DE1036312B - Circuit arrangement for interference blanking in synchronization circuits of television receivers - Google Patents

Description

When receiving television broadcasts, interference pulses that occur or are received lead to two larger ones Groups of disturbing phenomena that can occur individually or together and are in their Differentiate effect. On the one hand, the interference can be superimposed on the image signal and lead then, for example, to »snow« on the screen or to light or dark areas in the picture, depending on the type of modulation, etc.

On the other hand, glitches can cause synchronization of the deflection devices, preferably the vertical deflection generator, is severely disturbed whereby, for example, the picture begins to "run" or the individual lines at the edges of the picture are shifted against each other, so that the edge of the picture is no longer smooth, etc.

A large number of circuits are known for suppressing or compensating for such interference pulses. The stability of the synchronization circuits is determined, for example, by phase comparison circuits, by flywheel circles, etc., enlarged. It is also known to cause glitches by limiter circuits to cut off the tips with a very large amplitude. It is also known circuits to be used for interference blanking in the amplitude filter.

The known circuits have the disadvantage that when larger interference pulses occur, these are amplified by the pulse separation stage and thereby the synchronism of the deflection generator is severely disturbed. To remedy these disadvantages, it is known to use an additional tube system in which strong interference pulses that exceed the synchronous level, separated from the video signal and in suitable polarity and amplitude the grid of the amplitude filter are fed. The signals coming from the anode circuit of the video output tube have an opposite polarity so that the glitches cancel each other out and do not get to the pulse amplifier can. However, the effort involved in introducing this new level is relatively great. Around To reduce this high effort, it is also known to use a tube with two as an amplitude sieve Control grids, preferably a heptode, should be used.

It is also generally known to use a disturbed signal channel, for example the sound channel temporarily blanked by blocking pulses that are fed to the screen grid of an amplifier stage. With such a known circuit, however, the image channel is not interrupted during the disturbance, but the interference pulses are filtered out and via a normally blocked, additional tube, which is opened by the interference pulses, to a second grid of the picture tube in the opposite direction Circuit arrangement for interference blanking

in synchronizing circuits

of television receivers

Applicant:

Max Grundig,
Fürth (Bay.), Kurgartenstr. 37

Helmut Krug, Fürth (Bay.),
has been named as the inventor

Phase applied to the image signal. This circuit is also due to the need for an additional Tubing system, the effort is relatively large.

In another known circuit, the interference pulses in the television signal which exceed the synchronous level are removed from the screen grid of an intermediate frequency amplifier tube for the purpose of interference suppression and fed to the amplitude filter. However, this circuit also has significant disadvantages. For example, the IF amplifier tube mentioned must work in the lower curve of the curve in order to deliver pulses that can be used for interference blanking on the screen grid. A stage set in this way, however, provides no or only a very low gain for the useful (video) signal, due to the lack of screen grid current. Due to this fact, the known circuit of a circuit with additional ^{noise blanking stage 1 is} to be equated in terms of switching effort, since the tube mentioned does not amplify, but only gates out the disturbance. If you try to use the tube mentioned for video signal amplification, then the video signals that appear on the screen must be separated from the interference pulses. In the known circuit, this separation is carried out by integration. For integration, a

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Speaking dimensioned capacitor is necessary, which, however, blurs the interference pulses in their width, so that the Amplitude sieve is blocked longer than is actually necessary. On the other hand, the one used for blanking loses Pulse considerable in amplitude. It must therefore also be amplified in order to eliminate interference to achieve the necessary pulse amplitudes. In addition, when the pulses are decoupled, the Screen grid of the IF amplifier stage additional phase errors, and it is the video signal, due to the shape of the necessary characteristic, trimmed.

The invention now relates to a circuit arrangement for interference blanking in synchronization circuits of television receivers with probe tube for control voltage generation and pulse separation stage, in which the above-mentioned disadvantages and shortcomings of the known circuits are avoided in that interference pulses superimposed on the image signal are removed from the screen grid of the probe tube and the screen ao Grid of the pulse separation stage are fed in such a way that they the amplitude filter during the duration block the glitches. The inventive arrangement thus takes over the probe tube at a keyed control voltage generation the function of the otherwise necessary additional stage by the circumcision, Reversal and amplification of the glitches in this probe tube itself takes place. The coupling without time constant on the screen grid of the separation stage has the essential advantage that Charging of the grid combination can be avoided. The amplitude sieve thus actually becomes only blocked for the duration of the disturbance.

The invention will be explained in more detail with reference to the drawing.

In Fig. 1, the arrangement according to the invention is shown schematically, only for understanding The switching elements necessary for the arrangement are shown and others that are necessary per se, but for explanation unnecessary elements are omitted.

At the resistor 1 in the cathode circuit of the probe tube 2, which at the same time forms the cathode resistance of the video output tube (not shown), the negative image signal occurs in addition to the suitable bias voltage. The bias holds the probe tube 2 locked almost up to the black level of the image content. Only when the line sync pulses cancel the bias voltage and at the same time a positive pulse derived from the flyback transformer and fed to the probe tube 2 via point 3 of the anode 4 forms the anode voltage does a current flow through the probe tube 2, which at the load resistor 5 provides the control voltage for the IF- and / or RF amplifier generated. The screen grid current that occurs is insignificant. If interference pulses occur during the transmission of the image content, for example caused by spark plug sparks or dry shaving devices, etc., the amplitude of which exceeds the peak voltage of the sync pulses, then current is taken over by the screen grid 6. The screen grid 6 now acts as an anode, and the tips the interference pulses occur increasingly at junction 7 of the screen grid voltage divider with resistors 8 and 9. These pulses are now according to the invention via the branch point 10 of the resistors 11 and. 12 existing low-resistance voltage divider for the screen grid voltage of the tube 14 of the amplitude filter is fed to the screen grid 13 thereof. As a result, these pulses block the amplitude filter during the disturbance, even with the resistor 12, which is kept low for known reasons. Above all, this avoids the disruptive charging of the integration chain of the image synchronization, which results in constant fluttering of the image.

The double utilization of the tube 2 without additional switching means makes it a very effective one Glitch blanking reached. Compared to the known circuits, there is an essential one Saving on switching means with at least the same effectiveness compared to the use of a heptode As an amplitude filter tube, there is the advantage that even smaller interference pulses as soon as they are only about the sync level protrude, are rendered ineffective due to the amplification in the probe tube.

The connection between the two screen grids 6 and 13 of the probe tube and the pulse separation stage expediently takes place capacitively via the capacitor 15.

An advantageous further development of the invention is shown in FIG. This is where the connection is made between the point 7 or the screen grid 6 of the probe tube 2 with the point 10 or the screen grid 13 of the tube 14 via a correspondingly biased diode 16. The bias of this diode can be choose within certain limits by suitable choice of the voltage divider 8, 9 and 11, 12 such that they only interference pulses with a greater amplitude than the image pulse residues occurring on the screen grid 6 lets through. This has the further advantage that the image pulses do not appear on the amplitude filter are weakened by the image pulse residues originating from the tube 2.

It is also possible, by means of a further embodiment of the invention, to make suitable diodes 16 Pick up pulses and feed them to the picture tube in such a way that the interference pulses are otherwise visible Disturbances, bright or dark areas in the picture, can be compensated.

The invention is not limited to the embodiment described, but can, for example adapted accordingly, can also be used with grid-controlled probe tubes.

Claims (5)

Patent claims: 1. Circuit arrangement for blanking out interference in synchronization circuits of television receivers with probe tube for generating control voltage and pulse separation stage, characterized in that the image signal superimposed interference pulses on the screen grid (6) of the probe tube (2) removed and the Screen grid (13) of the pulse separation stage (14) are fed in such a way that they pass the amplitude filter block for the duration of the glitch. 2. Arrangement according to claim 1, characterized in that the screen grid of the probe tube (2) and the pulse separation stage (14) are capacitively connected to one another. 3. Arrangement according to claim 1, characterized in that the connection between the Screen grid of the Täströmhre (2) and the screen grid of the pulse separation stage (14) by a prestressed Diode (16) takes place. 4. Arrangement according to claim 3, characterized in that the bias of the diode (16) is chosen so that only glitches with a larger amplitude than the remaining image pulse on the probe tube (2). 5. Arrangement according to claim 3 and 4, characterized in that the diode (16) with a suitable Electrode of the picture tube is connected in such a way that the pulses passing through the diode additionally compensate for the corresponding image glitches. Considered © publications: Swiss Patent No. 310 370; French Patent No. 1,059,503; "Funkschau", 1954, issue 20, p. 422. 1 sheet of drawings