adjustable balancing elements and using the same-type elements matrix, controlled keys and control circuits, it is necessary to use additional decoupling elements - transformers or optocoupler pairs. Changing the value of the balancing parameter is carried out here by closing and opening the keys under the action of signals from a grounded electronic control circuit. If the balancing element is grounded, then no additional decoupling elements are required. Also, in the particular case of an ungrounded two-terminal object of measurement and the use of a sensor with a communication line, interference signals are induced on the latter and cause a corresponding additional component of the measurement error, since here the communication line is also non-grounded. A sensor or sensor together with a communication line is a multi-element equivalent circuit. If the measurement object is grounded, then the interference signals and the corresponding component of the measurement error are significantly less, since the communication line is grounded. An ungrounded communication line also has a parasitic capacitance relative to the ground. It can be noted that it is basically impossible to ground both multi-element bipolar in Maxwell bridges [Nizhny S.M. AC bridges. - M.-L.: Energy, 1966. - 88 p., P. 40, fig. 15], Heya [Nizhny S.M. AC bridges. - M.-L.: Energy, 1966. - 88 p., P. 40, fig. 16], Anderson [Nizhny S.M. AC bridges. - M.-L.: Energy, 1966. - 88 p., P. 42, Fig. 18].

The closest in technical essence and the achieved result to the claimed device is selected as a prototype bridge meter parameters of the three-element passive two-terminal [USSR AS No. 798607, G01R. Bridge meter of the parameters of three-element passive two-pole / G.I. Peredelsky. - Publ. in Bull., 1981, No. 3]. The bridge meter contains a series-connected pulse generator of complex shape, a four-arm bridge electrical circuit and a zero indicator.

Its disadvantage is the inability to ground both existing multi-element bipolar.

The problem to which the invention is directed is to reduce the measurement error by eliminating the component error from the parasitic capacitance with respect to the “ground” of the non-earthed multi-element bipolar, as well as the instability of this parasitic capacitance due to the use of only earthed multi-element bipolar.

This is achieved by the fact that in a bipolar bridge parameter meter containing a supply pulse generator, consisting of a synchronization cascade, a rectangular, linearly varying and quadratic pulse shaper, a switch and a power amplifier, the output of the synchronization cascade is connected to each input of the available three pulse shapers, the outputs of which are connected to the inputs of the switch, the output of which is connected to the input of the power amplifier, the output of the power amplifier forms the first output of the power pulse generator relative to the ground, the second output of the supply pulse generator - the synchronization output forms the output of the synchronization cascade, the common bus of the supply pulse generator is grounded, the first output of the supply pulse generator is connected to the generator diagonal of the four-arm bridge circuit (with the bridge input), which consists of two branches connected in parallel , the first of them consists of two series-connected resistors, the free output of one of them is connected to the first output of the supply pulse generator, and the free output of the other the ground is connected, the common terminal of two resistors forms the first output terminal of the four-arm bridge circuit, the second branch of the four-arm bridge circuit consists of a single resistor connected in series and two terminals for connecting the two-terminal object of measurement, the two-terminal object of measurement, in particular, consists of a series resistor and a coil inductance, a second resistor is connected in parallel with the last, the common output of a single resistor and the first terminal forms the second output terminal of the four-arm output tovoy circuit, the second terminal is grounded, as in chetyrehplechey circuit has a two-element bridge circuit of series-connected capacitor and resistor; two outputs of the four-arm bridge circuit output are connected to the differential input of the null indicator, its other input, the synchronization input, is connected to the second output of the supply pulse generator, the common bus of the null indicator is grounded, the connection of the elements, the two-element circuit from the capacitor and resistor (from the first branch of the four shoulders, are changed prototype bridge circuit) is transferred to the second branch of the four-arm bridge circuit, the free output of the capacitor is connected to the common output of a single resistor and the first terminal, and the free output of the rubber the two-point chain torus grounded.

The invention is illustrated in the drawing.

The bridge measuring device of two-terminal parameters contains a supply pulse generator 1, consisting of a shaper 2 of rectangular pulses (K ₀ t ⁰ ), a shaper of 3 linearly varying pulses (K ₁ t ¹ ), a shaper of 4 quadratic pulses (K ₂ t ² ), where K ₀ , K ₁ and K ₂ are constant coefficients, t is the current time of the power amplifier 5, switch 6, and synchronization stage 7. The output of the synchronization stage 7 is connected to each input of the formers of rectangular, ramp and quadratic pulses, the outputs of which are connected to the switch 6. The output of the switch 6 is connected to the input of the power amplifier 5. The output of the power amplifier 5 forms the first output of the generator 1 of the supply pulses relative to the "ground". The second output of the generator 1 of the supply pulses - the synchronization output forms the output of the synchronization stage 7. The common bus of the generator 1 of the supply pulses is grounded. The first output of the supply pulse generator 1 is connected to the generator diagonal of the four-arm bridge circuit (with the input of the bridge), which consists of two branches connected in parallel. The first branch of the four-arm bridge circuit is formed by two resistors 8 (R8) and 9 (R9) connected in series. The free output of the resistor R8 is connected to the first output of the supply pulse generator 1. The free terminal of resistor R9 is grounded. The common output of the resistors R8 and R9 forms the first output pin (the first peak of the measuring diagonal) of the four-arm bridge circuit. The second branch of the four-arm bridge circuit consists of a single resistor 10 (R10) connected in series and a two-element electrical circuit composed of a capacitor 11 (C11) and a resistor 12 (R12) connected in series, in parallel with which two terminals for connecting the two-terminal devices of the measurement object are connected. The first terminal is connected to the common terminal of resistor R10 and capacitor C11. The second terminal is connected to the common terminal of resistors R9 and R12, forming the second vertex of the generator diagonal of the four-arm bridge circuit (the first vertex of the generator diagonal is formed by the common terminal of resistors R8 and R10), and is grounded. The bipolar of the measurement object, in particular, consists of a series-connected first resistor 13 (R13) and an inductor 14 (L14), in parallel with which a second resistor 15 (R15) is connected. The common terminal of resistor R10 and the first terminal forms the second terminal of the output (second peak of the measuring diagonal) of the four-arm bridge circuit. Two outputs of the four-arm bridge circuit output are connected to the differential input of the null indicator 16. Another input of the null indicator 16 is a synchronization input connected to the second output of the supply pulse generator 1. The common bus zero indicator 16 is connected to the second peak of the generator diagonal of the four-arm bridge circuit and is grounded. In the four-arm bridge circuit, the resistance values of the resistors R8 and R10 are known and constant. The parameters are the resistors R13 and R15 and the inductor L14, which form the two-terminal device of the measurement object. Adjustable balancing variables are the parameters of resistors R9 and R12 and capacitor C11. The values of their parameters are known.

The work of a bridge measuring device of two-terminal parameters is as follows. Initially, the voltage at the input and output of the four-arm bridge circuit is zero. First of all, the input of the four-arm bridge circuit is a sequence of rectangular pulse signals. These signals are generated by the square-wave generator 2 in the supply pulse generator 1, and through the switch 6 and the power amplifier 5 they are supplied to the output of the supply pulse generator 1. In the steady state, under the influence of another rectangular pulse, an unchanged voltage is established at the output of the four-arm bridge circuit during the time interval from the end of the transition process to the end of the pulse. The flat top of this disequilibrium voltage is reduced to zero by a single adjustment of the variable balancing element R9, which ensures the fulfillment of the first equilibrium condition of the four-arm bridge chain

Then, the pulse train of a linearly varying voltage acts on the generator diagonal of the four-arm bridge circuit. When another such impulse is applied after the end of the transient process, a pulse equilibrium signal with a flat top is established in the measuring diagonal of the four-arm bridge circuit. This vertex, taking into account the fulfilled first equilibrium condition (1), is brought to zero by a single adjustment of the variable balancing element C11. In this case, the second equilibrium condition of the four-arm bridge chain is satisfied

In this case, the fulfillment of the first equilibrium condition (1) is not violated, since this condition does not contain a variable adjustable balancing element C11.

Lastly, through a switch 6 from the generator 1 of the supply pulses, quadratic pulses are fed to the generator diagonal of the four-arm bridge circuit. In its measuring diagonal under the influence of the next such pulse, a pulse nonequilibrium signal is established. This signal after the end of the transition process has a flat top, which under the conditions (1) and (2) is reduced to zero by a single adjustment of the variable balancing element R12. As a result, the third equilibrium condition of the four-arm bridge chain is satisfied

In this case, the fulfillment of the first (1) and second (2) equilibrium conditions is not violated, since these conditions do not contain a variable adjustable balancing element R12.

The required values of the parameters of the three elements of the two-terminal device of the measurement object R13, L14 and R15 are determined from the three equilibrium conditions of the four-arm bridge circuit (1) - (3). Therefore, three unknown parameters are found from the solution of three equations.

Thus, the proposed bridge meter of the two-terminal parameters allows to reduce the measurement error by eliminating the error component from the parasitic capacitance relative to the “ground” of the non-earthed multi-element two-pole, as well as the instability of this parasitic capacitance due to the use of only grounded multi-element two-terminal devices. Also, in the proposed bridge meter of two-terminal parameters, dependent separate balancing is implemented.

Claims (1)

A bridge two-terminal parameter meter containing a power pulse generator, consisting of a synchronization cascade, rectangular, linearly varying and quadratic pulses, a switch and a power amplifier, the output of the synchronization cascade is connected to each input of the available three pulse shapers, the outputs of which are connected to the inputs of the switch, the output of which connected to the input of the power amplifier, the output of the power amplifier forms the first output of the power pulse generator relative to the "ground", the second th output of the supply pulse generator - the synchronization output forms the output of the synchronization cascade, the common bus of the supply pulse generator is earthed, the first output of the supply pulse generator is connected to the generator diagonal of the four-arm bridge circuit (with the bridge input), which consists of two branches connected in parallel, the first of which consists of two series-connected resistors, the free output of one of them is connected to the first output of the supply pulse generator, and the free output of the other resistor is grounded, common output d of two resistors forms the first output terminal of the four-arm bridge circuit, the second branch of the four-arm bridge circuit consists of a single resistor connected in series and two terminals for connecting the two-terminal object of measurement, the two-terminal object of measurement, in particular, consists of a first resistor and an inductor connected in series parallel to the last the second resistor is turned on, the common output of a single resistor and the first terminal forms the second output terminal of the four-arm bridge circuit, the second terminal grounded, also in the four-arm bridge circuit there is a two-element circuit of a series-connected capacitor and resistor; two outputs of the four-arm bridge circuit output are connected to the differential input of the null indicator, its other input, the synchronization input, is connected to the second output of the supply pulse generator, the common bus of the null indicator is grounded, characterized in that the connection of the elements, the two-element circuit from the capacitor are changed in it, and resistor (from the first branch of the four-arm bridge circuit of the prototype) is transferred to the second branch of the four-arm bridge circuit, the free terminal of the capacitor is connected to the common terminal of a single resistor and the first glue mm, and the free terminal of the two-element circuit resistor is grounded.