DE972364C - Circuit for picture and line return blanking - Google Patents

Description

ISSUED JULY 9, 1959

F 14783 Villa / 21a ¹

Emil Siegel, Darmstadt

has been named as the inventor

TV G.m.b.H., Darmstadt

Patent issued on June 25, 1959

In particular in the case of television control receivers, it is absolutely necessary for image control that this the scanning beam is blanked during the beam return. The circuits proposed so far are either associated with a great effort to generate the blanking pulses, or they do not allow perfect blanking during the entire retrace.

The object of the present invention is to provide a circuit with which under relatively with little effort an exact blanking both during the image rewind and during of the line return is reached.

It is already known that blanking pulses of negative polarity are used for dark control of the Wehnelt electrode. the Kaitjhodien beam tube to gain from the sawtooth voltage supplied by the deflection device. A diode connected to the lead to the Wehnelt electrode only lets through the peaks of the sawtooth voltage as blanking pulses. The amplitude of the blanking pulses obtained in this way is only a small fraction of the amplitude of the sawtooth voltage, and the shape of the pulses is determined by the shape of the sawtooth. _t . as

It has also already been proposed to steepen the harmful parallel capacitance trailing edge smoothed to form a resistance of impulses to derive the charge of the harmful capacity accelerated by the charge reversal

909 551/14

the capacitance is initiated at the beginning of the trailing edge to an opposite potential and is terminated by an equilibrium straightener that acts as a switch when the zero potential is reached. In the circuit according to the designation for obtaining voti Ai3sta; 3timpulses of the required shape and width, narrow voltage pulses are taken from the deflection device, which charge a capacitor, from which the blanking pulses ίο are taken and whose recharge is interrupted by a parallel diode path before the recharging voltage is reached, so that a blanking pulse with an almost linear trailing edge is produced.

"The circuit according to the invention has the advantage that the shape and width of the obtained Blanking pulse is independent of the shape of the input voltage, and can be adjusted by appropriate Dimensioning of the circuit can be selected to be suitable for the intended use. It therefore emgangia impulses of any shape can be used that only meet the condition must have a stiff leading edge. If this does not exist from the start is, the steep flank can according to a development of the invention produced in a manner known per se by differentiating the input voltage turn around. As a rule, this is used for the image tilting device to obtain the image output impulses drawn voltage may be required. The voltage taken from the cell tilting device on the other hand it is normally already pulsed, so that a differentiation is not necessary; is.

It is particularly advantageous to connect the differentiating element with the charging capacitor via a diode associate. Because this diode during the beam trace is closed, the voltage on the charging capacitor is independent during beam tracking on the image-frequency voltage occurring at the differential element and only dependent on the ratio of the charging resistance to the internal resistance of the diode, which is parallel to the lacquer capacitor is switched.

Further details and advantages of the invention are described below with reference to FIGS. 1 to 3 showing the exemplary embodiments.

The signal taken from the image tilting device has the course indicated in FIG. 1 under α. It is an almost sawtooth-shaped voltage that lines up through the coupling of the deflection coils! requent pulses 1 are superimposed. It is fed to the sampling circuit via terminal 6, in which a differentiation is carried out by means of the C element 7, 8, the value of the time constant of the C element not being critical. Curve b in Fig. 1 shows the resulting pulse. This pulse charges the capacitor 9 via the diode 10 to the peak of the pulse voltage. During this time the diode 11 is blocked. The capacitor 9 discharges after reaching the peak voltage via the resistor 12 according to deT in Fig. 1 under c indicated discharge curve 13. If the diode 11 were not present, it would be reloaded to the voltage - u _v. The diode 11, however, prevents this complete charge reversal, since it opens as soon as its cathode has reached ground potential through charge reversal of the capacitor 9. As a result of this charge reversal in the direction of a negative potential, a much steeper trailing edge of the blanking pulse is achieved than if the capacitor were only discharged.

Further special properties of the circuit are shown on the basis of the equivalent circuit diagram in accordance with Flg. 2 explained. When using normal diodes, the longitudinal resistance 14 exhibits during the beam travel as a result of the blocking of the diode 10, a value of over 100 kΩ, while the transverse resistance 15, which corresponds to the internal resistance of the diode 11, only has a value of less than So as ι kQ owns. During the jet return are the reverse is true. Then the series resistance 14 has a value of about 1 kQ, while the transverse resistance 15 is greater than 10 JkQ. It follows that the blanking circuit during the run is very low resistance. This offers a very special advantage when a Black control takes place on the Wehnelt cylinder and blanking on the cathode. Despite activation this complex resistance in the cathode lead gives way because of the low resistance of the blanking circuit does not amplify direct and alternating currents significantly different from each other. This has practically no influence on the effect of the black control circuit exercised.

Furthermore, the potential at the exhaust electrode is constant and only given during the beam tracking by * the ratio of the voltage divider, which is determined by the resistor 12 and the internal resistance ' the diode 11 is formed It is independent on the voltage at the differentiating element.

Fig. 3 shows a circuit for simultaneous blanking during rewind and rewind Line return. The voltage taken from the image folding device 19 is via the terminal 16 and over the terminal 17 is supplied with the voltage taken from the line tilt device 20. The Austasite electrode the cathode ray tube 21 is connected to the point 18. no

The invention is not limited to the exemplary embodiments described, as it can For example, the blanking on a different electrode than on the cathode of the cathode ray tube be made without thereby exceeding the scope of the invention.

Claims (6)

PATENT CLAIMS: r. Circuit for blanking cathode ray tubes, where the narrow ones removed from the tilting device, possibly deformed Voltage pulses to generate · wider Off pushbuttons are used, thereby characterized in that the narrow voltage pulses charge a capacitor on which the blanking voltage is picked up and its recharging through a parallel to it lying diode path before reaching the recharging voltage is interrupted, so that a blanking pulse with an almost linear return flarike arises. 2. Circuit nadh claim i, characterized in that that the image tilting device ent; voltage is first differentiated and then used to generate the blanking pulses, while the one taken from the line tilt device Voltage tnittel'bar is used to form the blanking pulses. 3. Arrangement according to claims 1 and 2, characterized in that when the cathode of the cathode ray tube is blanked, the blanking pulse Has positive polarity, while the charge reversal takes place after a negative voltage, and that when blanking on the Wehnelt cylinder the blanking pulse has negative polarity, while the charge reversal takes place after a positive voltage. 4. Arrangement according to claims 1 to 3, characterized in that the simultaneous Blanking during picture and line rewind two charging capacitors bridged by diodes are connected in series and switched on via a common resistor negative potential, being the common point of the capacitors the pulse voltage occurring at the frame rate and that between the charging resistor and at one end of a capacitor the pulse voltage occurring at line frequency is fed. 5. Arrangement according to claims 1 to 4, characterized by the simultaneous application of a sampling circuit and a Black control. 6. Arrangement according to claim 5, characterized in that the blanking on the Cathode takes place and the Sohwarz control on the Wehnelt cylinder. Considered publications: U.S. Patent No. 2303924;
German Patent Nos. 832 028, 900 829;
German patent application T 6220/21 a ¹ , 36. 1 sheet of drawings