DE1086275B - Circuit arrangement for emphasizing the vertical sync pulses from the sync pulse mixture of a television signal - Google Patents

Description

The invention relates to a circuit arrangement for emphasizing the vertical sync pulses the synchronous pulse mixture of a television signal and delivers pulses with a high edge steepness and constant, Duration for synchronization, independent of the length of the vertical sync pulses in the composite sync signal of the vertical deflection generator, see The circuit arrangement can advantageously be used for highlighting of the vertical sync pulse from the sync pulse mixture in various television standards with different duration and shape of the vertical sync pulses can be used.

In the common television standards, the sync pulse mixture consists of horizontal sync pulses, whose width is a small fraction of the line length, and from vertical sync pulses with one or more pulses of greater width, e.g. B. of 40% of the length of the line. Highlighting the Up to now, vertical sync pulses from the sync pulse mixture have usually been carried out by integrating Switching elements. The vertical sync pulse obtained from the sync pulse mixture through integration however, has only a slight edge steepness. The amplitude of the leading edge and thus the starting point of the vertical deflection depends on the length and shape of the vertical sync pulse dependent in the synchronous pulse mixture. For different television standards with different shape and length of the vertical sync pulses one therefore does not get the same amplitude as that obtained therefrom Vertical impulses. It was therefore necessary to date the circuit to highlight the Vertical sync pulse for different television standards to be measured differently, and the use one and the same circuit for different television standards was previously not possible because the deflection devices to different amplitudes and different lengths of the sync pulse obtained speak to.

In order to increase the accuracy of the temporal use of the vertical synchronization, which in particular is important in the currently used interlace method, is to emphasize the Vertical sync pulse from the sync pulse mixture the use of a damped oscillating circuit known, which is excited in its natural oscillation by the impulses. A known circuit arrangement of this type contains an electron tube whose control grid is the synchronous pulse mixture is supplied and in the anode circuit a parallel oscillation circuit is arranged to which a directional conductor with the same direction of transmission as the electron tube is connected in parallel. The elements of the oscillation circuit are chosen so that the Circuit arrangement for highlighting

the vertical sync pulses

from the sync pulse mixture

of a television signal

Applicant:

TV G. mb H. _r

Darmstadt, Am Alten Bahnhof 6

Richard Sondermeyer, Darmstadt,
has been named as the inventor

The amplitude of the output pulses picked up by the latter depends on the duration of the input of the circuit arrangement supplied sync pulses is dependent. The synchronous pulse mixture becomes the grid of the tube supplied in a positive direction, a pulse-shaped current increase also occurs in the anode circuit on. The inductance of the oscillating circuit arranged in the anode circuit opposes this increase in current with a high resistance, so that the Anode current initially flows through the diode that is parallel to the oscillation circuit. During the duration of the Pulse, the current in the inductance increases and reaches a higher end value, the longer the Impulse lasts. After the end of the pulse, the current flows as a result of the inductance in the magnetic field stored energy in the same sense; however, he can neither use the electron tube that is after Termination of the pulse is blocked, nor the diode lying parallel to the oscillation circuit in their Flow through blocking direction. The current therefore flows into the parallel capacitor of the resonant circuit and charges this. The oscillating circuit then oscillates at its natural frequency, with the next half-wave reverse polarity is suppressed by the diode. The amount of the occurring at the oscillation circuit Voltage is different depending on the amount of energy stored in the inductor. Disadvantageous is in this circuit arrangement that in the sync pulse mixtures used in accordance with the television standards the horizontal sync pulses also produce output pulses of considerable amplitude. Furthermore, the output pulses occur after the pulse has ended, so that the synchronization occurs the trailing edge of the sync pulses is triggered.

009 569/194

To avoid these disadvantages, FIG. 3 shows an embodiment of a practical

Circuit arrangement for highlighting the vertical table circuit, its mode of operation with the help sync pulses from the sync pulse mixture of Fig. 4 is described.

of a television signal by means of an oscillation circuit. In Fig. 1, 1 means a resonance circuit, consisting

with parallel connected. Directional conductor, in particular for 5 from the inductance 2 and the capacitance 3. This optional use in various television resonance circuits is the synchronous signal S with the norms, according to the invention, the duration of a half-short horizontal synchronizing pulses h and the longitudinal oscillation of the oscillating circuit longer than the ren vertical synchronizing pulses ν For example, for the duration of the horizontal sync pulse, but shorter a tube 4 is supplied, in the anode circuit of which is connected as the duration of the vertical sync pulse and the io resonance circuit 1 and the sync signal 5 * is applied to the control resistor of the directional conductor in the conduction direction small grid. In parallel to the resonance resistance of the oscillation to the resonance circuit 1, a directional conductor 5 is connected, circular and against the resistance of the source of the syn- The synchronous applied to the grid of the tube 4

chronimpulsgemisches selected and the directional impulses cause during the time of each pulse a polarized and biased such that the discharge time 15 increases in the anode current of the tube. The leading edge of each pulse in the inductance of the oscillation circuit will excite the resonance circuit to a stored energy greater than the time between oscillation, provided that the inner horizontal sync pulses so that the resistance of the tube still appears large compared to the resonance oscillation circuit Is the horizontal resistance of the resonance circuit. The oscillation pulses start much later than the synchronous duration of the resonance circuit is due to corresponding pulses and can therefore only develop with low amplitudes of self-induction 2 and capacitance 3, while the longer types are dimensioned to be considerably longer than the vertical synchronizing pulses high resonance pulses at twice the duration of the horizontal sync pulses Ji, but cause an oscillating circuit. shorter than twice the duration of the vertical synchronous

Due to the action of the oscillatory circuit 25 impulses ν is.

diode connected in parallel with reverse polarity Without taking into account the effect of the directional

as in the known circuit arrangement, as well as conductor 5 has the by the horizontal pulses on caused by the inventive dimensioning of the resonance circuit voltage caused by the supply circle is obtained as a new and surprising curve 11 shown in FIG. The chip effect a much greater decrease in amplification increases during the duration of the horizontal pulse tude of the horizontal sync pulses (and on. After the horizontal pulse has ended, the the equalizing pulses) caused output - the voltage at the resonance circuit is reversed impulses compared to that of the longer direction and then sounds with corresponding vertical sync impulses triggered output pulses. the attenuation of the circle down to the zero value. At the In the case of synchronous pulse mixtures according to the 35 arrival of the next horizontal pulse again standing television standards, the ampli- fet the described process, tude of the horizontal sync pulses. The vertical pulse also makes the circle

triggered output impulses to a fifth to one. Because of the longer duration of the vertical tenth the amplitude of the longer vertical synchronizing pulse can now become a fully synchronous pulse generated output pulses down- 40 form constant resonance oscillation 12. the be set. This has the advantage of having the maximum amplitudes of the horizontal and the that excite the separation of the large output pulses for vertical sync pulses on the resonant circuit however, the vertical sync pulses from the very small voltages differ only slightly from the remaining ones Output pulses from the horizons.

Zontal synchronous impulses originate, significantly in parallel can be made more professional and more reliable than the resonance circuit can be a far-reaching Unterdies in the known circuit arrangement of the depression of the excited by the horizontal pulses Case is. Achieve tension. The one above the zero line

In a preferred embodiment, the branch of the oscillation curve 11 in accordance with the invention cannot form the resonance circuit through the secondary 50, because the directional conductor becomes conductive when the voltage winding of a transformer is reversed and the oscillation circuit is paralleled and the capacitance is formed while the directional conductor of the voltage is connected in parallel to a small constant value U _{1 on the} primary winding of the transformer. The current flow through the directional conductor lasts so that the synchronizing signal is also fed to it. long until the energy content of the coil of the Reso-It is advantageous, the synchronous pulse mixture of the nanzkreises is exhausted. If according to the invention the resonance circuit or the primary winding of the resonance this discharge time is longer than the time between the transformer from the output electrode of a horizontal pulse, then the next hori-tube is fed, at whose control grid the synchronous pulse is only a much smaller and chromed signal Applied with the appropriate polarity, the voltage on the resonance circuit is hesitant. 60 This voltage curve is shown by curve 12

When using one tube with two current-carrying. The extent of the delay t _{1 of} the fading electrodes, e.g. B. a tube with screen grid, supply use is determined by the fact that the horizontal sync pulse shown by the surfaces 13 and 14 can be picked up by the two electrodes at the same time. must be the same size.

The invention will now be described in more detail on the basis of the figures 65 Due to the longer duration of the vertical synchronization

explained. impulses will, however, if the other

Fig. 1 shows the principle of the given dimensioning rules according to the invention, even in the presence

Circuit arrangement; of the directional conductor the resonance pulse at the resonance

Fig. 2 is used to explain the basic circle can form with full amplitude. It he -

Mode of action; 70 is therefore entered through the action of the director

considerable difference in amplitude between the horizontal sync pulses and the Vertical sync pulses on the resonance circuit caused voltages, so that the vertical sync pulses can easily be separated from the small horizontal sync pulses by an amplitude filter can.

The amplitude ratio of the pulses generated by the horizontal and vertical sync pulses can be brought to 1: S to 1:10.

In the circuit arrangement of FIG. 3, which shows a practical exemplary embodiment, the synchronizing signal 6 * is applied to the control grid of a multi-grid tube 4. The resonance circuit 1 consists of the secondary winding 2 of a transformer and the parallel capacitance 3. The primary winding 6 of the transformer is bridged by the directional conductor 5. The screen grid of the tube 4 receives its operating voltage from the positive pole of the operating voltage source via the resistor 7 after the screen grid operating voltage has been blocked by the capacitor 8. The resistor 7 is dimensioned so that the screen grid of the tube is not overloaded when the grid alternating voltage is removed.

The resonance circuit 1 is grounded with one pole; The directional conductor 10 is connected to the other pole via the resistor 9. This resistor forms a voltage divider with the resistor 11, through which the diode 10 receives a positive bias voltage. This bias corresponds to the size M ₁₀ in Fig. 4b and is selected so that the low-amplitude pulses caused by the horizontal sync pulses at the resonance circuit are cut off. The vertical sync signal ν for synchronizing the vertical deflection generator with a voltage of about 20 V _ss can therefore be picked up at the diode 10, possibly with the interposition of a low-pass filter with the resistor 12 and the capacitor 13.

The arrangement is designed in such a way that it simultaneously also provides the horizontal sync pulses for synchronization of the horizontal deflection generator supplies. The decrease in the horizontal sync pulses takes place at the anode of the tube 4. A resistor 14 is in series with an inductance 15 as a working resistor intended to increase the gain at high frequencies. At the same time, the directional director 5 the advantage achieved that no negative feedback on the screen grid of the tube 4 for the horizontal sync pulses and the compensation pulses (satellite) occurs and thus at the anode of the tube 4 this Signals with full amplitude are present (no tearing of the grid at this point on the screen) .

Fig. 4 shows the pulse shapes at various points in the circuit. In Figure 4a are the pulses which form the composite synchronous signal which is applied to the grid of the tube 4. Fig. 4b shows the pulses caused at the resonance circuit, while Fig. 4c shows that the horizontal sync pulses induced impulses are cut off by the prestressed directional conductor 10, so that only the vertical sync pulses are present at the output of the circuit arrangement are.

The resonance frequency of the resonance circuit must be chosen to obtain the effect described be that when using the arrangement for several television standards, the period of oscillation of the Resonant circuit with advantage at most equal to twice the value of the vertical sync pulse of those Standard is selected in which the vertical sync pulse has the shortest length. You then get regardless of the length and shape of the vertical sync pulse in the sync pulse mixture for the different standards always a vertical sync pulse of the same slope, shape and amplitude. the The resonance frequency is advantageously chosen to be approximately equal to the line frequency. When using the arrangement for different standards with a different number of lines, e.g. B. 405, 625 and 819 lines, one becomes the resonance frequency with an average of the line frequencies, e.g. B. about 15 kHz.

The invention is not limited to the exemplary embodiment described, but can be in various ways Way to be realized.

Claims (8)

Patent claims: 1. Circuit arrangement for highlighting the vertical sync pulses from the sync pulse mixture a television signal by means of an oscillation circuit with a parallel-connected directional conductor, in particular for optional use with different television standards, characterized in that that the duration of a half oscillation of the oscillation circuit is longer than the duration of the horizontal sync pulse, however shorter than the duration of the vertical sync pulse is that the resistance of the directional guide in the direction of flow small compared to the resonance resistance of the oscillating circuit and against the resistance of the source of the synchronous pulse mixture and that the directional conductor is such is polarized and biased that the discharge time of the stored in the inductance of the resonant circuit Energy is greater than the time between the horizontal sync pulses, so that the am Oscillating circuit still appearing horizontal sync pulses start much later than the sync pulses and thus can only develop with a low amplitude, while the longer vertical sync impulses cause high resonance impulses in the oscillation circuit. 2. Circuit arrangement according to claim 1, characterized in that the resonance circuit is formed by the secondary winding of a transformer and a parallel capacitance and the Primary winding to which the synchronous pulse mixture is fed, the directional conductor connected in parallel is. 3. Circuit arrangement according to claim 1, characterized in that the resonance circuit is on the output electrode of a tube is connected to whose control grid the synchronous pulse mixture is created. 4. Circuit arrangement according to claim 1, characterized in that the synchronous pulse mixture controls the current to two electrodes of a tube, the resonance circuit for separation of the vertical sync pulse is connected to an electrode, while of the second electrode the horizontal sync pulses can be picked up. 5. Circuit arrangement according to claim 1, characterized in that the synchronous pulse mixture is fed to the control grid of a multi-grid tube with positively directed pulses and in the screen grid circuit the primary winding of a transformer with parallel rectilinear conductor lies, the secondary winding with a parallel capacitance forms the resonance circuit and the from this picked up, excited by the vertical sync pulse resonance oscillation with the desired Polarity is obtained via an amplitude sieve, while at one in the anode circuit lying working resistance the horizontal sync pulses are removed. 6. Circuit arrangement according to claim 1, characterized in that after the amplitude sieve a low-pass filter is arranged. 7. Circuit arrangement according to claim 1, characterized by the application for the separation of the vertical pulse in various television standards. 8. Circuit arrangement according to claim 1 and 7, characterized in that the resonance circuit is roughly matched to the mean value of the line frequencies of the various television standards. Considered publications:
French patent specification No. 1111 555. 1 sheet of drawings ® 009 569/194 7.60