DE2361563A1 - Time errors correcting cct. esp. video recorder signals - has controllable delay line in signal path - Google Patents

Abstract

The delay line is electronically controlled so that its delay time can be varied by a control signal representing the error, by a value delta T, starting from a value To. The control signal amplification is adjusted by a control circuit to the minimum of the curve which represents the residual delay error at the delay line output as a function of this gain. An a.c. voltage is applied to the control input of an amplifier is obtained by comparison of this a.c. voltage with the resultant a.c. voltage at the delay line output.

Description

Licentia Patent Verwaltungs-GmbH 6 Frankfurt / Main 70, Theodor-Stern-Kai 1.

Hanover, November 22nd, 1973 PT-Wp / gn H 73/88

Circuit to compensate for timing errors in a television signal, in particular from a recording device

A television signal received from a recording device, e.g. Magnetic tape or an optical disc, is known to be subject to timing errors caused by fluctuations in speed or changes in shape of the recording medium arise.

It is known to compensate for such time errors (DT-PS 1 014 an electronically controllable delay line in the signal path to turn on. By phase comparison of the faulty signal separated line sync pulses with constant line sync pulses a manipulated variable representing the time error is obtained, the running time of the delay line starting from a fixed base runtime changes to compensate for time errors. If e.g. the line duration of the signal is short, the running time is increased and the signal back to the correct value of the line duration; stretched.

The delay line in the path of the useful signal has a basic delay so that the delay is both positive and negative Direction can be changed canoe. In addition, the manipulated variable is in the way a certain delay is effective because the manipulated variable is only one

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can arise for a certain time after the error has occurred. The delay in the path of the manipulated variable is about half the length of a line. The basic runtime of the delay line is, however, in general lower. Because of this difference in the delay times the manipulated variable at the control input of the delay line does not take effect at the optimal point in time, but too late. The effect of this is that, at least at certain frequencies, the time error is not an optimal time error compensation achieved; will.

A transit time line with a correspondingly higher basic transit time, which is adapted to the delay time in the way of the manipulated variable means an additional effort for the delay line and brings with it unnecessary signal loss and signal distortion.

In an application filed at the same time, it was also suggested that to adapt the in the way of the Uutzsignals and in the way of the Actuating variable effective delay times to switch on an additional delay element in one of the ways. Such a delay element must have a relatively long delay time in many cases.

The invention is based on the object ^ the above time error recovery is not optimal for certain conditions without adding an additional delay to one of the paths.

This object is achieved by the invention described in claim 1. Advantageous embodiments of the invention are in the Subclaims specified.

The invention is based on the following knowledge. At the output dex * to the "Zeltfehlexausgloich serving transit time line in the V / tg des

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ORIGINAL

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Due to a time error in the original signal, a residual time error A. Time error A has a pronounced minimum at a certain optimal gain V. The position of this curve and thus the value of V _Q is, however, dependent on various parameters, for example on the frequencies of the time errors. It is therefore not possible to set the gain of the manipulated variable to an optimal value.

Based on this knowledge, according to the invention, the Gain of the manipulated variable is always regulated automatically so that the circuit works at the minimum of said curve A = f (V). Then the remaining time error becomes different even with fluctuations Parameters are always regulated to a minimum without any additional Delay in the path of the useful signal is required. The curve ■ A = f (V) can be determined mathematically or by measurement as the basis for the design of the circuit.

The invention is illustrated using the drawing using an exemplary embodiment explained. Show in it

1 shows a block diagram of the invention and FIG. 2 shows curves to explain the mode of operation.

In FIG. 1, a video signal 1 with Zei3.ensynchronimpulsen 2, which is afflicted with timing errors, is supplied from a terminal 3 to a controllable delay line 4 ·. Line 4 has a basic transit time '' C ''. A manipulated variable U _ß p, which represents the time error, changes the running time f by + δΤΓ to compensate for the time error. This produces a video signal I ¹ at a terminal 5, which has a reduced residual time error A.

The manipulated variable Ug ^ is obtained in the following way. With a

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Separation stage 6, the line sync pulses 2 are separated from the video signal 1 and fed to a phase comparison stage 7. This is also fed by a generator 8 synchronizing pulses with a constant frequency. _{A manipulated variable ü g} / i is obtained by phase comparison in stage 7, which represents the time error in signal 1. The generator 8 is preferably adjusted to the mean frequency of the line sync pulses 2 in the signal 1 via a control circuit. The manipulated variable Ug ^ reaches the delay line 4 via an amplifier 9 with controllable amplification as a manipulated variable Ug2.

2 shows the mathematically determined dependency of the residual error A in signal 1 'at terminal 5 from the amplification V des Amplifier 9 in the form of a characteristic curve 11. It can be seen that this curve has a pronounced minimum 10 at an optimal gain V.

According to the invention, the gain V is now with a control voltage U-D always regulated to the minimum 10, i.e. to the value V A fixed setting of V is not possible because curve 11 changes depending on various parameters, e.g. Depending on the frequency and the size of the time error, V shifts in the direction of the abscissa.

The control voltage Un is shown in Fig. 1 by an auxiliary circuit won. This works as follows. An alternating voltage 13 generated in a generator 12 is in an adder 14 of Control voltage Up is added and thus reaches the control input of the amplifier 9 · The frequency of this auxiliary voltage must considerably lower than the line frequency and selected in such a way that it is not commensurate with it. To not as Stork fluctuation should not appear in the picture either Be a multiple of 50 Hz. Generated on the basis of dex ^ characteristic curve 11 this alternating voltage 13 at terminal 5 has a corresponding one

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AC voltage 15. The voltages 13, 15 are a comparison stage 16 supplied, the control voltage via a low-pass filter 17 U-O delivers. . "- ■ -..... '

If, for example, the circuit initially works at operating point 18, so by combining the in-phase voltages 13, ' 15 a positive control voltage U "obtained. This control voltage causes the gain at the control input of the amplifier 9 to be reduced in the direction of arrow 19 until the minimum 10 is almost reached. Does the circuit work first at point 20, the tensions 13i 15 are due the opposite slope of the characteristic curve 11 opposite. The stage 16 now delivers a negative one via the low-pass filter 17 Control voltage Up. This increases the gain V in the direction of the arrow 21 so that the minimum 10 is again approximated. The control circuit thus operates in such a way that, given a constant amplitude of the alternating voltage 13, a minimum amplitude of the voltage 1-5 "is set at the terminal 5. The means according to the characteristic curve 11 a minimal residual time error A in. Signal 1 '. If now by changing parameters the characteristic curve 11 in Fig. 2 shifts in the direction of the axis V, so the rule management works again so that this is now also shifted minimum 10 is set. Through this, that the circuit always automatically sets the minimum 10, that is to say the minimum remaining time error A, is over wide limits the timing error, especially over a wide frequency range the time error, a good compensation of the time error is achieved. The voltage 15 is frequency-selective with a filter; 22 the overall signal at terminal 5 is evaluated ■ ·.

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Claims (2)

- 6 - H 73/88 Claims Circuit is changed by a value + δΊΓ to compensate for time errors in a television signal, in particular by a recording apparatus, with a lying in the signal path, electronically controllable delay line, the duration of time, starting by the error representing the manipulated variable from a basic run '"£", characterized characterized in that the gain of the manipulated variable (Ug) is controlled by a control circuit to the minimum .. (10) of the curve (11), the dependence of the remaining time error (A) occurring at the output of the delay line (4-) on this Represents gain (V). 2. A circuit according to claim 1, characterized in that an alternating voltage (13) is also applied to the control input of an amplifier (9) for the manipulated variable (Uo), and that the control voltage (U _R ) for the amplifier by comparing this alternating voltage ( 13) with the resulting alternating voltage (15) at the output of the delay line (4 ·) is obtained. 3. Circuit according to Claim 2, characterized in that the two alternating voltages are added and rectified (steps 16, I7 in Fig. 2). 509824/0787