DE1044265B - Harmonic analyzer - Google Patents

Description

Harmonic analyzer The invention relates to a harmonic Analyzer with an amplifier for filtering out one harmonic at a time with negative feedback, which includes all harmonics with the exception of the harmonics to be filtered out approximately in opposite phase leads back to the input. It is known analyzers build this type in such a way that one acts as a filter in the negative feedback path acting complex network in the form of a quadrupole that is coordinated in this way that it suppresses the harmonics to be filtered out by the analyzer. These Circuit is based on the idea that the harmonics not suppressed in the quadrupole, which are fed back to the input of the amplifier via the negative feedback path, to extinguish or at least dampen by the effect of the negative feedback, so that at the output of the amplifier the harmonic to be filtered out appears to be greatly increased.

The filter effect of this known circuit is not particularly good spicy. Because cancellation by negative feedback assumes that the Voltage at the input of the amplifier both in phase opposition to the input voltage as well as in the size of the input voltage.

You can tune a quadrupole so that these two conditions are fulfilled for a certain harmonic. But there are the individual harmonics different phase rotations in each quadrupole and, in general, also different ones Experienced attenuation, the two conditions can never be arbitrary meet large numbers of harmonics.

In the analyzer according to the invention, this disadvantage is eliminated by that according to the invention the amplifier in the main path between the two connections of the negative feedback path contains a network whose output voltage is only is frequency-dependent in the phase and the phase of the harmonics to be filtered out turns around 1800, in such a way that the negative feedback path free of complex network elements the harmonic to be filtered out in phase with the input voltage at the input returns. With the network in the main path, its output voltage only in phase Depending on the frequency, it is possible to track the individual harmonics via the negative feedback path correctly sized to the amplifier input, i.e. the size condition to be fulfilled for all harmonics.

As far as the phase condition is concerned, all those harmonics rotated the harmonic to be filtered out by 900 forwards or backwards are completely extinguished by the negative feedback. The remaining harmonics do not experience a complete deletion, but appear at the same time probably at the exit with a relatively small amplitude, since the one to be filtered out, rotated by 1800 in the phase rotator Harmonic experiences a very considerable boost from positive feedback.

In addition to the good filtering effect of the analyzer according to the invention structural simplicity is added, since a network whose output is only in the phase is frequency-dependent, can be built up from a few simple elements. The simplicity in the construction has the consequence that the time constant is low, the analyzer that is, changes in the magnitude of the voltage applied to the input with very little Delay equals.

The network lying in the main path can in a preferred embodiment of the invention consist of a bridge circuit, the diagonal of which is the output terminals contains and in which two elements separated by a diagonal knot together Form an RC element. A short-circuited Wien bridge can be placed in front of the amplifier input lie.

Wien bridges are known as filters in harmonic analyzers.

The drawing illustrates an embodiment of the invention. 1 shows the basic circuit of a phase rotator, and FIG. 2 shows the associated one Vector diagram, FIG. 3 shows a triode circuit which takes the place of that which appears in FIG Transformer can occur, Fig. 4 is a diagram of the negative feedback amplifier in the form a block diagram, FIG. 5 the amplifier circuit and FIG. 6 the overall circuit.

In Fig. 1 is an input transformer with secondary terminals 1, 2 and 3 connected to an RC element in the manner shown. The circuit shown Has is known the property that the output voltage eg at a given frequency is rotated by changing the resistance R in phase without changing their Size changes. Conversely, if one makes the frequency variable with constant resistance R, so the phase of the output voltage eO changes at constant amplitude. Contexts are explained in the vector diagram according to FIG. 2, the phase as a reference point of the voltages e12 and e23 appearing in FIG. 1 is assumed. IR is the voltage at R and IljcoC the voltage at C. The dashed straight line marked I should indicate that I and IR are in phase. w is the angular frequency. Assume that the consumer to which the voltage eO is high resistance, so that the neglect the current drawn by it and focus on the current drawn by R and C can restrict flowing current. With this assumption, the Vector eO a semicircle. The voltage it therefore changes when the frequency is all Values runs through their phase from 0 to 1800. The transformer according to FIG. 1 can be replaced by the more convenient means of a triode in the circuit of Fig. 3, where terminals 1, 2 and 3 are the also designated secondary terminals of the transformer and Rp is the anode resistance and R. is the cathode resistance.

Although it is per se possible a phase shift of total 1800 in a single stage, it is practically more convenient to do so in two Levels of 900 each to do. Use is made of this here too. You can with one Amplifier consisting of two stages as shown in Figures 1 and 3, any harmonic shift by 1800, whereby the frequency of these harmonics depends on how to choose the resistors R in the two stages.

Two circuits in series according to FIG. 1, in which the transformers are replaced by triodes according to FIG. 3, as can be seen from FIGS. 5 and 6 will result, in the example shown, an amplifier with phase rotator, the appears in the block diagram of FIG. 4 as block a. The output voltage of this Amplifier that occurs at a potentiometer P is via an amplifier b fed back in negative feedback to the input of a. All are in the exit of a Harmonics of the input voltage included. One of them, which may be called tO, is shifted in phase around 1800. The negative feedback amplifier b delivers in opposite phase all harmonics back to the input. With this all harmonics are partly deleted, partly attenuated, except only that of the frequency tO, which is due to the rotation occurs by 180 in a in phase at the input and amplified by feedback at the output appears. The arrangement according to Fig. 4 therefore behaves like a bandpass filter, the mean pass frequency of which is adjusted a single set of resistors in the phase rotator can be changed, where the output voltage remains constant.

The potentiometer P is used to set the degree of negative feedback. If it picks up a small voltage, the degree of coupling is low. The harmonic with the frequency f0 there is little gain and the remaining harmonics are few suppressed. The frequency characteristic of the circuit is flat and the selectivity is flat small amount. If the voltage tapped off by P is increased, the degree of coupling increases, the harmonic [@ is raised stc rlcer, and the remaining harmonics will more suppressed. At the same time, the overall gain increases. If you increase the tension even further, then finally the case occurs that the coupling which is positive for wo is, in so far as there is a real feedback, the system vibrates offset from the frequency fo. By setting P in the area below this Limit one can therefore change the selectivity and at the same time the gain. at With a fixed setting of P, however, selectivity and gain are theoretically independent on the frequency. In addition, it is of particular importance for the purpose pursued, that the width of the frequency band passed as a percentage of the mean pass frequency is independent of the value of the mean pass frequency.

Fig. 5 shows the circuit of an amplifier stage in detail. the Triodes 4 and V2 are components of the phase shifter with the elements R and C. The triode V4 lies in the negative feedback path and is determined according to the setting of the potentiometer P the degree of selectivity. For the purpose of the invention is it is advisable to form the resistors R from decades that correspond to the frequencies 50, 100 ..

500 Hz correspond. The resonance frequency is obviously that for which the reactance of the capacitor C is equal to the resistance R. The triode V3, which forms the output stage, is necessary so that the coupling is in the correct position Phase and is constant as seen from the input. It should be noted that the phase rotator stages V1 and V2 and the output stage V3 are in direct cascade connection to each to avoid unwanted phase shift.

Without going into the details of the calculation of the circuit elements, it should also be noted that the resistors R1 and R2 are carefully balanced must be in order to ensure the equality of the vectors t2 and e23 (Fig. 1 and 2). The values of these resistances should be relatively low, so that the internal Impedance of the phase rotator stages becomes small. The values are chosen accordingly of R and the reactance of C are relatively high. Otherwise one does it with consideration on the direct coupling of the stages in cascade connection the resistors R double as large as the resistances Rl and correspondingly three times the resistance R3 from Rl. The time constant of the circuit is negligibly small. The order thus also speaks to rapid changes in the amplitude of the current being investigated without delay.

Fig. 6 shows the overall arrangement in detail. The triodes V1, V2, V3, V4 are connected as in FIG. 5 and together form the phase rotator and the negative feedback. The drawing shows a single such system. In general but one will provide two systems of this type connected in series.

The two systems then have a slightly different average passage frequencies of which one is about 20/0 above and the other about 20/0 below the resulting mean pass frequency. This will change the frequency characteristic flat in the passage area and steep at the borders. To the repercussions of serving for filtering and therefore referred to here as selective amplifier To avoid amplifiers on top of each other, they are via a decoupling resistor tied together.

The main elements of the device according to the invention are as follows briefly described in detail: The input is a voltage divider S1, which is used for common voltages, i.e. about 220, 380, 110, 190, 10 and 1 Volts. The tension it delivers is best on the order of magnitude of 0.1 volts, a value at which saturation of the input stage is avoided. the The impedance of the voltage divider can be relatively high because of the input of the selective stage is high resistance. To determine the impedance of the voltage divider with respect to the grid of the To keep the selective level as constant as possible, a high resistance R41 can be used between placed the output of the voltage divider and the input grid of the first stage will.

A Vienna bridge connects to the voltage divider, which leads to the Basic frequency of the network, e.g. B.

50 Hz, is tuned and in front of the input of the first selective stage lies. This bridge is used when picking up the higher harmonics should. It suppresses the fundamental wave and allows one input voltage to work that is higher than would be permissible if the fundamental wave was present. An additional amplifier stage of around 10 times the gain is therefore saved. The Wien bridge can be short-circuited by a switch 8g and thus ineffective can be made when the fundamental wave is to be recorded.

Selective amplifiers are connected to the Wienbrücke in each case desired number. They consist of the triodes V1 to V4 in cascade connection, whereby the mean throughput frequencies of the units are offset against each other are that on the one hand the necessary bandwidth and on the other hand so much selectivity is obtained as necessary to separate adjacent harmonics. The device will on the fundamental or the desired harmonic with the help of the resistor sets R, which are built as decades, are set simultaneously in all units.

An amplifier is connected to the output of the selective stages consists of the tubes V5 to V5 and for the control of a recorder with continuous Paper flow is designed. The gain can be adjusted by a resistor Rlo will be to compensate for depending on the chosen Different sized harmonics To create the output voltage of the Wienbrücke. Rlo is a theorem of resistance that simultaneously is switched with the decades R.

A switch S4 allows either the calibration of the device to be checked or take a measurement. E represents the writer.

Claims (3)

PATENT CLAIMS: 1. Harmonic analyzer with a filter for filtering out each one harmonic serving amplifier with negative feedback, the all harmonics with the exception of the harmonics to be filtered out approximately in phase opposition to the input returns, characterized in that the amplifier in the main path between the two connections of the negative feedback path contains a network whose output voltage is frequency-dependent only in the phase and the phase of the filter to be filtered out Harmonics rotates around 1800, so that it is free of complex network elements Negative feedback path the harmonic to be filtered out in phase with the input voltage leads back to the entrance. 2. Harmonic analyzer according to claim 1, characterized in that that the network consists of a bridge circuit, the diagonal of which is the output terminals contains, and in which two elements separated by a diagonal knot together form an RC element. 3. Harmonic analyzer according to claim 1 or 2 characterized through a short-circuited Wien bridge located in front of the amplifier input. Publications considered: Austrian patent specification No. 176 904; Proceedings of the Inst. Of Radio Engineers, February 1938, pp. 226 bis 235; Rohde and Schwarz - Mitteilungen, No. 6, 1955, pp. 353 to 367.