DE1073029B - Circuit for contrast-independent black value stabilization in a television receiver - Google Patents

Description

It is known to maintain the operating point of an amplifier tube by a constant grid bias specified external resistances and specified voltages of the other electrodes. at the mass production of high-frequency devices, however, make the scattering of the tube data so noticeable that there are scattering of the working area and that with an optimally set Working point with overloading of a part of the tubes must be expected. This difficulty could by inserting a cathode resistor for automatic grid bias generation be corrected, but because of the low frequencies to be transmitted, it is a relatively large one Cathode capacitor required. It is now known that one can use a so-called "sliding Screen grid voltage «can keep the anode direct current of a tube constant. With such a circuit however, either the screen grid resistance will normally reduce the performance of the tube in reduced to an undesired extent or it must - when using a relatively small screen grid resistor - because of the low frequencies to be transmitted, a very large screen grid capacitor is used will.

It has also been proposed to use the screen grid particularly of the last intermediate frequency amplifier tube to avoid overloading via a relatively large resistance to the television receiver to put available booster voltage at the booster capacitor of the line deflection circuit. Furthermore it is known for contrast-independent black level stabilization, from the anode circuit one in its amplification adjustable intermediate frequency amplifier stage to take a contrast-dependent brightness control voltage and to feed the picture tube. According to the invention is a circuit arrangement for the contrast-independent Black level stabilization designed so that the screen grid of the video output stage over a relatively high resistance is connected to the booster voltage and that a tap of the high resistance Resistance connected directly or via switching elements to a control electrode of the picture tube in this way is that with a gain control of the video output stage, the black level of the picture signal on the picture tube is kept approximately constant. This ensures that when the operating point is stabilized to avoid overmodulation, simply adjust the black level with contrast control is kept constant.

The invention is explained in more detail below with reference to the drawing.

In this a video amplifier tube 1 is shown, the image signals from the output transformer 2 of the Circuit for contrast-independent

Black level stabilization in one

Television receiver

Applicant:

Telefunken GmbH,
Berlin NW 87, Sickingenstr. 71

Walter Bruch and Dipl.-Ing. Klaus Hecker, Hanover, have been named as inventors

last intermediate frequency amplifier stage via the image rectifier diode 3 are fed. The reinforced Image signals are sent to the cathode of the picture tube 4 from the anode resistor 5 of the video amplifier tube fed. To determine the operating point of the video amplifier tube, the latter is located on the control grid Tube a fixed potential (ground or negative bias). The circuit described so far has the Disadvantage that in the mass production of television receivers due to the data scattering of the tubes a large spread of the working range or the electrode currents for the various receivers is caused. To avoid this disadvantage, the screen grid has a high resistance 6 with the so-called booster capacitor 7 of the line deflection circuit, which is used for voltage recovery 8 connected, at one electrode of which a voltage is available that is essential higher than the anode voltage supplied by the receiver's power supply unit (e.g. 500 to 700 V). The screen grid of the video amplifier tube 1 is also connected to ground via a capacitor 9. The high booster voltage used makes it possible for the resistor 6 to have a very high resistance to make, so that to achieve the necessary for the transmission of the low frequencies high Time constants only a relatively small capacitor 9 is required.

With such a screen grid resistor, to which one of the size of the anode direct current or a on the gain of the tube is dependent voltage, is according to the invention by means of a part This voltage influences an electrode voltage of the picture tube in such a way that during the gain control or if the mean image brightness changes, the voltage value for black on the

909 709/201

The picture tube remains approximately constant or changes in a desired ratio.

By appropriately dimensioning the high resistance, it is also possible to use the Screen grid voltage so proportional to the input of the video amplifier tube supplied image signals to regulate that S tor voltages that are greater than the sync pulse peaks of the image signal, cut off by the lower bend of the characteristic curve corresponding to the respective screen grid voltage will. If the capacitor 9 is dimensioned relatively low, the high frequencies are increased, which can be used to influence the frequency response of the amplifier. By splitting up of the resistor 6 into two partial resistances, at the connection point of which one is connected to ground Capacitor is connected, can also increase the high frequencies for linearization or deformation of the frequency response can be achieved.

The capacitor 9 can in this embodiment, for. B. also replaced by the tube capacity of tube 1.

Claims (1)

Claim: Circuit arrangement for the contrast-independent tail value stabilization in a television receiver, characterized in that the screen grid of the video output stage (1) has a relative high resistance (6) is due to the booster voltage and that a tap of the high resistance Resistance connected directly or via switching elements to a control electrode of the picture tube in this way is that with a gain control of the video output stage, the black level of the image signal is kept approximately constant on the picture tube. Considered publications:
U.S. Patent No. 2,550,960. 1 sheet of drawings © 909 709/201 1.60