DE2312266A1 - CIRCUIT FOR SYNCHRONIZING THE DEFLECTION OF A CATHODE TUBE - Google Patents

Description

Circuit for synchronizing the deflection circuit of a cathode ray tube The invention relates to a circuit for synchronizing the deflection circuit of a Cathode ray tube, in particular the line deflection circuit of a television receiver, with a phase comparison circuit, the sync pulses and from the deflection voltage derived comparison pulses are supplied and their output voltage as control voltage is used for an oscillator.

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 To synchronize output pulses of the first line oscillator.

This circuitry effort is made because in this way, on the one hand, the synchronization of the first line oscillator a control loop with a relatively large time constant for the purpose of reducing the Interference sensitivity 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 regulation disruptive effects of the image content on the line synchronization are possible is.

The last-mentioned and in the cited laid-open specification in detail The problem described is based on the fact that the line frequency carried out in the line output stage Shutdown of the line output stage transistor each with a non-negligible Delay is going on, the energy drawn from the flyback transformer and thus - in the case of high voltage generation from the flyback transformer - from Beam current of the picture tube is dependent. Because of the delay mentioned, the starting points and the duration of the line return pulses can be influenced, it can be with a slow Regulation for the line synchronization happen that the written in the picture tube Lines can be shifted against each other depending on the image content.

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 means are provided for influencing the control voltage amplitude, and that to control the means, a disturbance variable that interferes with the synchronization derived control voltage is used.

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

The invention is based on an embodiment shown in the drawing is shown, explained in more detail. The drawing shows part of a circuit for a television receiver as a block diagram. The circuit shown is used to generate a sawtooth-shaped deflection current in the split into two sub-coils Deflection coil 23 in a picture tube 242 wherein the deflection current with the at the output a pulse separation stage 3 occurring synchronic pulses is synchronized.

The sync pulses are by means of the pulse separator 3 from the video signals received at terminal i and received by the television receiver severed.

Because of the reasons outlined at the beginning, a first Control loop with a phase comparison circuit 4 and a control voltage amplifier 6 an oscillator 7 synchronized to the sync pulses of the video signal. this happens in that the output pulses of the oscillator 7 via a line 5 the phase comparison circuit 4 are supplied, which these pulses with the sync pulses at the output of the pulse separation stage 3 compares. The phase difference of the opposite pulses dependent control output voltage of the phase comparison circuit 4 is amplified in the control voltage amplifier 6. The starting voltage of the control voltage amplifier 6 controls the oscillator 7 in its frequency. In a further control loop with a phase comparison line 8 and a control voltage amplifier 9, an oscillator 10 is then synchronized to the output pulses of the oscillator 7. The Oszilla tor 10 is used to control a line output stage 18 in the working group the primary winding 15 of a deflection transformer 16 is located. As comparison impulses for the phase comparison circuit 8 are used by the output of the line output stage 18 return pulses which feed the deflection coil 23 via a capacitor 19 Deflection voltage. The flyback pulses are in the phase comparison circuit 8 over the input terminal 13 of the synchronization circuit described above 2 freely supplied. The output pulses of the oscillator which control the line end stage 18 10 can be tapped off at the connection terminal 11 of the synchronization circuit 2.

The primary winding 15 connected to the operating voltage UB (terminal 14) connected deflection transformer 16 has, among other things.

a secondary winding 17, which is used to generate a high voltage. The output voltage of the secondary winding 17 is by means of a cascade rectifier circuit 20 rectified, so that a rectified high voltage for the operation of the picture tube 24 can be tapped.

To compensate for the influence of the image content, the synchronization circuit 2 has a control input 12, via the analogous the steepness of the second control loop can be controlled. This is done by that the control voltage amplifier 9 is controllable in its gain and with a corresponding input with the control input 12 of the synchronization circuit 2 connected is.

To control the control input 12 with a suitable control voltage to be able to, e.g. in the event of a white jump of the image content from black to white increases, the one with the cascade rectifier circuit 20 is connected together Base point capacitor 21 not directly but via a resistor 25 to the reference voltage connected. The line-frequency voltage generated across resistor 25 is rectified at diode 27. The one falling behind the diode 27 at the resistor 28 rectified voltage is by means of the filter capacitor 29 of line frequencies Components freed. The differentiator with the capacitor 30 and the resistor 31 is used to compensate for a delay caused by the capacity of the picture tube on the control voltage is applied0 The capacitor 26 serves as protection for the Diode 27 from high voltage surges.

The control DC voltage obtained in the manner described is The control input of the control voltage amplifier 9 is supplied via the control input 12. Since the gain of the control voltage amplifier 9 depends on the image content (beam current) is controlled and is therefore not included in the control loop, does not exist Risk of self-excitation of the control loop.

The synchronization circuit 2 described above can also fundamentally be structured differently. For the circuit according to the invention described it is only necessary that the synchronization circuit 2 has a control input possesses over which a control voltage acting in a synchronization control loop is controllable. The invention is therefore not directed to a synchronization circuit limited with two control loops of the type described. For example, it is also beneficial with an integrated synchronization circuit of the type TBA 950 the Company Intermetall can be used, whereby the connection terminal 12.

of the synchronization circuit 2 in the drawing is the connection point 11 corresponds to the circuit mentioned. The connection device 11 of the known integrated Circuit itself is for the static setting of the phase position of the line deflection intended. The inventive circuit leads this connection point of the integrated Circuit to a dynamic, essentially vertical frequency control voltage. The other two construction elements of a tried and tested circuit with the known integrated circuit, the following values were found to be advantageous: Capacitor 21 = 2.5 nF, resistor 25 = 82 ohms, capacitor 26 = 0.022 nF, resistor 28 = 68 kOhm, capacitor 29 = 1OnF, capacitor 30 = lOnF and resistor 31 = 27 kOhm.

Claims (6)

Claims 1) Circuit for synchronizing the deflection circuit of a cathode ray tube, in particular the line deflection circuit of a television receiver, with a phase comparison circuit, of the sync pulses and comparison pulses derived from the deflection voltage and whose output voltage is used as a control voltage for an oscillator, characterized in that means (9-) for influencing the control voltage amplitude are provided, and that for controlling the means (9) one of the synchronization the control voltage derived from the disturbing disturbance variable is used. 2) circuit according to claim ly characterized in that dic means from one arranged between the phase comparison circuit (8) and the oscillator (10) Control voltage amplifier (9) exist with controllable gain. 3) Circuit according to claim 1, characterized in that at one Television receiver receives the control voltage from the beam current feeding the picture tube is derived. 4) Circuit according to claim 3, for a television receiver, in which the Deflection transformer has an additional winding to generate a high voltage, with a rectifier cascade circuit for rectifying the high voltage a cascade base capacitor is provided, characterized in that the base point capacitor (21) is connected to the reference voltage via a resistor (25) is that to rectify the line rate voltage drop across the resistor (25) a rectifier path (27) is provided that the output of the rectifier path (27) on the one hand via a sieve element (29, 28) for sieving out the line frequencies Stress components to the reference voltage and, on the other hand, to the control input (12) for influencing the control voltage amplitude provided means is connected. 5) Circuit according to claim 4, characterized in that between the rectifier path (27) and the control input (12) a differentiating capacitor (30) switched. is. 6) Circuit according to claim 5, characterized in that in series a resistor (31) is connected to the differentiating capacitor (30).