NL8006354A - CIRCUIT FOR DERIVING A GRID SYNCHRONIZING SIGNAL FROM A COMPOSITE TELEVISION SYNCHRONIZING SIGNAL. - Google Patents

Description

,. .- «*> PHN 9895 1 N.V. Philips' Incandescent light factories in Eindhoven.

Circuit for deriving a frame sync signal from a composite television sync signal.

The invention relates to a circuit for deriving a frame synchronizing signal from a composite television synchronizing signal containing at least line synchronizing and frame synchronizing pulses, comprising a monostable multivibrator connected to the input terminal of the circuit.

Such a circuit is known from Dutch patent application 7900910. Herein, the frame synchronizing signal is derived from the composite television synchronizing signal by means of digital means, and use is made on the one hand of the fact that the duration of the equalization pulses occurring during the frame blanking interval is equal to half the duration of the line synchronizing pulses and, secondly, the time difference between the equalizing pulses is half the line period. However, if the incoming television synchronizing signal is subject to noise and disturbances so that a disturbing pulse can occur at any time qp, then these criteria cannot be determined with certainty, as a result of which a derived frame synchronizing pulse may have an incorrect edge qp at the wrong time. In addition, the known circuit is useless with signals that do not contain equalization pulses. Such non-standard 20 signals are generated by some test signal generators, for example for setting the convergence.

The object of the invention is to provide a circuit of the above type which is also equipped with digital means, which is more insensitive to disturbances than the known circuit and which also supplies a reliable field synchronizing signal in the absence of equalization pulses. To this end, the circuit according to the invention is characterized in that the circuit also contains a gate circuit, a first input terminal is connected to an output terminal of the multivibrator, while a second input terminal thereof is connected via a delay element to the input terminal of the multivibrator. , the duration of the pulse generated by the multivibrator being at least equal to the scm of the duration of a line synchronizing pulse and of the delay caused by the delay element / which delay is longer than the 8006354 PHN 9895 2 response time of the multivibrator, and wherein the gate circuit output signal does not contain line synchronizing pulses.

The circuit according to the invention preferably has the feature that the multivibrator is retractable.

The circuit according to the invention can be characterized in that the output terminal of the gate circuit is connected to the input terminal of a second monostable multivibrator for generating a pulse, the duration of which is at least equal to the duration of the frame synchronizing interval, wherein the second multivibrator can be retractor-10.

In one embodiment, the circuit according to the invention is characterized in that the gate circuit is designed as an NET-EN protocol whose input signals outside the field synchronizing interval have opposite polarities.

The invention will be further elucidated with reference to the accompanying figures by way of example, in which fig. 1 shows the schematic diagram of the circuit according to the invention, fig. 2 shows waveforms occurring therein and fig. 3 shows a more detailed embodiment. shows the circuit according to the invention.

In FIG. 1 represents 1 the input terminal of the circuit. To this, a composite television synchronizing signal originating from a synchronization separation stage is supplied. This signal is shown in Figure 2a. It contains line synchronizing pulses L with a duration of about 4.7 µm and which occur with a time difference H of about 64 µm. During the field blanking interval, first five pre-equalizing pulses E of about 2.3 μs qp occur with a time difference of 0.5 H. They are followed by five field synchronizing pulses F 30, the combined duration of which is also 2.5 H and between which screen saw pulses S with a duration of about 4.7 μs occur. This is followed by five post-equalization impulses E. The signal of fig. 2a applies to the European television standard. Other television standards deviate from this for a few details, which is of no importance for the invention. Fig. 2a is drawn for one of the two frames that form an image, namely the frame that ends with a half line.

Terminal 1 is connected to the input terminal I of a retractable monostable multivibrator 2 located on the rising edges of the 8006354. "-> HJN 9895 3-gang signal responds. A series of downpulses is present at an output terminal Q of multivibrator 2, the duration of which is set at, for example, approximately 1Cyus, and the leading edges of which coincide substantially with the rising edges of the signal of Fig. 2a. The signal at terminal Q 5 is shown in Figure 2b. It is supplied to an input terminal 3 of a NAND gate 4.

A delay element 6 is arranged between key 1 and another input terminal 5 of gate 4. This causes the signal at terminal 1 to be delayed by about 0.2 µs. This results in the signal drawn in FIG. 2c. The signal of Fig. 2d is present at the output terminal 7 of gate 4. Like the signals of Figures 2a, b and c, it can assume a logic 1 or a logic 0 value. From the figures it can be seen that the signal of Fig. 2d is a logic 1 during the entire grating stroke time and during the pre-equalization interval. This is due to the fact that the delayed pulses L and E of Fig. 2c are encapsulated, as it were, by the longer pulses of Fig. 2b, the leading edges of which appear a time earlier than that of the pulses of Fig. 2c. .

The foregoing does not apply to the delayed pulses F of FIG. 2c. After all, these pulses have a longer duration, viz. 0.5 H - 4.7 μm = 27.3 μm, than the pulses of Fig. 2b. At a time 10 µs after the leading edge of the first pulse F of FIG. 2a, the signal of FIG. 2d becomes a logic 0 and continues to hold until the trailing edge of the first delayed pulse F of FIG. 2c. Under these conditions, the signal of FIG. 2d contains five pulses that occur during the frame sync interval, the leading edge of the first of these five pulses occurring at the said precisely determined time. After the said interval, the situation before it repeats and the signal of Fig. 2d is a logic 1. The signal at terminal 7 is thus representative of the frame synchronization and can therefore be used as such.

It can also be applied to the input terminal T of a second monosable multivibrator 8 which may also be retractable and which responds to the falling edges. The signal of FIG. 2e is available at an output terminal Q thereof. Multivibrator 8 is set to a pulse duration, for example 48 µs, which is long enough to ensure that the signal of FIG. 2e contains only one pulse comprising the five pulses of FIG. 2d, the leading edge of which is at the above time occurs. Terminal Q is connected to the output terminal 9 of the circuit of fiq, 8006354 PHN 9895 4 de 1. The output signal of the circuit is suitable for supplying to a frame synchronizing circuit for generating a control signal for the vertical deflection.

An interference pulse N is shown in dotted lines in Figure 2a as a very short duration pulse with the same polarity as a useful pulse. Pulse N causes a pulse, also dotted, to the output terminal of multivibrator 2, as well as a delayed pulse at terminal 5. It can be seen from Fig. 2b, c and d that pulse N has no influence on the signal at terminal 7 and therefore on the signal at neither does clamp 9.

This also applies to a disturbance impulse that occurs just before a useful impulse, for example a pre-equalization impulse. In this case, it appears that one pulse in Fig. 2b has a longer duration, but the signal of Fig. 2d is not affected by this. A condition for suppressing the interference pulse is that the sum of its duration and of its delay ir 15 is less than the duration of pulse generated by multivibrator 2, which is 10 µm in the example described. A similar condition applies to the elimination of the equalizing and line synchronizing pulses from the signal of Fig. 2d.

If two or more pulses occur in rapid succession, then 20 will not be affected by the signal of Fig. 2d due to the fact that multivibrator 2 is retractable and therefore a signal to clamp 3 at each rising edge for 10 µs with the logic value causes 0. Now, if the signal of Fig. 2a is a logic 1, then an interference pulse has the negative polarity. If such a disturbing pulse 25 occurs within a shorter time than 10 µs after the rising edge of a pulse F, then the rising edge of the disturbing pulse multivibrator 2 is retracted, with the result that the rising edge of the pulse of FIG. 2b occurs later than otherwise. This gives rise to a slight shift, at most equal to .10 .mu., of the constant front edge of the pulse of FIG. 2d. If this time error relates to a pulse other than the first and multivibrator 8 is arranged in the circuit, this error has no effect whatsoever. Only a spurious pulse occurring within a shorter time than 10 µs after the rising edge of the first pulse F can cause an error, namely a shift of the leading edge of the pulse of FIG. 2e. A minor interlacing error occurs only once. Since this error is the only one that can precede, the circuit produces a fairly interference-insensitive and reliable raster synchronizing signal 8006354 PHN 9895 5 Po, even in the case that the incoming synchronizing signal does not contain equalization and / or raster saw pulses.

In Fig. 3 a more detailed embodiment of the circuit of Fig. 1 is given. Delay element 6 is herein constructed with the aid of two NAND gates 10 and 11 between which an RC network 12, 13 is arranged. The composite synchronizing signal is applied to the input terminal I of multivibrator 2 via an inverter 14.

The time constant of multivibrators 2 and 8 is set with the aid of an RC network 15, 16 and 17, 18 respectively. The circuit of Fig. 3 10 includes the following components: multivibrators 2 and 8: Philips type HEP 4528P ports 4, 10, 11 and 14: Philips type HEF 4011P resistor 12: 500 il

capacitor 13: 1 nF

15 resistance 15: 120 kilos

capacitor 16: 100 PP

resistor 17: 220 kilo capacitor 18: 470 pP.

The dimensioning of the circuit of FIG. 3 is not very critical. The only requirement for delay t is that it is longer than the response time of multivibrator 2. The pulse generated by this multivibrator must be able to at least eliminate the line synchronizing pulses, which means a minimum duration for this pulse of about 5 µs. Gate 4 can be replaced by any device, for example an adder, with the same function.

30 35 8006354

Claims (5)

Circuit for deriving a frame synchronizing signal from a composite television synchronizing signal containing at least line synchronizing and frame synchronizing pulses, comprising a monostable multivibrator connected to the input terminal of the circuit, characterized in that the circuit also comprises a gate circuit of which a first input terminal is connected to an output terminal of the multivibrator while a second input terminal thereof is connected to the input terminal of the multivibrator via a delay element, the duration of the pulse generated by the multivibrator being at least equal. 10 to the duration of a line synchronizing pulse and the delay caused by the delay element, which delay is longer than the response time of the multivibrator, and wherein the gate circuit output signal does not contain line synchronizing pulses. Circuit according to claim 1, characterized in that the multivibrator is retractable. 3. A circuit according to claim 1, characterized in that the output terminal of the gate circuit is connected to the input terminal of a second monostable multivibrator for generating an impulse, the duration of which is at least equal to the duration of the frame synchronizing interval. Circuit according to claim 3, characterized in that the second multivibrator is retractable. Circuit according to claim 1, characterized in that the gate circuit is in the form of a NAND gate whose input signals have opposite polarities outside the frame synchronizing interval. 30 35 8006354