DE1280290B - Circuit for synchronizing the line frequency switch in a color television receiver - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY GERMAN #KI PATENT OFFICE

EDITORIAL

Int. Cl .:

H04n

German class: 21 al - 34/31

Number:
File number:
Registration date:
Display day:

P 12 80 290.3-31 (T 30437)

February 11, 1966

17th October 1968

The invention relates to a synchronization circuit for the line frequency switch in a color television receiver for sequentially transmitted color signals of the PAL, SECAM or NIR type. Such color signal transmission takes place z. B. PAL, SECAM and in the so-called sequential NTSC (NIR), in which a quadrature modulated alternating from line to line Color carriers and a color sync signal are transmitted for the duration of one line. Receivers for such color television systems require a switch that turns on from line to line Color signal or a locally generated color carrier switches. It is known the burst to be dimensioned in such a way that it has a different characteristic from line to line, so that in the receiver a signal synchronizing the switch can be obtained from the color sync signal. A such a color synchronous signal with a phase switched from line to line is known under the name »alternating Burst «known. For the evaluation of the "alternating burst" in the receiver it is known that from the discriminator synchronizing the color subcarrier oscillator or from the mixture of two spectral lines from the frequency spectrum of the color sync signal a synchronization voltage for to derive the switch.

The invention is based on the object of a simple circuit for synchronizing the line frequency To create a switch that does without a locally generated color carrier.

The invention is based on a circuit for synchronizing the line-frequency switch in FIG a color television receiver of the PAL or SECAM or NIR type by means of a received Color synchronous signal made up of several color carrier oscillations, the phase of which is switched from line to line is.

A first alternative of the invention is that the received color sync signal sequence and a color sync signal sequence delayed by one line duration with respect to this sequence with insertion are fed to a mutual phase shift of a multiplication stage and the output voltage the multiplication stage after filtering out the color carrier frequency voltage components to the synchronization input of the line rate switch is supplied.

A second alternative of the invention is that the received color sync signal sequence is fed to a PAL signal splitting circuit and the voltages at the outputs of the adding stage and the subtracting stage of this circuit are switched on for synchronization
of the line rate switch
in a color television receiver

Applicant:
Telefunken

Patentverwertungsgesellschaft mb H.,
7900 Ulm, Elisabethenstr. 3

Named as inventor:

Dr. Walter Bruch, 3000 Hanover

addition of a mutual phase shift are fed to a multiplication stage or adding stage, their during the duration of the burst

The output voltage occurring after screening Color carrier frequency voltage components fed to the synchronization input of the line frequency switch is.

In order to explain the invention in more detail, several exemplary embodiments are provided below Hand of the drawings described.

F i g. 1 and 2 show the carrier-frequency color signals and color sync signals derived in the usual way from the composite color video signal. (B = burst = color sync signal at the beginning of each line, F = carrier-frequency color signal, K = identification pulses = color sync signals during the vertical utilization period, index 1 = lines with color sync signal phase 1, index 2 = lines with color sync signal phase 2).

3a and 3b are vector representations of the Color synchronizing signals of successive lines.

4, 6 show embodiments for the first and
Fig. 5 shows an embodiment for the second alternative of the invention.

4 shows a so-called delay time signal splitting circuit with a line delay line 1 to which the color carrier-frequency signal F ₁ , F _{% is} fed. The output voltage of the delay line 1 is fed, on the one hand, to an adder stage 2 and, on the other hand, to a subtracter stage 3, both of which also receive the undelayed signal.

809 627/1088

3 4

The output signals of stages 2, 3 arrive at 90 °, so the amplitude of the positive and negative is a decoder 4, which differentiates the color difference signals BY, pulses. At 45 ° the one pulse RY, GY is delivered. The undelayed color carrier zero. Behind the filter 8 there is also a low-pass filter that is not darfrequent, a gate 5, which is fed from the asymmetrical, the line-frequency gating pulses 6 5 metric signal a sawtooth half lines for the duration of the color sync signals B ₁ , B ₂ frequency or a sawtooth-like waveform is opened periodically. The undelayed, half line frequency makes, as is the case with the Gedem Tor 5 transmitted color sync signals B ₁ , the synchronization voltage for the switch B ₂ and the corresponding delayed color from the discriminator for the synchronization of the sync signals B ₂ , B ₁ from the output of the Time-of-flight io color subcarrier oscillator is known. Opposite the line 1 arrive at a multiplication stage M, known synchronizing circuits are not locally which supplies a pulse train 7 at their output which is required by the color carrier borrowed. The circuit can therefore also be used in decoders, which are not fed to a frequency switch, via a low-pass filter. In the way of needing such color carriers, z. B. for systems, the delayed (or the delayed) color synchronous 15 in every second line a color carrier of constant signals, a phase rotator 9 is arranged, which transmit the phase position (NIR). Another advantage phase of the instantaneous and delayed coloring of the invention is that synchronous signals are shifted from one another by 90 ° during transmission. of color sync signals only during the vertical are now color sync signals with return from line (so-called identification pulses) or with phase switched for ge to line received, either ao white time blanked color sync signals no at the beginning of each line (B1, BI in Fig. 1) or select Disturbances at the beginning and the end of the blanking entrend some lines in the vertical blanking time (Kl, stand. With the known addition and subtraction K2 in Fig.2), then by multiplication of the phase-switched direct color synchro and the delayed by a line duration results from chronologically successive lines th color sync signal sequence without the use of an AS by means of a delay line namely a low-frequency control pulse is created with the reference carrier - always at the beginning and at the end of the color sync sequence 7 with half the line frequency for the sync signal sequence if only one color sync signal is present at the line frequency (not shown) is a half amplitude signal. Either switch. This multiplication delivers, if the delayed sequence still contains a color synchronous multiplication stage M behind, the carrier-frequency 30 signal, while the undelayed sequence is already screened away for components that end directly, or in the undelayed sequence is at Befrequente pulse sequence 7, the pulses of Line already starts a color sync signal in which the polarity is reversed to line. This pulse-delayed sequence, however, does not. This acts in the sequence 7 can not be used directly to synchronize the circuit according to the invention, because it is used in switches. It can also be under 35 multiplication - as at the mention of the interposition of a of FIG said 6 to half of the blanking circuit -. For generating a horizontal frequency f _H / ² matched filter, for example, an output voltage is always both signals present at f _H / ² vibrating Resonance circuit 16, must be in.

sieved in a known manner and then to control the Fig. 5 shows a further embodiment for

Switch can be used. For the separation of the 40 the switch synchronization. This circuit is color sync signals from the entire color carrier - gate 5 is used both on PAL and on the above-mentioned sequential frequency signal. This gate can be used with the NTSC system (NIR). That also lie behind the multiplication stage M in FIG. The example provided is intended for PAL receivers, it is moderately inserted into a path of the two color The circuit contains a known transit time signal synchronization signal sequence; because during the 45 on saving circuit from a line delay line 1, time in which an adder 2 and a subtracter 3 are fed to the multiplication stage M. It is therefore not necessary for both signals 14 to be sampled with constant phase and at the output of the paths. The circuit described Subtrabierstufe 3 color sync signals 15 with from enables a particularly simple synchronization 50 line to line by 180 ° alternating phase. By circuit. It provides a synchronizing voltage to the 90 ° phase rotator 9, the color sync large amplitude, because the output voltage of the signals at the outputs of stages 2, 3, the same multiplication stage have the square of the input amplitudes, with the exception of the line frequency voltages is proportional. To multiply the polarity reversal of the color sync signals 15 at the output stage, a synchronous demodulator, a ring gear of stage 3, can be made in phase. They will be used as a demodulator or the like. If one of the _ is added in an adder 11 and after both color synchronous sequences of the multiplication insertion result one during the duration of the color level M with a much smaller amplitude, z. B. with synchronous signals opened gate 5 and an ampli-10% of the normal amplitude, or is tudengleichrichtersl3 (envelope rectification) one of the two sequences by a larger factor, 60 pulse train? with a positive pulse in every z. B. 10 amplified, then results at the output of the second line. Instead of the adding stage 11, a multiplication stage can be inserted into the amplitude change, a multiplication stage. Then a directly proportional signal, similar to the usual one, arises at its output from line to line multiplicative mixture. Each phase rotation in alternating positive, negative, and positive phase rotator9 results in the desired pulse sequence7, 65 pulse, as in FIG. 4. Gate 5 can then have a phase rotation of 90 ° before or after the multiplication stage. The positive and negative pulses of the pulse train 7 rectifier 13 are not needed in this case, the same amplitude. If the phase shift is not just a low-pass filter.

Claims (6)

Patent claims: 1. A circuit for synchronizing the line-frequency switch in a color television receiver of the PAL or SECAM or NIR type by means of a received color sync signal from several color carrier oscillations, the phase of which is switched from line to line, characterized in that the received color sync signal sequence (Bl, B 2 ) and a color sync signal sequence (B 2, Bi) delayed by one line length with respect to this sequence, with the insertion of a mutual phase shift (90 °), are fed to a multiplication stage (M) and the output voltage (7) of the multiplication stage (M) is fed to the synchronization input after filtering out color carrier-frequency voltage components of the line rate switch is supplied (F i g. 4, 6). 2. Circuit for synchronizing the line rate switch in a color television receiver of the PAL, SECAM or NIR type by means of a received color sync signal from several color carrier oscillations, whose phase is switched from line to line, characterized in that the received as Color sync signal sequence (Bl, B 2) of a PAL signal splitting circuit (1-2) and the voltages (14, 15) at the outputs of the adding stage (2) and the subtracting stage (3) of these Circuit with insertion of a mutual phase shift (90 °) of a multiplication stage or adder (11) are supplied, the Output voltage occurring during the duration of the color sync signal after screening color subcarrier-frequency voltage components to the synchronization input of the line-frequency switch is supplied (Fig. 5). 3. A circuit according to claim 1 or 2, characterized in that the introduced mutual Phase shift equal to the amount (90 °) of the line-frequency phase switch of the color sync signal (Bl, B 2) is. 4. Circuit according to claim 1 or 2, characterized in that the multiplication stage (M) a phase dependent rectifier, e.g. B. a synchronous demodulator or a ring demodulator is. 5. A circuit according to claim 1, characterized in that a color burst signal sequence (B 2, Bl) without and the other color sync signal sequence (Bl, B 2) together with the modulated Color carrier of the multiplication level (M). is supplied (Fig. 4). 6. A circuit according to claim 1 or 2, characterized in that the phase shift is so is dimensioned that at the output of the multiplication stage (M) or adder (11) a signal (7) is produced only in every second line. Considered publications:
Belgian patent specification No. 654 631;
radio mentor, 1965, no. 2, pp. 103 to 109. Legacy Patents Considered:
German Patent No. 1240 919. 1 sheet of drawings 809 627/1088 10.68 ® Bundesdruckerei Berlin