DE1123362B - Arrangement for black control in a television receiver - Google Patents

Description

Arrangement for black control in a television receiver The invention relates to an arrangement for black control in a television receiver at the control electrode a video output tube which is supplied with a television signal without a direct current component and the cathode of the television picture tube is connected to its anode in direct coupling is.

It is already known to arrange a diode in such an arrangement for black control parallel to the grid bleeder resistor of the video output tube, which keeps the potential at the control grid of the video output tube constant for the peaks of the sync pulses. So that the potential at the cathode of the television picture tube for the reference value of the television signal remains constant, the video output tube should have an approximately constant gain for all frequencies, including direct current. Often the gain factor is smaller for direct current because the bypass capacitors used in the arrangement, e.g. B. for the screen grid or the cathode of the end tube lose their effectiveness with direct current. It is also already known to compensate for the black level error that occurs as a result by forming the working resistance of the video output tube as a function of frequency by dividing the working resistance and bridging a partial resistance by a capacitor. The black level error is defined by the ratio of the shift of the black potential in relation to the change in the signal mean value and indicates what percentage of the signal mean value is missing from the reintroduction of its full value. The black control diode also causes a black level error, since because of the finite resistance of the diode circuit, the larger the signal mean, the greater the amplitude of the synchronous signal required to restore the charge of the grid capacitor that has flowed through the grid leakage resistor in the time between the sync pulses.

From previous investigations it was finally recognized that the Maintaining the same potential for the black level for television signals with different Mean value does not give the same impression for picture black on the screen of the television picture tube results. Rather, it has been found that with television signals with an average Mean, as z. B. occur in a halftone image, a greater luminance is required for the same subjective impression for image black as for television signals with a small signal mean, which predominantly contain image black. For a satisfactory Picture reproduction of television pictures of different character is therefore a small one negative black level error is desirable, and it has also been suggested that this by overcompensation of the positive black level error.

The obvious way to overcompensate this by setting the size of the part of the working resistance bridged for the video frequencies of the video end tube has several disadvantages. Primarily This setting becomes the operating point on the characteristics of the video output tube postponed. Furthermore, the tolerances of the switching elements, in particular the Black control diode, the positive black level error in different copies of a series of receivers is not sufficiently constant.

In order to avoid these disadvantages, an arrangement for black control in a television receiver with a video output tube that transmits a television signal without a direct current component is supplied and at its anode in direct coupling, the cathode of the television picture tube is connected, while the Wehnelt electrode of the picture tube is connected to the tap of a voltage divider whose voltage source also supplies the operating voltages for the video output tube, according to the invention in the anode circuit of the video output tube in series with the working resistance for the video frequencies a working resistance of this type which is only effective for direct current Size switched on that a significant negative black level error occurs, and in series with a black control diode located on the grid of the video output tube Resistance of such a size arranged that the resulting positive black level error the negative black level errors are reduced to such an extent that the Television signals with different mean values produced television pictures the same create a subjective impression for image black.

In a preferred embodiment of the arrangement according to the invention a negative black level error due to the working resistance effective for direct current from 20 to 25%. By means of the series resistance to the black control diode a positive black level error is introduced, or this is enlarged to such an extent that that there remains a negative black level error of such magnitude that for images with different average brightness the same subjective impression for image black arises. Based on the examinations carried out, this is the case if the change in the black level in the television signal between a predominantly white one and a black image is about 7% of the black-and-white jump, which is approximately corresponds to the usual black contrast for the television signal of the Gerber standard. From it a desired negative black level error of about 9% is calculated, so that below the above assumption of a negative black level error of 20 to 25% due to the additional a positive black level error of 11 to 16% can be set by selecting the appropriate series resistance for the black control diode is.

The arrangement according to the invention has the main advantage that the setting of the desired negative black level error without shifting the Operating point can be made on the characteristic curve of the video output tube. A Another advantage is that the series resistance to the black control diode in the preferred embodiment of the arrangement, substantially greater than the resistance of the diode is in the forward direction and that therefore scattering of the internal resistance the diode become so ineffective that no individual testing and adjustment of the individual devices in a series is more necessary.

Due to the high working resistance in the anode circuit, which is effective for direct current the video output tube also has the advantage that the voltage difference between cathode and Wehnelt electrode of the picture tube for the black level, which the luminance for image black is determined, largely independent of fluctuations the operating voltage is as it is caused by mains voltage fluctuations can.

The invention will now be explained in more detail with reference to the figure representing an embodiment. This represents an excerpt from the circuit of a television receiver, in which the video end tube, the cathode and the Wehnelt electrode of the television picture tube as well as the power supply of the video end tube and the Wehnelt electrode from a common direct current source are shown. Via the coupling capacitor 1 , the television signal passes through the loss of the direct current component to the control grid of the video output tube 2, e.g. B. the pentode system of a composite tube of the type PCL 84. With the anode of the pentode 2, the cathode 3 of a television picture tube is connected in direct coupling. The dimensioning of the switching elements given below relates to television picture tubes with a deflection angle of 110 ° and a blocking voltage between approximately 40 and 80 V. The television signal with positive polarity on the grid of the tube produces a negatively directed signal at the anode of the tube 2 , so that the voltage at the anode becomes more negative as the signal amplitude increases and thereby causes the picture tube to be controlled in the correct sense while the potential of the Wehnelt electrode is maintained . The control signal occurs as a voltage drop across the anode resistor 4 of the tube 2. The resistor 4 has a value of 3.3 k0, for example. To improve the frequency response at high frequencies, a resonance choke can be arranged in series with the resistor 4 in a known manner, which, however, due to its negligible DC resistance, does not affect the voltage distribution for direct current, which is the only important factor here and which is therefore not shown in the figure is. To set the correct operating point on the characteristic curve of the video output tube, a cathode resistor 5 (e.g. 1802) is provided, which can be bridged by a small capacitor 6 (500 pF) to further improve the frequency response in the area of higher video frequencies.

According to the invention is now in series with the anode resistor 4, a relatively large resistor 7 of z. B. 1.8 k @ 2 switched on, but this is bridged by a large capacitor 18 (z. B. 8 gF) to the reference line, so that it is essentially only effective for direct current. The screen grid voltage of the tube is taken from the connection point of the resistors 4 and 7. Via a screen resistor 8 (z. B. 330 S2), after which z. B. the operating voltages for the pre-stages of the video amplifier can be removed, the operating voltage of the video output tube 2 of the high voltage of z. B. 250 V of a power supply supplied. A voltage divider for obtaining the bias voltage of the Wehnelt electrode 9 of the picture tube is connected to this upper voltage. The voltage divider consists of a fixed resistor 10 (e.g. 120 k92) and a potentiometer 11 (e.g. 250 k12), with which the bias voltage of the Wehnelt electrode can be set to obtain the correct basic brightness. The voltage from the wiper of the potentiometer 11 passes through the protective resistor 12 (e.g. 0.82 MSZ) to the Wehnelt electrode 9. The purpose of the bleeder resistor 13 (e.g. 2.2 MQ) is that when switching to remote control the brightness If the remote control potentiometer is not connected, the Wehnelt electrode receives a defined potential which corresponds to zero potential and which therefore causes the picture tube to be blanked.

Parallel to Gitterleitwiderstand 14 (z. B. 330 k12) of the video-output tube 2 of the invention is now switched in accordance with a resistor 16 in series with the diode 15 black control. If the diode were directly connected to the grid, the specified dimensions would result in a negative black level error of around 20 to 25% that is much too large.

By suitable choice of resistor 16 a positive black level error from 1l to 16 will now be '/ o introduced, so that the negative error de n desired value decreased from about 9 0/0. When using a semiconductor diode of the type 0A 5 for the black control diode, a value of the resistor 16 of about 10 kn is required for this. This resistance value is a multiple of the internal resistance of the diode 15 in the conduction direction and therefore makes the effectiveness of the circuit practically independent of the different internal resistance of different copies of the diode of the same type.

If the brightness of the picture tube is set correctly by the controller 11 during the transmission of a predominantly black picture, that is, in such a way that the screen is not yet brightened, then between the cathode and Wehnelt electrode of the picture tube there is almost the full reverse voltage of the tube, and the operating point is close to the zero value of the beam current at the beginning of the characteristic curve of the picture tube, which is curved at the beginning.

In relation to the television signal, this operating point roughly corresponds to the black level of the signal. The blanking value is then already below the blocking voltage of the picture tube with the usual black contrast of about 5010. Now comes a television signal with a higher mean value z. B. corresponds to a normal halftone image at the input of the video output tube, the high resistance 7, which is effective only for direct current, assuming normal black control, would cause such a shift in the operating point for the signal mean value at the anode of the video output tube and thus at the cathode of the picture tube cause the picture black to be reproduced much too brightly. As a result of the action of the resistor 16 , however, there is now a shift in the operating point on the grid of the video output tube, which works in the opposite direction. This is due to the fact that the resistor 16 limits the diode current at the time of the occurrence of the sync pulses so far that the current can only partially replace the charge of the capacitor 11 that has flown through the resistor 14 in the time between the sync pulses. The result is that the operating point shifts from the characteristic curve of the picture tube in the negative direction, whereby the influence of the resistor 7 is largely compensated for. With the specified dimensions, the luminance of the picture tube increases compared to the predominantly black image to such an extent that subjectively the same image impression is produced for black as with a predominantly black image. The operating point moves out of the curved starting part of the picture tube characteristic, and a satisfactory gradation is obtained even in dark parts of the picture. The shift of the operating point required for this, based on the television signal, corresponds approximately to the size of the black contrast, so that now approximately the blanking value comes to lie at the beginning of the picture tube characteristic.

An additional advantage of the arrangement according to the invention is that the voltage difference between the cathode and Wehnelt electrode of the picture tube is largely independent of fluctuations in the operating voltage. If the operating voltage - as usual - is obtained from the alternating current network by means of half-wave rectification, the set luminance remains practically unaffected by mains voltage fluctuations. The following table shows the voltages at the Wehnelt electrode of the picture tube for the specified dimensions of the arrangement shown in the figure, as well as their difference in the event of changes in the mains voltage based on measurements taken: Tension tension Mains cathode - Wehnelt voltage voltage picture tube electrode - difference picture tube (V) (V) (V) (V) 200 140 100 38 205 138 102 38 210 144 106 38 215 147 110 37 220 149 111 38 225 151 114 37 230 154 116 38 235 158 120 38 240 160 122 38 This shows that when the mains voltage changes between 200 and 240 V, i.e. by almost 20%, the voltage u between the cathode and Wehnelt electrode of the picture tube fluctuates by a maximum of 1 V and can therefore be regarded as practically constant.

Claims (3)

PATENT CLAIMS: 1. Arrangement for black control in a television receiver with a video output tube, det a television signal without direct current component is supplied and to whose anode the cathode of the television picture tube is connected in direct coupling, while the Wehnelt electrode of the picture tube is at the tap of a voltage divider whose voltage source the operating voltages of the video output tube supplies, characterized in that-end tube video is turned on (2) in series with the load resistor (4) for the video frequencies effective for DC load resistor (7) of such size in the anode circuit of that a significant negative black level error occurs, and in series with a black control diode (15 ) lying on the grid of the video output tube (2) a resistor (16) is arranged of such a size that the resulting positive black level error reduces the negative black level error so much that the of TV signals with different M Average value generated television images produce the same subjective impression for image black. 2. Arrangement according to claim 1, characterized in that the negative black level error caused by the working resistance (7) effective for direct current is approximately 20 to 25%. 3. Arrangement according to claim 1, characterized in that the setting of the size of the required positive black level error is made by suitable selection or setting of the series resistor (16) to the black control diode (15) . Documents considered: German Auslegeschrift No. 1067 855; German utility model No. 1803 945; "Radio Mentor", 1960, issue 1, pp. 041 to 043.