DE3906596A1 - Reproduction circuit for a SECAM colour television signal - Google Patents

Abstract

To reduce the visibility of the colour subcarrier in the picture, a notch filter for the colour subcarrier is located in the path of the luminance signal, as is well-known. This also suppresses useful frequencies of the luminance signal and reduces the sharpness of the picture. The invention is intended to suppress the colour subcarrier optimally but to affect the picture sharpness as little as possible. The filter (7) has an electronically shiftable locking point (8) which is adjusted to the respective instantaneous frequency of the colour subcarrier (F) by the colour difference signals. Especially for a colour television receiver or a video recorder. <IMAGE>

Description

The invention is based on a playback circuit according to the preamble of claim 1. Such a circuit is known from the DD-Z "radio and television" 1966, issue 4, Page 105, Figure 9.

The suppression of the color carrier within the luminance signals during playback is necessary to be visible to reduce the color carrier in the image. This measure is particularly important at SECAM, because because of the Fre Frequency modulation of the color carriers always with full amplitude is available.

It is known to be a band reel in the path of the luminance signal re provide the frequencies within the bandwidth of the modulated color carrier suppressed. This solution has the Disadvantage that the corresponding frequencies in the Luminance signal can be suppressed and the image sharpness is reduced.

It is also known to suppress the color carrier in the Path filter to provide the blocking filter places at defined frequency intervals. This solution is however relatively complex. Also be there too Groove frequencies suppressed in the luminance signal.

The invention has for its object to a circuit create an optimal suppression of the color carrier and at the same time minimal impairment of the light density signals.  

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

The invention is based on the following consideration. The SECAM Color carrier takes a certain due to its modulation Frequency range of approximately 3.9 MHz-4.75 MHz extends. This initially leads to frequencies within this frequency range must be suppressed. Other on the other hand, the ink carrier has only one at any moment certain frequency. This fact becomes apparent with the invention exploited by the blocking filter dynamically always on this respective instantaneous frequency is controlled. It takes place al so no static suppression of frequencies, but egg ne dynamic suppression that automatically affects the sets the respective instantaneous frequency. There in every eye almost a singular frequency is suppressed, remains the impairment of the luminance signal mi nimal.

The invention is particularly advantageously applicable in devices in which an improved separation of luminance resist gnal and ink carrier is required. This is e.g. the case in novel video recorders based on the S (Super) -VHS system and improved color television receivers with a so-called SCART input socket.

According to a development of the invention, the controlled Filters instead of suppressing the color carrier also the NEN, the color carrier from the CVBS signal frequency-selective evaluate. For this purpose the filter contains an electro nisch controllable passage point by the control signal each controlled to the instantaneous frequency of the color carrier is heard. The two variants, namely oppression of the color carrier in the CVBS signal with a controlled lock  place or the evaluation of the color carrier from the FBAS-Si gnal with a controlled passage point can also addi tiv applied, e.g. pure light in one way density signal without color carrier and in a second way the pure color support without luminance signal available to ma chen.

The solution according to the invention is thus used with a circuit effort with proper suppression of the Color carrier an improvement over previous circuits The sharpness of the luminance signal is reached. It is there possible, with improved result circuits to picture Sharpness increase, so-called dynamic crispening circuit use such as e.g. in DE-PS 31 40 761 be are written.

An embodiment of the invention is based on the drawing explained. Show in it

Fig. 1 is a block diagram of the circuit according to the invention and

Fig. 2 shows a detailed circuit diagram for the notch filter used.

Fig. 1 shows in simplified form the structure of a SECAM playback circuit. The CVBS signal passes from terminal 1 to the identification circuit 2 , which visually evaluates various parameters. The color carrier F passes through the bandpass filter 3 with a pass band of about 3.9-4.75 MHz, which also causes the SECAM equalization, on the SECAM decoder 4 , which, among other things, the line delay line, the line-frequency operated cross switch, the Contains FM demodulators and equalization circuits. The decoder 4 supplies the color difference signals BY and RY to the matrix 5 , which supplies the color signals R , G , B at its outputs. The decoder 4 is fed by the circuit 2 with the half-line frequency switching voltage 6 for the zeilenfrequen th switch in the decoder 4 .

The CVBS signal also passes through the low-pass filter 6 with a cut-off frequency of 5 MHz to the controllable filter 7 , which has a discrete blocking point 8 at one frequency. The position of the blocking point 8 can be shifted electronically in frequency by applied control voltages U 1 , U 2 so that the blocking point is always at the instantaneous frequency of the color carrier.

The control voltages U 1 , U 2 are won in the following manner: The color carrier F also reaches the FM demodulator 9 , which has two outputs. One output provides a voltage that corresponds to the quiescent frequency of 4.25 MHz during every other line. The other output corresponds to the color difference signal RY and a color carrier frequency of 4.040625 MHz in the lines in between. The two control voltages thus obtained reach the two reference levels 10 , 11 . These stages effect according to the two quiescent frequencies f 1 and f 2, a clamping of the signals to such different voltages that the control voltage U 1 or U 2 given , taking into account the frequency switching of the SECAM color carrier, the blocking point 8 in each line to the instantaneous frequency of the color carrier The control voltages U 1 , U 2 are therefore dynamic control voltages which change in accordance with the color difference signals and which represent a measure of the instantaneous frequency of the color carrier. In this way, the color carrier F fed to the filter 7 is suppressed frequency-selectively at any moment, so that a luminance signal Y without the color carrier is supplied to the matrix 5 in the desired manner. The control voltage U 1 , U 2 are obtained from the color carrier only by frequency demodulation, and are therefore not equalized in accordance with the SECAM predistortion. At the stages 10, 11 of the circuit 2 half-line switching voltages 12 , 13 are applied in push-pull. The switching voltages conditions 12 , 13 cause the control voltage U 1 and U 2 to alternately reach the control terminal of the filter 7 from line to line.

Fig. 2 shows a circuit example of the filter 7 in the form of a notch filter. The combined signal from the luminous density signal Y and the color carrier F passes from the terminal 14 via an emitter follower with the transistor 15 to the input of a comparable coil 16 , the output of which is connected to the input of an emitter follower with the transistor 17 . At the terminal 18 , the luminance signal Y is taken without the ink carrier F. Parallel to the coil 16 is an RC element 19 and also a circuit 20 with four capacitance diodes. The control voltages U 1 , U 2 are alternately applied to the capacitance diodes. The control voltages U 1 , U 2 dynamically change the resonance frequency of the resonant circuit with the coil 16 , the capacitor of the RC element 19 and the capacitance diodes 20 in the manner described. The filter shown has a blocking point with a reduction of approximately 60 dB and a bandwidth of 50 kHz. The capacitance diodes of the circuit 20 are preferably of the type 1 T33C from Sony.

The band-pass filter 3 of FIG. 1, of the frequency-selective For evaluation of the color carrier F is used, could also be formed by a dyna mixing controlled filter. The filter would then have a pass-through instead of a blocking point at a discrete frequency, which is controlled accordingly by the control voltages U 1 , U 2 on the respective instantaneous frequency of the color carrier. By two dynamically controlled filter according to Fig. 2, a controlled with a locking point and one with a controlled passage point, ie a optima le separation of the luminance signal Y and the color carrier F can in each case without minimal influence of the transmitted useful signal take place.

Claims (10)

1. Playback circuit for a SECAM color television signal with a luminance channel with a cut-off filter for the color carrier and with a color channel, the color difference signals are provided, characterized in that the fil ter ( 7 ) has an electronically displaceable blocking point ( 8 ) by a frequency demodulation by ( 9 ) of the color carrier ( F ) obtained control voltage ( U 1 , U 2 ) is controlled to the respective instantaneous frequency of the color carrier ( F ). 2. Circuit according to claim 1, characterized in that the blocking point ( 8 ) has an attenuation of about 60 dB. 3. A circuit according to claim 1, characterized in that the blocking point ( 8 ) has a bandwidth of approximately 50 kHz. 4. Circuit according to claim 1, characterized in that the filter ( 7 ) is a notch filter ( Fig. 2). 5. A circuit according to claim 4, characterized in that the filter ( 7 ) contains an inductor ( 16 ) lying in the signal path, to which a capacitance diode ( 20 ) acted upon by the control voltage ( U 1 , U 2 ) is connected in parallel ( FIG. 2) . 6. Circuit according to claim 5, characterized in that in front of and behind the inductance ( 16 ) each have an Emitterfol gerstufe ( 15 , 17 ) ( Fig. 2). 7. Circuit according to claim 1, characterized in that the amplitude of the control voltage ( U 1 , U 2 ) is switched from line to line by a constant amount corresponding to the line-by-line switching of the frequency of the SECAM color carrier ( F ). 8. A circuit according to claim 1, characterized in that for the frequency-selective evaluation of the color carrier ( F ) from the composite signal, a filter is provided with an electronically displaceable pass-through point which is obtained by a control voltage obtained by frequency demodulation of the color carrier ( F ) on the respective Instantaneous frequency of the ink carrier ( F ) is controlled. 9. A circuit according to claim 1, characterized in that the color difference signals (BY, RY) are used as the control voltage ( U 1 , U 2 ). 10. The circuit according to claim 1, characterized in that the control voltages (U 1 , U 2 ) are not subjected to the SECAM equalization.