SU636546A1 - Method of measuring parameters of multicomponent two-pole networks - Google Patents

Claims (2)

The invention relates to electrical measuring technique and can be used in measuring parametro passive pole. Methods are known for measuring the parameters of multi-element two-terminal networks based on switching the measurement object into a zero measuring circuit powered by a voltage of a number of frequencies and determining the values of the object's parameters from the values of adjustable elements after bringing the measuring circuit to the equilibrium state l. However, the known method is complicated. The closest in technical essence is a method for measuring the parameters of multi-element two-terminals, including connecting an object to a measuring circuit powered by a sinusoidal voltage of a number of frequencies, modeling the frequency dependence of the object of measurement by voltage (current), comparing active physical quantities, such as currents flowing through measurable and exemplary two-terminal networks, and a change in the adjustable objects of the model until equality of the compared active values is obtained at all frequencies | 2. However, the control process according to the known method is complicated and long, due to the curvature of the control lines. The purpose of the invention is to reduce the balancing time and simplify the balancing process by obtaining straight balancing lines when measuring the parameters of multi-element two-terminal devices described by the dependence t (m .a, ... x P ... (w, a, a2 ... .a „) where Z is the impedance of the measured double-pole. Ohm; P, (w, s (. ,, a2 -. o (1 and P2 (w, a., s) (2 ... a„ -) are polynomials UU - circular frequency, rad / s, j-cfrT measured parameters (inductance, capacitance F, capacitance F, resistance Ohm, conductivity Stim) - is achieved due to the fact that according to the well-known method of measuring the parameters of dual cell poles, including connecting an object to a measuring circuit fed by a sinusoidal voltage of a number of frequencies, modeling the frequency dependence of the object to be measured with voltage (current), comparing active physical quantities, such as currents flowing through the measured three-dimensional bipolar, and changing adjustable elements of the model to achieve equality of the compared values at all frequencies simulate the frequency dependence of the measured and exemplary two-terminal networks and regulate the elements of the models they way that when equality of the compared values of the active voltage (current) supplied to the branch of the two-pole model, is proportional to the polynomial P (W, a, a,. . . a) to the voltage (current) supplied to the measuring branch of a two-terminal device — the R. polynomial, and a cin). The proposed method is carried out as follows. The measured object is supplied with a voltage proportional to the polynomial P (w, 0.0.2, .... A), and to the exemplary two-terminal YO (usually the sample capacitance or resistance) a voltage proportional to the polynomial P (w, 0, dg then the equilibrium condition is recorded as K., P, (w, a, o, ago, -.cl „VP, (uC, cl ..... cln), a ,, a ... a„) .. a) o, -P2. “y. ° th - io where K and d are constant dimensional coefficients; adjustable pair of models. K K .; Y. With the condition and equilibration of the circuit at a sufficient number of frequencies, it is possible to equate the coefficients at various powers of the W and P full genes and obtain conditions by n From (1) it is easy to notice that the controllable parameters, a ... a, e enters only the numerators of the term of (1.) and, consequently, only linear changes in the active reactive components of the disequilibrium signal vector, i.e. Lines of new arrivals will always be straight. In the drawing, a vector diagram is shown confirming the indicated position. A three-element two-terminal device is described by the T .. dependence (Nn and RX are the active elements of the two-terminal device x- is the reactive element of the two-terminal network. Then the unbalance current 1 is generally equal to (the input resistance 6 of the equilibrium detector is negligible): n,) i --ii- хг х /: -.) -Speak, п, 1 - -1 As the measuring circuit is equilibrated at several frequencies and the equilibrium condition 1, O is fulfilled independently of the frequency 14), then you can equate the coefficients with the same powers of x. Reducing the terms in square brackets of expression (3) to a common denominator, we first equate the numerator coefficients of the second degree, it is RO-Hf,, C RL L- R.,, ax b ft Z 1 ax x n, h A and we get y :: equilibrium 2 6 Equating the numerator coefficients that do not contain tu iri C OC j () х x, x, (. g / C5: d) taking into account condition (5) and the equality n Hj due to the associated adjustment of these windings we get x / - ig-- RocRpt .vi,. CT) Similarly, we get 2 1 "OS O From expressions (5), (6) and (7), it can be seen that the number of turns of windings П Hg (Hj) is proportional to the measured parameters R x Changes in current vector 1 when adjusting these turns are linear, and direct balancing lines, which greatly simplifies the balancing process and allows you to automate it. The invention The method of measuring the parameters of multi-element two-terminal network, including the connection of an object to a measuring circuit fed by a sinusoidal voltage; a series of frequencies, modeling the frequency dependence of the object of measurement by voltage (current), comparing active physical quantities, for example, currents flowing through the measured and exemplary two-terminal circuits, and changing the adjustable elements of the model to obtain equality of the compared active quantities at all frequencies This is because, in order to shorten the balancing time and simplify the balancing process by obtaining straight balancing lines when measuring parameters of multi-element bipolar, 2 P (.q.a2 .... oh) XP (",, a, .oj, ... 7 where the impedance of the measured two half a room, Ohm ;. i (, 0,, 1 02 - -uomnom 4 -round frequencies a, rad / s measured parameters (inductance. G, capacitance F, resistance. Ohm, conductivity, Stim), simulate the frequency dependence of the measurement object voltage (currents applied to the branches of the measured and exemplary two-terminal networks and regulate the elements of the models in such a way that, at the time of equality of the compared active quantities, the voltage (current) supplied to the branch of the model two-terminal network is proportional polynomial Pe (ui) / a. , a, ..., 01), and the voltage (current) supplied to the branch of the two-terminal network being measured is the polynomial P (w with | I and,, ... a). a а - Sources of information taken by shiki in attention during the examination: 1. USSR author's certificate 158627, cl. G01 R 27/02, 1963. 2. Authors certificate of the USSR 356571, cl. Q01 -R 17/06, 1970. R) .x , - "