DE972808C - Circuit arrangement for separating line and image synchronization pulses - Google Patents

Description

ISSUED OCTOBER 1, 1959

15531 VIII a 12i a *

The invention relates to a circuit arrangement for separating the line and frame synchronization pulses in television receivers. It is also aimed at the separate generation of the synchronizing pulses to be carried out while largely eliminating the influence of interference. In particular It is the object of the invention to produce pulses with a large edge steepness with positive polarity.

The previously known circuits for generating pulses with a steep edge have the disadvantage that the pulses occur with negative polarity. Therefore, they do not come directly to the Control of certain types of time base circles in question, for example those with thyratrons work.

The circuit proposed according to the invention makes it possible to assign these basic time circles directly synchronize, as the generated pulses are sufficiently steep and at the same time of positive polarity are. ao

As is known, the image signal can be derived from the composite synchronizing signal separate by feeding the television signal to the input grid of a tube which is only controlled by the positive synchronizing signals, while as the image content falls below the kink in the characteristic curve of the tube and is suppressed. In this way you get z. B. with a pentode already output side separate synchronization signals for the Line and image changes at the anode and at the

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Screen grid, whereby the mutual influence of both output circuits is switched off with the help of diodes must become. As is known, this tube wall can be circumvented, for example, by that one uses the braking grid of the pulse separator tube and thus tube two different working states possible.

Such a circuit works according to the Transitron principle as follows: The line pulses cause negative screen grid pulses that are used to deflect lines. In addition, the falling Screen grid potential via a differentiating element as a negative pulse on the braking grid Effect, whereby the anode current is blocked, the screen grid current is additionally supported. the The time constant of the retarder charge maintains this state for the line pulse duration. At the However, when a much longer image pulse occurs, the anode current sets in, causing the Screen grid current is weakened and therefore the braking grid, now very quickly in the opposite direction Working in favor of the anode current. Arise on the screen grid so line pulses at the anode only. As a disadvantage of this procedure When the tube function is reversed, S tor pulses occur at the electrodes to be blocked on, furthermore the polarity of both types of impulses is negative. The Transitron flip-flop is working semi-independent, so it is relatively sensitive to changes in operating voltage and interference pulses.

These disadvantages are eliminated by the present invention, which manages exclusively with dependent pulse generation and also produces positive pulses. This is achieved according to the invention in that the synchronization mixture is first removed from the screen grid of a first tube, Vi, and fed to the control grid of a second tube, and that at the output of this tube, on the one hand, the line pulses are removed and, on the other hand, the pulse mixture is fed to an integration circuit. This integration circuit is connected to the negatively biased braking grid of the first tube, so that its anode can only carry current at a certain level of the integrated pulse voltage, i.e. only at the time of the picture change. The pulse voltage that is also active on the grid of this tube triggers a sharp, positively directed anode voltage pulse through the back of the first image change pulse. In contrast to the previously known circuits, the following functions are fulfilled according to the invention with only two tubes: image clipping, separation of the sync pulses and generation of positive control pulses for both time base circles of the television receiver. Furthermore, the influence of interfering pulses including the line alternating pulses is prevented by the fact that the negative braking grid potential normally blocks the anode current at all, i.e. does not first have to be put into this state by the line pulses. In addition, the proposed integration for controlling the braking grille is naturally superior to a method that works with differentiation given the short duration of interference pulses.

The invention will now be based on an exemplary embodiment and with reference to the drawing explained.

The television signal is applied to the control grid of a pentode V 1 via a network consisting of the resistor R ι and the capacitance C 1. It is assumed that in this composite signal the image signals are negative and the synchronizing pulses are positive. The time constant of the input network Ri, Ci then acts in such a way that a grid bias occurs when the tube is activated, so that the image signals are practically suppressed and only the positive synchronizing signals are involved in the control. These cause corresponding pulses of negative polarity on the screen grid, while the anode current remains blocked by the negative bias voltage of the braking grid fed via a resistor R S. The anode and the screen grid are connected to the positive pole of the supply voltage via the load resistors R6 and R7.

The negative pulses occurring on the screen grid of the tube V1 are fed to the control grid of a second tube V 2 via a network consisting of the resistor R 2 and the capacitance Cz. In the present exemplary embodiment, this tube is a pentode whose anode and screen grid are at positive potential via the load resistors R8 and Rg , while the braking grid is at the potential of the cathode, i.e. at ground potential. The tube 2 works as a phase rotator for the purpose of bringing the pulses to positive polarity. The line pulses can either be taken from the screen grid or from the anode. The entire pulse mixture occurring at the anode of this tube and in phase with the pulse voltage at the control grid of tube Vi is applied to a resistor-capacitance network i? 3, C 3, which is connected to the braking grid of tube V1 via a decoupling capacitor C 5 stands. The network R 3, C 3 represents an integration circuit, the time constant of which is dimensioned such that there is a large difference between the charging voltages caused by the short line and the long image change pulses. In other words, the voltages which occur at the braking grid of the tube V1 depend on the length of the pulses, so that only the long image change pulses are able to generate a positive voltage of a reasonable amount. The negative bias voltage which the braking grid of the tube V 1 generally carries is sufficiently great that the integrated line pulses are unable to achieve a potential shift at which an anode current can flow. Only the voltage generated by an integrated image pulse is above the blocking limit value, so that the tube

in this case begins to conduct current and receives a more and more negative anode potential. At the end of the first image pulse, the tube is quickly blocked by the back front of this pulse, which simultaneously acts on the control grid, so that a steep, positive-directed pulse occurs at the anode , which is picked up via the differentiating element R 4, C4 and fed to the basic time circuit for the image change .

It goes without saying that deviations from the exemplary embodiment explained above are possible are without thereby departing from the basic concept of the invention.

Claims (3)

PATENT CLAIMS: i. Circuit arrangement for the separation of line and picture synchronization pulses in television receivers, in which the picture signals directed opposite to these pulses are separated from the mixture of synchronization pulses in the input circuit - a pentode (Vi) , characterized in that the synchronization signal mixture is taken from the screen grid of this tube and the control grid of a second tube (V 2) is supplied and that at the output of this tube on the one hand the line pulses are picked up and on the other hand the pulse mixture is applied to an integration network that is connected to the negatively biased braking grid of the first tube, so that its anode is only at a certain height of the integrated impulse voltage, i.e. only at the time of the image change, the impulse voltage also effective at the control grid of this tube triggers a sharp, positively directed anode voltage impulse through the back of the first image change impulse. 2. Circuit arrangement according to claim 1, characterized in that the second tube (V 2) is a pentode. Publications considered:
British Patent No. 629 504. 1 sheet of drawings 3 509 700/332 3. (909 611/4 9.59)