DE1260520B - Color television system with color sync signals for generating a reference carrier and line-frequency switching in the receiver - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

H04n

German KL: 21 al - 34/31

Number: 1 260 520

File number: T 25813 VIII a / 21 al

Filing date: March 13, 1964

Open date: February 8, 1968

The invention relates to a color television system with a color carrier consisting of several vibrations, for generating a reference carrier in the receiver serving color sync signals and line-frequency switching in the receiver. Such a line-frequency switching is for example in a SECAM color television system (German patent specification 1148 256) and in a PAL color television system (German patent specification 928 474) required. For the PAL color television system, there is a Receivers have been proposed in which the received color carrier freed from the phase modulation and is split into two color subcarrier-frequency color signals of constant phase. It is necessary to to generate a reference carrier for a demodulator which differs by 180 ° from line to line Phase has. In this case, line-frequency switching is necessary to adjust the phase of the reference carrier to change line frequency.

To synchronize such a line-frequency switching, it is known to use the line sync pulses to use. In addition, however, the correct switching phase of the switch must be determined. For this purpose, it is known that the distance between the last To take advantage of the line sync pulse from the first upstream. It is also already known (German patent specification 1164 466), the phase of the color burst signals transmitted in each line, for example to be changed briefly after each grid. It has also been proposed to use the burst signals to modulate the amplitude with an alternating voltage of low frequency and that Selective signal obtained by rectifying the dye sync signals for controlling the switch to take advantage of.

It is also known (US Pat. No. 2,735,886) to apply a first color sync signal with a constant phase at the beginning of each line to synchronize the reference carrier oscillator and to control a raster-frequency switchover in the receiver during the vertical blanking time with a second color sync signal with a phase switched from raster to raster transfer. However, this arrangement is not readily suitable for a system with a line-frequency switchover, because it would only be possible to monitor the switching phase of the line-frequency switch after a raster has elapsed. Apart from that, the switching phase would not be properly controlled because the second color burst continues with a constant phase over several lines during the vertical blanking time and color television system with color burst signals
for generating a reference carrier and a
line-frequency switching in the receiver

Applicant:
Telefunken

Patentverwertungsgesellschaft mb H.,
7900 Ulm, Elisabethenstr. 3

Named as inventor:
Walter Bruch, 3000 Hanover

In addition, a grid consists of an odd number of lines, so that after a grid has expired it is undesirable Way a change in the switching phase would be made.

The invention is based on the task of defining the switching phase of a line-frequency Changeover switch in the receiver by means of the color sync signals and the generation of a reference carrier with from line to line to simplify different phase.

It is also known in the case of a system with a periodically changed color sequence (USA. Patent 2 754 356) to switch the phase of the oscillations of a color sync signal periodically. Here will but not solved the double task of generating a reference carrier of constant phase in the receiver and to synchronize a line rate switch. The reference carrier oscillator in FIG Phase of the respective phase of the color sync signal.

The invention is based on a color television system of the last described type with a first one Color sync signal for generating a reference carrier of constant phase and a second color sync signal to control a periodic switching in the receiver and consists in that at a line-frequency switchover, both color sync signals are transmitted at the beginning of each line, namely successively or simultaneously with a phase shift of 90 ° to each other, and that the two color sync signals are separated from each other again in the receiver.

809 507/449

The second color sync signal can be demodulated, for example. The resulting square pulse, which occurs when the phase of this second signal is switched by 180 °, can be used directly for Control of a toggle switch can be used because 5 it has half the line frequency. On the other hand, can with a phase change of 180 °, the second color sync signal is directly entrained Control the oscillator, which then creates a reference carrier with a phase that differs by 180 ° from line to line generated, as required, for example, in the PAL color television receiver described above will. Each of the two color sync signals can therefore be evaluated on its own.

An advantage of the invention is that the switching phase of the switch in each line to correct value is brought. With the second oscillation component of the color sync pulse a reference carrier with a phase that differs by 180 ° from line to line can be generated directly. A Phase switch is then no longer necessary. Regardless of this, through the first component a reference carrier of constant phase can be generated.

The invention is explained in more detail below with reference to the drawings.

Figs. 1 and 2 each represent an embodiment of the color sync signal according to the invention;

3 shows a circuit for evaluating the color sync signal formed according to the invention;

Fig. 4 shows the application of the circuit of Fig. 3 to a signal of Fig. 1;

5 shows the basic circuit diagram of a demodulation circuit for a color television receiver for receiving the with the color sync signal according to the invention equipped PAL color television system.

In FIG. 1, the color sync signal 2 following the line sync pulse 1 is divided into two oscillation components 3 and 4 which follow one another in time. The component 3 has the same phase position in all lines and can be used in a known manner can be used to synchronize a reference carrier oscillator of constant phase. The component 4 has a phase which differs by 180 ° from line to line. They can either be rectified and used to control a line-frequency switch or directly to take along an oscillator are used, which then has a reference carrier with 180 ° different from line to line Phase generated. Since 20% of the line duration is generally available for the line return, both components 3, 4 can be timed so long that each of the two components perfect synchronization of an oscillator is possible.

In Fig. 2, the color sync signal 2 consists of two simultaneously present, at 90 ° to each other offset oscillation components 3, 4, which are composed to form the resulting color sync signal 2. The vibration component 3 in turn has the same phase in all lines while the oscillation component 4 is switched from line to line by 180 °, so that in every second line a phase-switched color sync signal 2 'arises.

In Fig. 3 a line period, the color burst signals are added 2 and 2 'two chronologically successive lines of FIG. 2 in an adder 6 by means of a delay line 5 with the delay time. As a result, an oscillation 3 with a constant phase occurs in each row at output terminal 7. In a subtraction stage 8, the color sync signals 2 and 2 'of two temporally successive lines are subtracted. This creates vibrations 4 at a terminal 9 with a phase that differs by 180 ° from line to line.

FIG. 4 shows the application of the circuit according to FIG. 3 to a signal according to FIG. 1. At terminal 7 are the vibrations 3 with a phase that is constant from line to line, because they coincide in time Components 4 of the successive lines cancel each other out because of their different polarity. The components 3 cancel each other out at the terminal 9, and vibrations 4 are also generated phase differing by 180 ° from line to line. For the evaluation of the color sync signal according to 1, however, a delay line 5 according to FIG. 3 is not absolutely necessary. The separation of the components 3, 4 can also be carried out by blanking pulses that correspond in time to the components 3 and 4 correspond. This solution can be advantageous for a SECAM receiver because here the Delay line is not phase accurate enough for an exact delay.

5 shows the application of the invention for a receiver for the PAL color television system in which a color carrier with two color signals is quadrature modulated according to two modulation axes and one modulation axis is switched by 180 ° at a line rate. The receiving modulated color carrier is available at a terminal 10 together with the color sync signal formed according to the invention according to FIG. 1 or 2. By means of a delay line 5, the received signals of two consecutive lines are added in an adding stage 6. At the output of the adder 6, the color signal Q ' corresponding to the axis that has not been switched arises in the form of a color carrier frequency. With a blanking stage 11, which is only open during the line trace time, the color sync signal is suppressed. The output signal of the blanking stage 11 is fed to a demodulator 12. The demodulator 12, on the other hand, receives the reference carrier with the constant phase Q from a reference carrier oscillator 13. The video-frequency color signal Q " is thus available at an output terminal 14 of the demodulator 12. In a similar way, the color carrier-frequency signal / 'with from line to line of different polarity and freed of the color sync signals in a blanking stage IS. The output signal of blanking stage 15 is fed to a demodulator 16, which on the other hand receives a reference carrier from a reference carrier oscillator 17 with a phase + / 'and - Γ different from line to line. An an output terminal 18 is thus the video-frequency color signal / "available.

The synchronization of the reference carrier oscillators 13, 17 with the aid of those designed according to the invention Color burst occurs in the following way:

At the output of the adder 6, as shown in FIG. 3 or 4, the components 3 are constantly constant Phase available. These are activated with a blanking level 19, which is only available for the duration of the Sync signal is open, removed and

is supplied to the reference carrier oscillator 13 via a line 20. They ensure that the reference carrier oscillator 13 always oscillates with the correct phase Q 'at the beginning of a line. The output voltages Q ' and /' of the two blanking stages 11, 15, which have only two defined phase positions (O and π) , are fed to a circuit 21. In the circuit 21, the color carrier-frequency signals are brought to the same phase and, for example, doubled in frequency by double rectifiers and thus freed from 180 ° phase jumps. At the output of the circuit 21 there is thus a signal which has a constant phase. This signal is fed to the reference carrier oscillator 13 and is used to finely synchronize the phase of the line trace, which is roughly set during the color sync signal. A 180 ° phase jump in one of the signals / 'or Q' or in both of these signals has no effect on the phase of the oscillation generated in the reference carrier oscillator 13 (German patents 1 189 124, 1 196 700, 1 197 500).

The components 4 at the output of the subtraction stage 8 according to FIG. 3 with a phase different from line to line by 180 ° are separated out with a blanking stage 22, which is only open for the duration of the color sync signals, and fed to the reference carrier oscillator 17. They ensure that the reference carrier oscillator 17 oscillates in the desired manner with a phase that differs by 180 ° from line to line. The fine synchronization of the reference carrier oscillator 17 also takes place during the line trace from the circuit 21. At the output of the reference carrier oscillator 17 there is thus a reference carrier switched from line to line by 180 ° in phase. In this circuit, the color sync signal designed according to the invention is used to generate a reference carrier which, as desired, has a phase which differs by 180 ° from line to line. At the same time it is ensured that the switching phase is correct, ie that the reference carrier generated by the oscillator 17 has the correct one of the two possible phase positions (O and π) in a certain line.

A color synchronizing signal designed according to the invention can also be used for synchronizing a quartz oscillator without using a delay line, if this only has a sufficiently high quality. A reference carrier then arises, the phase of which lies approximately in the middle between the phases of the two oscillation components of the color synchronous signal. It is also possible, in the color sync signal according to FIG. 1, to sample out only the oscillation component 3 with a blanking pulse and to synchronize a quartz oscillator with it. It is also possible to control a quartz oscillator with the oscillation component 3 and to synchronize a second oscillator from this via a phase rotation element, which is switched line-frequency by the oscillation component 4, which then generates a reference carrier with a different phase from line to line. The production of the color sync signals according to the invention in the transmitter is particularly simple because modulators for the axes / 'and Q' are already available.

Claims (7)

Patent claims: 1. Color television system with a first, consisting of several vibrations of a color carrier The burst signal transmitted at the beginning of each line has a constant phase and serves to synchronize a reference carrier oscillator in the receiver, and a second Color sync signal that has a periodically switched phase and is used to control a corresponding periodic switching in the receiver is used, characterized in that that with a line-frequency switch, both color sync signals (3, 4) at the beginning each line are transmitted, in time one after the other or simultaneously with a phase shift of 90 ° to each other, and that the two color sync signals (3, 4) are again separated from each other in the receiver. 2. Color television system according to claim 1, characterized in that the phase of the second Component (4) is switched line frequency by 180 °. 3. Color television system according to claim 1, characterized in that in the receiver the first component (3) is used to generate a reference carrier of constant phase (Q ') and the second component (4) is used to generate a reference carrier with phase different from line to line. 4. Color television system according to claim 1, characterized in that in the receiver the color sync signals of two consecutive lines are added in an adder (6) and subtracted in a subtracter (8) so that at the output of the adder (6) a first oscillation with a constant Phase (O) and at the output of the subtraction stage (8) a second oscillation (+ / ')' with a phase that differs by 180 ° from line to line occurs (Fig. 3, 5). 5. Color television system according to claim 2, characterized in that with the second component (4) a driving oscillator (17) serving to generate a reference carrier is controlled which generates a reference carrier (+ / ') with a phase that differs from line to line (FIG. 5). 6. Color television system according to claim 4, characterized in that the second oscillation (+ / ') rectified and used to synchronize a line-frequency switch will. 7. Color television system according to claim 1, wherein a color carrier with two color signals after two modulation axes quadrature modulated and one modulation axis line-frequency by 180 ° is switched (PAL), characterized in that the phase of the color sync signals between the two modulation axes and is a mirror image of the one that has not been switched from line to line Modulation axis is switched (Fig. 2). Considered publications:
German Patent Nos. 928 474, 1 148 256; U.S. Patent Nos. 2,735,886, 2,754,356. Legacy Patents Considered:
German Patent No. 1 164 466. 1 sheet of drawings 809 507/449 1.68 © Bundesdruckerei Berlin