DE3149893A1 - Circuit arrangement for low-jitter separation of line and frame repetition pulses from a video signal - Google Patents

Abstract

To achieve a constant direct-voltage potential at the output of the clamping circuit, a constant additional current is sent through the clamping diode (D), connected to earth, via a constant-current source during the line and frame repetition pulses. The constant current source is controlled via a threshold amplifier. <IMAGE>

Description

Circuit arrangement for the low-jitter separation of line

and frame pulses from a video signal The invention relates to a circuit arrangement for the low-jitter separation of line and image change pulses from a video signal with a series capacitor clamping circuit and a downstream one Threshold amplifier.

When processing television signals digitally, it is necessary to to generate a sampling clock from the line pulses transmitted with the video signal. If an entire coding system is supplied with clocks derived from these line pulses is to be, it is essential for proper function that the sampling clock only has a negligibly small phase jitter. This is for example by using a voltage controlled oscillator and a phase locked loop achieved. The phase comparator of this phase-locked loop receives the incoming Video signal separated line and image change pulses supplied. The compensation impulses are added to the picture change impulses, if not mentioned separately. In general For example, only the leading edges of these pulses are evaluated. the The phase-locked loop works more precisely, the less phase jitter there is from the video signal have separated pulses.

Since the incoming video signal does not generally have a constant mean value has, a reference potential must first be generated by a clamping circuit. This reference potential can be determined with the help of the line pulses contained in the video signal (also called line sync pulses), image change pulses and compensation pulses, if necessary also by means of the so-called black shoulder, which is before and after each line pulse in the Horizontai blanking intervals is to be determined. Such Clamping circuit consists, for example, of a series capacitor C and one after Ground connected diode D (Fig. 1). One disadvantage of this circuit arrangement is It, however, -that, because of the finite sheet resistance of the diode D, the charging voltage on the capacitor C depends on the duration of the applied pulses. The broad ones Image change impulses cause more reloading than the narrower line impulses. As a result, the clamping voltage generated in this way is inconstant over time. The lines- or image change pulses are sampled by a trigger with a constant threshold. With a change in the clamping voltage it changes because of the finite edge steepness the line or image change pulses the scanning point relative to the ideal scanning raster, which leads to phase jitter. In conventional television receivers, this is the effect irrelevant, since no visible part of the image is transmitted in the image blanking interval. This phase jitter disturbs the generation of reference clocks for an entire system however considerably.

In the book "Fernsehempfangstechnik, Schwarzweiß und Farbe" 1969, Franzis-Verlag, Munich, is on page 191 an active series capacitor clamping circuit shown. Instead of the diode, a switch is used that only operates during the Black level is closed by clocks. But since it is precisely these bars that are generated are to be, an extensive circuit arrangement is required for this solution I.

The object of the invention is to provide a circuit arrangement of a simple Specify clamping circuit that supplies a constant reference potential and thus the Generation of a low-jitter reference clock enabled.

On the basis of a circuit arrangement as described above Art this object is achieved in that a diode from the output side of the Capacitor on Reference potential (ground) is connected that the input of a threshold amplifier is connected to the output side of the capacitor is and that a switchable constant current source, whose switching input with the output of the threshold amplifier is connected in parallel with the diode.

The invention is based on the knowledge that the clamping voltage then is constant if during the line and frame change pulses through the diode on constant current flows. The constant current source becomes parallel during the image pulses switched to the diode. The constant current source is controlled by a threshold amplifier, at the input of which the clamped video signal is present.

It is advantageous to have a high resistance between the output side of the capacitor and a negative reference potential.

Due to the high resistance, the capacitor is discharged to the point that that the picture change or line pulses switch through the threshold amplifier can.

If the video signal is coming from a high impedance source, so it is advantageous that an auxiliary resistor is connected in series with the diode and that the threshold amplifier and / or the constant current source to the output side of the capacitor or to the connection point of the auxiliary resistor with the diode are turned on.

The auxiliary resistor prevents the voltage source from being applied to an im conductive state low-resistance diode must work, which require very high currents would. The constant current source and the amplifier can be used together or separately connected to the cathode of the diode or directly to the output side of the capacitor When dimensioning the switching threshold, however, the voltage drop case to be observed on the auxiliary resistor.

In a simple circuit arrangement, it is advantageous that as Threshold amplifier a differential amplifier is provided, the first input of which connected to the cathode of the diode is that the second input of the threshold amplifier is connected to a reference potential that a first output of the differential amplifier the constant current source switches and that the second output of the differential amplifier forms the output of the clamping circuit.

As a threshold amplifier for controlling the constant current source and only a single one is used as a comparator for separating the line and image change pulses Differential amplifier required.

Further advantageous embodiments of the invention are in the rest Subclaims specified.

The invention is based on basic circuit diagrams and an exemplary embodiment explained in more detail.

FIG. 1 shows a conventional clamping circuit, FIG. 2 shows a television signal, FIG. 3 and FIG. 4 show an excerpt from the television signal with a line pulse in front of or behind the clamping circuit, FIG. 5 the clamping circuit with an auxiliary resistor and FIG. 7 shows a circuit implementation of the circuit arrangement according to the invention.

In Figure 1 is a known clamping circuit with series capacitor shown. It essentially consists of a capacitor C between the input E and output A and one connected to ground from output A. Diode D. A high resistance R1 is between the output A and a negative one Reference potential -U connected.

A video signal shown in FIG. 2 is present at input E. figure 2 is currently showing a picture change.

The line pulses ZI, the image change pulses BI and also the compensation pulses AI (here the lowest potential in each case) serve as a reference potential for the video signal.

This makes it possible to recover the black level of the image signal BS, even if it was not kept constant during the transfer.

The input voltage uE of the clamping circuit shown in FIG represents a section of the video signal with the image signal BS and with a line pulse ZI represents.

This input voltage can have an arbitrary DC voltage mean value within wide limits exhibit. The line pulse ZI, which is negative here, controls the diode D of the clamping circuit through and ensures that the output voltage at the output A of the clamping circuit the forward voltage UD of the diode as the most negative potential during a line pulse D (Fig. 4). The capacitor C is here based on the difference between the DC voltage components the input voltage uE and the output voltage uA charged.

The alternating voltage component reaches output A unadulterated, da the diode D is blocked during the active line duration (image signal) and the high-resistance one Resistor R1 is chosen so large that the capacitor C during this time does not noticeably reload via the high-resistance resistor R1.

The capacitor charges during the broad image change impulses 10 more than during the line pulses.

Because of the capacitor C and the resistance of the diode D formed time constant, the charging current decreases exponentially, so that the voltage goes to zero across the diode D. The most negative output potential is therefore approaching 0 volts, while it was previously negative because of the shorter duration of the line pulses Had value.

Because of the finite edge steepness, this results in the Separation of the image change pulses and the line pulses, temporal fluctuations, which are noticeable as phase jitter.

Through the resistor R1 the initial conditions for a reliable Function of the circuit achieved. The DC voltage potential is passed through the resistor R1 at output A after switching on to approx. 0 volts or a slightly negative value drawn. The resistor R1 can be very high resistance, z-.B. 1 megaohm.

A basic circuit diagram according to the invention is shown in FIG. Like the clamping circuit in FIG. 1, it contains the capacitor C, which is connected to Ground connected diode D and the resistor R1. To the output side of the capacitor C, which is connected here to the cathode of diode D, is the input of a threshold amplifier V connected, the output of which switches a constant current source CC. This is through a switch S, which is in series with the constant current source CC, is shown. the Constant current source CC with switch S is parallel to diode D, but forms functionally with her a circuit.

The threshold amplifier is activated by a negative line or image change pulse V, whose threshold is expediently around 0 volts, is switched through and closes the switch S. This switches on the constant current source CC. This sends a constant current IK through the diode during the entire pulse duration D and keeps it constant until changed the input voltage uE the voltage at the input of the threshold amplifier on the trailing edge of a pulse becomes positive again. As a result, the threshold amplifier switches the constant current off and thus blocks the diode D. A constant current through the diode D means a constant DC voltage level at output A of the clamping circuit.

If the constant current IK is chosen to be sufficiently large (approx.

10 milliamps), the remaining voltage change due to the additional charging current caused by the image or line pulses is neglected because the forward voltage at the diode due to the exponential characteristic curve only is still little dependent on electricity.

So that the voltage source does not work on a low-resistance diode D. an auxiliary resistor R2 can be provided (Fig. 6).

This auxiliary resistor R2 is expediently connected in series with the diode D switched. A connection point P1 of the auxiliary resistor R2 is on the output side of capacitor C, the other, P2, to the cathode of diode D.-The threshold amplifier V and the switchable constant current source CC can be connected to either of these Connection points P1, P2 are switched on, but with the voltage drop across the auxiliary resistor R2 must be taken into account. In the embodiment of FIG. 6, the threshold amplifier is used V and the output A of the clamping circuit to the connection point P2, the cathode of the Diode D, switched on and the switchable constant current source CC to the connection point P1 switched on.

An exemplary embodiment is shown in FIG. The clamp circuit again contains the capacitor C, which is connected to the input El, the diode D and resistor R1. A differential amplifier is used as a threshold amplifier V1 used with PNP transistors T2 and T3.

A common emitter resistor R7 of the transistors T2 and T3 is connected to a positive potential + U.

The first input El of the differential amplifier is to the cathode of the Diode D connected, the second input E2 of the differential amplifier V1 is applied a reference potential which is generated by the base resistors RB1 and RB2.

The base resistances are at the positive reference potential + U or at negative reference potential -U switched on.

The collectors of the transistors T2; and T3 are via collector resistors R5 or R6 connected to the negative potential -U. The collector of the transistor T2 forms a first output A1 via which the constant current source is switched. The constant current source consists of a transistor T1 with an emitter resistor R3, which is also connected to the negative reference potential -U.

The collector of the transistor T1 is also connected to the cathode of the Diode D. The collector of the transistor T3 represents the output A2 of the circuit arrangement represent.

For example, a line pulse ZI, the transistor T2 of the differential amplifier V1 switched through and conductive. The second transistor T3 of the differential amplifier blocks and gives the negative reference potential to its collector -U from. The transistor T1 becomes the constant current source via the switched on transistor T2 switched through, so that a constant current IK flows through it during the pulse. With the positive edge of the pulse, the transistor T2 blocks and thus the constant current source.

The effects caused by the switching times of the differential amplifier 1 and the constant current source are negligible, so that no further measures have to be taken, e.g. no limitation of the switching time the constant current source is required by a monostable multivibrator.

It is also not necessary to have the voltage at the base of the transistor To keep T1 particularly constant, as is the case with Zener diodes or a compensation diode known in series with R5. Shift caused by temperature changes the threshold is irrelevant because it is slow and there is therefore no phase jitter cause.

If the transistor T2 is blocked, the transistor T3 is the differential amplifier V1 conductive, which means that there is a more positive signal at the output.

Instead of the simple differential amplifier shown, can of course an integrated differential amplifier.

When dimensioning the resistor R1, it must be ensured that that it has to compensate for any residual currents through the semiconductors.

The circuit can of course be used for a differently polarized video signal be built up in a complementary manner.

The capacitors C2 and C3 shown in FIG. 7 form RC elements with the collector resistors R5 and R6, respectively, in order to prevent residual crosstalk of the color carrier if necessary.

Claims (7)

Circuit arrangement for low-jitter separation of Line and frame change pulses from the video signal with a series capacitor clamping circuit and a downstream threshold amplifier, characterized in that a C. Diode (D) from the output side of the capacitor (C) to a reference potential (ground) is connected that the input of a threshold amplifier (V) to the output side of the capacitor (C) is connected and that a switchable constant current source (CC), whose switching input is connected to the output of the threshold amplifier (V) is connected in parallel to the diode (D). 2. Circuit arrangement according to claim 1, characterized in that a high resistance (R1) between the output side of the capacitor (C) and a negative reference potential (-U) is connected. 3. Circuit arrangement according to claim 1 or 2, characterized in that that an auxiliary resistor (R2) is connected in series with the diode (D) and that the Threshold amplifier (V) and / or the constant current source (CC) to the output side of the capacitor (C) or to the connection point of the auxiliary resistor (R2) with the diode (D) are switched on. 4. Circuit arrangement according to one of the preceding claims, d a d u r ch e k e n n n z e i c h n e t that a differential amplifier is used as a threshold amplifier (V1) is provided, the first input (El) to the output side of the capacitor (C) is connected, that the second input (E2) of the threshold amplifier (V1) to a reference potential is turned on that a first output (Al) of the differential amplifier switches the constant current source (CC) and that the second output of the differential amplifier forms the output (A2) of the clamping circuit. 5. Circuit arrangement according to claim 4, characterized in that A transistor (T1) with an emitter resistor (R1) is provided as a constant current source is. 6. Circuit arrangement according to claim 4 or 5, d a d u r c h g e k E n n z e i c h n et that the collector of the transistor (T1) of the constant current source (CC) is connected directly to the input (E1) of the differential amplifier (V1) and that the output (A1) of the differential amplifier directly to the base of the transistor (T1) is connected. 7. Circuit arrangement according to one of the preceding claims 4 to 6, characterized in that the differential amplifier (V1) has two collector resistors (R5, R6) which are connected to the negative reference potential (-U) and that a capacitor (C2 or C3) to each collector resistor for sieving is connected in parallel in terms of alternating voltage.