RU2447452C1 - 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. Three arms of the four-arm bridge circuit contain a single resistor each, the resistance values of which are constant and known. The fourth arm of that bridge circuit is formed by a potential frequency-independent two-terminal device, having two multi-element two-terminal devices - with the unknown parameters and variable controlled balancing elements.

EFFECT: reduced measurement error by excluding the error component from stray capacitance relative the earth of an unearthed multi-element two-terminal device, as well as instability of that stray capacitance, by using only earthed multi-element two-terminal devices.

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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 [A.S. USSR No. 1157467, G01R. Bridge meter parameters of multi-element passive two-pole / G.I. Peredelsky - Publ. in bull. No. 19, 1985], containing a series-connected pulse generator with voltage changes 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 not stable and, as is known, varies significantly over time and especially with temperature. In the particular case, with 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, when the measurement object is not earthed and a sensor with a communication line is used, interference signals are induced on the latter and cause a corresponding additional component of the measurement error, since here the communication line is also not 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 pp., P. 40, Fig. 15], Heya [Nizhny S.M. AC bridges. - M.-L.: Energy, 1966, 88 pp., P. 40, Fig. 16], Anderson [Nizhny S.M. AC bridges. - M.-L.: Energy, 1966, 88 s, 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 four-element passive two-pole [A.S. USSR No. 918862, G01R. Bridge meter of parameters of four-element passive two-pole / G.I. Peredelsky. Publ. in bull. No. 13, 1982]. The bridge meter contains a trapezoidal pulse generator, a four-arm bridge circuit, and a zero indicator connected in series.

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, through the use of only earthed multi-element bipolar.

This is achieved by the fact that in the bridge two-terminal parameters meter containing a supply pulse generator, consisting of a synchronization cascade, a shaper of rectangular, linearly varying, quadratic and cubic pulses, a switch and a power amplifier, the output of the synchronization cascade is connected to each input of four available pulse shapers, outputs 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 generator pulses 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 parallel-connected branches, each of which has a single resistor of two shoulders of the relationship, the common conclusion of these single resistors forms the first peak of the generator diagonal of the four-arm bridges ohm circuit, its second vertex is grounded, the free output of the first resistor of the relationship arm forms the first output terminal of the four-arm bridge circuit, and the free output of the second resistor of the relationship relationships forms the second output output of the four-arm bridge circuit, the first single arm of the arm consistently connected to the first branch of the four-arm bridge circuit relations and a multi-element two-terminal, which is a potentially frequency-independent two-terminal, which consists of two branches connected in parallel, in the first of they include two terminals for connecting a two-terminal device of the measurement object, which, in particular, consists of series-connected first and second resistors, and a series-connected capacitor and inductive coil are connected in parallel to the last, the common output of the second resistor and inductive coil is grounded, the second branch of the multi-element two-terminal connected in series with the first resistor and inductive coil, the free output of which is grounded, to the common output of the first resistor and inductive coil a capacitor is switched on, and a second resistor is connected to the grounded output of the inductive coil, 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, three are introduced additional resistors, the first of them is connected between the first output terminal of the four-arm bridge circuit and an ungrounded terminal for connecting the two-terminal object of measurement, the second additional p a resistor is connected between the first output terminal of the four-arm bridge circuit and the free terminal of the first resistor of the second branch of the multi-element bipolar, the third additional resistor is connected between the second output terminal of the bridge circuit and the ground, the free terminal of the second resistor of the second branch of the multi-element bipolar is connected to the common terminal of the first resistor, inductive coil and capacitor, and the free output of the capacitor of the second branch of the multi-element bipolar - with "ground", the general conclusion of the third additional p a resistor and a multi-element bipolar forms the second peak of the generator diagonal of the four-arm bridge circuit.

The invention is illustrated in the drawing.

The bipolar bridge measuring device comprises 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 ), a shaper of 5 cubic pulses (K ₃ t ³ ), where K ₀ , K ₁ , K ₂ and K ₃ are constant coefficients, t is the current time of the power amplifier 6, switch 7 and synchronization stage 8. The output of the synchronization stage 8 is connected to each input of the formers of rectangular, ramp, quadratic, and cubic pulses, the outputs of which are connected to the switch 7. The output of the switch 7 is connected to the input of the power amplifier 6. The output of the power amplifier 6 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 8. 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 includes a series-connected first single resistor 9 (R ₉ ) of the ratio arm and a multi-element bipolar, which is a potentially frequency-independent bipolar. The common output of a single resistor R ₉ and a potentially frequency-independent two-terminal forms the first output terminal (first peak of the measuring diagonal) of the four-arm bridge circuit. A potentially frequency-independent two-terminal network consists of two branches connected in parallel. Its first branch includes the first additional resistor 10 (R ₁₀ ) and two terminals for connecting the two-terminal device of the measurement object with the desired parameters, which, in particular, consists of the first resistor 11 (R ₁₁ ) and the second resistor 12 (R ₁₂ ) connected in series in parallel to which a capacitor 13 (C ₁₃ ) and an inductive coil 14 (L ₁₄ ) are connected in series. The common output of the resistor R ₁₂ and the inductive coil L _{14 is} grounded. The second branch of a potentially frequency-independent bipolar includes a second additional resistor 15 (R ₁₅ ), the resistance value of which is equal to the resistance value of the resistor R ₁₀ , and a four-element electric circuit connected to it with variable adjustable balancing elements, consisting of the first resistor 16 and connected in series connected in parallel with an inductive coil 17 (L ₁₇ ), a second resistor 18 (R ₁₈ ) and a capacitor 19 (C ₁₉ ), the common terminal of which is grounded. The second branch of the four-arm bridge circuit is formed by a single resistor 20 (R ₂₀ ) of the second link arm and a grounded third additional resistor 21 (R ₂₁ ), the common terminal of which forms the second output terminal (second vertex of the measuring diagonal) of the four-arm bridge circuit. The common conclusion of the single resistors R ₉ and R _{20 of the} two shoulders of the relationship forms the first peak of the generator diagonal of the four-arm bridge circuit, its second peak is grounded. Two outputs of the four-arm bridge circuit output are connected to the differential input of the null indicator 22, its other input, the synchronization input, is connected to the second output of the supply pulse generator 1. The common bus of the null indicator 22 is grounded. The common conclusion of the third additional resistor R ₂₁ and a potentially frequency-independent bipolar forms the second peak of the generator diagonal of the four-arm bridge circuit. In this bridge circuit, the resistor values R ₉ , R ₁₀ , R ₁₅ , R ₂₀ and R _{21 are} known and constant.

A bridge meter for the parameters of bipolar operates as follows. In the initial state, the voltages on the generator and measuring diagonals of the four-arm bridge circuit are zero. To ensure relatively cumbersome mathematical expressions, the values of the resistances of the resistors R ₉ , R ₁₀ , R ₁₅ , R ₂₀ and R ₂₁ should be made equal, i.e., in the particular case, the expression

Вначале на генераторную диагональ четырехплечей мостовой цепи воздействует последовательность импульсных сигналов прямоугольной формы, подаваемых посредством коммутатора 7 с генератора 1 питающих импульсов формирователем 2 прямоугольных импульсов. В установившемся режиме при воздействии очередного импульса прямоугольной формы в измерительной диагонали четырехплечей мостовой цепи устанавливается неизменяющееся в течение некоторого интервала времени напряжение неравновесия. После окончания переходного процесса плоская вершина этого напряжения неравновесия приводится к нулю при выполненном условии (1) однократной регулировкой переменного уравновешивающего элемента R₁₆, что обеспечивает выполнение первого условия равновесия четырехплечей мостовой цепи:

Initially, the generator diagonal of the four-arm bridge circuit is affected by a sequence of rectangular pulse signals supplied by the switch 7 from the generator 1 of the supply pulses by the generator 2 of rectangular pulses. In the steady state, under the influence of another rectangular pulse in the measuring diagonal of the four-arm bridge circuit, a non-equilibrium voltage that remains unchanged for a certain time interval is established. After the transition process, the flat top of this disequilibrium voltage is reduced to zero under condition (1) by a single adjustment of the variable balancing element R ₁₆ , which ensures the fulfillment of the first equilibrium condition of the four-arm bridge circuit:

Then, a pulse train of a ramp voltage is supplied to the generator diagonal of the four-arm bridge circuit by means of a switch 7 from the generator 1 of the supply pulses by the rammer 3 of the ramp pulses. When the next such pulse 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, which, taking into account the fulfilled preliminary condition (1) and the first equilibrium condition (2), is brought to zero by a single adjustment of the variable balancing element L ₁₇ . In this case, the second equilibrium condition for the four-arm bridge chain is fulfilled:

The fulfillment of the first equilibrium condition (2) in this case is not violated, since this condition does not contain a variable adjustable balancing element L ₁₇ .

Further, as a result of the action of a quadratic-shaped sequence of supply pulses supplied to the four-arm bridge circuit diagonal by means of a switch 7 from a supply pulse generator 1 by a quadratic pulse shaper 4 in its measuring diagonal, upon exposure to the next such pulse, a nonequilibrium pulse signal is established having a flat peak after the end of the transition process, which under the conditions (1) - (3) is reduced to zero by a single adjustment of the variable R oveshivayuschego element _18, which ensures the equilibrium conditions of implementation of the third bridge circuit chetyrehplechey:

In this case, the fulfillment of the first (2) and second (3) equilibrium conditions is not violated, since these conditions do not contain a variable adjustable balancing element R ₁₈ .

Finally, the action of a sequence of cubic-shaped power pulses supplied to the four-arm bridge circuit diagonal by means of a switch 7 from a power-pulse generator 1 by a cubic-pulse shaper 5 leads to the fact that in its measuring diagonal, when exposed to the next such pulse, a nonequilibrium pulse signal is established, having after the transition flat top of the process, which under the conditions (1) - (4) is reduced to zero by a single adjustment of variable noveshivayuschego element C _19, which makes it possible to perform the last quarter of the equilibrium conditions chetyrehplechey bridge circuit:

In this case, the previous three equilibrium conditions of the four-arm bridge chain (2) - (4) also remain satisfied, since they do not have a variable balancing element C ₁₉ .

The counting of the four required parameters: R ₁₁ , R ₁₂ , C ₁₃ and L ₁₄ is taken from the four equilibrium conditions (2) - (5), essentially from the four equations.

Thus, the proposed bridge meter of the two-terminal parameters allows to reduce the measurement error by eliminating the component error from the parasitic capacitance relative to the “ground” of the non-earthed multi-element two-terminal, as well as the instability of this parasitic capacitance, due to the use of only grounded multi-element two-terminal devices. In addition, the proposed bridge meter of the two-terminal parameters implements such an important property of bridge circuits as dependent separate balancing.

Claims (1)

A bridge two-terminal parameter meter containing a supply pulse generator consisting of a synchronization cascade, rectangular, linearly varying, quadratic and cubic pulses, a switch and a power amplifier, the output of the synchronization cascade is connected to each input of four available 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 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, each of which there is a single resistor of the two shoulders of the relationship, the common output of these single resistors forms the first vertex of the generator diagonal of the four-arm bridge circuit, its second vertex is grounded, the free output of the first resistor of the arm of the relationship forms the first output terminal of the four-arm bridge circuit, and the free output of the second resistor of the arm of the relationship forms the second output terminal of the four-arm bridge circuit, the first single resistor of the arm of the relationship and a multi-element bipolar, which are sequentially connected, form the first branch of the four-arm bridge circuit is a potentially frequency-independent two-terminal network, which consists of two branches connected in parallel, the first of which includes two terminals for connection of a two-terminal device of the measurement object, which, in particular, consists of series-connected first and second resistors, and a series-connected capacitor and an inductive coil parallel to the last, the common output of the second resistor and inductive coil is grounded, the first resistor is connected in series to the second branch of the multi-element bipolar an inductive coil, the free output of which is grounded, a capacitor is connected to the common output of the first resistor and inductive coil, and to to the ground terminal of the inductive coil - a second resistor, two outputs of the four-arm bridge circuit output are connected to the differential input of the null indicator, its other input is the synchronization input, connected to the second output of the power pulse generator, the common bus of the null indicator is grounded, characterized in that three additional resistors, the first of them is connected between the first output terminal of the four-arm bridge circuit and an ungrounded terminal for connecting the two-terminal object of measurement, the second additional a resistor is connected between the first output terminal of the four-arm bridge circuit and the free output of the first resistor of the second branch of the multi-element two-terminal network, the third additional resistor is connected between the second output terminal of the bridge circuit and the ground, the free output of the second resistor of the second branch of the multi-element two-terminal network is connected to the common terminal of the first resistor, inductive coil and capacitor, and the free output of the capacitor of the second branch of the multi-element bipolar - with "ground", the general conclusion of the third additional resistor and a two-pole multi-element forms a second diagonal vertex generator chetyrehplechey bridge circuit.