DE2843210C2 - Circuit for eliminating lateral image shifts in a data display device - Google Patents

Description

Datasichtgeräie with a picture tube, as they are z. B. to Representation of digits, numbers or images are used, as is well known, require a line deflection and a vertical deflection. The synchronization of the line deflection is generally done, e.g. B. in one Television receiver, based on the principle of indirect synchronization. There is one with the line frequency oscillating oscillator provided. This is synchronized by a control voltage, which is determined by phase comparison the line sync pulses with the locally generated pulses, e.g. B. obtained the line retrace pulses is. This so-called flywheel synchronization is in the way of the because of the high time constant Control voltage relatively insensitive to disturbances, e.g. B. Failure of some sync pulses.

It is also known to synchronize such a line deflection according to the principle of direct synchronization. Here solve z. B. line sync pulses coming from an external source directly affect the line deflection off, d. H. the principle of flywheel synchronization is not used.

It has been shown that in the case of data display devices with direct synchronization, this is shown on the screen picture written on the picture tube with increasing beam current by about 2 to 3 mm (with a ^ "picture tube) shifts. This means that, depending on the brightness of the image, the written image is more or less horizontal Direction is shifted. This phenomenon disturbs when looking at the picture, especially when Observation of small symbols displayed and greater changes in the image brightness. Also can different light areas of the image may be offset from one another in the horizontal direction.

The invention is based on the object of eliminating this image shift.

This object is achieved by the invention described in claim 1. Advantageous further training of the invention are in the subclaims be

wrote.

The invention is based on the following consideration. The line output transistor has a certain amount when it is switched off Free time or clearing time of the base room.

This means that after the actual occurrence of the The switch-off edge at the base takes a certain amount of time until all charge carriers are removed and the collector current is removed has subsided. This clearing time increases with increasing collector current at constant BaJsstrom

ίο smaller. So when the beam current is increased, it occurs in principle a faster turn-off of the transistor. This is not directly visible in the displayed image, since the line deflection current is a pure deflection current, so the lines do not shift to the left.

but those shown, written by the image signal Characters shift to the right. The line retrace pulses then appear a little earlier in time with respect to the line sync pulses, & h. it rode one Shift between the synchronizing line sync pulses and the line return lines which are synchronized and which are a measure of the show the actual distraction period.

In the invention, the actual cause of the disruptive image shift is now advantageously

namely the change in the jet current, exploited, the Shift the beginning of the line deflection in time so that the line deflection is relative to the image signal always starts at the same point in time. It is achieved that the electron beam on the screen at a certain point in time of the line period of the video signal controlling the picture tube on the screen always has the same spatial position, i.e. the picture does not move to the right depending on the picture content is moved.

The invention is explained using the drawing using an exemplary embodiment. Simplified representation This shows the line deflection fo ^r a picture tube of a visual display unit.

The figure shows an integrated circuit 1. the at least contains a flip-flop and the switching voltage 3 for the line output transistor via the driver stage 2 4 supplies. The circuit 1 is connected to the terminal 5 by line sync pulses coming from an external source 6 synchronized d. H. one pulse 6 determines the point in time at which the line deflection begins. This point in time is also dependent on the voltage at terminal 7, which is generated via resistors 8, 9 is connected to a positive operating voltage. Furthermore, the primary winding 10 and are shown

jo the high-voltage winding U of the flyback transformer 12, the high-voltage rectifier 13. the picture tube 14 serving as a coupling capacitor serving tangent capacitor 15 and the line deflection coil 16.

The base point of the high-voltage winding 11 is not earthed as usual, but rather connected to earth via the resistor 17. As a result, a control voltage - U _s , which is dependent on the beam current i and increases with it in the negative direction, arises at the resistor 17, which reaches the connection point 19 of the resistors 8, 9 via the resistor 18.

The mode of action is as follows. As the picture becomes lighter, the picture displayed on the picture tube 14 would shift to the right without any special measures. As the image becomes brighter, the beam current; ', has increased and the voltage U, has thus become more negative. Since this voltage acts on terminal 7, the phase position of switching voltage 3 is

changes. This changes the switching instant of the driver 2, ie the instant at which the switching voltage 3 initiates the flow of current in the transistor 4 at the beginning of the line trace. This in turn means a temporal shift in the deflection period. This temporal shift takes place precisely in such a way that the temporal shift in the deflection period caused by the increase in the beam current is compensated for. The deflection period, that is to say, for example, the travel time in which the electron beam travels from the left to the right edge of the image, has the same position relative to the image signal, so that the image written on the picture tube 14 no longer has any shift in relation to the screen that is dependent on the image brightness Control voltage Us can influence the phase of the entire switching voltage 3 or the phase of the edge of the switching voltage 3 which determines the deflection / trace period only via the pulse duty factor.

In a practically tested embodiment, the examples shown had the following values:

Circuit 1: Integrated circuit SN 74 221
Resistor 17: 2.2 KOhm
Resistance 18:68 KOhm.

25th

1 sheet of drawings

30th

35

40

45

50

55

60

65

Claims (4)

Patent claims: 1. A circuit for eliminating a lateral image shift in a directly synchronized display device with a picture tube and a line deflection coil fed by a line output stage, characterized in that a voltage (U ₅ ) dependent on the beam current (i _s ) of the picture tube (14) for controlling the switching instant the line output stage (4) is used. 2. A circuit according to claim 1, characterized in that the control voltage (U _s ) is taken from a resistor (17) located between the base point of the high-voltage winding (11) and earth. 3. A circuit according to claim 1, characterized in that the control voltage (U ₁ ) influences the pulse duty factor of a circuit which controls the line output stage (4) tspa <u: .ung (3) 4. A circuit according to claim!, Characterized in that the switching voltage (3) is generated in a flip-flop and the control voltage (U ₅ ) is applied to a terminal (7) of the flip-flop (1), the voltage of which Phase or the duty cycle of the generated switching voltage (3) is dependent.