DE934051C - Circuit for the automatic frequency control of the deflection oscillator of television receivers - Google Patents

Description

The invention relates to a new circuit for the automatic frequency control of the Deflection oscillator, preferably the horizontal oscillator, of television receivers using the pulse-time method. The circuit according to the invention avoids the disadvantage of known circuits that -the regulation of the amplitude of the supplied sync pulses depends.

The synchronization between) image scanning on the transmitter side and composition on the receiver side is in the system commonly used today in television broadcasting by synchronizing signals, the are inserted into the video signal. The sync signals take effect after they have been disconnected from the video signal in the receiver to the vertical or Horizontal oscillator. They consist e.g. B. according to the CCJ-R standard from horizontal syndrome impulses of 5.8 ^ sec and vertical sync pulses of i86 ^ ttsec duration. ao

In practical operation, caused by the ignition sparks of the internal combustion engines, Sparking from household electrical appliances and interference, disturbances. These call im Video channel short-term interference pulses of large amplitude that are stored between or above the sync pulses. As a result of the large time constant of the filter in front of the vertical oscillator, the ^ short interference peaks are not so strong it can act like on the horizontal oscillator, where one because of the short duration the horizontal pulse is forced to use a filter with a small time constant.

To make the horizontal oscillator less sensitive to interference pulses, there are a number of Circuits have been developed under the

Names "automatic frequency control of the horizontal oscillator" are known. Their basic idea is to integrate a number of the horizontal pulses into a DC control voltage, which influences the frequency and phase of the horizontal oscillator. This is done in such a way that the conductivity of one or two tube systems is influenced both by the horizontal pulses and by an alternating voltage which originates from the horizontal oscillator itself or from a stage following it. Depending on the type of this alternating voltage, the circuit is called the "sine wave, sawtooth or pulse time type": While the sine wave and sawtooth types basically only integrate the horizontal pulses mixed with the interference pulses, the pulse time type adds a further improvement that contributes to the insensitivity to interfering impulses; it consists in the fact that conductivity of the control tube is only possible during the duration of the pulses derived from the horizontal oscillator, i.e. a disturbance pulse that does not occur at this time is incapable of influencing the control voltage. · In Fig. Ι the principle of the pulse time type is shown. The switch .S "1 is closed by the horizontal _{pulses I 1} from the transmitter and by interference pulses and the switch 5" 2 by pulses I ₂ derived from the horizontal oscillator (comparison pulse series). In synchronism, both pulse friction I ₁ and I ₂ overlap more or less, and depending on the pulse width, a certain DC voltage forms at point R , which is the horizontal voltage. 35 oscillator regulates its frequency via line L. It can be seen that an interference pulse can only cause a change in the pulse width if it occurs during the time t _v -t _a . In FIG. 2, t _v denotes the width of the comparison pulses I ₂ and t _s denotes that of the horizontal sync pulses I _1, and t _a denotes the overlap of the two. The term (t _v -t _a ) depends on the size of the readjustment and, _{assuming f v} -i _s , is 5.8, itsec with minimum and ο, «. Sec with maximum readjustment; In the worst case scenario, a glitch can only have an effect during o. ° / o of the line; whether this time is before or after the horizontal pump I ₁ depends on the control device of the horizontal oscillator. This additional advantage gives the pulse-time type some superiority.

The circuits according to FIGS. 3 and 4 are known for the technical implementation of the pulse time type. Both circuits have been tried and tested several times in the field of a television station have shown good results. In terms of complexity, the circuit according to FIG. 4 is superior to that according to FIG. 3, because it only works with a tube system as a readjustment device. But she owns the disadvantage that the control voltage not "only depends on the phase position, but also on the amplitudes depends on both pulse series. The circuit according to the invention is intended to reduce the cost of the Combine the circuit according to FIG. 4 with the amplitude independence of the circuit according to FIG.

The independence of the amplitudes of the pulse series is achieved in the circuit according to FIG. 3 by grid current limitation, for the horizontal pulse series on the triode grid of tube Rö 1 (ECH 42) and for the comparison pulse series on grid 1 of the hexode system of Rö 1. The DC voltage determined by the pulse width at the anode of the hexode (point R) regulates the frequency of the horizontal oscillator, illatorsi? Ö2, which in turn controls the horizontal output stage Rö 3. Both Rö 1 systems are involved in building up the control voltage; the connection from the grid of the ini? 0i contained triode to grid 3 of the hexode ensures this function. T ₁ is the output transformer for the horizontal pulses.

In the circuit (Fig. 4) both pulse trains I ₁ and I _{2 are} fed via C 5 and C 6 to the control grid of the control tube R04 , which is made negative by a grid bias voltage derived from the horizontal oscillator R05 so far that only the peaks of the pulses die Open control tube R04. The control voltage effective at point R for the horizontal oscillator therefore depends not only on the pulse width, but also on the height of the pulses that control the control tube from the lower bend. This disadvantage has to be accepted because of the low cost compared to the circuit according to FIG. 3.

In the invention, as in the known circuits, the sync pulses and the comparison pulses to form an S expensive voltage for the frequency adjustment of the oscillator different Grids of a multigrid tube, preferably a hexode, fed and compared therein. According to the invention, the circuit is designed so that the one pulse series, z. B. the Horizontalitnpulse, through grid current limitation at the first grid of the multigrid tube in their Modulation is kept constant and the second series of pulses, e.g. B. the comparison pulses, by galvanic connection of another grid of the multi-grid tube with one in the Grid current area controlled electrode of the oscillator or a tube following it is kept constant in their modulation.

The circuit according to the invention is shown in FIG. Here the horizontal _{pulse series J 1} arrives at grid 1 of the hexode system of tube Rö 7. This is biased by grid current to such an extent that the hexode system of Rö 7 is completely blocked, regardless of the voltage on its grid 3; only when the horizontal _{pulse J 1} itself is present does the voltage on grid 1 (Og ₁ ) become equal to zero and enable the hexode system to be controlled by grid 3. If the comparison _{pulse series J 2 were} fed to grid 3 in the same way, then because of the blocking of the hexode system between the horizontal pulses j for grid 3 alone there would not be the possibility of a preliminary

The comparison pulse series is inserted in such a way that the grid voltage occurring on the grid of the horizontal oscillator, which is designed as a blocking oscillator via T ₃ with Roy’s triode part, serves as the reference pulse series and this grid with grid 3 of Roy’s hexode system is galvanic connected is. 6 shows the voltage as it occurs on the grid of the blocking oscillator and thus also on the grid 3 of the hexode system; it runs from large negative values to zero, forms a pulse peak due to the oscillation of the blocking oscillator, which is limited by the grid current in the triode system. The curve shape has a pulse component of about 20 V and has the effect that the hexode system is completely blocked by grid 3 during the entire time, with the exception of the presence of the pulse peak. The control process is therefore independent of the amplitude of both pulse frequencies. The voltage at the working resistor W of the hexode (control point R) , which is only determined by the pulse width, influences the frequency and phase of the horizontal oscillator.

Claims (3)

PATENT CLAIMS: I. Circuit for the automatic frequency control of a deflection oscillator, preferably the horizontal oscillator, of television receivers according to the pulse time method, in which the synchronous pulses (Z ₁ ) and the comparison _{pulses (Z 2} ) to generate a control voltage for the frequency adjustment of the oscillator different grids of a multi-grid tube, preferably a hexode, fed and compared therein, characterized in that the one pulse series, z. B. that of the horizontal _{pulses (Z 1} ) is kept constant in its modulation by grid current limitation on the first grid of the multi-grid tube, and the second series of pulses, preferably that of the comparison pulses (Z ₂ ), by galvanic connection of another grid of the multi-grid tube with one in the Grid current area controlled electrode of the oscillator or a tube following it is kept constant in its control. 2. Circuit according to claim 1, characterized in that that the oscillator is designed in a manner known per se as a blocking oscillator, the grid of which is galvanically connected to a grid, preferably grid 3, the multi-grid tube, preferably hexode, is connected. 3. Circuit according to claim 1 or 2, characterized characterized in that a composite tube for the Me'hrgitterröhre and the blocking oscillator tube is provided. Referred publications:
Swiss Patent No. 201 785. For this purpose I sheet drawings I 509 S5S 10.55