DE1122985B - Circuit arrangement for obtaining antiphase clamping pulses from a video signal - Google Patents

Description

Circuit arrangement for obtaining clamping pulses in antiphase from a video signal The invention relates to a circuit arrangement for extraction of antiphase clamping pulses from a video signal with one as an amplitude filter working tube, in whose anode circuit an oscillating circuit is arranged, to the a rectifier is connected in parallel, with the exception of the first half-wave the energy stored in the resonant circuit is short-circuited.

There are already circuit arrangements for obtaining antiphase Clamping pulses known from a video signal.

Fig.l shows the basic circuit diagram of such a circuit arrangement, which essentially consists of a single-stage tube amplifier with a subsequent amplitude filter and an output stage acting as an amplitude limiter to which a Clamping bridge connects.

The incoming, positively directed BAS signal reaches the control grid of the first tube Rö 1 via the coupling capacitor 1 and the grid discharge resistor 2; From this amplifier stage, the amplified and polarized signal is sent via the coupling capacitor 3 to the control grid of the second tube Rö 2, which is connected as an amplitude filter; In this tube stage, the image content of the signal is cut off from the BAS signal in a known manner, so that only the sync pulses are contained in the anode current of this tube; the anode current modulated with the synchronizing pulses triggers the parallel resonant circuit 4, 5 arranged in the anode circuit of this tube to oscillate, which begins at the leading edge of the pulse and, depending on the damping of the resonant circuit, decays more or less quickly according to an exponential function until the next Impulse the next trigger occurs.

The diode 6, which is arranged parallel to the oscillating circuit, is blocked during the first half oscillation of each wave train, while it becomes permeable during the second half oscillation and short-circuits the energy stored in the oscillating circuit, so that all following waves are suppressed and the grid of the following third tube Rö 3 only the first half-wave of the oscillation process becomes effective.

In this way you get a at the output of the second tube stage Pulse train which corresponds to the pulse train frequency of the sync pulses; the amplitudes however, the impulses are not completely constant, but fluctuate depending on the image content, the rise time of the sync pulses and the pulse train. because but the clamping circuit must be supplied with pulses with a constant amplitude, the impulses must be limited again by means of the third tube Rö 3 will.

Since this last tube stage has to deliver positive and negative pulses of the same size to the clamping circuit, an equal resistor 7, 8 are arranged in the anode and cathode supply lines and coupling capacitors of the same size are arranged in the connecting lines of the clamping circuit bridge.

In this circuit arrangement, the clamping pulses are during the sync pulse base available; should they come only during the back porch, so will still further tube stages needed, by means of which the necessary time delay can be effected.

However, these known circuit arrangements have the following disadvantages: 1. Since the internal resistance of the anode output is identical to the resistor 7 and the internal resistance of the cathode output from the parallel connection of the resistor 8 with, S. exists, but the resistors 7 and 8 must be of the same size with regard to the impulse voltage equality, the internal resistance of the cathode source is always smaller than that of the anode source.

With the output stage of this circuit arrangement, the condition desired for controlling a clamping circuit, that the clamping pulses come from sources with very low and equal internal resistances, cannot be met. 2. If several clamping circuits are to be operated in one amplifier, the clamped amplifier stages would be coupled to one another via the common internal resistance of the clamping pulse sources; the amplifier would therefore tend to oscillate as soon as one of the clamping circuits has the slightest asymmetry; several clamping circuits can therefore only be operated from one and the same circuit arrangement if the individual clamping pulse sources are decoupled from one another; With the known circuit arrangement, this could only be achieved by connecting several limiter stages Rö 3 connected in parallel to the second tube stage Rö 2 acting as an amplitude filter, ie a further tube would be required for each additional clamping pulse source.

3. The video signal at the input can contain low-frequency interference voltages included, e.g. B. superimposed mains hum. Once the ripple voltage is around 5 to 15010 reaches the video voltage, the clamping pulse shaping circuit fails because the amplitude filter suppresses ripple voltage; this is particularly disadvantageous in those cases in which the clamping circuit is currently being used to suppress ripple voltage.

In addition, it is already known to use tactile pulses in antiphase Derive the help of push-pull transformer circuits from a single original pulse. However, this known circuit arrangement can by no means for the following reasons can easily be used as a phase inversion stage in a video circuit. At the The anode resistance of the tube stage working as an amplitude filter is obtained from the previously known circuit arrangements for obtaining clamping pulses from one Video signal pulse series comprising both vertical and horizontal pulses; the frequency spectrum of these pulse series does not only consist of the line frequency of 15 kHz and their harmonics, but it also contains components of 25 and 50 Hz and their harmonics.

Push-pull transformers covering a frequency band from 25 Hz to about 3 MHz could be transmitted with the correct amplitude and phase, but are with the previously known technical means not feasible.

In the circuit arrangement according to the invention for obtaining antiphase Clamping pulses from a video signal with a tube working as an amplitude filter, in the anode circuit of which a resonant circuit is arranged, to which a rectifier is parallel is switched by, with the exception of the first half-wave, those in the resonant circuit stored energy is short-circuited, these disadvantages are avoided by that the resonant circuit coil at the same time the primary winding of a transformer with a Forms center-grounded secondary winding on which is symmetrical via capacitors Clamping pulses are removed, both for feeding its own clamping circuit as well as external clamping circuits, whereby the capacitance of one of the two capacitors, via which the clamping pulses are fed to its own clamping circuit, at least by 5010 larger than that of the other, and that in the primary circuit of the transformer Rectifier is arranged, which has a voltage divider and a capacitor - In a manner known per se - is biased so that the first let through Half-wave is limited to a specified value.

An advantageous development of the invention is that the Rectifier that suppresses the vibrations excited by the sync pulses with the exception of the first half-wave, between the center tap and a The end of the secondary winding of the transformer is arranged.

The symmetrical ones taken from the secondary winding of the transformer Clamping pulses can be used to feed external clamping circuits as well as a serve their own clamping circuit, according to a further embodiment of the invention In the anode circuit of the tube, which works as an amplitude sieve, several oscillating circuits are connected in series whose coils also form the primary windings of symmetrical transformers, which are used to receive pairs of clamping pulses for other third-party clamping circuits.

2 shows the circuit diagram of an embodiment of the invention. The mode of operation of this circuit arrangement is described and explained in more detail below. The incoming BAS signal reaches the control grid of the first tube Rö 1 via a clamping circuit 9, in which - as in the known circuit arrangement described at the beginning - it is amplified and polarized and then over one ° n Coupling capacitor 3 is placed on the control grid of the second tube Rö 2, which is connected as an amplitude filter. In the anode circuit of this tube is a parallel resonant circuit, which consists of a capacitor 11 and the primary winding 10 of a decoupling transformer Ü 1 ; the required amplitude limitation of the sync pulses is carried out in this case in the primary circuit of the decoupling transformer by means of a diode 13, the bias of which can be tapped in a known manner at a voltage divider 14, 15 and determined by appropriate selection or setting of the resistance values or the dividing ratio of this voltage divider. A capacitor 16 is also connected in parallel with the partial resistor 14.

The suppression of all further wave trains of the sync pulses except for the first half-wave is effected by a diode 12 ; this is in this case not arranged parallel to the parallel resonant circuit in the anode circuit of the second tube, but in the secondary circuit of the decoupling transformer U 1 , because this avoids the risk of the pulse voltage exceeding the permissible reverse voltage of the diode.

The secondary winding 19 of the decoupling transformer Ü 1 is provided with a center tap and connected to ground with this; consequently, positive and negative clamping pulses of the same amplitude from sources both low and the same internal resistance are obtained at the output terminals of the secondary winding of the decoupling transformer.

If the clamping pulses obtained in this way are fed via isolating capacitors 17, 18 to the clamping circuit bridge 9 located at the input of the circuit arrangement, any ripple voltage disturbances that may occur in the input circuit of the amplifier tube Rö 1 are suppressed, i.e. the arrangement for generating the clamping pulses clamps itself, so to speak ; However, there is now an alternating current connection between the output and the input of the circuit arrangement, which in the event of the slightest detuning of the clamping circuit bridge 9 could act as a feedback circuit and lead to self-excitation of the circuit arrangement; In order to avoid this, according to the invention, a slight detuning of the clamping circuit bridge is caused by the fact that the capacitance of one of the two isolating capacitors 17, 18, via which the clamping pulses are fed to the clamping circuit bridge 9, is selected to be at least 5 ()! () greater than that of the other Separating capacitor, so that the voltage coming from the output of the circuit arrangement via the clamping circuit bridge to the grid of the VersLärkerröhre Rö 1 causes a negative feedback.

The clamping pulses for the external clamping circuit are extracted through the capacitors 27, 28.

FIG. 2 shows a second decoupling arrangement with a further transformer G'2 with a primary resonant circuit 20, 21 and a secondary winding 29 for a further pair of clamping pulses; since there is considerable power available in the anode circuit of the second tube despite the low current. On the circuit arrangement described above, several pairs of clamping pulses can also be picked up by means of further decoupling transformers; The individual pulse sources are, however, coupled to one another via the internal resistance of the second tube; but since this is very large, this coupling does not have a disadvantageous effect in practice.

The circuit arrangement according to the invention thus has compared to the known circuit arrangements have the following significant advantages: 1. that one Clamping pulse pairs of equal amplitude from sources both low and equal Internal resistance is obtained, 2. that several pairs of clamping pulses can be obtained without the need for additional tubes can win from one and the same circuit arrangement, while with the previously known circuit arrangements for each pulse source a separate tube he; i (itigt was, 3. that the self-locking pulse shaping circuit fails only when the ripple voltage is significantly greater than the peak voltage of the video signal.

Claims (3)

PATENT CLAIM: 1. Circuit arrangement for obtaining antiphase clamping pulses from a video signal with a tube working as an amplitude filter, in whose anode circuit an oscillating circuit is arranged, to which a rectifier is connected in parallel, through which the energy stored in the oscillating circuit, with the exception of the first half-wave is short-circuited, characterized in that the resonant circuit coil (10) at the same time forms the primary winding of a transformer «11) with a center-grounded secondary winding (19) from which symmetrical clamping pulses are picked up via capacitors (17, 18 or 27, 28) to feed its own clamping circuit (9) as well as external clamping circuits, the capacitance of one of the two capacitors, via which the clamping pulses are fed to the own clamping circuit, is at least 50/0 greater than that of the other, and that in the primary circuit of the transformer ( (11) a rectifier (13) is arranged, which has a Voltage divider (14, 15) and a capacitor (16) - in a manner known per se - is biased so that the first half-wave that is allowed to pass is limited to a predetermined value. 2. Circuit arrangement according to claim 1, characterized in that the rectifier (12), which serves to suppress the oscillation components excited by the sync pulses that follow the first half-wave, between the center tap and one end of the secondary winding (19) of the transformer (Ü 1) is arranged. 3. Circuit arrangement according to claims 1 and 2, characterized in that in the anode circuit of the tube (Rö 2) working as an amplitude sieve several resonant circuits (10, 11 and 20, 21) are connected in series, the coils (1l0 or 20) of which are also the primary windings of symmetrical transformers (Ü 1 and Ü 2) , which are used to pick up clamping pulse pairs for other third-party clamping circuits. Considered publications B. Chance et al: "Waveforms", McGraw-Hill, 1949, p.49.