DE1114531B - TV receiver with an automatically tuned line oscillator - Google Patents

Description

Television receiver with an automatically tuned line oscillator The invention relates to a line oscillator whose frequency is controlled by a retuning arrangement is regulated, which is supplied with a control voltage via an RC element with a high time constant whose first component is a negative, preferably from the grid of a tube voltage taken from the line oscillator and dependent on its oscillation amplitude which is used to initially capture the line, and its second component The output voltage of a phase detector is that of maintaining the once produced line synchronism is used and the phase difference between a AC voltage generated by the line oscillator and a synchronization signal depends.

In television receivers with such within a certain pulling range Self-tuning line frequency oscillators can interfere with the Line frequency synchronization through glitches or short-term failure of the image signal and thus the synchronization pulses per se by inserting a RC element with a very large time constant between the output of the phase detector and the entry of the retuning arrangement can be avoided. With that way However, the increase in interference immunity achieved is a noticeable reduction in the Capture range, so that the time constant of this RC element in known devices is only chosen so large that there is no significant influence on the synchronization more occurs due to glitches. Since with such a dimensioning of the RC element the catching range of the retuning arrangement is no longer sufficient for all operating cases is wide, the size of the first of the grid is in known television receivers Line oscillator tube removed component of the control voltage of the retuning arrangement adjustable with the help of a so-called line regulator, so that the position of the capture area is displaceable within a larger frequency range of the line oscillator.

The aim now is to maintain good immunity to interference to enlarge the capture range of the retuning arrangement so that an adjustment of the Line frequency and thus also the associated setting element are no longer available can. Known television receivers achieve this by using a direct to indirect synchronization and vice versa automatically switching line oscillator. A disadvantage with them is the large amount of material required for this and that at every switchover, there are several times to and fro between the two switching states. Another television receiver used to generate the control voltage for the Retuning arrangement a phase discriminator and additionally a special frequency discriminator, whose output voltage takes the place of that used in ordinary television receivers of the line regulator adjustable bias occurs. This circuit is disadvantageous In addition to the large amount of material used, the very difficult and cumbersome adjustment process, that it requires.

An arrangement is also known in which one of synchronizing pulses and a voltage composed of sawtooth-shaped line pulses positive or negative pulse voltage is converted, which is amplified and rectified is used as retuning voltage for the line oscillator. This arrangement is however, it is very expensive and still does not have a sufficiently high immunity to interference on. Furthermore, arrangements are known in which an interference voltage of small amplitude should be weakened or faded out, as it is z. B. is the case when a Pulse generator located in the same device and a slight hum in the sync signal is included. However, such an arrangement is little for a television receiver useful, as there are predominantly interference voltages with the same or greater amplitude than that of the synchronization pulses to disturbances and to the falling out of the line oscillator to lead.

The disadvantages mentioned can be avoided if according to the invention the control voltage fed to the retuning arrangement has a third component, those created by amplifying the phase detector when stepping out of the way Alternating beat voltage via the RC element with a high time constant to the input of the retuning arrangement got. The advantage here is that, with little expenditure on material, no material whatsoever It is necessary for the adjustment process that the resulting capture range is symmetrical to the free oscillation frequency of the line oscillator and that a high immunity to interference is achieved.

In the television receiver according to the invention one arrives at the output terminals of the phase detector in the unsynchronized state of the line oscillator Beat between the synchronization pulses and that of the line oscillator or one AC voltage supplied by this controlled output stage in such great strength to the RC element that it is synchronized despite its large time constant State of the line oscillator whose high immunity to interference is guaranteed, still in an amount at the input terminals that is sufficient to safely capture the line the retuning arrangement of the cell oscillator appears.

In the drawing, the invention is shown schematically on the basis of three exemplary embodiments. 1 shows an excerpt from the circuit of a first exemplary embodiment representing the generation of the control voltage, FIG. 2 shows an excerpt according to FIG. 1 of a second exemplary embodiment, and FIG. 3 shows an excerpt according to FIG. 2 of a third exemplary embodiment.

In a television receiver, the frequency of a line oscillator 2 controlling a line deflection output stage 1 is influenced by a retuning tube 3. In front of the grid of the tuning tube 3 is a composite RC filter element 4, which keeps pulse voltages from the grid. The tuning tube 3 is controlled by an arrangement which is used for phase comparison and which essentially consists of diodes 5, 6, resistors 7, 8 and a capacitor 9 . This phase detector 5 to 9 is supplied with line synchronization pulses from a pulse sieve 10 via a capacitor 11 and an alternating sawtooth voltage at another point, which passes via the capacitor 13 as a line return pulse and is formed in an integrator 12, 9 . In this arrangement, the phases of the two voltages are compared in a known manner, and their output voltage at terminals 14 and 15 forms a first component of the control voltage fed to the tuning tube 3.

A second component of the control voltage; which is taken from the tap of a voltage divider formed from the resistors 16 and 17 , between ground and the grid of a tube of the line oscillator 2, not shown in detail, is at the base terminal 14 of the phase detector 5 to 9, which for pulse voltages via the capacitor 18 to ground is placed, and forms a basic bias for the grid of the retuning tube 3.

If the line oscillator 2 does not run synchronously with the received synchronization pulses, a third component of the control voltage consisting of an alternating voltage is fed to the base terminal 14 via a capacitor 19 from the cathode of an amplifier tube 21, which is connected to ground via a resistor 20. The grid of the tube 21 is connected to the first output voltage terminal 15 of the phase detector 5 to 9 , so that this tube is controlled by the alternating voltage component of the output voltage of the phase detector. Its anode is connected to a terminal 22 carrying a positive operating voltage and to ground via a capacitor 23.

The alternating voltage component, which occurs at terminals 14 and 15 when the line oscillator is running asynchronously, appears so much amplified at resistor 20 and thus also between ground and terminal 15 that, even after it has been attenuated by the RC element 4, the grid of the tuning tube 3 through and thus causes a capture of the line synchronization. If the line oscillator then runs synchronously again, the beat voltage at terminals 14 and 15 and thus also the AC voltage at resistor 20 disappears, so that only the first and second components of the control voltage are effective on the grid of the tuning tube 3.

In the embodiment shown in FIG. 2, not only the AC voltage component of the output voltage of the phase detector, but also its DC voltage component is amplified in the amplifier tube 211 and fed to the grid of the retuning tube 3 via the RC element 4. In this way, the capacitor 19 can have a significantly smaller capacitance than in the first exemplary embodiment. Furthermore, in the synchronized state of the retuning arrangement, there is a greater control steepness.

The circuit shown in FIG. 2 differs from that according to FIG. 1 essentially in that the capacitor 19 is bridged by a series circuit of two resistors 24 and 25 , which produces a DC voltage coupling between the terminal 14 and the cathode of the tube 21. Since this is a direct current connection between the terminal 14 and ground, is omitted here of the resistor 16 of FIG. 1. With the help of connected in parallel to the resistor 25 rectifier 26 which is connected via a resistor 27 to the tap of an adjustable voltage divider 28, which on the one hand to ground and on the other hand to a terminal carrying negative line return pulses via a capacitor 29 , a fourth control voltage component is fed to the retuning arrangement, which is used to compensate for the quiescent DC voltage component of the third component of the control voltage supplied by the tube 21.

The negative voltage generated by rectifying the line return pulses set at the voltage divider via the rectifier 26 is in this case applied to the positive voltage generated at the cathode of the tube 21. With the correct setting of the voltage divider 28 , this negative voltage is so great that the same negative voltage is present at the base point 14 of the phase detector during synchronization as at the output terminal 15 of the phase detector. If there is now a shift in the phase position between the alternating voltages applied to the phase detector, the potential of the output voltage terminal z. B. to the positive. Since this voltage is also applied to the grid of the tube 21, the potential at the cathode will also change towards the positive. However, this also creates a more positive voltage at the base point 14 of the phase detector, which in turn shifts the voltage at the output voltage terminal 15 even further towards the positive and thereby supports the retuning of the line oscillator.

If interference voltages now reach the grid of the tube 21 via the phase detector, they are filtered away by the relatively large capacitor 18. If, on the other hand, a beat occurs at the phase detector in the non-synchronized state, this will occur to a greater extent at the output voltage terminal 15 of the phase detector, since it is much lower frequency. In order to achieve an amplification of the beat and a filtering out of the interference voltages, the capacitor 19 in a circuit according to FIG. 1 must therefore be selected to be significantly larger than the capacitor 18 or additional filter elements must be arranged.

In the third embodiment shown in FIG. 3 , as in the second embodiment, the entire output voltage of the phase detector is amplified. A transistor 30 whose collector C is connected to terminal 14, whose emitter E is connected to ground and whose base B is connected to ground via a resistor 31 and to terminal 15 via a resistor 32 is used for this purpose. The second component of the control voltage fed to terminal 14 via resistor 17 ' simultaneously serves as operating voltage for transistor 30 , resistor 16 in FIG. 1 also being omitted here.

Claims (2)

PATENT CLAIMS: 1. TV receiver with a line oscillator, the frequency of which is regulated by a retuning arrangement, to which a control voltage is fed via an RC element with a high time constant, the first component of which is a negative voltage, preferably taken from the grid of a tube of the line oscillator and dependent on its oscillation amplitude which is used to initially capture the line, and the second component of which is the output voltage of a phase detector, which is used to maintain the cell synchronism once established and which depends on the phase difference between an AC voltage generated by the line oscillator and a synchronization signal, characterized in that the control voltage is a has a third component which, by amplifying the beating alternating voltage that occurs at the phase detector when stepping out, reaches the input of the retuning arrangement via the RC element with a high time constant. 2. TV receiver according to claim 1, characterized in that the television receiver has an anode base amplifier for generating the third component of the control voltage, the anode of which with a terminal carrying a positive operating voltage, the grid of which is connected to a first output voltage terminal of the phase detector and which is connected to the RC element The cathode is connected to ground via a load resistor on the one hand and to a second output voltage terminal of the phase detector via a large capacitance coupling capacitor, which in turn is connected to ground via a small capacitance capacitor for the pulse voltages fed to the phase detector and to the tap of a voltage divider, which is the first Component of the control voltage leads and is connected on the one hand to the grid of the line oscillator tube and on the other hand to ground. 3. Television receiver according to claim 2, characterized in that in parallel with the coupling capacitor of large capacitance, a resistance transmitting the DC voltage components of the anode base stage controlling the output voltage of the phase detector and the third control voltage component emitted by this stage is connected. 4. TV receiver according to claim 3, characterized in that the control voltage has a fourth component which serves to compensate for the DC voltage component of the third control voltage component supplied by the anode base stage and which is obtained by rectifying negative line return pulses. 5. Television receiver according to claim 4, characterized in that the resistor connected in parallel to the coupling capacitor has a tap which is connected on the one hand to the terminal of a directional conductor corresponding to an anode, the other terminal of which is on the cathode of the anode base tube, and on the other hand via a resistor is connected to the tap of an adjustable voltage divider, one terminal of which is connected to ground and the other terminal of which is connected via a coupling capacitor to a terminal carrying negative line retrace pulses. 6. Television receiver according to claim 1, characterized in that the television receiver has a transistor amplifier in collector base arrangement for generating the third component of the control voltage, the base of which is located at the tap of a voltage divider between ground and a first output voltage terminal of the phase detector connected to the RC element, its collector on the one hand via a working resistor on the grid of the line oscillator tube carrying a negative voltage and on the other hand on a second output voltage terminal of the phase detector and its emitter is connected to ground. Considered publications: German Patent Specifications No. 808 961, 851967; British Patent No. 652 122.