DE945633C - Circuit for generating a pulse series with adjustable time delay compared to a control pulse series - Google Patents

Description

Circuit for generating a series of pulses with adjustable time Delay compared to a series of control pulses, especially with measuring devices for the In the field of television technology, there is sometimes the requirement to use a series of impulses in to shift their phase, the absolute phase position being irrelevant, but a shift by as much as zoo / o of the pulse repetition time is required.

It has already been proposed two monostable vibrators for this purpose to be connected in series and to synchronize the first with the control pulse to be shifted. The first vibrator generates a pulse, the width of which in a known manner a time constant is determined. With the trailing edge of the one delivered by the first vibrator Impulse that z. B. by ro to 90% compared to the leading edge of the control pulse may be delayed, the second vibrator is triggered. This also generates a pulse, the width of which is determined by the corresponding time constant element is. The trailing edge of this pulse is the sum of the delays that -in both vibrators arise, delayed compared to the original control impulse.

The setting of the pulse shift is done with this known one Arrangement by changing the time constants themselves. There are then either two independent or two mechanically coupled control elements are required. Through this technological difficulties arise, especially due to the enlargement the number of so-called "hot" lines carrying high-frequency voltages are conditional.

Another option is to change the charging voltage for the to change both time constant members. If you want to have two downstream multivibrators' make a pulse shift by 100% of the pulse train time, where z. B. both Multivibrators are supposed to produce a delay of 25 to 75'10, that is a regulation the charging voltage is required within relatively wide limits. This will the steepness of the discharge curve at the point of use may be relatively low.

The object of the present invention is to eliminate these disadvantages.

The invention relates to a circuit arrangement for generation a series of impulses, one adjustable against periodically occurring control impulses has a time delay. In this circuit arrangement, two are monostable Vibrators used, the second of which by the trailing edges of the. from the first The generated pulses are synchronized and the desired pulse series from the trailing edges the pulses generated by the second vibrator is obtained. According to the invention thereby .the charging voltage for the width of the pulses generated by the second vibratar _ Determining time constant element of this vibrator from the output from the erroern vibrator .-Pulse voltage obtained by integration.

Such an arrangement has compared to the previous circuits the essential advantage that a delay that can be shifted by 100% of the pulse repetition time a series of pulses can be achieved by changing a single switching element can.

It is particularly advantageous to adjust the charging voltage for - the Time constant term of the first vibrator, which is the width of the vibrator output Impulse intended to be kept constant and only to change the time constant itself. As a result, the steepness of the discharge curve at the point of use is as great as possible held.

In some cases, on the other hand, it can also be useful to shift the pulse series by changing the charging voltage for the time constant element of the first vibrator.

The invention is described below with reference to an exemplary embodiment FIGS. 1 and 2 shown.

The circuit essentially consists of the two as monostable Vibrators switched tubes i and 2. The exact operation of a monostable Vibrators can be assumed to be known. The control pulses that come with this Circuit are to be shifted, as indicated, with negative polarity at the terminal 3 via the capacitor 4, the control grid of the tube i. In Fig. 2, diagram a shows these control pulses. They cause the left to be blocked System of the tube i, so that the voltage at the anode is equal to the battery voltage- + UB increases. As a result, the right system of the tube i is opened and at the same time The left control grid of the tube i is controlled far into the negative via the capacitor 5. The negative voltage now on the control grid of the left system decreases - Due to the time constant of the RC element 5, 6 - slowly down until the point of use is reached and the left system opens again. This creates a negative impulse from the left anode to the right control grid, making the right system again locks.

A is thus created at the anode of the left system of the tube i Square pulse train, as indicated in Fig. 2 under b. Through differentiation by means of the capacitor 7 and the resistor 8, the leading edge of this Square-wave voltage positive and negative pulses obtained from the trailing edge, whereby the positive ones. Pulses are cut off again by the diode 9. Get it thus negative pulses, as they are recorded in Fig. 2 under c, to the left Control grid of the tube 2, which works in the same way as the tube i. The time constant term which is the width of the pulses generated at the anode of the left system of tube 2 determined, is composed of the capacitor io and the resistor i i. At the anode of the left system creates a rectangular pulse sequence as shown in Fig. 2 is indicated under d. This pulse sequence becomes over by differentiation the capacitor 1.2 and the resistor 13 and after cutting off the positive pulses a series of pulses obtained by the diode 14 (Fig. 2 under e), which are applied to the terminal 15 can be removed.

The resistor ii, through which the capacitor io is reloaded, is now not connected to + UB, but is, according to the teachings of the invention, at the capacitor 16, which in connection with the resistor 17 is the pulse-shaped occurring at the anode of the left system of the tube i Voltage b integrated. The size of the resulting charging voltage on the capacitor 16 is proportional to the width of the pulses b and therefore proportional to the delay set on the first tube RC element of the second vibrator and thus the width of the pulses it generates.

In the illustration in FIG. 2, on the basis of the pulse shift is to be explained further, it is assumed that the vibrator i synchronized by the control pulses a, can generate square-wave pulses, the width of which depends on the Setting of the time constant between io and go% of the pulse repetition frequency can be changed are. A reduction below 10% and a magnification above 90/0 is not favorable. The second vibrator is supposed to Generate impulses whose breadth through change the charging voltage fluctuates between 5o and 70% of the pulse repetition time. This small one The change range has the advantage that the steepness at the point of use only changes changes insignificantly.

By changing the resistance 6, the time constant of the first Vibrator chosen so that there is only a delay of io%, so has the second vibrator the minimum delay of So 1 / o, so that, as in Fig.2 shown under e, a total delay of the output pulses by 6o% compared to the control pulses a results.

If, on the other hand, the maximum delay is achieved by changing the resistance 6 set in the vibrator i, so that square-wave pulses f of 90% of the pulse repetition frequency result from the trailing edge again the control pulses g for the second vibrator are obtained, it is generated as a result of a change in the charging voltage on the capacitor 16 the maximum delay of 70%. This results in an overall delay of the Output pulses i compared to control pulses a of 16o%. Within the ioo% The range between 6o and 16o% can therefore change the output pulse series of the resistor 6 can be moved at will.

The invention is not limited to the exemplary embodiment described, but it can also be used instead of the time constant, for example in the case of the first vibrator the charging voltage can be changed by using the control grid of the left system is applied to a voltage divider. Any number of multivibrators can also be used be connected in series, with the charging voltage of each subsequent from the pulse voltage of the first through. Integration is gained so that arbitrarily large pulse shifts achieved by changing a single switching element can be. Such modifications are easily made by those skilled in the art can be, the scope of the present invention is not exceeded.

Claims (3)

PATENT CLAIMS: i. Circuit arrangement for generating a series of pulses, compared to periodically occurring control pulses an adjustable time Has delay using two monostable vibrators in which the second is synchronized by the trailing edges of the pulses generated by the first and the desired series of pulses from the trailing edges of those generated by the second vibrator Pulses is obtained, characterized in that the charging voltage for the Time constant term determining the width of the pulses generated by the second vibrator this vibrator from the pulse voltage emitted by the first vibrator by integration is won. 2. Arrangement according to claim i, characterized in that the displacement of the delayed pulses by changing the charging voltage for the time constant element of the first vibrator is set, which is the width of the output from this vibrator Impulses determined. 3. Arrangement according to claim i, characterized in that the Shifting the delayed pulses by changing the time constant of the first vibrator associated time constant element is set, which is the width of the impulses emitted by this vibrator. q .. arrangement according to claim i to 3, characterized in that the shift in relation to the control pulses delayed pulses is 100% of the pulse repetition time.