DE1253752B - Video demodulator circuit - Google Patents

Description

Video Demodulator Circuit The invention relates to a video demodulator circuit with a direct current to a control electrode one with means for regulating of the frequency response in its cathode circuit equipped video amplifier tube coupled and the demodulator circuit galvanically connected to ground.

To give the television audience the opportunity to adjust the image sharpness TV sets can change the reproduced television picture to suit their own taste be equipped with a so-called sharpener, d. H. with means to influence the upper limit frequency of the reproduced television picture signal. The regulation of the Sharpening is in a known form either continuously or in an or several stages made by a switch. Thereby the necessary Control organs for influencing the image frequency expediently in the cathode line built into the video tube of the television receiver circuit. So that the desired control effect occurs, the cathode resistance must have a certain size. Through him becomes a basic negative feedback is formed, which is then through controllable impedances within can change certain frequency limits.

Because of the tube characteristics, the result is not always an optimal one Operating point when - as in a known circuit (see FIG. 1) - the high-frequency rectifier circuit 1 is based on mass. For different types of tubes, one must be set for the purpose of setting optimal working point of the cathode resistance has a very specific resistance value which does not give an optimal sharpening effect. It therefore becomes a tube type preferred, its operating point - with a high-frequency rectifier circuit referenced to ground and a sufficiently large cathode resistance - is to be chosen so that one is also sufficient Large negative feedback for setting the desired sharpening effect available is.

As favorable for this z. B. the tube type PCL 84 proved, whose pentode part is especially suitable for video power amplifiers. The one for an optimal The cathode resistance required at the operating point is only 33 ohms for this tube. However, this value is too small to be regulated by connecting in parallel Impedance results in a desired sharpening effect (changed negative feedback).

Attempts have been made to overcome this disadvantage with these tubes in connection with a sharpener the high-frequency rectifier circuit "floating" build up, d. H. to relate it no longer to ground, but to the cathode potential or to a suitable part of the voltage that drops across the cathode resistor. An example of this circuit is shown in FIG. 2, in which, in contrast to FIG. 1 the high-frequency rectifier circuit 1 with direct current to the cathode line, however, it is only capacitively connected to ground (capacitors Z and 3).

This type of circuit has difficulties in that the high-frequency circuit grounding of the rectifier circuit due to the wire lengths of the coupling capacitors is good as if this circle is ohmically related to ground. Also must for the Blocking a high quality HF capacitor with the largest possible capacitance value used so that the low frequency is diverted to ground (e.g. a Electrolytic capacitor of the order of 5 J), as well as a resistor with which the corresponding cathode voltage is fed to the RF demodulator circuit.

Other known circuit arrangements operating as sharpener can be referenced in the FIGS. 1 and 2 lead back circuit arrangements shown.

The object of the invention is that of the known circuits avoid any difficulties that arise.

According to the invention, this object is achieved in a video demodulator circuit with a direct current to a control electrode one with means for regulating of the frequency response in its cathode circuit equipped video amplifier tube coupled and the demodulator circuit, which is galvanically connected to ground, is solved by that between the demodulator circuit and the control electrode of the connected video amplifier tube above a fixed voltage divider a positive DC voltage is coupled, with the help of which the working point of the tube is optimally determined will.

The drawing shows in FIGS. 3 and 4 two exemplary embodiments the invention.

According to FIG. 3, the cathode resistor 9 of the video output tube 5, z. B. of the type PCL 84. chosen so that it brings a desired sharpness. In series with the usual demodulation circuit 1, ie between this and the grid 4 of the tube 5, a resistor-capacitor combination 6, 7 is now provided. The resistor 6 serves to transmit the low frequencies from 0 Hertz, and the capacitor 7 connected in parallel feeds the high frequencies to the video tube. The grid of the video tube is controlled without power at the operating point. For this reason, the RC combination 6, 7 cannot have any influence on the video transmission characteristic. If z. B. the capacitor 7 has a value of 1000 pF and the grid cathode capacitance of the tube is 10 pF, then 99 0; `o of the high frequencies are transmitted.

The capacitor 7 connected in parallel with the resistor 6 can therefore be dimensioned to be relatively small. In practice it has been shown that a transmission of z. B. 90 ° 'o the amplitude of high frequencies (with the input capacitance of 10 pF and a coupling capacitor of 100 pF) is still completely sufficient. Due to the RC combination 6.7 , the grid circuit resistance compared to the circuit according to FIG. 1 has become much higher.

By switching on a further resistor 8 between the grid 4 of the video tube and the positive pole of the anode voltage source, a voltage division occurs which shifts the grid potential by a certain amount in a positive direction compared to the potential that is present behind the HF rectifier circuit. The cathode resistance is denoted by 9 and the control circuit for the sharpener is denoted by 10 .

If the corresponding values are used for the considerations described here, the result for resistor 8, which must pull the grid to a positive potential (approx. +200 V), is a resistance value of approx. 15 ... 20 megohms. In the case of the voltage division occurring here, it can be seen that practically about 980.

By switching on the in F i g. 3 described switching elements the grid of the video tube is so positively biased that between the voltage, that drops across the cathode resistance, and the voltage that is applied to the grid, the optimum working point is set.

The advantage of this circuit is that the RF rectifier circuit 1 exactly as in FIG. 1 is ohmically related to ground and the switching elements used in the uncritical video part and not in the HF part, as in FIG. 2, built-in are.

When using the circuit specified here in conjunction with the commercially available duty cycle control circuits result in a relatively simple control option, by changing the voltage of the resistor related to the positive potential $ is made.

F i g. 4 shows a circuit example in which the grid of the tube 5 compared to the HF rectifier circuit 1 with a special positive bias voltage source is connected via an adjustable voltage divider 11. This adjustable bias can also be used to adjust the contrast in conjunction with the touch control of the device can be used.

Claims (4)

Claims: 1. Video demodulator circuit with a direct current to a control electrode with means for regulating the frequency response in its Cathode circuit equipped video amplifier tube coupled and galvanically directly demodulator circuit connected to ground, characterized in that between the Demodulator circuit (1) and the control electrode (4) of the connected video amplifier tube (5) a positive DC voltage via a fixed voltage divider (6, 8) is coupled, with the help of which the working point of the tube (5) is optimally set will. 2. Video demodulator circuit according to claim 1, characterized in that the positive one introduced between the demodulator circuit (1) and the control electrode (4) DC voltage through the voltage divider circuit (6, 8) from the anode voltage is won. 3. Video demodulator circuit according to claim 1, characterized in that that introduced between the demodulator circuit (1) and the control electrode (4) positive DC voltage from a special voltage source, e.g. B. one ir the circuit built-in battery. 4. video demodulator circuit according to claim 1, 2 or 3, characterized in that the voltage applied to the voltage divider (6, 8) positive reference voltage can be changed for the purpose of contrast control. Into consideration pulled documents: U.S. Patent No. 2,470,048; "Radio Mentor", 1958, No. 5, p. 264; "Radio Mentor", 1958, No. 6, p. 395; »Funkschau«, 1958, issue 1, P. 24; “Most Often Needed Television Servicing Infor. mation ', 1956, pp. 38/39; Siemens publication SE 6 / 317-4585 R (»Siemens TV set TM 843«).