DE1268737B - Method for generating a directional voltage which is a function of the phase difference between two alternating voltages - Google Patents

Description

Method of generating a directional voltage which is a function of the The phase difference between two AC voltages is. The invention is concerned with one Method of generating a rectified voltage that is a function of the phase difference of two alternating voltages, where the two have a sum or difference voltage is obtained whose time function on the basis of the time functions of this individual AC voltages is such that the ratio of the two peak values, namely the positive and negative amplitudes, this sum or difference voltage in a function of the phase difference between the two in relation to their time average tensions to be compared is.

By the German patents 940 908 and 905 383 are already Phase comparison circuits with two diodes are known, with which one can get from the phase difference derives a directional voltage from two generally non-sinusoidal voltages, which is preferably used for phase matching.

The earlier German patent 1104 031 is based on the task to reduce the cost of these known phase comparison circuits. this happens in the circuit arrangement proposed by this older right for generation a control voltage dependent on the phase position of two voltages to be compared in that, in parallel with a diode, the pulse voltages to be compared are supplied, a series circuit of a linear and a non-linear Resistance lies. The diode is used to generate the phase-dependent directional voltage. The non-linear resistor has the task of comparing the outgoing control voltage to ground to symmetrize, so that the control voltage output 0 volts at the target phase position will. In this older law, a non-linear resistance is used saved a diode of the known phase comparison circuit.

The invention has the task of reducing the circuit complexity to reduce further and the phase comparison only with a single two-pole element perform. In order to enable the use of a two-pole element, arises the invention also has the object of a method for generating a directional voltage to create, which is a function of the phase difference between two alternating voltages, where a single voltage is added or subtracted to feed it Two-pole element is obtained and the ratio of the two peak values of these single voltage in relation to its time average is a function of the phase difference of the two voltages to be compared. This is used in a method of generating a directional voltage, which is a function of the phase difference between two alternating voltages is, in which a sum or difference voltage is obtained from both, whose Time function based on the time functions of these individual alternating voltages in such a way is that the ratio of the two peaks, namely the positive and negative Amplitudes of this sum or difference voltage in relation to their temporal Mean value is a function of the phase difference between the two voltages to be compared is achieved according to the invention in that this sum or difference voltage a polarization-independent element with a non-linear voltage characteristic is supplied, which supplies the directional voltage.

The inventive method has the advantage that a non-linear polarization-independent element, preferably a VDR resistor, not just one, but replaced two diodes.

In addition to this economic advantage, the method has the advantage circuit simplicity. Another non-linear polarization independent Element is z. B. a symmetrical glow path. For example, if you have a tubular Choosing a glow path, one can even use the ratio of the glow path lengths to one another also read off the phase position optically.

In the method according to the invention, the two alternating voltages become a sum or difference voltage obtained that has such a time curve has that, if the phase position is desired, the two voltage peak values (the negative and the positive) of this total or differential voltage, based on the mean value, are the same size, and that if there is a deviation from this phase position in the one or in the other direction one or the other peak value becomes larger or smaller. This sum or. Difference voltage, the time course of which is a function of the Phase difference of the two individual voltages is used for rectification the non-linear, polarization-independent element supplied. The DC voltage obtained in this way is the desired phase-dependent rectified voltage.

As a first embodiment of an arrangement for implementing the Method is a phase comparison circuit for synchronizing a horizontal deflection generator a television receiver with reference to FIG. 1 described. In the circuit shown the synchronization pulse voltage is fed to terminals 1, 2. At the terminals 3, 4 is the known pulse-shaped voltage of the horizontal deflection. This voltage is in the embodiment with the resistor 5 and the capacitor 6 integrated (e.g. it could also be differentiated). At the capacitor 6 This integration results in a sawtooth-shaped voltage. With the capacitor 7 and the resistor 8, the synchronization pulses are differentiated (they could z. B.- can also be integrated). So there is a total voltage at point 9 from differentiated synchronization pulses and integrated deflection voltage. These The sum voltage is fed to the VDR resistor 13 via the coupling capacitor 12. The resulting directional voltage is derived with the resistor 14 and with the condenser 15 sieved.

F i g. 2 shows another circuit variant in which the VDR resistor between the differentiated synchronizing voltage and the integrated deflection voltage is so that on him the differential voltage; of both lies. The switching elements each have the same tasks as in FIG. 1 and are therefore numbered the same.

The circuit can be implemented in such a way that one of the leads Via a resistor with ground or a fixed or adjustable bias voltage is connected, while the directional voltage from the other supply via a resistor is removed.

Occasionally it can be advantageous that two working in push-pull phase-dependent directional voltages are generated. To do this, the circuit is made designed in such a way that the two leads preferably have equal resistances are connected to ground and from the two leads via two further resistors two polarity opposite directional voltages can be picked up.

F i g. 3 shows the total voltage. Where 10 is the sawtooth voltage and 11 the differentiated synchronizing pulse. The phase position of the two voltages is drawn as it is desired. In this case the two peak values are based on the mean value, which coincides with the time axis in this figure, same size. Hence, if you apply this voltage to a VDR resistor, As with the supply of a sinusoidal voltage, no directional voltage occurs.

Fig. 4 shows a phase position in which the synchronizing voltage leads. The positive peak value is now much larger than the negative peak value, both related to the mean. The dash-dotted lines in the figures are supposed to Specify the voltage from which the VDR resistor noticeably draws current. Since there is no closed direct current path, the time average must be of the current flowing through the VDR resistor must be zero. The voltage across the VDR resistor so adjusts itself in such a way that both peak values are equal to the respective dash-dotted line Cross the line so that a negative mean value voltage arises. she will indicated by the dashed line.

F i g. 5 shows the opposite case in which there is a positive Adjusts the directional voltage. It is appropriate to make the differentiated voltage greater than to choose the sawtooth voltage in order to avoid that the peak values of the sawtooth voltage also contribute to rectification.

As already said, the directional voltage is with the correct phase position Zero. Even if there are no synchronization pulses, it is zero. i.e., it is a symmetrical directional voltage generation with its well-known advantages. These Symmetry is achieved in that the two individual voltages have one such time course that they have alone without the additional presence of others with a VDR resistor or another non-linear polarization-independent resistor Element, cannot be rectified. In the case of pulsed voltages, to achieve this, as has been shown, through integration or differentiation.

It is therefore appropriate that the positive peak value of each of the two to be compared, fed to the non-linear polarization-independent element Tensions, based on their respective time average, are the same as is the associated negative peak value.

In the case of a higher frequency or short pulse times, the one to be compared pulse-shaped voltages, it is useful to balance both voltages to integrate and to form the differential voltage, because when both are integrated Voltages cannot disturb the self-capacitance of the VDR resistor, as they are only added to the capacitance of the integration capacitors.

Since the addition of two sinusoidal voltages of the same frequency, as well as their subtraction, again results in a sinusoidal voltage, sinusoidal voltages but no directional voltages at VDR resistors, the method is a phase comparison of two Sinus voltages not possible immediately. However, one can certainly face this difficulty overcome by adding one of the two in a previous amplifier stage comparing sinusoidal voltages doubled in frequency, because a phase comparison of a Sinusoidal voltage with a sinusoidal voltage of double frequency is also available with this method possible without difficulty.

F i g. 6, 7 and 8 show the resulting total voltage form in Dependence on the phase position of the two voltages to one another.

In this way it is also possible to use a frequency discriminator circuit for sinusoidal voltages.

F i g. 9 shows such a circuit arrangement in principle. It is 16 a limiter and distorter that also emits even-numbered harmonics. He delivers a current that flows through the two circles 17 and 18. One of the two circles is tuned to the fundamental and the second circle to double the frequency. It helps increase the slope and Linearity of the resulting Discriminator curve when the quality of the fundamental wave circle is much higher as the quality of the harmonic circuit selects.

Such an arrangement can be used both for obtaining a retuning voltage as well as for demodulating a frequency-modulated signal.

Claims (7)

Claims: 1. A method for generating a directional voltage that is a function of the phase difference between two alternating voltages, where the two a sum or difference voltage is obtained, the time function of which is based on of the time functions of these individual alternating voltages is such that the ratio of the two peak values, namely the respective positive and negative amplitudes, this sum or difference voltage in relation to its mean value over time The function of the phase difference between the two voltages to be compared is d a d u r c h g e -k e n n n z e i c h n e t that this sum or difference voltage is a polarization-independent element with non-linear voltage characteristic is supplied, which supplies the directional voltage. 2. The method according to claim 1, characterized characterized in that the non-linear, polarization-independent element is a voltage-dependent Resistance is. 3. The method according to claim 1 and / or 2, characterized in that that the positive peak value of each of the two to be compared, the non-linear polarization-independent element supplied voltages, based on their respective temporal mean value, the same size as the associated negative peak value. 4. The method according to claim 3, characterized in that when using pulse-shaped Equivalent stresses these are differentiated or integrated. 5. Procedure according to Claim 4, characterized in that when using a differentiated and of an integrated voltage, the differentiated voltage is greater than the integrated Tension is. 6. The method according to claim 1 to 3, characterized in that when Comparison of two sinusoidal voltages one of the two is frequency doubled and the total or difference voltage from the doubled and the not doubled is formed. 7. Circuit for carrying out the method according to one or more of the preceding claims, characterized in that one of the comparison voltages of one feed and the other reference voltage of the other feed of the non-linear, polarization-independent element is supplied. B. circuit after Claim 7, characterized in that when using high-frequency or with Short pulse times afflicted comparative voltages, both with a resistor-capacitor combination each to get integrated. 9. Circuit according to claim 7 or 8, characterized in that that one of the leads via a resistor to ground or a fixed or also adjustable bias is connected while feeding from the other The directional voltage is picked up via a resistor. 10. Circuit according to claim 7 or 8, characterized in that the two feeds are preferably the same large resistors are connected to ground and from the two leads across two further resistances two directional voltages opposite in polarity are removed will. 11. Circuit according to one or more of the preceding claims, characterized characterized in that it is used to generate a directional voltage, the one Function of the frequency deviation of a signal from a nominal frequency is, its Current excites two resonant circuits, one of which at the setpoint frequency and the second to an even multiple, preferably the second multiple of Setpoint frequency, is adjusted, and that the sum or from both circuit voltages Differential voltage is formed. Publications considered: German Patent Specifications No. 905 383, 892 310; British Patent No. 676112. Earlier contemplated Patents: German Patent No. 1104 031.