DE1277904B - Control circuit to maintain the delay time in a PAL runtime signal splitting circuit - Google Patents

Description

Control circuit for maintaining the delay time in a PAL runtime signal splitting circuit With the PAL runtime signal splitting circuit, the color carriers of two are temporal successive lines by means of a delay line with the delay time a line duration made available at the same time and in a certain phase relationship added in an adding stage and subtracted in a subtracting stage. At the exit the adder is then the one corresponding to the modulation axis that has not been switched and at the output of the subtraction stage that corresponding to the switched modulation axis color carrier frequency signal. These color carrier-frequency signals are used for demodulation a locally generated reference carrier added. For perfect functioning This transit time signal splitting circuit must have the color carriers at the two inputs the adding stage and the subtracting stage have a precisely defined phase relationship. If this phase relationship deviates from the nominal value during operation, the amplitude of the mentioned color carrier frequency signals falsified.

It is known to set the exact phase relationship in series to switch an additional, adjustable delay line to the delay line, with which the exact phase relationship can be set (Telefunkenzeitung, 1964, H. 1, p. 63; radio mentor, 1964, H.2, p.113). Due to various influences, e.g. B. by Change the delay time of the delay line or the additional delay line due to temperature fluctuations or a change in the frequency of the color carrier the phase relationship can change in an undesirable manner.

It has been proposed (German Patent 1230 074), in series an electrical delay line with a temperature dependency to the delay line to switch the delay time, which is opposite to that of the delay line is directed. Such a circuit is relatively complex and speaks also only respond to temperature changes.

A precise delay time is also suggested been (earlier patent application T 30297 VIII a / 21a 1), horizontal sync pulses or line-frequency appearing color sync signals at the output and input of the Compare delay line in phase with each other and from this a manipulated variable to gain, which affects the delay time of the delay line. For example the manipulated variable acts electronically in series with the delay line controllable delay line. This solution requires gates to control the line frequencies Feel impulses out of the signal.

A transit time signal splitting circuit for a PAL receiver is known (German patent specification 1175 731), in which the reference carrier used for demodulation is the received color carrier before the delay line, with a line-frequency mirrored phase on the non-switched modulation axis; will be added. At the output of the adding stage and the subtracting stage of the transit time demodulator, no additional carrier is then required, and the color signals can be obtained here directly by amplitude demodulation of the color carrier-frequency signals at the output of these stages.

The invention is based on the knowledge that with such a circuit precise readjustment of the desired phase relationship in a particularly simple manner at the adding stage and the subtracting stage is possible.

The invention is based on a control circuit for compliance with the Delay time in a transit time signal splitter circuit for a PAL color television receiver, in the case of the modulated color carrier received, a color carrier with a line frequency is added mirror-inverted to the fixed modulation axis switched phase and then the modulated color carrier by addition and subtraction with the in a line delay line, the modulated color carrier of the time-delayed previous line to one of the fixed and one of the line-frequency switched Modulation axis corresponding color carrier frequency voltage is split.

The invention consists in that the switched modulation axis corresponding color carrier frequency voltage in a synchronous demodulator by means of of a color carrier with a phase corresponding to the switched modulation axis is rectified and the manipulated variable thus obtained via a time constant element with a long time constant compared to the line duration, the delay time of the Line delay line controls so that the color carrier frequency signals in successive Lines of equal amplitude and approximately the phase of the modulation axis corresponding to them to have.

The color carrier added to the modulated color carrier and the color carrier for the synchronous demodulator can be of the same, through transmitted color sync signals synchronized oscillator can be generated. As a color carrier for the synchronous demodulator The color carrier frequency voltage obtained by addition can also be used. the The manipulated variable acts, for example, on the running time of a line in series with the delay line lying, electronically controllable delay line.

A major advantage of the invention is that no gate circuits are required to separate a signal from the complete color signal. In addition, a phase correction is made possible during the entire line sequence, because the manipulated variable to readjust the phase from the color subcarrier-frequency signal is derived.

The invention is illustrated below with reference to the drawing using an exemplary embodiment explained in more detail.

F i g. Fig. 1 shows a circuit example of the invention; F i g. 2 and 3 show vector images and waveforms to explain the mode of operation.

In Fig. 1, the modulated color carrier F or the complex conjugate in every second line, mirrored on the non-switched modulation axis U, is fed to an adder 2 from a terminal 1. In addition stage 2, a color carrier T or T * is added to this modulated color carrier, which is also mirrored in phase on the modulation axis U that has not been switched. This color carrier is generated in an oscillator 3 and switched with a phase switch 4 by means of a half-line frequency switching meander 5 by: L 45 ° to the modulation axis U. By adding the modulated color carrier F or F * with the reference carrier T or T *, a modulated color carrier without suppressed carrier with a degree of modulation m <1, which is also mirrored on the modulation axis U, is created. This carrier is denoted by S or S *, the index v denoting the color carrier delayed by one line duration. The color carriers S and S * of two consecutive lines, which are provided with additional carriers, are made available simultaneously by means of a delay line 8 and a delay line 9 serving for fine phase adjustment, which together cause a delay by the length of the line, and are added and subtracted in an adder 6 and a subtractor 7 . At the output of the adding stage 6 and the subtracting stage 7 there are two color carrier-frequency signals with additional carriers which, after amplitude demodulation in amplitude rectifiers 10, 11, supply video-frequency color signals U and V. The circuit described so far is known from German patent specification 1175 731.

According to the invention, the color carrier-frequency signal S- S, * or S * -S, at the output of the subtraction stage 7 is fed via a capacitor 12 to a synchronous demodulator 13, to which a reference carrier is fed on the other hand via a line 14 , which comes from the oscillator 3 and has a phase rotator 15 is brought to the constant phase of the modulation axis jV. The output voltage of the synchronous demodulator 13 acts via a time constant element 16 with a time constant that is large compared to the line duration on the delay time of the delay line 9, which is electronically controllable.

The mode of operation of this control circuit is illustrated in FIG. 2 and 3 explained in more detail. The demodulated signals in FIG. 2 and 3 are as square wave voltages shown at half the line frequency. This corresponds essentially to the demodulated Ink carrier component in axis jV. In fact, you are still demodulated Signal component superimposed. Since this is the one toggled from line to line Is a signal component, it can be neglected in the following explanations will. It is also assumed that between consecutive Lines the image has no information difference.

In Fig. 2 it is assumed that the delay time of the circuit elements 8, 9 is correct and the two color carriers at the inputs of the adding stage 6 and the subtracting stage 7 have the correct phase. Assuming that successive lines have the same information content, the color carrier-frequency signals at the output of the subtraction stage 7, namely SS, * and S * -S, have opposite polarity and the same amplitude. By synchronous demodulation along the axis jV in the synchronous demodulator 13, a manipulated variable 18 therefore arises from these signals, which is alternately positive and negative line by line by the same amount. At the output of the integrator 16, ie at the input of the delay line 9, there is therefore a manipulated variable 19 with the direct current value of the manipulated variable 18, ie with the value zero, which does not change the correct delay time of the circuit elements 8, 9.

In Fig. 3 it is assumed that the delay time of the circuit elements 8, 9 has an error y. The undelayed modulated color carrier S or S * at the input of the subtraction stage 7 then retains its phase from FIG. 2, while the delayed modulated color carrier Sz and Sv * are shifted by the angle y. F i g. 3 shows that the color subcarrier-frequency signals S-Sv * and S * -Sv of two successive lines at the output of the subtraction stage 7 then differ in amplitude, namely S-Sv * is too small and S * + Sv too large . You are also in the phase opposite FIG. 2 rotated by the angle V / 2. Likewise, the amplitude of the signal S + Sv * and S * + Sv at the output of the adder 6 is falsified because here too the angle between the added signals S and Sv * or S * and Sv is once too small and once too large . This amplitude distortion, which is opposite from line to line, can lead to banding in the image. The manipulated variable 18 then occurring at the output of the synchronous demodulator 13 then no longer has the mean value zero, so that a standing variable 19 with a negative value is produced at the output of the integrating element 16. This manipulated variable now acts on the delay time of the delay line 9 in such a way that the phase of the color carrier Sv or Sv * at the input of the subtracting stage 7 and the adding stage 6 is changed in such a way that the error of F i g. 3 is eliminated and the relationships according to FIG. 2 can be achieved. The magnitude of the manipulated variable 19 is the difference between the two signals SS, * and S * -S, in FIG. 3 proportional. It can be proven mathematically that with small displacements y it is also proportional to the angle y. When the signals Sv * and Sv are shifted by the angle y in the opposite direction, the manipulated variable 19 is correspondingly positive and again eliminates the shift y.

The manipulated variable at the output of the integrator 16 can also act directly on the delay line 8. The color carrier-frequency voltage S + S, * or S * + Sv at the output of the adder 6 can also serve as the color carrier for the synchronous demodulator 13, because this has the constant phase of the modulation axis U. It would then have to be shifted by 90 ° onto the phase of axis jV with a phase rotator. This solution has the advantage that, in the event of an error y, the phase of this color carrier frequency voltage changes by the same angle V / 2 as the color carrier frequency voltage SS, * or S * -S "and thus the phase between the signals SS, * or S * -S, and the reference carrier S + Sv * or S * + Sv used here is independent of the phase error y of the delay elements 8, 9. The manipulated variable controls e.g. 9 is used.

Claims (2)

Claims: 1. Control circuit to maintain the delay time in a delay time signal splitting circuit for a PAL color television receiver, in which the received modulated color carrier is added a color carrier with line-frequency mirror-inverted phase to the fixed modulation axis and then the modulated color carrier by addition and subtraction with the in a line delay line delayed modulated color carrier of the temporally preceding line is split into one of the fixed and one of the line frequency switched modulation axis corresponding color carrier frequency voltage, characterized in that the color carrier frequency voltage corresponding to the switched modulation axis (jV) (SS "*, S * -Sv) in a synchronous demodulator (13) is rectified by means of a color carrier with a phase corresponding to the switched modulation axis (jV) and the manipulated variable (18) obtained thereby via a time constant element (16) a time constant that is large compared to the line duration controls the delay time of the line delay line (8, 9) so that the color carrier frequency signals (S + Sv *, S * + Sv or S-Sv *, S * -S,) have the same amplitude in successive lines and have approximately the phase of the corresponding modulation axis (U or jV). 2. Control circuit according to claim 1, characterized in that the color carrier added to the modulated color carrier and the color carrier for the synchronous demodulator (13) are generated by the same color carrier oscillator (3) synchronized by transmitted color synchronous signals. 3. Control circuit according to claim 1, characterized in that the color carrier-frequency voltage obtained by the addition (S + Sv *, S * + Sv) is used as the color carrier for the synchronous demodulator (13). 4. Control circuit according to claim 1, characterized in that the manipulated variable (19) controls the transit time of an electronically controllable additional transit time line (9) lying in series with the line delay line (8). 5. Control circuit according to claim 4, characterized in that the manipulated variable (19) controls capacitance diodes of an electronically controllable phase shifter. Documents considered: German Patent No. 1175 731; Telefunken-Zeitung, 1964, H.1, p.63; radio mentor, 1964, H. 2, p. 113. Earlier patents considered: German Patent No. 1230 074.