DE2307203A1 - CIRCUIT ARRANGEMENT FOR SYNCHRONIZATION OF THE DEFLECTION CIRCUIT OF A CATHODE TUBE - Google Patents

Description

Circuit arrangement for synchronizing the deflection circuit of a Cathode ray tube The invention relates to a circuit arrangement for synchronization the deflection circuit of a cathode ray tube, in particular the line deflection circuit a television receiver, with a phase comparison circuit, the sync pulse and comparison pulses derived from the deflection voltage are supplied.

For synchronizing the line deflection circuit of a television receiver it is known (DT-OS 2 211 100), initially using a first line oscillator a first phase comparison circuit to the line sync pulses received from the receiver to synchronize and then a second line oscillator, which is used to control the line output stage is used by means of a second phase comparison circuit to the Synchronize output pulses of the first line oscillator. This circuitry The effort is therefore pre-standard because this is the way on the one hand the synchronization of the first line oscillator with a control loop with a relatively large time constant The purpose of reducing the susceptibility to interference and, on the other hand, the synchronization of the second cell oscillator with a control loop with a relatively small time constant for the purpose of faster compensation of disruptive effects of the image content on the Line synchronization is possible.

The last mentioned and in detail in the published patent application cited The problem described is based on the fact that the line frequency carried out in the Zei-1nendstufe Shutdown of the line output transistor each with one not negligible delay is going on from the flyback transformer withdrawn energy and thus - in the case of high voltage generation from the flyback transformer - depends on the beam current of the picture tube. Because of the said delay of the The start point and the duration of the line return pulses can be influenced with a slow control for the line synchronization it happens that the in The lines written on the picture tube against each other depending on the picture content be moved.

This difficulty is avoided in large part in that the above-mentioned second control loop is provided with a small time constant. In order to avoid the mentioned difficulty as far as possible, the control effect must of the control loop for the second phase comparison can be improved. this could happen by increasing the control steepness, but this measure 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 the second To improve the control loop without the risk of self-excitation, with the technical implementation of the corresponding circuit should be simple.

The invention relates to the circuit mentioned at the beginning.

The circuit arrangement according to the invention is characterized in that that Ser signal path for the comparison pulses contains a phase control circuit, which has a control input via which the in the phase comparison circuit as Comparison parameter used parameters of the comparison pulses can be controlled, and that the control voltage for the phase control circuit from a synchronization impairing disturbance is derived.

Further developments and advantageous embodiments of the invention are described in the subclaims.

The invention is based on two exemplary embodiments that are shown in FIG Drawings are shown, explained in more detail. They show: FIG. 1 an inventive Circuit arrangement as a block diagram, FIG. 2 shows an exemplary embodiment for the phase control circuit shown in FIG. 1 and FIG. 3 shows a further exemplary embodiment for the phase control circuit shown in FIG.

Fig. 1 shows part of a circuit for a television receiver as a block diagram. The circuit shown is used to diffract a sawtooth Deflection current in the deflection coil 23 of a picture tube, which is divided into two partial tracks 24, whereby the deflection current with the applied to the terminal 3, from that of the television receiver received video signal separated sync pulses 4 are synchronized.

Because of the reasons outlined at the beginning, a first Control circuit 1, a first oscillator 7 is synchronized with the synchronizing pulses 4. this happens in that the output pulses of the oscillator 7 via a line 5 a phase comparison circuit 6, which these pulses with the sync pulses 4 compares. The output voltage dependent on the phase difference of the mentioned pulses the phase comparison circuit 6 regulates the oscillator 7 in terms of its frequency.

Ir. A further control loop 2 is then fed to the deflection coil 23 Deflection voltage with the output voltage of the oscillator 7 synchronized. The control loop As is known, 2 has a much smaller control time constant than that Regulation 1, it was very quick, in the deflection circuit with the output stage 10 and disturbances occurring in the deflection transformer 16 can be corrected. The output stage 10 contains, inter alia, a driver circuit, an output stage transistor, a Flyback capacitor and a flyback diode, the primary winding 17 of the transformer 16 is in the working circuit of the output stage transistor. The primary winding 17 is with one end connected to the operating voltage UB (terminal 15) while on its connection point 21 with the output stage 10 via a capacitor 22, the deflection coil 23 is connected. A secondary winding 18 of the transformer 16 serves together with the rectifier 19 to generate a required for the operation of the picture tube 24 and 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.

Since the phase comparison circuit 8, the phase position of the output pulses of the oscillator 7 (control circuit 1) with the serving as comparison pulses and am Circuit point 21 compares return pulses 12 that can be tapped off, regulates the output voltage the phase comparison circuit 8 the phase position of the flyback pulses 12 so that they are synchronized with the sync pulses 4.

In the signal path for the comparison pulses of the control loop 2 is a phase control circuit 11 is connected, the input 13 of which receives the return pulses 12 are supplied, and the output 14 controls the phase comparison circuit 8. The phase control circuit 11 has a control input 26, and it is constructed so that in her that parameter of the return pulses 12 is controllable, which in the Phase comparison circuit 8 with the corresponding parameter of the output pulses of the oscillator 7 is compared. This parameter can e.g. the temporal occurrence The leading edge of the comparison pulses or the temporal center be the comparison pulse. In the following it is assumed that the leading edges of the comparison pulses 12 as a comparison variable for the phase comparison circuit 8 to serve.

The circuit according to the invention with the phase control circuit 11 works as follows: The input as a disturbance variable when synchronizing the line output stage called change of the picture content of the picture displayed in the picture tube 24 is thereby used to obtain a control voltage that in series with the Secondary winding 18 of the transformer = 6, a resistor 25 is connected to which a voltage drop that is dependent on the beam current and thus zcm image inc. old occurs. This voltage drop is fed to the control input 26 of the phase control circuit 11, so that - assuming the correct polarity of the voltages to be processed - the Leading edges of the return pulses 12 at the output 14 as a function of the image content more or less advance. In the case of small disturbances, the phase angle is only small and in the case of large disturbances, the phase angle is changed more strongly. In this way is also the output voltage of the phase comparison circuit 8 determining Phase difference between the pulses of the oscillator 7 and the comparison pulses at the output 14 of the phase control circuit 11 controlled by the image content. this in turn then requires a corresponding readjustment of the oscillator 9, so that accordingly the steepness of 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 is an advantageous circuit for realizing the Pasestecr circuit 11 shown in FIG. At input 13 there is one derived from the return pulses Pulse train 27, which by means of a first, a series resistor 28 and a Integrating capacitor 31 included integrator is integrated. Those mentioned and in the following Components still to be named are dimensioned in such a way that the next to the individual circuit points shown impulse sequences result. The pulse sequence that forms at node 33 32 is by means of a second integrator with a series resistance 34 and an integrating capacitor 36 so deformed that at the node 35 the pulse train 37 appears.

This signal 37 is via the capacitor 38 that of the Audion circuit operated transistor 41 supplied, the base of which via the resistor 39 to the Reference voltage is connected.

The emitter of transistor 41 is connected to the operating voltage via terminal 42 + Us connected, while the collector supplies the reference voltage via the load resistor 43 connected. At the terminal connected to the collector of transistor 41 14, the signal 44 can be tapped, in which, due to the audio effect of the transistor 41 the leading edge of the individual pulses at time tx compared to the leading edges the pulses 27,32, 37 is leading.

A decoupling resistor 29 is connected to the circuit point 33 a voltage 30 supplied to the terminal 26 is connected. The control voltage is 30 proportional to the beam current I beam of the television receiver. The circuit described causes the amplitudes of the pulse trains 32 and 37 as a function of -'er Control voltage 30 can be modulated. This in turn causes the width of the output pulses 47 of the circuit shown is modulated accordingly. That way is the Time tx by which the comparison pulses that can be tapped off at terminal 14 are compared to the Return pulses 27 lead, in the above-described and desired dependency modulated by the image content.

The standards for the amplitudes of the pulse trains shown are Chosen differently to simplify the drawing.

In a practically tested embodiment of the illustrated The circuit have the alternating voltage amplitudes of the individual pulse trains the following values: U27 approx. 450 volts, U32 approx. 20 volts, U37 approx. 2 volts, U30 approx. 20 volts and U44 approx.

10 volts.

The functionality of the circuit described remains essentially obtained when the control voltage 30 instead of to the node 33 to the node 35 is connected.

The desired modulation of the phase position of the comparison pulses 44 is also achieved when the control voltage 30 is applied directly via a resistor 29 the base of transistor 41; i.e. connected to circuit point 40, as shown in Fig. 3. aThis circuit operates essentially like the circuit shown in FIG. The modulation mentioned occurs here, however by directly controlling the operating point of transistor 41.

To further improve the circuits described so far 2 and 3, it is advantageous to the node 33 or the node 35 a pulse sequence synchronous with the return pulses 27 via a resistor 45 46 feed with opposite polarity. Tried and tested in the aforementioned Embodiment of the invention, the amplitude of these pulses was; 46 approx. 50 Volt.

The circuit described for the phase control 11 in FIG. 1 can are so dirnenioniert that the desired modulation of the comparison pulses 12 represents a modulation of the trailing edges. This is e.g. necessary if in the phase comparison circuit 8 in Fig. 1 not the front flanks, but rather the trailing edges or the middle of the output signals of the oscillator 7 are compared with the corresponding trenches of the comparison pulse 12.

The invention is not limited to a television receiver; she can be used advantageously wherever a cathode ray tube is used Generation of an image is used, e.g. in display devices for data processing systems.

Claims (10)

P a t e n t a n s p r ü c h e 1) / Circuit arrangement for synchronizing the deflection circuit of a Cathode ray tube, especially the line deflection circuit of a television receiver, with a phase comparison scarf device, the sync pulses and from the deflection voltage derived comparison pulses are supplied, characterized in that the Signal path for which the comparison pulses (44) contain a phase control circuit <11), which has a control input (26) via which the phase comparison circuit (8) parameters of the comparison pulses (44) used as a comparison variable can be controlled is, and that the control voltage for the phase control circuit (11) from a die Synchronization impairing disturbance is derived. 2) Circuit arrangement according to claim 1 'for the synchronization of the Line deflection circuit of a television receiver having a first and a second Contains control loop, the time constant of the second control loop being relatively small compared to the time constant of the first control loop, with the return pulses derived comparison pulses for the second control loop, characterized in that that the control input (26) of the phase control circuit (11) to one of the image content dependent control voltage (30) is connected. 3) circuit arrangement according to claim 1 or 2, characterized in that that the phase control circuit (11) one to the input for the not yet processed Comparison pulses (12) connected first integrator with a first series resistance (28) and a first integrating capacitor (31) which is used to feed a second integrator with a second series resistor (34) and a second Integrating capacitor (36) is used, and that the output of the second integrating element to one connected in the manner of an audion Transistor stage (41) is connected, at its output (14) one of the inputs of the phase comparison circuit (8) is connected. 4) circuit arrangement nach'Anspruch 3, characterized in that the control voltage for the phase control circuit (11) to the output (33) of the first Integrating member is supplied. 5) Circuit arrangement according to claim 3, characterized in that the control voltage for the phase control circuit (11) of the base of the audion stage forming transistor (41) is supplied. 6) Circuit according to claim 4 or 5, characterized in that the Control voltage via a decoupling resistor (29) to the phase control circuit (11) is connected. 7) Circuit arrangement according to claim 3, characterized in that the bias of the transistor (41) forming the audion stage is dimensioned so that due to the modulation of the comparison pulses that is present as a function of the control voltage (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. 8) Circuit arrangement according to claim 3, characterized in that additionally to the output (33) of the first integrator via an impedance (45) the comparison pulses (46) are connected with reversed polarity. 9) Circuit arrangement according to claim 1, characterized in that the control voltage for the phase control circuit (11) to the output (35) of the second Integrating member is supplied. 10) Circuit arrangement according to claim 3, characterized in that additionally to the output (35) of the second integrator via an impedance (45) the comparison pulses (46) are connected with reversed polarity. L e r s e i t e