DE1196700B - Color television receiver with a color demodulator - Google Patents

Description

Color television receiver with a color demodulator Addition for registration: T 23980 VIII a / 21 a1 - Auslegeschrift 1 189 124 The main patent application T 23980 VIIIa / 21at relates to a color television receiver with a color modulator for demodulation color subcarrier-frequency signals, to which at least one with only one color signal suppressed carrier amplitude-modulated signal occurs whose phase is only two has defined positions, and with a local oscillator for generating a color carrier frequency Reference carrier for the demodulation, which consists of color sync signals some oscillations of color subcarrier frequency at the beginning of each line, synchronized especially for signals of the NTSC-PAL or SECAM-AM system.

The invention according to the main patent application is that for Adjustment of the coarse phase or the polarity of the generated in the local oscillator Reference carrier to the oscillator, the color sync signals are fed and that for Setting the exact phase of the reference carrier generated in the oscillator the received Color carrier-frequency signals are used after these from the phase jumps have been released.

The inventor has already proposed elsewhere in to bring two color carrier-frequency signals both to the same phase and their sum for fine control of the phase of the reference carrier. This solution has the advantage that the color carrier-frequency signal used for fine adjustment of the phase also then is present when one of the two color carrier frequency signals is zero.

The present invention is based on the object of synchronization of the reference carrier oscillator with the two color carrier frequencies brought to the same phase Signals and the color sync pulse in a particularly simple and advantageous way perform.

The invention consists in that both the brought to the same phase color carrier-frequency signals as well as the color sync pulses through the oscillator synchronize direct pick-up.

The oscillator is activated by the color sync pulse at the beginning of a line taken with the right phase. During the line, the two then take over color carrier frequency signals the further precise phase control of the by the color sync pulse in the roughly adjusted reference carrier phase.

In an embodiment of the invention in which the color carrier frequencies Signals are offset from one another by 900 and before being fed to the oscillator in Push-pull stages implemented with diodes to double the color subcarrier frequency and thereby are freed from 180 ° jumps, the diodes in the first push-pull stage polarized differently than the diodes in the second push-pull stage. That way will achieved that the signals obtained to control the oscillator with double Color carrier frequency have the same phase.

A major advantage of the invention is that in place of the expensive crystal oscillator previously used, a simple LC oscillator is used since a control signal for the oscillator is available at any moment is. The structure of the oscillator is also particularly simple because all three Synchronization signals can be fed to the same point of the oscillator.

The invention is described below with reference to the drawing on a receiver for a so-called PAL color television signal.

F i g. 1 shows a block diagram for the synchronization of the Reference carrier oscillator; F i g. 2 shows a practically implemented circuit of the Reference carrier oscillator; in Fig. 3 is explained in more detail how the two color carrier firequenten Signals are brought to the same phase.

In Fig. 1, using a delay line 1 in a subtracter 3 and an adder 4 the difference and the sum of the in successive lines received conjugate complex modulated Color carrier frequency signals of the form Q 'cos w0t +1' sin o and cos cos m0 t-I ' sin w0 t is formed. This creates alternating 3 at the output of the subtraction stage the signal +21 'sin cvDt and -21'sinw0t and at the output of the adder 4 constantly the signal + 2 Q cos w0 t.

These two color carrier frequencies, each amplitude-modulated with only one color signal Signals are fed to two synchronous demodulators 15, 16, which are connected to terminals 5, 6 supply the low-frequency color signals 21 and 2 Q '. The synchronous modulator 15 is the reference carrier generated in the oscillator 12 via a line 16 and a line frequency Reversing switch 17 supplied. According to the phase position of the two color carrier frequencies Signals at the outputs of stages 3 and 4 become the reference carrier of the synchronous demodulator 16 is supplied via a 900-phase rotating element 18. From the received color carrier frequency Signal are generated by line-frequency pulses 19 in a gate circuit 13 color sync pulses 35 sampled out, in a phase shift member 20 with a phase shift of 570 brought the phase of the signal 1 'sin w0 t at the output of the subtracter 3 and A terminal 21 of the reference carrier oscillator 12 is supplied via a line 14.

These color sync pulses 35 are used in direct entrainment between the lines the coarse phase (0 or n) of the reference carrier generated by the oscillator 12 to adjust. The output signals of stages 3 and 4 become two push-pull stages 7, 8 supplied with diodes 24, 25 and thereby converted to double the color carrier frequency and at the same time freed from 180 ° phase jumps. The output signals of the push-pull stages 8, 7 are applied to terminals 22, 23 of the oscillator 12 and are used during of the lines to set the exact phase of the reference carrier generated in the oscillator 12. The entrainment signals for the color carrier oscillator 12 obtained from l 'and Q' have although double color subcarrier frequency.

However, it is easily possible to use one tuned to a frequency Oscillator with a control signal of double frequency 2f on the frequency! to trace. The 900 phase difference between the two signals 21 'sin w0 t and 2 Q' cos w0 t at the output of the stages 3, 4 is eliminated by the fact that the diodes 24 of the push-pull stage 7 are polarized differently than the diodes 25 of the push-pull stage 8. The color sync pulses at terminal 21 and the color carrier frequency signals at terminals 22 and 23, which have a constant phase that is independent of the modulation, synchronize the Oscillator 12 in direct entrainment.

In Fig. 2 is a circuit for the oscillator 12 shown. The oscillator contains a transistor 26 with an oscillating circuit 27 in the collector circuit. A voltage is taken from the resonant circuit 27 via a kawzitive voltage divider and coupled into the emitter circuit of transistor 26 via a feedback path 28. The base of the transistor 26 is connected via the series connection of a capacitor 29 and a resistor 30 grounded. The terminals 21, 22, 23 are via decoupling resistors 31 connected to the connection point 34 of the capacitor 29 with the resistor 30. The synchronization signals at terminals 21, 22, 23 are thus sent to the same circuit point 34 of the oscillator 12. The oscillator is carried along Consequently in the base circuit of the transistor 26, while the oscillator itself by a Feedback on its emitter is made to oscillate. The capacitor 29 has for example a value of 68 nF and the resistor 30 a value of 100 Ω.

On the basis of FIG. 3 explains how the color subcarrier frequencies offset by 900 Signals l 'sin w0 t and cos w0 t at the output of stages 3, 4 so on the same phase are brought that they are used to regulate the phase of the reference carrier generated in the oscillator 12 can be used. For this purpose, the diodes 24, 25 are in the push-pull stages 7 and 8 polarized opposite. In Fig. 3 a is turned off by the push-pull stage 7 the signal Q 'cos co0 t a signal 32 obtained that of 1800 phase jumps in the signal Q 'is free and its negative peaks at times tl, t2, t3 and t4 Has. In FIG. 3b, the signal is offset by 900 with respect to the signal Q 'cos w0 t I'sincs0t is converted in the push-pull stage 8 to a signal 33, which is also doubled Has color subcarrier frequency and is exempt from 1,800 phase jumps. This signal 33 also has its negative peak values at times t 1, t2, t3, t 4.

It can thus be seen that if, for example, these voltage spikes at times tl, t3 or t2, t4 are used to entrain the oscillator 12, the synchronizing signals at the oscillator 12 at the terminals 22, 23 are the same Have phase.

To get the two color carrier frequency signals 1 'sin w0 t and Q' cos o) To bring 0 t to the same phase, no 900-phase rotating element is necessary.

Claims (5)

Claims: 1. Color television receiver with a color demodulator, on which two amplitude-modulated with one color signal each with suppressed carrier Signals occur and with a local oscillator to generate a color subcarrier frequency Reference carrier whose rough phase or Polarity through additionally transmitted color sync pulses and its Fine phase is determined by the color subcarrier-frequency signals themselves, according to patent application T 23980 VIII a / 21 a1, d a - characterized in that both the on the same phase brought color carrier frequency signals (1 'sin w0 t, Q' cos w, t) as well as the Color synchronizing pulses (35) synchronize the oscillator (12) by direct entrainment. 2. Color television receiver according to claim 1, characterized in that that the oscillator (12) is an LC oscillator. 3. Color television receiver according to claim 2, characterized in that that the oscillator (12) has a transistor (26) in common base with a feedback (283 contains on the emitter, and that the color carrier-frequency signals (I'sinw, t, Q 'cos co0 t) and the color sync pulses (35) are coupled into the base circuit (29, 30) will. 4. Color television receiver according to claim 1, characterized in that that the two color carrier frequency signals (1 'sin c90 t, Q' cos w, t) and the Color sync pulses (35) to the same circuit point (34) of the oscillator (12) be guided. 5. A color television receiver according to claim 1, wherein the color carrier frequencies Signals are offset by 900, characterized in that the color subcarrier frequencies Signals (1 'sin w0 t, Q' cos w0 t) before being fed to the oscillator (12) in push-pull stages (7, 8) with diodes (24, 25) to double the color carrier frequency implemented and thereby freed from 180 ° phase jumps and that the diodes (24) in the first push-pull stage (7) are polarized differently than the diodes (25) in the second push-pull stage (8), so that the negative and positive peaks of the obtained signals (32,33) double color subcarrier frequency same phase ttl, t2, t3, t4) have.