DE2116431A1 - Circuit arrangement for electron beam deflection - Google Patents

Description

Circuit arrangement for electron beam deflection The invention relates to a circuit arrangement for electron beam deflection, especially for the vert ical deflection in a color remote display device used to correct tangent distortion (Linearity correction) the sawtooth deflection voltage is changed in an S-shape.

About the so-called tangent distortion caused by nonlinear deflection to avoid the electron beams on the screen, the deflection current is allowed do not have a purely linear sawtooth shape, but must have an S-shape, in such a way that that the slope of the deflection current is strongest in the center of the picture and at the beginning and on Flatter at the end of the initial phase. This linearity correction is used in the Vertical deflection achieved in that the sawtooth deflection voltage is sinusoidal ge component.

circuits for this purpose are known in which the linear sawtooth deflection voltage deformed approximately parabolically over a capacitor and after integration by means of a RC element is brought into S-shape. Capacity values are in the order of magnitude of over 1GO µF required.

The commonly used electrolytic capacitors have large Tolerances in the capacitance values (up to 50), which impair the linearity correction will. Capacitors with lower tolerance values are very expensive.

In addition, large capacitors are used in integrated circuits Unsuitable construction.

The invention is based on the object of a posture arrangement for the linearity correction of the vertical deflection, in particular for an integrated one To create circuit in which large capacitors with the disadvantages mentioned be avoided. This is achieved according to the invention in that from the approximately linear sawtooth deflection voltage in a square wave generator and an RC filter one of the sawtooth deflection voltage phasenglei surface, approximately sinusoidal correction voltage is generated and this the approximately linear sawtooth deflection voltage in an adder will be added.

The linearity setting that is symmetrical with respect to the center of the image can be advantageous by changing the amplitude of the approximately sinusoidal correction voltage take place. To set the asymmetrical linearity, the phase position of the approximately sinusoidal correction voltage compared to the approximately linear sawtooth voltage, e.g.

by adjusting a variable resistance in the longitudinal branch of the RC-Siltcrs postponed. The said adding stage can also have a second line-frequency correction voltage for east-west iron rectification are fed.

The invention is described below with reference to the drawings, for example explained in more detail: FIG. 1 shows the basic circuit according to the invention, FIG. 2 occurring voltage forms, FIG. 3 a simultaneously acting as a comparison stage Adding stage, Fig. 4 shows an embodiment according to the invention for the integrated Design, Fig. 5 Voltage forms when generating the sinusoidal correction voltage.

In the block diagram of FIG. 1, the BAS signal is converted into the amplitude filter 1 the synchronous mixture obtained and fed to a synchronization circuit 2, in which the integrated bi-alternating impulses are generated and amplified; these will further input to a sawtooth oscillator 3, which has a linear sawtooth voltage generated. The output 31 of the sawtooth oscillator 3 is one with the input 41 Network 4 and the output 32 connected to a square wave generator 5.

In the RC filter 6, from the square pulses supplied by the square oscillator 5, which are in phase with the linear sawtooth pulses at output 31 of the sawtooth oscillator 3, the fundamental wave is filtered out and fed to the input 42 via an amplifier 7 the subcircuit 4 is supplied. The subcircuit 4 receives a via the input 43 horizontal frequency Correction voltage for the LV raster rectification.

Furthermore, the subcircuit 4 receives a control signal via the input 44 fed, which is tapped via the resistor R1 and dcm deflection current proportional is. The subcircuit 4 has the task of serving as an adder for the Inputs 41, 42 and 43 supplied voltages and on the other hand as a comparison network value to serve for the control loop, which consists of the amplifier stage 8, the driver 9, the End stage 10 and the deflection coil 11 consists.

In Fig. 2a is that of the sawtooth oscillator 3 as a function of time The saw tooth voltage U1 generated is applied, while FIG. 2b shows the sinusoidal voltage U2 which is fed to the adder stage via input 42. From the tensions U1 and U2 become the S-shaped discharge voltage required for linearity in adding stage 4 U3 won.

In Fig. 3 the adder 4 is connected to a comparison network is combined to generate the control voltage for the amplifier, again in detail shown. The target voltage U3 is determined by adding the sawtooth voltage U1, which is present at input 41, with the sinusoidal voltage U2 which is present at input 42, obtain. The feedback voltage is supplied to the comparison network 4 via the input 44 U / + supplied, which is tapped at the resistor Ri (Fig. 1), proportional to the deflection current and compared to the nominal voltage composed of the sum of the voltages U1 and U2 around 180 ° is in phase. At resistor R5 the Differen1: voltage is between the setpoint voltage U3 and the feedback voltage U4, which are transmitted via the output 45 of the Amplifier circuit 8 is supplied. The amplitude of the sinusoidal voltage U2 is with adjustable with the setting resistor R3. This will adjust the level of sawtooth distortion fully of the voltage U1 and thus the linearity correction can be set. The gauze passages the voltages U1 and U2 occur at the same time. Furthermore, there is the tilt back time negligibly small compared to the run-time. The amplitude of the target voltage U3 is therefore determined by setting the linearity, with appropriate dimensioning of the resistance network is not influenced (see Fig. 2).

The amplitude de. Deflection voltage U7 is above the feedback voltage U4 set at the negative feedback resistor R1 Due to the feedback effect, which makes the amplitude of the feedback voltage U4 and the target voltage U3 equal, the setpoint voltage U3 does not change when the deflection current amplitude is set. Voltage fluctuations at the output stage influence the form and amplitude of the nominal voltage U3 also not due to the feedback. However, care must be taken that the nominal voltage U3 itself remains constant. This is the case with integrated circuits achieved by stabilizing the operating voltage. In FIG. 4, a Circuit arrangement for generating the sinusoidal voltage U2 specified for the integrated Construction is suitable. The sawtooth voltage generated by the sawtooth generator 3 U1 is at the entrance <flng 51 to the square wave generator 5 via the coupling capacitor C1 supplied. The base of the transistor T1 is connected to the resistor R1 and R2 m the base of the transistor T2 verbundes The emitter of the transistor T1 is on the one hand Via the resistor R3 at the negative pole of the voltage source and on the other hand the base of the transistor T3, while the emitter of the transistor T2 on the one hand via the resistor R4 to the negative voltage source unc? on the other hand at the Base of transistor 14 is located. The collectors of transistors T1 and T2 are directly connected to the positive pole of the voltage source while the collectors of the transistors T3 and T4 are connected to the positive pole via the resistors R5 and R6, respectively are. The emitter of the transistor T3 is through the resistor R7, the emitter of the The transistor T4 is connected to the collector of the transistor T5 via the resistor R8. The emitter of the transistor T5 is connected to the negative pole of the resistor R9 Voltage source. The base of the transistor T5 is through the voltage divider, the consists of resistors R10 and R11, connected to the emitter of transistor T6, which is at the same time connected to the negative pole via resistor R12. The lower end of the Resistor R11 is connected to the negative pole via a transistor connected as a diode D1 placed. The collector of transistor T6 is directly on the positive pole, while the base of this transistor T6 via the resistors serving as a voltage divider R13 and R14 are connected to the positive or negative voltage pole. After all, that is common connection point of resistors R1 and R2 with the emitter of the transistor T6 connected.

The transistors T1, T2, T3 and T4 form a differential amplifier. The transistor T5 represents the required current source for a constant current. The inputs of the differential amplifier are connected to the series resistors R1 and R2 at the same fixed potential as the voltage divider R10, R11 of the constant current source T5. Becomes the base of the transistor Ti due to the sawtooth voltage applied to the input 51 positive to the base of transistor T2, then transistors T1 and T5 conductive and transistor T3 takes over the entire amount applied by transistor T5 constant current. Will the tension; ar the base of the transistor T1 negative compared to the voltage at the base of the transistor T2, the transistors T2 and T4 conductive and the transistor T4 takes over the entire current in this case. Of the The differential amplifier consisting of the transistors T1 to T4 is therefore overdriven.

The square-wave voltage generated by this is passed through the resistor R5 tapped from the collector of the transistor T3 and to the output 52 of the square wave generator 5 led.

The output 52 of the square wave generator 5 is connected to the Ba.

sis of the transistor T7, the emitter of which is connected to the positive pole of the Supply voltage source and its collector connected to the base of transistor T8 is. The collector of the transistor T8 is connected to the positive pole, while the emitter dreses transistor on the one hand via the resistor R15 on the negative pole and on the other hand is at the base of the transistor T9. The collector of the transistor T9 is directly connected to the positive pole of the supply voltage source, while the emitter is connected to the negative pole via the resistor R16. The combination of transistors T7 and T8 are used as voltage amplifiers, transistor T9 is used as an impedance converter switched. Ai.j input 61 of the RC filter 6 is then shown in Fig. 5b Square-wave voltage U5, which compared to the sawtooth S arnung v.

Fig. 5a at the input 51 of the square wave generator 5, a deed phase position and efn has a duty cycle of 1: 2. Via the adjustable resistance R17, the can serve to binstelb development of the phase position if necessary, this square pulse is U5 to the three-member RC filter 6 with the elements C2 to C4 and R18 to R20 performed, the phase rotation of 180 ° for a frequency of 50 Hz are dimensioned. In the RC filter, the square wave voltage U5 becomes the fundamental wave U2, which is shown in Fig. 5c, filtered out and through the resistor R21 to the output 62 of the RC filter 6. Close reinforcement in the amplifier stage 7, the sinusoidal voltage U2 is added to the adding or. Comparison network 4 supplied as this has already been described with reference to FIGS. 1 and 2.

The setting of the linearity, which is symmetrical with regard to the center of the image takes place by symmetrical change of the S-shaped distortion of the deflection current, by increasing the amplitude of the approximately sinusoidal correction voltage U2 by the adjustable resistance R3 in Fig. 3 is changed.

Unbalanced linearity occurs at the deflection units or the picture tube distorted, the deflection current U3 must be distorted asymmetrically. This is done by shifting the phase position of the sinusoidal correction voltage U2 with respect to the phase position of the linear sawtooth voltage U1. The phase shift can example, by changing the adjustable resistor R17 in Fig. 4, which is in the series branch of the RC filter 6, take place.

In order to maintain a constant output voltage of the To obtain RC filter 6, it may also be advantageous to use the RC filter 6 unaffected and to change the phase position of the square wave voltage U5. This can be achieved, for example, by using 5 instead of the above-mentioned square wave generator overdriven differential amplifier with the transistors T1 to T4 a monostable Multivibrator is used, which delivers square-wave pulses of constant width. By Adding or subtracting an adjustable DC voltage to the sawtooth voltage the threshold value at which the multivibrator switches at a selected point in time on the Vcrderflanke of the sawtooth voltage U1, which is supplied by the sawtooth generator 3 will be achieved. This is the switching time of the multivibrator and thus the phase of the square wave voltage U is set at a constant pulse width.

In order to keep this constant after setting the phase, the sinusoidal correction voltage that occurs at the output 62 of the RC filter 6, with the sawtooth voltage U1 delivered by the sawtooth oscillator 6 in a phase comparison stage compared and the differential voltage is used to control the ReeÄ $ 'corner generator 4. In In this case, the phase adjustment can also take place by the difference in voltage an adjustable DC voltage is added, whereby the switching time of the Multivibrators and thus the phase position can be set.

If, if necessary, also the amplitude of the sinusoidal correction voltage U2 is to be kept constant, this can be done by increasing the amplitude the sinusoidal correction voltage U2 and the sawtooth voltage U1 compared and a control voltage is formed from the difference voltage, which the Square-wave generator 5 is supplied for constant amplitude control. Here, too, can an amplitude adjustment of the sinusoidal correction voltage U2 by adding or subtracting an adjustable DC voltage from the control voltage.

The overall circuit arrangement with the subcircuits described is particularly advantageous in the application for integrated circuits.

Patent claims:

Claims (9)

Claims: t.9 circuit arrangement for electron beam deflection in particular for the diversion of values in a color television display device the sawtooth deflection voltage to correct the tangent distortion (linearity correction) S-shaped is changed, characterized in that from the approximately linear Sawtooth deflection voltage (U1) in a square wave generator (5) and an RC filter (6) an approximately sinusoidal in phase with the sawtooth deflection voltage (T) Correction voltage (U2) is generated and this the approximately linear sawtooth deflection voltage (U1) is added in an adder (4). 2.) Circuit arrangement according to claim 1, characterized in that the linearity setting symmetrical to the center of the image via an adjustable resistor (R3) by symmetrical change in amplitude of the approximately sinusoidal correction voltage (U2) takes place (Fig. 3). 3.) Circuit arrangement according to claims 1 and 2, characterized in that that in an amplitude comparison stage the amplitudes of the approximately sinusoidal Correction voltage (U2) and the approximately linear sawtooth voltage (U1) compared and the differential voltage for amplitude constant control to the square-wave generator (4) is fed. 4.) Circuit arrangement according to claims 1 and 3, characterized marked, that the amplitude setting of the approximately sinusoidal correction voltage (U2) practice 'the amplitude comparison stage takes place. 5.) Circuit arrangement according to claims 1 to 4, characterized in that that the linearity setting, which is asymmetrical to the center of the image, is achieved by moving the Phase position of the approximately sinusoidal correction voltage (U2) compared to tier approximately linear sawtooth voltage (U1) via an adjustable resistor (R17) in the longitudinal branch the RC filter (6) takes place (Fig. 4). 6.) Circuit arrangement according to claims 1 to 5, characterized gekennzeiclmet that the shifting of the phase position of the approximately sinusoidal correction voltage (U2) compared to the approximately linear sawtooth voltage (U1) by setting the Bias of a monostable MSltivibrator serving as a square wave generator (4) he follows. 7.) Circuit arrangement according to claims 1 to 6, characterized in that that in a phase comparison stage, the phases of the sinusoidal correction voltage and the linear sawtooth voltage are compared and the differential voltage for Phase constancy control is fed to the square wave generator. 8.) Circuit arrangement according to claims 1 to 7, characterized in that that the phase adjustment of the sinusoidal Correction voltage takes place via the phase comparison stage. 9.) Circuit arrangement according to claims 1 to 8, characterized in that that the adder (4) via the input terminal (43) a second line frequency Correction voltage for the east-west pillow equalization is supplied.