DE2160841A1 - SYNCHRONIZATION CIRCUIT FOR LINE DEFLECTION IN A TELEVISION RECEIVER WITH AUTOMATIC ADAPTATION TO LARGER FLUCTUATIONS IN THE LINE FREQUENCY - Google Patents

Description

Synchronizing circuit for the line deflection in a television receiver with automatic adaptation to larger fluctuations in the line frequency in one As is known, the line deflection is synchronized with the television receiver a flywheel circuit, in which the line sync pulses and the in a local Line generator generated pulses are fed to a phase comparison stage. This generates a control voltage that is sent to the generator via a time constant element is fed. The time constant is used to eliminate interference in the received signal of the time constant member dimensioned relatively large. This is possible because because the line frequency of a television broadcast signal is practically constant.

When connecting a video recording device such as a video tape recorder or an optical disk device, the line frequency of the signal is subject to fluctuations. The control voltage cannot handle these fluctuations because of the large time constant follow quickly enough. This has the consequence that interference, in particular during playback Deformations of vertical edges occur.

It would be conceivable to fundamentally reduce the time constant, see above that the control voltage to the frequency fluctuations of the coming from the recording device Signal can follow. But this would have the disadvantage that then the The desired freedom from interference is no longer given during normal television reception.

It is also known to make the time constant switchable by automatically when a recording device is connected in the time constant element a resistor or a capacitor is switched. However, even with one Recording device malfunctions are present, which in turn have a large time constant expedient do. For example, if the frequency of the signal coming from the recording device is largely is constant and there are interference pulses of a different type, then the large time constant is expedient.

The invention is based on the object of the synchronization circuit to be trained so that they can be used for normal television radio reception without switching as well as when playing back from a recording device works optimally. This task is achieved by the invention described in claim 1. Advantageous further training of the invention are specified in the subclaims.

The circuit according to the invention works with normal television reception unchanged compared to known circuits. This. is due to the fact that the frequency evaluation because of the high constancy of the line frequency of a television signal does not emit a manipulated variable and the synchronization via the large time constant of the Rule loop is effected. However, when playing back from a recording device the frequency fluctuations are registered in the frequency evaluation and immediately Effective without inertia in the sense of a readjustment of the distraction. If on the other hand the recorder sends a signal with constant Line frequency supplies, the large time constant is nevertheless advantageously effective, while the frequency evaluation has no influence. Interference in the form of glitches, which are eliminated by the high time constant during normal reception, are therefore in the solution according to the invention also when a recording device is connected the high time constant that remains in effect is eliminated. The circuit adapts itself automatically to the respective conditions without switching between normal television reception and operation with a recording device is necessary.

The invention is explained below with reference to the drawing.

1 shows a block diagram of a first embodiment and FIG. 2 is a block diagram of a second embodiment of the invention, FIG. 3 shows a practical embodiment of the circuit according to FIG. 1 and FIG. 4 shows another practical one Embodiment of the invention.

Fig. 1 shows a line deflection circuit with a separation stage 1, a phase comparison stage 2, a filter element 3, a line oscillator 4, a Line output stage 5 and line deflection coils 6. The circuit is connected to a terminal 7 the video signal 8 is supplied. The phase comparison stage 2 is taken from the output stage 5 A comparison pulse 9 is supplied via a line 8. The phase comparison stage 2 generates a control voltage UR, which in the sense of a synchronization to the frequency of the generator 4 acts. The circuit described so far is known.

According to the invention, the line sync pulses 10 from the output of Separation stage 1 is additionally fed to a frequency discriminator 14. Dieeer delivers on a line 12 one of the ever manipulated variable corresponding to the respective frequency U5, which is added to the control voltage UR in an adding stage 13.

The mode of operation is as follows: With normal television radio reception the frequency of the line sync pulses 10 is extremely constant. The frequency discriminator 11 then does not provide a manipulated variable U5 or a pure DC voltage, which also can be separated by capacitive coupling. The route according to the invention is 11,12 then ineffective, and the synchronization takes place in the usual way via the desired high time constant of the filter element 3.

When connecting a recording device, the line sync pulses 10 provided with frequency errors. These are now in the frequency discriminator 11 evaluated without inertia, and the manipulated variable representing the frequency fluctuations Us is at the output of the adder 13, that is, behind the high time constant of the filter element 3, effective immediately and controls the frequency of the oscillation generated in oscillator 4 so that the deflection follows the line sync pulses 10 in frequency and phase. The path 11, 12, 13 therefore responds without inertia to frequency fluctuations and has an effect the readjustment of the line deflection desired for perfect image reproduction such that the deflection current generated in the deflection coils 6 in frequency and phase always coincides with the line sync pulses 10 of the video signal 8.

Fig. 2 shows a deflection circuit in which in a manner known per se two line oscillators 4, 4 'are connected in series, each with a phase comparison control loop are provided.

This is indicated by the symbols 2 ', 3', 4 ', 8', 9 '. The manipulated variable U acts here on a phase modulator 13 in the path of the comparison pulse 9 'to the phase comparison stage 2 'and shifts the phase of the comparison pulse 9' such that the phase the deflection current generated in the output stage of the respective frequency and phase of the Line sync pulses 10 during operation with a recording medium follows. With normal TV reception US is again constant and ineffective. With this circuit can Us can also be taken from the output of the phase comparison stage 2, as indicated by the dashed line 14 is indicated. Then there is no frequency discriminator 11.

The circuit of FIG. 3 operates on the principle of FIG.

1. The manipulated variable US is transferred to a resistor 15 of the filter element 3 coupled in, so that the filter element 3 itself acts as an adder 13 according to FIG. The comparison pulse 9 is here not from the return pulse, but with a Differentiator 16 obtained from the line sync pulse 10. The phase comparison stage 2 return pulses 17 are fed in push-pull. At the synchronization input the generator 4 regulated by UR + US.

In FIG. 4, the phase comparison and the extraction of U5 occur the same way as in FIG. 3. Only the coupling of the manipulated variable Us into the Rule loop is done in a different way.

Here the phase comparison stage 2 is used to generate a sufficient Correction also used. For this purpose, U5 is fed to two transistors 1a, 19 and converted there into two manipulated variables in antiphase. The collectors of the transistors 18sol9 are parallel to the resistor voltage dividers for the return pulses 17. The transistors are controlled so that at the time when the phase comparison stage 2 generates the highest control voltage, the largest clock pulse 17 coupled into the diode branch which generates the greatest control voltage.

In the circuit according to the invention there is still the advantage that the manipulated variable U5 obtained from the frequency evaluation only controls the frequency, thus does not represent a closed control branch, so that control oscillations are avoided will. The frequency evaluation can be done by additional measures such as coincidence levels or frequency-selective stages are largely freed from interference. With noisy Additional limiter circuits can be provided for synchronizing signals.

It can be useful to also use filter elements to set the manipulated variable US to lead with specially dimensioned frequency responses. This measure depends on whether the manipulated variable must also be sent via the filter element (Fig. 4) or whether the manipulated variable reaches the oscillator to be controlled in such a way that additional phase rotations be avoided (Fig. 3). Since the existing phase comparison is also still on the If the frequency interference is involved in regulation, the additional manipulated variable must always be be so large that the remaining residual error is corrected.

The circuit is also suitable for retrofitting in devices that have already been built.

Claims (6)

Claims Synchronizing circuit for the line deflection in a television receiver with automatic adjustment to larger fluctuations in the line frequency in the the line sync front impulses and impulses generated locally by a line generator a phase comparison stage, the output voltage of which is supplied via a time constant element is fed as a control voltage to the generator, in particular for the connection of a Video recording device, characterized in that additionally the frequency the line sync pulses (10) are evaluated and the manipulated variable obtained thereby (us) is coupled into the control loop for the generator (4). 2. Circuit according to claim 1, characterized in that the evaluation the frequency takes place with a frequency discriminator (11). 3. A circuit according to claim 1, characterized in that the evaluation the frequency takes place in an already existing phase comparison stage (2) (Fig. 2). 4. A circuit according to claim 4, characterized in that the manipulated variable (US3 of the control voltage (U,) added after the time constant element (3) additively becomes (Fig.1,3). Circuit according to Claim 4, characterized in that the manipulated variable (US) the phase position of an oscillation fed to the phase comparison stage (2 ') t98 influenced (Fig. 2). 6. A circuit according to claim 3, characterized in that at one Circuit with two line oscillators (4,4 ') connected in series, each with one Phase comparison control loop, the frequency evaluation in the phase comparison stage (2) of the first line oscillator (4) takes place (line 14 in Fig. 2). L e r s e i t e