DE1273571B - Circuit arrangement for deriving a continuous sequence of line-frequency pulses - Google Patents

Description

Circuit arrangement for deriving a television sync signal According to the Gerber standard, there is a continuous sequence of line-frequency pulses, as is well known during the field sequence from horizontal sync pulses occurring at the beginning of each line and during the vertical blanking time from occurring at intervals of half the line duration Compensation pulses and vertical sync pulses. The result of line-frequency pulses is thus disturbed during the vertical blanking time.

In many cases it is necessary to convert this sync signal to a continuous sequence of line-frequency impulses that also gain during the Vertical blanking time remains unchanged. Such a pulse train is z. B. in a Color television coding circuitry for a PAL or SECAM signal required to have a line rate To control toggle switch. Such a switch must be independent of the vertical blanking time can be switched continuously from line to line. Such continuous pulse trains are also required in cross-fading devices.

They are so-called flywheel-synchronized line deflection circuits known, in which the output voltage of an oscillator oscillating at line frequency compared in phase with the line sync pulses and from this a control voltage is derived, which the oscillator exactly to the frequency of the line sync pulses synchronized. Such a circuit also provides a continuous sequence line-frequency pulses, e.g. B. the so-called return pulses. This circuit but is relatively complex because several assemblies are required. In addition, the phase position of the pulses of the continuous pulse train is for studio purposes or coding circuits not sufficiently constant.

Efforts are therefore made to obtain the continuous pulse train from the synchronizing signal to gain yourself and to blank out the disruptive impulses during the vertical blanking time.

For this purpose it is known (Telefunken-Zeitung 1965, Issue 1, p. 66) to generate pulses corresponding to the leading edges of the sync pulses by differentiating the sync signal and to feed them to a transistor serving as a gate. By means of an oscillating circuit located in the collector circuit of a transistor, tuned to the line frequency and triggered by the differentiated pulses, a line-frequency sinusoidal voltage is obtained, one half-wave of which blocks another transistor serving as a gate during the occurrence of the undesired impulses resulting from the equalizing impulses and vertical synchronizing impulses. In the output circuit of the transistor used as a gate, only the desired pulses appear in line spacing, which represent the desired continuous pulse train. Through the differentiation, the leading edge of a pulse is evaluated because it has a constant phase position in relation to a line for all pulses of the synchronizing signal, while the trailing edges of the pulses have different phases due to the different durations of horizontal synchronizing pulses, compensating pulses and vertical synchronizing pulses. This known circuit is relatively complex. It requires a transistor for the gate and another transistor to generate the sinusoidal voltage.

The invention is based on the object of this known circuit to simplify.

The invention is based on a circuit arrangement for derivation a continuous train of line-rate pulses from a television sync signal with horizontal sync pulses as well as half-line frequency compensation pulses and Vertical sync pulses, in which by means of a in the collector circuit of a transistor lying resonant circuit, tuned to the line frequency, by the leading edge differentiated pulses corresponding to the synchronizing pulses are triggered, a line-frequency sinusoidal voltage is obtained, one half-wave of which one at one Input electrode from the differentiated pulses controlled transistor during the occurrence of the undesired, offset by half a line period from one another Blocks pulses, the output circuit of this transistor being the desired continuous Pulse train is taken, especially for a color television coding circuit.

The invention consists in that a single transistor for these tasks is provided in that its collector circuit contains the resonant circuit, its Base the differentiated pulses are supplied, the sinusoidal voltage occurring in the resonant circuit fed back to the base via a diode that only passes through one half-wave and the continuous pulse train is taken from the emitter circuit.

In a preferred embodiment of the invention, the inductance of the resonant circuit formed by the primary winding of a transformer, its secondary winding supplies the voltage fed back to the base.

The main advantage of the invention is that both tasks namely the generation of the sinusoidal voltage and the blanking out of the undesired ones Pulses, can be solved by a single transistor and compared to the known Circuit several components are omitted.

The invention is illustrated below with reference to the drawing using an exemplary embodiment explained in more detail.

F i g. 1 shows a circuit example of the invention, while in F i g. 2 curves are shown to explain the mode of operation. The digits on these curves correspond to the circuit points in FIG. 1 at which these tensions stand.

In Fig. 1 is a terminal 1 at which the sync signal is available a capacitor 2 connected to a point 3 which is connected to the base of a transistor 4 is connected. The collector of transistor 4 is via an oscillating circuit 5, the inductance 6 of which is formed by the primary winding of a transformer 7 is connected to an operating voltage terminal 15. The secondary winding 8 of the Transformer 7 is grounded on the one hand and on the other hand via a diode 9 to the Point 3 connected, which is grounded via a resistor 10. The emitter of the transistor 4 is grounded via a resistor 11 and delivers the desired value to a terminal 12 continuous pulse train. The resonant circuit 5 is tuned to the line frequency.

The mode of operation of this circuit is illustrated in FIG. 2 explained. The synchronous mixture at terminal 1, which consists of horizontal sync pulses H, compensation pulses AI and vertical sync pulses V, is differentiated by the capacitor 2 and the resistor 10, so that the differentiated pulse train 13 occurs at point 3, the pulses of which are determined by the leading edge of the pulses according to Curve 1 arise. Since the transistor 4 is slightly blocked in the idle state, the positive pulses generated by the differentiation, which arise from the trailing edge of the pulses according to curve 1, have no effect on the transistor 4 and are therefore shown in FIG. 2 not shown in curve 13. Since the differentiated pulses in curve 13 correspond to the leading edges of the pulses A1 and V, their leading edges also have a precisely defined phase position, namely the leading edges each have a distance of exactly one line or half a line. The differentiated pulses at point 3 excite, by means of the transistor 4, the resonant circuit 5, which is tuned to the line frequency and which generates a sinusoidal voltage with a line frequency on the secondary winding 8. With the diode 9 only the positive half-wave of the sinusoidal voltage 8 is evaluated and fed to the point 3. At point 3, ie at the base of transistor 4, the pulse train 13 and the positive half-wave of the sinusoidal voltage 8 overlap to form a pulse train 3. In the times during the equalization pulses A1 and vertical sync pulses V, in which the undesired differentiated pulses at the base 14, which interrupt the continuous line-frequency pulse train in the curve 13 occur, the transistor 4 is positively biased at the base by the positive half-wave of the sinusoidal voltage 8. The transistor 4 is blocked so strongly that the pulses 14 in the output circuit, ie at the emitter of the transistor 4, do not appear. The amplitude of the sine half-wave reaching the base is greater than the amplitude of the pulses at the base 3 according to curve 13. During the occurrence of the desired, line-spaced pulses of the pulse train 13, however, the diode 9 is blocked, so that during this time the The sinusoidal voltage occurring at the secondary winding 8 has no influence on the base, the differentiated pulses 13 control the transistor 4 to be conductive and therefore appear at the terminal 12. Thus, only the pulse train 12 appears at the terminal 12, which has been freed from the undesired pulses 14 and which, in the desired manner, represents a continuous train of line-frequency pulses.

Claims (2)

Claims: 1. Circuit arrangement for deriving a continuous Sequence of line-frequency pulses from a television sync signal with horizontal sync pulses as well as half-line frequency equalization pulses and vertical sync pulses the line frequency by means of a located in the collector circuit of a transistor tuned resonant circuit, the corresponding by the leading edges of the sync pulses, differentiated pulses are triggered, a line-frequency sinusoidal voltage is obtained one half-wave of which is differentiated from the one at an input electrode Pulses controlled transistor during the occurrence of undesirable to half Line period mutually offset pulses blocks, the output circle this Transistor the desired continuous pulse train is taken, in particular for a color television coding circuit, characterized in that for these tasks a single transistor (4) is provided, in which its collector circuit is the resonant circuit (5) contains the differentiated pulses (13) fed to its base The sinusoidal voltage (8) occurring at the resonant circuit (5) over only one half-wave Passing diode (8) is fed back to the base and the emitter circuit continuous pulse train (12) is taken. 2. Circuit arrangement according to claim 1, characterized in that the inductance of the resonant circuit (5) by the Primary winding (6) of a transformer (7) is formed, the secondary winding (8) supplies the voltage fed back to the base. Pamphlets contemplated United States patent No. 2,676,254.