DE1194897B - Circuit arrangement for automatic line standard switching - Google Patents

Description

Circuit arrangement for automatic line standard switching The invention relates to a circuit arrangement for automatic line standard switching with a a pulse separator using a multigrid tube.

An option to switch from one line shape to another (e.g. B. from 625 to 819 lines) is particularly desirable where stations with different Line standards can be received or if a line standard change from the broadcast must be done because the program of a station with a different line standard was taken over will. Switching is advantageously not left to the user of the device, but takes place automatically with the help of a suitable switching device, for example a relay.

To a circuit arrangement for automatic line standard switching but there are certain demands to be made. It must be controlled with pulses which are free from other signals. This means that the ones used for driving Synchronization pulses must be free of the information signal. Furthermore, the The decoupling between the horizontal pulses and the automatic switchover must be so great that that with certainty no "dragging along" can occur. To function correctly so only synchronization pulses are used. Also, the circuit must be so selective ensure that proper functioning is guaranteed even if that Signal is affected by interference. And with everything, the circuit may be the normal one Do not influence the function of the device, d. that is, there must be neither reinforcement nor a damping, also no distortion of the impulses occur.

A circuit arrangement for switching the line standard has become known, which fulfills these requirements in itself. This known circuit consists of one Pentode as a synchronizing separation stage, a triode as a limiter stage and one another triode as a switching tube for the changeover relay. Through the limiter tube it is achieved that the line transformer comes from the device itself Line sync pulses are separated, d. H. no influence on the interrupter of the relay. The induced in an inductance in the anode circuit of the pentode Line pulses generate at resonance in connection with a capacitance after Rectification of such a large DC voltage in the grid circle of the interrupter that this is blocked. If other voltages are induced as a result of other line frequencies, if there is no resonance, the DC voltage drops. so that the interrupter unlocks will. As a result, the switchover relay picks up and causes the device to switch to the other line norm.

The separation of the synchronization pulses on the transmitter side in the anode circuit the pentode is only possible if the comparison pulses are transmitted by a limiter stage are kept away from the device. That means that the known circuit only is functional if two stages (synchronization disconnection and limiter stage) are present.

In many television sets, however, there is such an additional limiter stage not provided. Then the circuit described must fail because at the anode the synchronizing separation stage the comparison pulses are already present to such a large extent are that coupling the automatic switchover in the anode circuit is pointless; the automatic would also be influenced by the comparison pulses coming from the device. aside from that are in such single-stage circuits, the synchronization pulses on the grid of Synchronization separation stage still affected by the video signal.

On the other hand, it is a two-stage separation circuit for image and Line sync pulses known, the task of which is to use a multi-grating tube Image synchronization pulses that start exactly in time and have been freed from line synchronization pulses and pick up both pulses at different electrodes of the multigrid tube to be able to. With this circuit, however, it is no longer possible to obtain a control voltage the line synchronization pulses for the purpose of automatic line standard switching not possible. Furthermore, a single-stage pulse separation stage is known that simultaneously supplies a control voltage for the horizontal deflection generator on the anode side. The "high frequency" The line signal is picked up at the anode, the "low-frequency" image signal on the other hand on a screen grid because of the line scanning pulses applied to the anode the image signal could not be removed unadulterated. These known circuit arrangements, however, do not give any indications for the invention, namely take a line signal on the screen or brake grid of the pulse separation stage and gain a control voltage for the automatic line switching from this.

The invention creates a very simple one with very little effort working circuit arrangement in which the single-stage pulse separator circuit simultaneously used to generate the control voltage required for the line standard switchover without the pulse separation provided at the anode of the pulse separation circuit suffer from. These advantages are achieved according to the invention in that the Screen or brake grid of the same tube with a line frequency tuned and the switching signal delivering resonant circuit in such a transformer or is capacitively coupled and the ratio of the coupling elements to one another in such a way it is selected that, on the one hand, the DC voltage required to block the interrupter is sufficiently large even under unfavorable reception conditions, on the other hand the possibly The negative feedback caused by the inductance is negligibly small.

The invention is shown below on the basis of an exemplary embodiment explained in more detail and shown in the drawing.

F i g. 1 shows a basic circuit diagram with the coupling according to the invention; F i g. 2 and 3 each show a variant of the circuit according to FIG. 1, with only the different parts of the circuit are shown.

In all figures, the same elements are given the same reference symbols Mistake.

At the pentode 1 , which works as a synchronizing separation stage, the comparison pulses from the device itself are at the anode 2 , which, coming from the flyback transformer, reach the circuit at 3 and also in terms of transformers at 16 the anode circuit of the pentode 1. At 5, the video signal is available, which the control grid 4 can influence. The control pulses for the switching tube 6, in the anode circuit of which the switching relay 7 is located, are best picked up on the screen grid 8 of the pentode 1, but the braking grid 9 can also be used for this purpose. The pulses are then fed to an adapted resonant circuit 11, 12 via a capacitor 10. The capacitor 10 serves both as a coupling and as a blocking capacitor, ie, in addition to the coupling, it keeps the screen grid 8 or the braking grid 9 free. The inductor 11 of the resonant circuit 11, 12 is tapped on the one hand, the negative feedback of a negligible is given by the lying against mass Teilinduktivtät 11, on the other hand, however, the required on the grid 14 of the switch tube 6 DC voltage is so large that even in the most unfavorable reception conditions the interrupter 6 is safely locked. Too high a tapping of the inductance 11 would have an unfavorable effect on the anode signal as a result of the negative feedback. The rectification takes place in a known manner by means of a rectifier 13.

For special applications it can be beneficial or even desirable not to make the coupling by tapping the resonant circuit inductance, but the impulses picked up from the screen or braking grid inductively by a to transmit further inductance 15 to the resonant circuit II, 12 (FIG. 2).

In Fig. 3 is a further embodiment of the invention shown. Here the coupling is capacitive via two capacitors 12a, 12b.

For the safe blocking of the interrupter a sufficiently high DC voltage is applied to its grid, d. i.e. the one on the screen grid of the pulse separation stage decoupled voltage must be stepped up accordingly. The relationship of the two transformer sides (coil 11 a to 11 in Fig. 1; coil 15 to 11 in F i g. 2; Capacitor 12 a to 12 b in F i g. 3) is chosen so that once the necessary reverse voltage for the interrupter is available on the secondary side, but that the primary side does not cause any negative feedback, because this would adversely affect the anode signal of the pulse separation stage.

Claims (2)

Claims: 1. Circuit arrangement for the automatic line norms keeping with a multi-grid tube using a pulse separator, characterized in that the screen or braking grid of the same tube is so transformer-coupled or capacitive with an oscillating circuit that is tuned to the line frequency and delivers the switching signal, and the ratio of the coupling elements to each other (11a: 11, 15:11; 12a: 12 b) is chosen such that on the one hand the DC voltage required to block the interrupter (6) is sufficiently high even under unfavorable reception conditions, and on the other hand the potential caused by the inductance (11a, 1.5) caused negative feedback is negligibly small. 2. Circuit arrangement according to claim 1, characterized in that the coupling capacitor (10) also serves as a blocking capacitor. Considered publications: German Auslegeschriften No. 1019 700, 1050 805, 1098 991.