RU2471197C2 - Bridge measuring device for measuring parameters of two-terminal devices - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: bridge measuring device for measuring parameters of two-terminal devices has series-connected feed composite electrical signal generator, a bridge circuit and a null indicator. The bridge circuit has a two-terminal device with balancing elements, an additional third circuit which is part of the bridge circuit and is connected in parallel to a circuit consisting of a first resistor, an inductance coil and the second resistor of that two-terminal device, wherein functional earthed elements of the two-terminal device with balancing elements are adjustable, and elements of the two-terminal device of the measuring object act as the three unknown parameters - first and second resistors and first capacitance.

EFFECT: reduced measurement error owing to exclusion of the error component from spurious capacitances relative the earth terminal of the adjustable balancing elements, reduced instability of these spurious capacitances.

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Description

The invention relates to instrumentation, automation and pro-electronics. In particular, it allows you to determine the parameters of three-element bipolar or sensor parameters with a three-element equivalent circuit.

A well-known bridge meter of the parameters of five-element passive two-terminal devices (USSR AS No. 1147986, G01R 17/10, BI 1985, No. 12), containing a pulse generator with voltage change in series during their duration according to the laws of power functions, a bridge electrical circuit and a zero indicator.

Its disadvantage is the increase in measurement error due to the component error from parasitic capacitances that form ungrounded adjustable balancing elements relative to the ground. In the indicated meter, in principle, it is impossible to ground all the adjustable balancing elements, therefore, the aforementioned stray capacitances and the component of the measurement error caused by them are necessary. An additional component of the error also arises from the instability of stray capacitances. In addition, to reduce the negative impact of external electromagnetic fields and pickups, balancing elements are often shielded. Moreover, in the event that these elements are not grounded, there is uncertainty about the top of the electric bridge, with which it would be advisable to connect the screens. If the above elements are grounded, then it is obvious that the screens should be connected to the ground. In the case of regulation of ungrounded balancing elements through the use of electronic keys and control electric signals, additional difficulties arise for them - the need to use decoupling elements, for example transformers or optocoupler pairs. When grounding all balancing elements, such difficulties are eliminated.

Known bridge meter parameters of multi-element bipolar (USSR AS No. 1247762, G01R 17/10, BI 1986, No. 28), containing sequentially connected pulse generator with voltage change over their duration according to the law of power functions, a bridge electrical circuit and a zero indicator.

Its disadvantage is the increase in measurement error due to the component error from parasitic capacitances that form ungrounded adjustable balancing elements relative to the ground.

The closest in technical essence and the achieved result to the claimed device is a bridge meter selected for use as a prototype of a three-element passive two-terminal device (AC of the USSR No. 798607, G01R 17/10, BI 1981, No. 3), containing a series-connected pulse generator of complex shape, an electric bridge circuit and zero indicator.

Its disadvantage is the increase in measurement error due to its component from stray capacitances formed by ungrounded adjustable balancing elements relative to the ground.

The problem to which the invention is directed is to reduce the measurement error by eliminating the component error from stray capacitances relative to the ground of adjustable balancing elements and the instability of these stray capacities. These parasitic capacitances are absent because only grounded balancing elements are used in the meter.

This is achieved by the fact that in a bridge meter of two-terminal parameters, it contains a supply pulse generator, which consists of pulse shapers with voltage changes over their duration according to the law k ₀ t ⁰ , k ₁ t ¹ and k ₂ t ² (where k ₀ , k ₁ and k ₂ are constant coefficients, t is time), of a switch, the inputs of which are connected to the outputs of the formers, and the output is connected to a power amplifier, the output of the latter forms the first output of the pulse generator relative to the ground, the synchronization unit, the outputs of which are connected to the synchronization inputs shapers, and one of its outputs forms the second output of the pulse generator relative to the ground (synchronization output); the first output of the pulse generator is connected to the input of the electric bridge, the first of two branches of which is formed by two terminals for connecting a two-terminal device of the measurement object, which consists, in particular, of a first resistor, in parallel with which a capacitor and a second resistor are connected in series, a single resistor is connected in series with two terminals the first of the two shoulders of the relationship of the bridge circuit, the second branch is formed in series by a single resistor of the second shoulder of the relationship and bipolar com with balancing elements, which is formed in series by the first resistor and the inductor, the second resistor is connected in parallel with the last, the first output of the bridge circuit input forms the common output of one of the existing terminals and the resistor of the second arm of the ratio, the second output of its input is grounded and formed by the common output of the resistor of the first the shoulder of the relationship and the two-terminal with balancing elements, the first output of the bridge circuit output is formed by the common output of the other of the existing terminals and the resistor of the first ratio, and the second output terminal is formed by the general output of the second shoulder resistor and two-terminal resistor with balancing elements, a null indicator, one input of which (synchronization input) is connected to the second output of the pulse generator, two outputs of the bridge circuit output are connected to another input (differential input ) a null indicator, its common bus and the common bus of the pulse generator are grounded, an additional (third) resistor connected in parallel to the existing circuit from p is inserted into the two-terminal with balancing elements the first- resistor, inductor and second resistor of the two-terminal network.

The invention is illustrated in the drawing. The bipolar bridge parameter meter contains a supply generator 1, which consists of shapers 3, 4 and 5 of sequences of rectangular, linearly varying and quadratic pulses and has two outputs formed by three terminals, one of which is grounded. The generator also contains a switch 7, the inputs of which are connected to the outputs of the formers, and the output is connected to a power amplifier 6, the output of the latter is the first output of the pulse generator relative to the ground, and a synchronization unit 2, one output of which is connected to the inputs of the synchronization of the formers, and the other output is the second the output of the pulse generator relative to the ground (synchronization output).

The first of the two branches of the electric bridge has two terminals for connecting a two-terminal device of the measurement object, consisting of a first resistor 8 (R ₈ ), in parallel with which a capacitor 9 (C ₉ ) and a second resistor 10 (R ₁₀ ) are connected in series, and a series one with two terminals a single resistor 11 (R ₁₁ ) of the first of the two arms of the bridge circuit relationship. In the second branch of the bridge circuit, a single resistor 12 (R ₁₂ ) of the second relationship arm and a two-terminal device with balancing elements, which is formed by series-connected the first resistor 13 (R ₁₃ ) and the inductor 15 (L ₁₅ ), are connected in series with the second resistor 16 ( R ₁₆ ), in parallel with the circuit of the first resistor, inductor and second resistor, a third resistor 14 is also included (R ₁₄ ).

The common terminal of one of the available terminals and the single resistor 12 (R ₁₂ ) of the second ratio arm forms the first terminal output of the generator diagonal of the bridge circuit, the second terminal of its input is grounded and is formed by the common terminal of resistor 11 (R ₁₁ ) of the first ratio arm and two-terminal with balancing elements 14 (R ₁₄ ), 15 (L ₁₅ ) and 16 (R ₁₆ ). The common terminal of the other terminal and resistor 11 (R ₁₁ ) of the first ratio arm forms the first output of the measuring diagonal of the bridge circuit; in the second branch of the bridge circuit, the common terminal of the resistor 12 (R ₁₂ ) of the second ratio arm and the two-terminal with balancing elements forms the second terminal of the measuring diagonal , both outputs of the measuring diagonal form, relative to the ground, the differential output of the four-arm bridge circuit, which is connected to the differential input of the null indicator 17, the common bus of which is grounded, and the second input one zero indicator - the synchronization input - is connected to the synchronization output of the generator 1.

A bridge meter for the parameters of bipolar operates as follows. In the initial state, the voltages at the input and output of the four-arm bridge circuit are zero. We apply a rectangular pulse train to the bridge from generator 1. Under the action of the next pulse in the steady state, unchanging voltages are established in the branches of the bridge circuit. The nonequilibrium voltage here depends only on the resistance values with the exception of 16 (R ₁₆ ). The first condition for the equilibrium of the bridge is

By a single adjustment of the resistance value of the adjustable resistor 14 (R ₁₄ ), the flat peak of the pulse nonequilibrium signal is reduced to zero, thereby fulfilling the first equilibrium condition of the bridge (1). The equilibrium of the bridge here and hereinafter is indicated by the zero indicator 17, while the synchronization signal from the second output of the generator 1 to the second input of the zero indicator 17 ensures the stability of its readings. Next, at the bridge input, we feed from the generator 1 a sequence of pulses that vary linearly. When the next such pulse is applied, after the end of the transient process, a pulse signal of equilibrium with a flat top is established at the bridge output. The second condition for the equilibrium of the bridge is

It is performed by adjusting the value of the inductance of the coil 15 (L ₁₅ ). By adjusting the inductance once, we bring the flat top of the pulse nonequilibrium signal to zero, i.e. we fulfill the second equilibrium condition (2), while the first condition (1) is not violated, since the parameter 15 (L ₁₅ ) regulated here is not included in it. Then, at the bridge input, we feed from the generator 1 a sequence of quadratic pulses. When the next such pulse is applied, at the end of the transient process, a pulse equilibrium signal with a flat top is established at the bridge output. The third condition for equilibrium of the bridge is

By adjusting the resistor 16 (R ₁₆ ) once, we bring the flat peak of the impulse nonequilibrium voltage to zero and fulfill the third equilibrium condition (3), while the first two equilibrium conditions (1) and (2) are not violated, since the parameter of resistor 16 (R ₁₆ ) is not included in them.

The above shows that the separate balancing of the bridge circuit should be carried out in the sequence shown - 14 (R ₁₄ ), 15 (L ₁₅ ), 16 (R ₁₆ ). According to the equations of equilibrium conditions (1), (2) and (3), the desired three parameters are counted: 8 (R ₈ ), 9 (C ₉ ), 10 (R ₁₀ ). The values of the parameters of the elements 11 (R ₁₁ ), 12 (R ₁₂ ), 13 (R ₁₃ ) are constant and known. Parameters 14 (R ₁₄ ), 15 (L ₁₅ ) and 16 (R ₁₆ ) are adjustable and also known.

Thus, this bridge meter of the parameters of three-element bipolar devices, which has the property of separate balancing when adjusting the values of the balancing parameters once, contains a bipolar of one of the arms of the ratio, in which all adjustable balancing elements are grounded, which eliminates the components of the measurement errors introduced by the parasitic capacitances of the earth balancing elements .

Claims (1)

A bridge meter of two-terminal parameters containing a supply pulse generator, which consists of pulse shapers with voltage changes over their duration according to the law k ₀ t ⁰ , k ₁ t ¹ and k ₂ t ² (where k ₀ , k ₁ and k ₂ are constants coefficients, t is time), of the switch, the inputs of which are connected to the outputs of the formers, and the output is connected to a power amplifier, the output of the latter forms the first output of the pulse generator relative to the ground, a synchronization unit, the outputs of which are connected to the synchronization inputs of the formers, and one from the outputs it forms the second output of the pulse generator relative to the ground (synchronization output); the first output of the pulse generator is connected to the input of the electric bridge, the first of two branches of which is formed by two terminals for connecting a two-terminal device of the measurement object, which consists, in particular, of a first resistor, in parallel with which a capacitor and a second resistor are connected in series, a single resistor is connected in series with two terminals the first of the two shoulders of the relationship of the bridge circuit, the second branch is formed in series by a single resistor of the second shoulder of the relationship and bipolar com with balancing elements, which is formed in series by the first resistor and the inductor, the second resistor is connected in parallel with the last, the first output of the bridge circuit input forms the common output of one of the existing terminals and the resistor of the second arm of the ratio, the second output of its input is grounded and formed by the common output of the resistor of the first the shoulder of the relationship and the bipolar with balancing elements, the first output of the bridge circuit output is formed by the common output of the other of the available terminals and the resistor of the first a relationship, and the second output terminal is formed by the common output of the resistor of the second ratio arm and a two-terminal with balancing elements, a null indicator, one input of which (synchronization input) is connected to the second output of the pulse generator, two outputs of the bridge circuit output are connected to another input (differential input ) a null indicator, its common bus and the common bus of the pulse generator are grounded, characterized in that an additional (third) resistor is inserted into the two-terminal with balancing elements of the bridge circuit, included first available parallel circuit of a first resistor, an inductor and second resistor of the two-terminal network.