DE2208731A1 - CIRCUIT FOR CONVERTING A SECAM COLOR CARRIER INTO TWO LINE-SEQUENTIAL COLOR DIFFERENCE SIGNALS ACCORDING TO THE PAL STANDARD - Google Patents

Description

Circuit for converting a SECAM color carrier into two line-sequential ones Color difference signals according to the PAL standard For transcoders and multi-standard color television receivers the task can occur from the modulated SECAM color carrier two line-sequential Generate color difference signals R - Y and B - Y according to the PAL standard.

These sequential color difference signals can be used, for example, with a video frequency Delay line made like a clocked memory again and then simultaneously a color television receiver or a PAL coder. You can also modulated onto a PAL color carrier and with a line delay line in one PAL decoder can be made available again simultaneously.

The SECAM color carrier is known to be associated with the two color difference signals R - Y and B - Y frequency modulated, the rest frequency of the color subcarrier from line to line is switched between two values. With demodulation of the color carrier in an FM demodulator, the white levels of the generated signals for the (B - Y) - Line and the (R - Y) line have a different value. Besides, the linear one Reduction of the amplitudes of the (R - Y) signal and the (B signal in SECAM and PAL different. For the further processing of the signals R - Y and B - Y in one PAL circuit, however, requires that the white levels of the signals be more consecutive Lines have the same value and the amplitude coefficients correspond to the PAL standard.

The invention is based on the object of a simple circuit to create line-sequential color difference signals from the SECAM color carrier R - Y and B - Y with the same white level and with amplitude coefficients according to the PAL standard generated.

This object is achieved by the invention described in claim 1 solved. Advantageous further developments of the invention are specified in the subclaims.

The circuit complexity is low. The invention exists in an advantageous dimensioning of components already present in the circuit.

The invention is explained below with reference to the drawing.

FIG. 1 shows an exemplary embodiment of the invention and FIG FIG. 2 shows a modification of the circuit according to FIG. 1.

In Figure 1, the SECAM color carrier is from a terminal 1 to the input an FM demodulator 2 fed from a terminal 3 via a resistor R4 is supplied with an operating voltage. With the resistor R4 is the working point of the FM demodulator 2 adjustable.

The FM demodulator 2 supplies the signals alternately from line to line R - Y, B - Y, whose instantaneous values are marked with the symbol UB. ' This tension controls a transistor 4, which has a load resistor R3 and a negative feedback resistor R1 is provided. The signals R - Y and B - Y with the same white level and amplitude coefficient According to the PAL standard, 5 is removed from a terminal. The resistor R1 is a Resistor R2 through a diode 6 and a switch? can be connected in parallel. The desk 7 is controlled by a half-line frequency switching voltage 8 whose phase is off is synchronized with the identification signal of the incoming SECAM signal. While the line R - Y the switch 7 is in the left position, so that the The cathode of the diode 6 is connected to earth, the diode 6 is permeable and thus the resistance R2 is effective in parallel with R1. The switch is located during line B - Y 7 in the right position, so that the diode 6 by a coming from a terminal 9 positive voltage blocked and the resistor R2 is not effective.

It will first be explained how the correct amplitude coefficients can be achieved with this circuit. The following values apply for this: Reduction factor reduction factor PAL Secam PAL Secam 230 B - Y 0.49 1.5 x ------ = 1.23 (RY) 280 ----- 1.8 1.54 280 (BY) R - Y 0.88 1.9 x ----- = 1.9 280 VR-Y 1.8 ---- = --- = 1.16 VR-Y = step gain during Vo 1.54 RY line VB-Y VB-Y = step gain during ---- = 1 the BY time Vo VR-Y # R3 = 1.16 Vo R1 11 R2 VB-Y # R3 = R1 R1 H R2 = #### = 0.86 R1 R2 = 6.25 R1 The reduction factors shown are included in the signals on the transmitter side. When the signals R - Y and B - Y are obtained, the signal B - Y obtained by demodulating the SECAM carrier would have to be divided again by 1.23 and the signal R - Y by 1.9. For the generation of the signals R - Y and B - Y according to the PAL standard, 3 - would have to be multiplied by 0.49 and R - Y by 0.88. This then results in the other values shown above for the gain factor of transistor 4 for rows R - Y and B - Y. Since the gain during row R - Y through resistor R3 and the parallel connection of resistors R1 and R2 and during of the line B - Y is given only by the resistors R3 and R1, the condition shown for this gain switchover by the switching voltage 8 is the condition R2 = 6.25 shown. R1. Then the signals at terminal 5 have amplitude coefficients according to the PAL standard.

The following explains how the equalization of the white levels of the signals R - Y and B - Y is achieved. The white levels of these two signals appearing sequentially at the base of the transistor 4 must produce the same collector currents IC in the transistor 4. The following applies: OCR-Y = OCR-Y = ##### ### = ## # ## = Collector current of the white level during the RY line JCB-Y = collector current of the white level during the BY line UBR-V = base voltage of the white level during the RY time ##### = 0.86 + 0.14 #### # # 0.86 UBR-V = base voltage of the white level during the RY time USa lock spur of the transistor The DC operating point of the FM demodulator 2 is now set with the resistor R4 in such a way that the above-mentioned ratio between the voltages UB for the white level o .86 is. As a result of this ratio and the effective switching of the gain factor, the signals at terminal 5 have both the amplitude coefficient corresponding to the PAL standard and the same white level in successive lines.

Figure 2 shows a modification of the circuit of Figure 1. Here is the necessary ratio of the white level through a between the output of the FM demodulator 2 and the base of transistor 4 switched on Zener diode 10 set, This Diode serves as a DC voltage source and thus for potential transformation of the Signals.

Such a potential transformation can also do that Set the desired ratio.

Claims (6)

PATENT CLAIMS 1. Circuit for converting a SECAM color carrier into two line-sequential ones Color difference signals R - Y and B - Y with the same white level and with amplitude coefficients according to the PAL standard with an FM demodulator fed by the color subcarrier and one connected to it connected transistor amplifier, characterized by the following features: a) The gain V of the transistor amplifier C4) is by a half-line frequency Switching voltage (8) during line B - Y to the value V0 and during the line R - Y to the value 1.16. V0 switched. b) The DC voltage at the output of the FM demodulator (2) generated signals is adjusted so that the ratio of the white levels of R - Y za B - Y at the input of the amplifier (4) is approx. 0.86. 2. Circuit according to claim 1, characterized in that the signals R - Y and B - Y according to the PAL standard of one in the collector circuit of the transistor (4) lying working resistance (R3) are removed and a resistor in the emitter circuit El is, which during the line R - Y by the switching voltage t8) a resistance R2 = 6.25 Pl is connected in parallel. 3. A circuit according to claim 1, characterized in that the DC voltage level achieved by setting the working point (resistor R4) of the FM demodulator (2) is (Figure 1). 4. A circuit according to claim 1, characterized in that the DC voltage level through one between the output of the FM demodulator (2) and the input of the amplifier (4) switched DC voltage source (10) is set (Figure 2). 5. A circuit according to claim 4, characterized in that the DC voltage source is formed by a Zener diode (10) (Figure 2). 6. A circuit according to claim 1, characterized in that the phase position the switching voltage (8) is synchronized by the incoming SECAM signal.