DE1278490B - Demodulation circuit for signals of a color television system of the PAL type - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY GERMAN WTWW ^ PATENT OFFICE Int. CL:

H04n

EDITORIAL

German class: 21 al -34/31

Number: 1278 490

File number: P 12 78 490.6-31 (T 30442)

Filing date: February 12, 1966

Opening day: September 26, 1968

The invention relates to a demodulation circuit for signals of an NTSC system with a line frequency Switching a modulation axis (NTSC-PAL).

For an NTSC system with line-frequency switching of a modulation axis, there is a runtime signal splitting circuit known, in which the color subcarrier-frequency signals of two consecutive Lines are constantly added in one adding stage and constantly subtracted in a second adding stage will. Because of the switchover, those after the modulation axes are created at the outputs of these adding stages separate color carrier frequency signals or carriers. These color carrier-frequency signals the color carrier restored at the receiver is added at the output of both adder stages. It is also already known, in such delay-time signal splitting circuits, the color subcarrier in front of this circuit to superimpose the color carrier signal additively, in such a way that the color carrier before the addition is switched line-frequency in the phase. In this way it became possible to demodulate to be achieved by simple amplitude rectification.

In the past, this was the case with such an addition of the color subcarrier, which has been switched in the phase at a line frequency difficult to connect the color stages with direct current coupling to the demodulator, because with the simple diode rectifiers the color carrier results in a DC voltage component, which in individual Color signals have different sizes and polarities because of the different matrixing. In this known circuit, it was also not previously possible to use an inexpensive passive carrier regenerator to use the amplitude of which is not constant between the bursts and also of the amplitude of the burst signal vote etc. is dependent, because this too is the DC component would affect.

The invention is based on the object of creating a demodulation circuit in which the described Disadvantages are avoided.

The invention is that the resulting in the color demodulators, by the added Tension components caused by the color carrier are compensated for by corresponding counter-tension, which are derived from the color carrier regenerator 3.

To explain the invention in more detail, an exemplary embodiment is shown below with reference to the Drawing described in more detail. This shows a demodulation circuit in which the color carrier frequency Color television signal without carrier via a bandpass

Demodulation circuit for signals of a
PAL type color television system

Applicant:
Telefunken

Patentverwertungsgesellschaft mb H.,
7900 Ulm, Elisabethenstr. 3

Named as inventor:

Dipl.-Ing. Werner Scholz, 3000 Hanover

filter 1 for the color signal to the base of an addition transistor 2 arrives, which also transfers the color carrier generated in a color carrier regenerator 3 a switchable phase shift member 4 is supplied, which z. B. from a half-line frequency square wave voltage 5 is controlled. The color subcarrier can match the color subcarrier frequency signal at each circuit point be added in front of the rectifier. The color carrier regenerator 3 is from the color sync signals phase-synchronized to the frequency of the color carrier. The tube 3 can also be a Be the amplifier and limiter tube of a passive color carrier regenerator.

The phase- and amplitude-modulated color carriers at the collector and emitter of the addition transistor 2 get from the collector directly and via a 180 ° phase rotating element 7 to the adding stages 8 and 9 and from the emitter via a delay device 10 with a delay of one line to the other two inputs Adding stages. At the output of the adders 8, 9, the runtime Signalaufspaltschaltung used together with the phase shifter 7, the delay device 10 and the serving for time correction additional line 10 a as a, (B. RY and BY z.) Are formed thus the modulation axes corresponding farbträgerfrequenten signals in normal amplitude modulation, which are demodulated in simple amplitude rectifiers 11, 12, 13 a, 13 b . The three are then on terminals 14, 15, 16

809 618/367

demodulated color difference signals α (RY), γ (GY), β (BY) are available. Between the transit time signal splitting circuit and the demodulators, impedance converters are shown in the drawing, which feed transformers 23, 24. The turns of these transformers are dimensioned so that the amplitudes of the demodulated color difference signals are matched to the phosphor coefficients of the color picture tube and the color difference signal GY is formed by adding the signals produced at the demodulators 13 a and 13 b. The color levels 17, 18, 19 can then be designed for the same gain.

The outputs of the demodulators 11, 12, 13 are connected to the color output stages 17, 18, 19 with direct current coupling. This is possible because, according to the invention, counter voltages are fed into the base points of the demodulators 11, 12, 13, which compensate for a direct voltage component caused by rectification of the color carrier in the demodulators, which can be superimposed by a sawtooth voltage when using a passive color carrier regenerator. In the drawing, the counter voltages are generated by two rectifiers 20, 21, which are coupled by means of transformers to the output of the color carrier oscillator or the corresponding amplifier tube of the passive color carrier regenerator 3. The counter voltages required for the color carrier voltage compensation are determined by the number of turns of the transformer 22. As a result, on the one hand, the rectifier 20 generates the negative voltage required for the demodulators 11 and 12 and, on the other hand, the positive voltage required for the demodulators 13 a and 13 δ. This is expressed by the polarity of the two rectifiers 20 and 21. The rectifier 21 is connected to a tap on the secondary winding of the transformer 22, as a result of which it receives a lower amplitude of the regenerator voltage. As a result, and due to the different polarity of the rectifier diodes 20 and 21, voltages of different polarity and size arise at the associated IC elements 20a and 21a. During the demodulation of the color difference signals, DC voltage components of the same size and positive polarity arise for the signals RY and BY, while a smaller DC voltage value with negative polarity is created for the signal GY. The size ratio and the approximate size of the desired counter voltages are set by the number of turns of the secondary winding of the transformer 22. A fine adjustment is made by the controllable resistor 25, ie by a slight change in the amplitude of the switched color carrier. Such a fine adjustment could also be carried out in the line (or lines) of the counter voltages. A transformer 26 is provided upstream of the delay line 10 to transform the signals, which are relatively large due to the carrier addition, and an amplifier 27 is provided at the output of the delay line to increase the signals. 65

Claims (7)

Patent claims: 1. Demodulation circuit for signals of a color television system of the PAL type in which a Color carrier is quadrature modulated with respect to two axes with two color signals and one Modulation axis is switched line frequency by 180 °, the received conjugate complex color subcarrier-frequency signals of two consecutive lines after a delay of the one signal are added or subtracted in two adding stages and the demodulation the color subcarrier-frequency color signals generated thereby and separated according to the axes Addition of a color sync signals transmitted in a color carrier regenerator again produced color carrier takes place, which the received color subcarrier-frequency PAL color television signals is added, the phase of the added color carrier according to the line-frequency switching of a modulation axis at the transmitter is switched line frequency, characterized in that the color demodulators (11, 12, 13) Tension components caused by the added ink carrier through corresponding Counter voltages are compensated, which are derived from the color carrier regenerator (3). 2. Demodulation circuit according to claim 1, characterized in that the counter voltages by rectification (20, 21) of the resulting in the output of the color carrier regenerator (3) Color carrier are derived. 3. Demodulation circuit according to claim 2, characterized in that the output of the Color carrier regenerator (3) a transformer (22) is arranged, which has a separate secondary winding with taps to obtain counter voltages of various sizes and polarities possesses, wherein the base point of the secondary winding is connected to a ground potential. 4. Demodulation circuit according to claim 3, characterized in that the transformer (22) contains several separate secondary windings, their base points with different basic potentials are connected. 5. Demodulation circuit according to claim 3 or 4, characterized in that the taps or the number of turns of the transformer (22) are chosen so that the values of the Counter voltages correspond to the various voltage components that are used in demodulation arise through the influence of the ink carrier. 6. Demodulation circuit according to claim 5, characterized in that the relative values the counter voltages due to the number of turns of the secondary windings in front of the color demodulators (11, 12, 13) arranged output transformers (23, 24) are determined. 7. Demodulation circuit according to one of claims 1 to 6, characterized in that for fine adjustment of the counter-voltages in the path of the regenerated color carrier to the runtime signal splitting circuit an adjustable resistor (25) is arranged. 1 sheet of drawings 809 618/367 9.68 © Bundesdruckerei Berlin