DE2307203C3 - Circuit for synchronizing the line deflection of a picture tube - Google Patents

Description

The invention relates to a circuit arrangement for Synchronization of the line deflection circuit of a picture tube, in particular the Zdlenablenk circuit of a Television receiver.

For the synchronization of the line deflection circuit of a television receiver, it is known (DE-OS 22 11 100), initially using a first line oscillator a first phase comparison circuit to the line sync pulses received from the receiver synchronize and then a second line oscillator, which is used to control the line output stage, to synchronize to the output pulses of the first line oscillator by means of a second phase comparison circuit. This circuitry effort is made because in this way on the one hand, the synchronization of the first line oscillator with a control loop with a relatively large one Time constant for the purpose of reducing the susceptibility to interference and, on the other hand, the synchronization of the second line oscillator with a control loop with a relatively small time constant for the purpose of faster adjustment disruptive effects of the image content on the line synchronization is possible.

The problem mentioned last and described in detail in the cited laid-open specification is based on the fact that the line-frequency disconnection of the line output stage transistor carried out in the line output stage in each case with a non-negligible delay that differs from that of the Line transformer extracted energy and thus - in the case of high voltage generation from the Line transformer - depends on the beam current of the picture tube. Because of the said delay the The start point and the duration of the line return pulses can be influenced, it can be with a slow one Regulation for the line synchronization happen that the lines written in the picture tube in Depending on the image content can be shifted against each other.

This difficulty is avoided in large part by having the above mentioned provides the second control loop with a small time constant. To the mentioned difficulty as possible To largely avoid this, the control effect of the control loop for the second phase comparison must be improved will. This could be done by increasing the control steepness, taking this measure however, there are limits due to the risk of self-excitation of the control loop.

The invention is based on the object of the control effect of a control loop for line synchronization to the effect that the phase position of the line deflection when the beam current changes is stabilized without the risk of self-excitement due to excessive amplification. the The solution according to the invention is particularly applicable to the second phase comparison described above.

This object is achieved by the invention described in claim I. Advantageous further training of the invention are set out in the subclaims ι wrote.

It is a circuit through DE-AS 20 08 656

known, in which to shift the entire horizontal image position the comparison pulses a Synchronization circuit can be changed in phase position by a manually operated potentiometer. This is done by manually changing the time constant of an integrator that is in the signal path the comparison pulses is arranged. However, this citation is not based on that of the invention lying problem can be removed, nor can the circuit of the citation to solve the Apply the invention underlying task.

The invention is explained in more detail with the aid of two exemplary embodiments which are shown in the drawing explained. It shows

F i g. 1 shows a circuit according to the invention as a block diagram,

FIG. 2 shows an exemplary embodiment for the one shown in FIG phase change circuit shown and

F i g. 3 shows a further exemplary embodiment for the phase change circuit shown in FIG. 1.

Fig. 1 shows part of a circuit for a TV receiver as a block diagram. The circuit shown is used to generate a sawtooth-shaped Deflection current in the deflection coil 23, which is divided into two sub-coils, forms a picture tube 24, the deflection current with the video signal at terminal 3 from the video signal received by the television receiver separated sync pulses 4 is synchronized.

Because of the reasons outlined above, there is initially a first in a first control loop 1 The oscillator 7 is synchronized with the synchronizing pulses 4. This happens because the output pulses of the Oscillator 7 are fed via a line 5 to a phase comparison circuit 6, which these pulses with the sync pulses 4 compares. The one that depends on the phase difference of the said pulses The output voltage of the phase comparison circuit 6 regulates the frequency of the oscillator 7.

In a further control circuit 2, the deflection voltage feeding the deflection coil 23 is then synchronized by the output voltage of the oscillator 7. The control loop 2 has, in a known manner, a much smaller control time constant than the control loop 1, so that rapid disturbances occurring in the deflection circuit with the output stage 10 and the deflection transformer 16 can be corrected. The output stage 10 contains, among other things, a driver circuit, an output stage transistor, a flyback capacitor and a flyback diode, the primary winding 17 of the transformer 16 being in the working circuit of the output stage transistor. One end of the primary winding 17 is connected to the operating voltage Ub (terminal 15), while the deflection coil is connected to its connection point 21 to the output stage 10 via a capacitor 22

23 is connected. A secondary winding 18 of the transformer 16 serves together with the rectifier 19 for generating a for the operation of the picture tube

24 required high voltage that can be tapped at terminal 20.

The output stage 10 is controlled by an oscillator 9, which in turn is controlled by a phase comparison circuit 8 is controlled. Since the phase comparison circuit 8, the phase position of the output pulses of the Oscillator 7 (control circuit 1) with those used as comparison pulses and which can be tapped off at circuit point 21 Comparing return pulses 12, the output voltage of the phase comparison circuit 8 regulates the phase position of the return pulses 12 so that they with the

Synchronization pulses 4 are synchronized.

A phase change circuit U is in the signal path for the comparison pulses of the control loop 2 switched, whose input 13 the return pulses 12 are fed, and whose output 14 the phase comparison circuit 8 controls. The phase change circuit 11 has a control input 26 and is so constructed so that that parameter of the return pulses 12 can be controlled in it, which is in the phase comparison circuit 8 is compared with the corresponding parameter of the output pulses of the oscillator 7. This parameter can e.g. B. the temporal occurrence of the leading edge of the effective as comparison pulses Return pulses 12 or the middle of the comparison pulses. The following is of this assumed that the leading edges of the comparison pulse are pulsating. 12 as a comparison variable for the phase comparison ', circuit 8 serve.

The circuit with the phase change simulation 11 works as follows: The input as a disturbance variable in the Synchronization of the line output stage called change of the picture content in the picture tube 24 reproduced image thereby becomes extraction a control voltage is used that in series / u of the secondary winding 18 of the transformer 16 a Resistor 25 is connected, at which a beam current and thus dependent on the image content Voltage drop occurs. This voltage drop is the control input 26 of the phase change circuit Ii fed so that - correct polarity of the to processing voltages provided - the leading edges of the return pulses 12 at output 14 advance more or less depending on the image content. In the case of small disturbances, the phase angle becomes The phase angle is changed only a little and with large disturbances. That way will also the output voltage of the phase comparison circuit 8 determining the phase difference between the Pulses of the oscillator 7 and the comparison pulses at the output 14 of the phase change circuit 11 from Controlled image content. This in turn requires a corresponding readjustment of the oscillator 9, so that the control slope of the control loop 2 as a function of the disturbance variable »Image content« is controlled. Because of the control, there is no risk of self-excitement.

In Fig. 2, an advantageous circuit for realizing the phase change circuit 11 in Fig. 1 shown. At the input 13 there is a pulse train 27 derived from the return pulses, which by means of a first integrating element containing a series resistor 28 and an integrating capacitor 31 is integrated. The components mentioned and to be mentioned below are dimensioned so that the result next to the individual circuit points drawn pulse sequences. Which are at the switching point 33 forming pulse train 32 is by means of a second integrator with a series resistor 34 and an integrating capacitor 36 so deformed that the pulse train 37 appears at the node 35.

This signal 37 is fed via the capacitor 38 to the transistor 41 operated in Audion, the base of which is connected to the reference voltage via the resistor 39. The emitter of the transistor 41 is connected to the operating voltage + Ub via the terminal 42, while the collector is connected to the reference voltage via the load resistor 43. The one with the collector

of the terminal 14 connected to the transistor 41, the signal 44 can be tapped, in which, due to the audion effect of the transistor 41, the leading edge of the individual pulses is leading by the time t _x compared to the leading edges of the pulses 27, 32, 37.

A voltage 30 supplied to terminal 26 is connected to switching point 33 via a decoupling resistor 29. The control voltage 30 is proportional to the beam current Ismhi of the television receiver. The circuit described has the effect that the amplitudes of the pulse trains 32 and 37 are modulated as a function of the control voltage 30. This in turn has the effect that the width of the output pulses 44 of the circuit shown is modulated accordingly. In this way, the time by which the comparison pulses that can be tapped off from the terminal 14 lead the return pulses 27 is modulated in the above-described and desired dependence on the image content.

The scales for the amplitudes of the pulse trains shown are different to simplify the drawing. In a practically tested embodiment of the circuit shown, the alternating voltage amplitudes of the individual pulse sequences have the following values: L / 27 approx. 450 volts, L / 32 approx. 20 volts, Un approx. 2 volts, U ₃₀ approx. 20 volts and U. « About 10 volts.

The operation of the circuit described is essentially retained when the control voltage 30 is connected to the circuit point 35 instead of the circuit point 33.

The desired modulation of the phase position of the comparison pulses 44 is also achieved when the Control voltage 30 is connected directly to the base of transistor 41, i.e. to node 40, via a resistor 29, as shown in FIG. 3 shown is. This circuit operates essentially like that in FIG. 2 circuit shown. The said modulation arises here through the direct control of the operating point of the transistor 41.

To further improve the circuits described so far according to FIGS. 2 and 3, it is advantageous to the Circuit point 33 or circuit point 35 via a resistor 45 with the return pulses 27 supply synchronous pulse train 46 with opposite polarity. Tried and tested in the aforementioned As a general example of the invention, the amplitude of these pulses 46 was approximately 50 volts.

The circuit described for the phase change circuit 11 in Fig. 1 can be dimensioned so that the desired modulation of the comparison pulses 12 results in a modulation of the trailing edges represents. This is e.g. B. required when in the phase comparison circuit 8 in Fig. 1 not the Leading edges, but the trailing edges or the middle of the output signals of the oscillator 7 with the corresponding sizes of the comparison pulse 12 are compared.

The invention is not limited to a television receiver; it can be used advantageously anywhere where a picture tube is used to generate an image, e.g. B. in display devices for data processing systems.

1 sheet of drawings

Claims (9)

Patent claims: 1. Circuit for synchronizing the generator for the line deflection and for the high voltage from the return line for a picture tube with a phase comparison circuit, its output voltage via a time constant element with a variable for the compensation of effects Beam current of the picture tube on the line synchronization measured time constants Generator is supplied to synchronize it, in which the phase comparison circuit synchronizing pulses and comparison pulses derived from the flyback voltage are supplied as a result characterized in that the comparison pulses (12) of the phase comparison circuit (8) via a electrically controllable phase change circuit (11) are supplied, the control input (26) of which a the beam current of the picture tube proportional control voltage (30) is supplied. 2. Circuit according to claim I, characterized in that the phase change circuit (11) is a the first integrating element connected to the input for the comparison pulses (12) that have not yet been processed with a first series resistor (28) and a first integrating capacitor (31), for feeding a second integrating element with a second series resistor (34) and a second integrating capacitor (36) is used, and that the output of the second integrator to a after Type of an Audion switched transistor stage (41) is connected, at the output (14) of one of the Inputs of the phase comparison circuit (8) is connected. 3. A circuit according to claim 2, characterized in that the control voltage (30) for the Phase change circuit (11) is fed to the output (33) of the first integrator. 4. A circuit according to claim 2, characterized in that the control voltage (30) for the Phase change circuit (H) supplied to the base of a transistor (41) forming the audion stage is. 5. A circuit according to claim 3 or 4, characterized in that the control voltage (30) via a decoupling resistor (29) to the phase change circuit ( 11) is connected. 6. A circuit according to claim 2, characterized in that the bias of the audion stage forming transistor (41) is dimensioned so that, depending on the control voltage (30) existing modulation of the comparison pulses (44) essentially the time of the trailing pulse edge of the output signal of the audion stage is modulated with respect to the input signal of the audion stage is. 7. A circuit according to claim 2, characterized in that the comparison pulses (46) with reversed polarity are also connected to the output (i3) of the first integrator (28, 31) via an impedance (45). 8. A circuit according to claim 2, characterized in that the Stcucrspannung (30) for the Phase change circuit (11) is fed to the output (35) ties / wide integration elements (J4,) β). 9. Circuit according to claim 2, characterized in that that in addition to the output (35) of the / wide Integrierglicdes (M, 56) via an impedance (45) the comparison pulses (46) are connected with reversed polarity.