DE1107268B - Circuit arrangement for the interference-immune separation of synchronization pulses from a television signal - Google Patents

Description

Circuit arrangement for the interference-immune separation of synchronization pulses from a television signal In television receiver technology, the task arises that for synchronization of the deflection devices necessary synchronization pulses from the received To separate out the television signal.

It is known to use the synchronizing signal from the image signal to separate from triodes or pentodes in audio circuit. These cut-off tubes to which the video signal is supplied with positive polarity of the sync pulses work with a short and as steep as possible IQ / U characteristic curve. The image signals are then cut off at the lower bend of the tube characteristic. This type of signal separation however, it has two shortcomings. Namely, appear in the output circle of the cut-off tube In addition to the synchronization pulses, there are also interference pulses that may be contained in the video signal. Any interference signal that exceeds the sync pulse level will also call one Grid current through which the working point of the cut-off tube is proportional to the Amplitude of the disturbance more or less strongly in the negative grid voltage range is pushed in. However, this causes the subsequent synchronization pulses suppressed until the grid voltage corresponds to the time constant of the Grid combination has returned to its normal value.

Various circuits have become known in which the interfering signals be suppressed. These circuits work with a double control tube, e.g. B. a hexode, the two control grids of which the video signal with opposite amplitude is fed. The second control grid works in audio circuit and is used for Separation of the synchronization pulses as described above. Strong to the first positively biased control grid will synchronize the signal with negative polarity of the synchronizing pulses supplied. Interfering impulses now occur that affect the composite signal tower above the first. Control grid locked without inertia: However, this circuit has the disadvantage of being so critical that it In general, it cannot be adjusted effectively enough to operate at large Amplitude of the input = "signal a self-cancellation of the synchronization pulses to avoid.

A circuit arrangement has become known in which this disadvantage by automatic co-regulation of the blanking threshold, d. H. the amplitude value, in which the first control grid blocks the tube, depending on the amplitude of the received signal, is avoided. A corresponding circuit arrangement is required however, a certain effort that makes the recipient more expensive.

The invention is now based on the object as simple as possible and an inexpensive arrangement for the disruptive separation of synchronizing pulses to create from a television signal. According to the invention, this object is achieved using a multi-grid tube with two control grids, the first control grid of which is the complete Television signal with negative polarity of the synchronizing pulses and their second Control grid the complete television signal with positive polarity of the sync pulses are fed and the first control grid via a resistor to a positive Bias is solved in that the bias of the first control grid of the tube is greatly increased during the presence of synchronization pulses.

The invention is explained in more detail below with reference to the drawings. 1 shows a circuit arrangement according to the invention and FIG. 2 shows a family of characteristics to explain the mode of operation of the circuit arrangement according to FIG. 1. The double control tube 3 (Hexode) is the received video signal 4 with interference superimposed on the two Control grids 1 and 2 supplied. The second control grid working in a cutoff circuit 2 receives over the amplifier stage 5 and from the capacitor 6 and the resistor 7 existing Audio combination a video signal with positive polarity the synchronization pulses. That through the voltage divider 11 via the resistors 10 and 9 strongly positively biased first control grid 1 is the video signal 4 supplied via the capacitor 8 with negative polarity of the synchronizing pulses. The separated synchronization pulses can then be applied to the anode resistor 14 of the tube 15 can be removed.

In Fig. 2, the transmission characteristic of the tube 3, i. H. the anode current 1 "or the voltage that can be picked up at the anode, depending on the amplitude U, des Pulse component represents the video signal 4 fed to the two control grids 1 and 2. The right flank 23 of the transmission characteristic is through the characteristic of the second control grid 2, while the left flanks 16, 17 and 18 are determined by the characteristic curve of the first Control grid 1 and thus are determined by its positive bias Uo. the somewhat greater steepness of the right flank 23 determined by the control grid 2 is due to the amplifier stage 5. The amplitude of a sync pulse to be truncated (e.g. 20 in Fig. 2) and thus the amplitude of the supplied complete video signal 4 should now be selected so that the synchronizing pulse 20 to be cut off is as possible falls into the straight branch 24 of the transmission characteristic, thus at the anode of the tube 3 the separated pulse 19 occurs with the highest possible amplitude. Impulses like z. B. the pulse 22, the amplitude of which differs greatly from that of the pulse 20, occur So at the anode with a greatly reduced amplitude z. B. as a pulse 21 or quite suppressed. However, in the case of a strongly fluctuating input signal U, there is a suppression to prevent the synchronization pulses whose amplitude is not exactly in the horizontal Part 24 of the transmission characteristic should fall, as has already been suggested, the position the transmission characteristic or at least the position of the left flank of the amplitude the input signal can be made dependent. According to the invention, however, is during the presence of synchronizing impulses the positive bias of the control grid 1 increases and thus the transmission characteristic is widened so that it becomes the left flank z. B. the curves 17 or 18 result. The horizontal part 25 of the transmission characteristic and thus the area in which the synchronizing pulses are separated from the amplitude of the input signal U, have become much larger. The increase the bias voltage U, and thus the broadening of the transmission characteristic are now like this to choose that sync pulses are certainly not suppressed themselves.

The preload can be increased either by adding an additional Bias or acts. In Fig. 1, the bias voltage Uo is reduced by lowering of the bleeder resistor 10 due to the addition of the capacitors 12 supplied positive pulses 13 increased. These pulses 13 can either be separated from the Synchronization pulse or derived from the horizontal and vertical deflection voltages will. The pulse can also be obtained in a simple manner from the flyback voltage will. Another way to increase the preload is to reduce it of the bleeder resistor 10. This bleeder resistor is then passed through an electron tube or replaces a controllable semiconductor element, to which one of the just listed, Pulse voltages coinciding with the occurrence of synchronization pulses is supplied as control voltage.

Claims (7)

PATENT CLAIMS: 1. Circuit arrangement for interference immune transmission of synchronizing pulses from a television signal with a multigrid tube two control grids, in which the first control grid of the tube carries the complete television signal with negative polarity of the synchronizing pulses and the second control grid that supplied complete television signal with positive polarity of the sync pulses and in which the first control grid has a resistor connected to a positive Bias, characterized in that the bias of the first control grid is greatly increased during the presence of synchronizing pulses. 2. Circuit arrangement according to claim 1, characterized in that the increase in the preload by Reduction of the series resistance is effected. 3. Circuit arrangement according to claim 2, characterized in that an electron tube as a variable series resistor or a controllable semiconductor element is used. 4. Circuit arrangement according to Claim 1, characterized in that the increase in the bias by applying an additional positive pulse is effected to the first control grid. 5. Circuit arrangement according to Claim 4, characterized in that the additional Pulse is derived from the separated synchronization pulses. 6. Circuit arrangement according to claim 4, characterized in that the additional pulse from the horizontal and / or vertical deflection voltages is derived. 7. Circuit arrangement according to claim 4, characterized in that the additional pulse from the line return pulses is derived.