DE878961C - Circuit arrangement for deflectors in television receivers - Google Patents

Description

Circuit arrangement for deflection devices in television receivers In television receivers, in which the image is generated with a Braun tube, devices must be used exist between lines or. Image arrangement and image content the same Create assignment that was given in the image to be transferred. These devices form the receiving device. They are synchronized with the Senders controlled and build up the line grid, in which then the picture dinlialt assigned intensity distribution is classified.

In the following, only systems with so-called single-channel synchronization are considered considered, id. H. Transmission systems in which the various signals that control the deflection of the cathode ray in both coordinate directions, with one another are mixed. The various signals (hereinafter referred to as line and image pulses) are used to control various deflection organs (line and image deflection or in the case of the interlace method, serial deflection); they need to be sorted out from the mix so that they can take effect individually on the organs assigned to them. There are basically two ways of doing this, as shown in the schematic illustration Ader Fig. I a and i b are explained. In Fig. I a the pulse mixture is simultaneous given on the two deflectors; the image deflection only reacts to image impulses, the line deflection on line and image pulses. Reacting to line impulses is desirable; the image impulse only lifts the for the length of its duration controlled Line deflection on. In the case of Fig. I b, the line and image deflection are located one after the other in the course of the line. The pulse mixture is applied to the line deflection given; the line deflection reacts in the desired way to line impulses, and the disturbance generated when a low pulse arrives in the line deflection generator serves here to stimulate the deflection of the image, i.e. to separate the impulses.

Two practical explanations for these two cases are shown in Fig. 2 a and 2 c explained. On the control grid of a so-called thyratron. i in Fig. 2a the pulse mixture is given. This thyratron is located in the anode lead a resistor, 2, through which a capacitor 3 is charged. At every line pulse If there is a passage of current in the thyratron, the capacitor 3 is discharged. The sawtooth-shaped voltage created on it is applied to a pair of deflector plates Braun's tube placed or used when it comes to magnetic deflection should, to generate or control a deflection current. From the control grid, des Thyratrons i leads a supply line via a resistor q to the control grid 5 of a Thyratrons 6; A capacitor 7 is located between the control grid 5 and the earth potential. The RC element 4, 7 is dimensioned in such a way that the pulses when line pulses arrive The voltage surges occurring at the control grid 5 are not sufficient: the thyratron 6 to ignite. If, on the other hand, a picture pulse arrives, which, according to its duration, has many line pulses @ includes, the control grid 5 comes to such a 'high potential that the thyratron 6 is ignited. This potential profile at the control grid 5 is together with the Impulse mixture in A # bb. 2 b, where the - dashed line, the grid potential indicates at which the thyratron is ignited. If a current flows in the thyratron 6, will the capacitor 8, which was charged via the resistor.9, discharged, and the The sawtooth-shaped voltage produced at the capacitor 8 is transmitted to the second pair of deflecting plates fed to the Braun tube.

A circuit for the case that line and image deflection .in the course of the line 'are one behind the other, is shown in Fig. 2c. On the control grid of an electron tube, which is supposed to do the line deflection, is again given the pulse mixture. The capacitor i2 charged through the resistor i i is discharged in the rhythm of the line impulses; .these voltage fluctuations are once fed to a pair of deflector plates and also capacitively to the control grid a pipe 13 coupled, which here has the function of a Umkehrmahres. Its anode aesthetically coupled to the control grid of the image thyratron 14, via Anode resistor 15, the capacitor 16 is charged, its sawtooth voltage serves as a distraction again. The grid of the thyratron 14 is on one such a potential, that there is a positive impact, .that there is a short-term, by a line pulse triggered discharge .des capacitor 12 via the tube 13 receives, the Thyratron can not yet open. If, on the other hand, there is now an image impulse in the pipe io, the condenser 12 becomes much longer and thus on a deeper one Discharge potential. The current through the pipe 13 is much smaller than before, the voltage at the anode rises to a higher value, the grid of the thyratron 14 becomes more positive and the thyratron ignites and causes the discharge of capacitor 16.

The act of distraction consists of two essential parts of each other different. Phases. While the capacitor is charging, e.g. 3 in Fig. 2a, the cathode ray becomes slow as its voltage increases guided over the screen of the Braun tube; during this time the baffle is (i in Fig.: 2 a) blocked. - The deflection tube is made current-permeable by the synchronization pulse made; the capacitor is discharged and thus the rapid return movement takes place the cathode ray to its starting point, e.g. B. to the left of the picture. Only during This rapid return movement is therefore: the deflecting tube is in action at all, and this phase of the process is always meant here when of the effect or activity of the thought generator or of the distraction is simply the talk.

The two deflection circuits described in Fig. 2a and 2c adhere another fundamental deficiency that severely affects their effectiveness. - During the duration of the image pulse, the line deflection tube is always there by virtue of its grid potential in an operating state that differs from the normal (synchronized Line deflection) deviates and can lead to considerable interference. In the case of the Fig. 2 a is able to carry out the line thyratron i free oscillations, and since the Neither known number of free oscillations during the duration of the image pulse can still be influenced, at the moment when the constraint (synchronization with line pulses), every possible phase position on the Zeälenthyratron exist, so that the synchronized line deflection may not work properly he follows.

In the case of the Alb. 2, c will if: the synchronization with line pulses fails and the tube is OK .strom-permeable, the capacitor 12 to another Discharge potential; . And so the mean power consumption of the pipe is a be different than in the normal state. With the sensitivity of the devices at hand this change in load will also have a disruptive effect.

To avoid these uncertainties, it is proposed according to the invention that the line deflection generator for the duration of the image pulse or line series pulse -to be put out of action after the image deflection has been initiated is. This can be done by allowing current to pass through during the deflection of the image Bdldablenkrohr generates a pulse until the end of the just effective image pulse stops and to block the line deflection generator serves.

Accordingly, the circuits shown in Fig. 2 a and 2 c can be used in can be easily improved, as shown in Fig. 3 a and 3 b. before the cathode of the thyratron 6 is a resistor 17, and the cathode itself is connected to the cathode of the thyratron i. If a current flows in the thyratron 6, then there is a positive voltage at the resistor 17, which the potential position between Control grid and cathode of the thyratron i influenced so that this thyratron i remains locked. In an analogous way, the second circuit (see Fig. 3b) in front of the cathode of the thyratron 1q. a resistor 1ä placed, and the cathode of the Thyratrons 1q. is connected to the cathode of the tube io. Here, too, arises again during the duration of the image pulse at resistor 18 a positive voltage, which blocks the thyratron io.

It is clear that the measure described here (introduction of a Cathode resistance) is not the only possible one; it will be in many ways succeed in generating a voltage during the duration of the currently effective image pulse, which puts the line deflection generator inoperative.

It can also be seen that the deficiencies outlined above are a Influence of the line deflection generator by the image deflection generator during the duration of the image pulse does not affect the switching arrangements shown in Fig. 2a and 2c are limited.

With all possible deflection generators, be it multivibrators, self-locking oscillating arrangements, so-called blocking oscillators, etc., can be used Basically differentiate between three groups: I. Externally controlled deflection organs, in which every single phase of the process .d; is caused by the control and the are deactivated without control.

II. Excited deflecting organs. These are indicated by a signal, e.g. B .. synchronization pulse, triggered once to execute the process; .the signal only triggers the process off, it has no influence on the further course of the process, and after the one-off In the course of the process, the deflecting organ is put out of action again.

III. Self-oscillating deflection generators: These perform the desired periodic movements are completely automatic, due to the synchronization just kept her in step with a prescribed rhythm; the synchronization but has no influence on the type and course of the process.

The present invention relates to steering generators of the Groups II and III. It is obvious that a group III deflector is through minor changes can be converted into a Group II change; because Controlled discharge vessels are used in all of the circuits for deflection devices considered here used, the control is done by a control grid, and its potential let yourself. set so that the generator just cannot swing freely, but is lifted into this state by Synchronisiersigna.le. On the other hand, a line deflection generator belonging to group 1I, i.e. the one in the pauses between the line pulses cannot oscillate freely during the duration of the image pulse transformed into a group III generator; .because here has the control grid permanent such a potential that the generator can oscillate freely. Therefore the measure of the present invention also for generators of group II necessary.

In all cases you will be from the currently effective image pulse, z. B. at the image deflection generator, can derive a voltage that the line deflection generator locks for the duration of the image pulse. Are in the deflection device so-called blocking oscillators is used, there is also the possibility of an inductive influence, the line deflection generator from the Bdldablenkgenerator her. For example, in the grid circle of the line deflection generator lying coil inductively from the one in the grid circle or from one in the anode circle of the Image deflection generator lying coil can be influenced in the desired manner.

Claims (2)

PATENT CLAIMS: i. Circuit arrangement for deflection devices in television receivers with Braunseher tube for the system, the single-channel synchronization, with which from the incoming impulse mixture according to the respective effective impulse line or B21. deflection generators are controlled,. characterized in that line deflection generators, which can oscillate themselves or which are repaired by synchronization signals vibrate, always for most of the duration of the each effective image pulse by one derived from the image deflection generator Voltage can be influenced so that it except for the end of the duration of the image pulse Activity can be set after the image deflection has been initiated. 2. Circuit arrangement according to Claim i, characterized in that one during of the image pulse current-carrying tube has a resistance in its anode circuit and that the voltage generated across it blocks the line deflection generator.