DE2008956A1 - Circuit for eliminating time errors in a chrominance signal - Google Patents

Description

Circuit for eliminating timing errors in a chrominance signal Bei the transmission of a composite color video signal, which is a chrominance signal with a frequency of color subcarriers contains, timing errors can often occur in the chrominance signal. For the NTSC or PAL color TV signal Such time errors result in a falsification of the hue or the color saturation the end.

Such time errors can occur, for example, in scattering reception via satellites through the Doppler effect or when recording the color television signal on a recording device due to fluctuations in the speed of the recording medium (Magnetic tape) occur, To eliminate these errors it is for a recording device known (DT-PS 1 239 723), the blue beard signal preferably together with the rest BAS signal via an electronically controllable delay line. the period this line is controlled by a control voltage obtained by phase comparison of the color sync signal coming from the recording device with a color carrier more constant Phase is won. This circuit can also be used with the PAL signal by adding the Phase of the color sync signal coming from the band or of the unmodulated color subcarrier is switched line-frequency.

It is also known that the chrominance signal coming off the tape with a To demodulate the color carrier, the 3-arbsynchro signals coming from the tape is synchronized and thus follows the phase fluctuations of the chrominance signal, and the obtained color signals a new color carrier of the exact phase to modulate. However, this solution requires demodulation and no-modulation.

The invention relates to a simple circuit with which the described Time errors (frequency and phase errors) of the chrominance signal without demodulation and Remodulation can be eliminated. The invention consists in the claims marked measure, An advantage of the invention is that the at demodulation and remodulation of the chrominance signal and the increased circuit complexity can be avoided. In the solution according to the invention the fact that the reference frequency of the chrominance signal with the reference line frequency is used is coupled via a constant factor k. This coupling is common to all color television systems necessary for reasons of compatibility. The coupling can be e.g. a Gaazzeilenversa-tz (k integer n), a half-line offset (k = n + 1/2) or a quarter-line offset (k = n + 1/4) or a quarter line offset with an additional 25 Hz offset (PÄL) be.

The invention is illustrated below with reference to the drawing using the example of a w drawing device explained. 1 shows a block diagram of the invention, 2, 3 each shows a circuit example for the coupling between the line frequency and the pilot frequency. In the figures, the frequencies are on the individual lines of the fi signal that occurs in each case. Here f0 mean the setpoint frequency of the Chrominance signal, i.e. of the unmodulated color carrier k: coupling factor between f0 and fH #f: Frequency error in the line frequency fH: Target line frequency F: Chrominance signal In FIG. 1, this is done by a recording device 7 Coming composite color video signal with a low pass filter 2 and only the chrominance signal Passing bandpass filter 3 splits into the signals BAS and F The BAS signal arrives Via a delay element 4 serving for delay compensation to an adder 5, at its output terminal 6 a composite video signal with a corrected chrominance signal Fk is stationary The chrominance signal F from the output of the bandpass filter 3 has due to a fluctuation in speed of the recording device 1 the frequency f0 + k # #f and arrives in this form a Modulator 7 With a separation stage 8, the FBAS signal is used to generate the line sync pulses 9 separated with the frequency fH + # f and in a frequency multiplier 10 on the Frequency k. (fH + #f) = f0 + k # #f implemented and in this form a modulator 11 supplied. In a crystal oscillator that oscillates at a constant frequency f0 12 a normal frequency f0 is generated and in the modulator 11 with the frequency f0 + k. " f mixed. The voltage with frequency 2 is derived from the modulation product f0 + k # #f added to the modulator 7. From the modulation product at the output of the Modulator 7, the component with the frequency f0 + k # #f - (f0 + k # #f) = f0 is screened out and fed to the editing stage 5. This latter component F (f0) is a chrominance signal with the correct frequency f0, in the adder 5 is the BAS signal again a chrominance signal with the corrected frequency f0 is added, whereby the corrected Signal FkBAS arises.

Fig. 2 shows a circuit with which the conversion of the frequency fH + »f to the frequency f0 + k ## f according to FIG. 1 takes place.

The oscillator 14, which can be regulated via a dummy stage 13, is set to the frequency f0, the frequency f0 is the frequency of the PAL color carrier. flit a stage 15, which cancels the 25 Hz offset of the PAL color subcarrier, and a quarter line offset divider 16 the frequency fo + k. # F with the division factor k to the frequency fH + au implemented and fed to a phase comparison stage 17 in this form. This receives also the line sync pulses 9o The one won at level 17 Control voltage UR acts on the dummy stage 13 in such a way that the line sync pulses 9 and the voltage from divider 16 at the inputs of stage 17 have the same frequency and have phase. This means that the oscillator 14 generates a pilot voltage, whose frequency is greater than the frequency fH + #f by a factor of k. The rest of the way it works the circuit is the same as in FIG. 1.

In Fig. 3, the pilot carrier is at the frequency f0 + k .Z f in the Oscillator 14 is generated, which is regulated with a control voltage UR, the control voltage UR is obtained in a phase comparison stage 18, the voltage with the output of the oscillator 14 and the color sync signals 19 of the composite signal is controlled. The color sync signals are connected to a gate 20, which is driven by line-frequency pulses 21 is permeable during the line retrace time, gated from the BBAS signal. Since the color sync signals 19 contain the frequency f0 + k # #f and with the repetition frequency fH + #f appear, the oscillator 14 supplies a pilot voltage through the control circuit with the frequency f0 + k # #f, which is further processed as in Fig. 1 for the Generation of the pilot voltage from the composite signal coming from the tape can be known Circuits used to couple a color subcarrier frequency with the line frequency will.

The factor k does not need to be an integer. The PAL system is he z0B. equal to 283.75 if one disregards the additional 25 Hz offset. At the Half-line offset is e.g. k = 283.5. The invention is also applicable when the Frequency of the recorded color carrier is reduced, i.e. e.g. a RAL color carrier is recorded at the halved frequency of 2.2 MHz. The invention is at NDSC, SECAM and also PAL can be used. The normal frequency f0, which in the oscillator 12 can also be a multiple of f0. It is essential that from a line rate voltage coming from the recorder is the frequency error containing color carrier frequency voltage derived and under addition a voltage with a fixed frequency to a frequency conversion of the color carrier Elimination of the frequency error is processed. It may be appropriate to use circuit means provide which prevent the frequency k. (fH + f) of the pilot voltage a frequency offset by the line frequency, e.g. (k # 1). (fH + #f) remains.

Claims (7)

P a t e n t a n s p r ü c h e 1. Circuit for eliminating timing errors in, for example, one Color television recording device taken from chrominance signal, whose setpoint frequency fO with the target line frequency f11 according to the relationship f0 = k. fit coupled and with a Pehlerbf in the line frequency has the value k # (fH + #f), characterized in that, that from a voltage taken from the signal and containing the line period (9,19) a pilot voltage with the frequency fp = k (fH + #f) is derived (steps 10; 13-18) that the pilot voltage by mixing with a normal frequency fO = k. fH converted to a correction voltage with the frequency 2 k fH + kgf and the faulty one Chroma signal (F) with the correction voltage to form an error-free chrominance signal (Fk) is implemented with the frequency fO = k ¢ fit. 2. Circuit according to claim 1, characterized in that as the Line period containing voltage is the line sync pulse separated from signal aL (9) serves 3. A circuit according to claim 1, characterized in that as the line period containing voltage, the color sync signal (19) separated from the signal is used. 4. Scha'tung according to claim 2, characterized in that the line sync pulses (9) implemented in a frequency multiplier (10) with the factor k on the pilot voltage (Fig. 1). 5. A circuit according to claim 2, characterized in that the pilot voltage is generated in an oscillator (14), which is controlled by a control voltage (UR) is controlled by phase comparison of the line sync pulses (9) with a voltage obtained by dividing the pilot frequency by the factor k is generated (Fig. 2). 6. A circuit according to claim 3, characterized in that the pilot voltage is generated in an oscillator (14) which is controlled by a control voltage (UR) is obtained by phase comparison of the color burst signal taken from the recording device (1) (19) with the pilot voltage is generated (Fig. 3), 7. Circuit according to claim 1, characterized in that circuit means are provided which prevent the frequency of the pilot voltage to a frequency offset by the line frequency fH turns L e r s e i t e