DE960567C - Device for generating a saw tooth tension during a time interval that is dependent on a DC control voltage and, if desired, adjustable - Google Patents

Description

ISSUED MARCH 21, 1957

N 9371 Villa / 2ig

The invention relates to a device for generating a sawtooth voltage during a time interval dependent on a DC control voltage. Such a device is under used for generating deflection voltages for cathode ray tubes in connection with other things with the evaluation of echo imagers in radar receivers. This device contains:

i. an integration circuit including a pentode with an integrating network, its Integrationskondensatoor one between the control grid circuit and the anode circuit of the pentode Represents a feedback capacitor whose coating connected to the anode circuit has a the maximum potential of this deposit limiting diode connected to the control DC voltage source is;

2. a grid-controlled, normally current-carrying interrupter, the anode of which is connected to the catching grid said pentode is coupled such that the pentode is normally disabled;

3. one between an output electrode of the pentode and an input electrode of the interrupter lying coupling capacitor, which serves to put the interrupter and the pentode in their original location attributed when the

Interrupter locked and the pentode is made live.

A disadvantage of this device is that

that especially with smaller values of the DC control voltage inaccuracies in the S expensive DC voltage-dependent time interval occur.

According to the invention, in a device of the type described at the outset, that is mentioned

ίο Disadvantage largely eliminated by the fact that for Support for returning the interrupter to its original position in the connecting line between the integration capacitor and the control voltage source and in A coil is switched on in series with the limiter diode.

By applying the measure according to the invention it is achieved that with an increase the anode voltage of the mentioned pentode temporarily suppresses the limiting effect of the diode will. In this way, + achieves that of the even with low values of the DC control voltage The voltage fed to the output electrode of the switching tube is used to quickly return the voltage

Interrupter in the current-carrying position sufficiently high value.

The invention is explained in more detail using the exemplary embodiment shown in the drawing.

The circuit shown in the figure has an integrating network with an integration capacitor 2 and a series resistor 3. The integration capacitor 2 represents a feedback capacitor located between the control grid circuit and the anode circuit of a pentode 1, the coating of which is coupled to the control grid via the grid current limiting resistor 4 via the series resistor 3 is connected to the positive terminal of an anode voltage source HT . The anode circuit of the pentode 1 contains the series connection of a linearization coil 5 connected to the anode voltage conductor and two resistors 6 and 7. The resistor 6 is large compared to the resistor 7 connected to the anode, e.g. B. about a factor of 10 larger. The coating of the integration capacitor 2 which is coupled to the anode via the resistor 7 is coupled to a DC control voltage source E ₁ via a diode 8 which limits the maximum potential of this coating.

The anode of the pentode 1 is coupled to a diode 9 which limits the minimum potential of the anode and whose anode is connected to a constant voltage source E ₂ for this purpose. The anode of the pentode 1 is at the same time connected via a coupling capacitor 10 to the control grid of an interrupter 11 consisting of a pentode.

The cathode of the interrupter 11 is biased negatively with respect to the grounded terminal of the anode voltage source, and "was due to the" voltage caused by the cathode current together with the screen grid current by means of a voltage divider through a potentiometer current at the adjustable cathode resistor 12 and the resistors 13 and 14. The capacitors Decoupling capacitors 15 and 16. The anode of the interrupter 11 is grounded via an anode resistor · ΐγ and at the same time directly connected to the catching grid of the pentode 1.

The control grid of the interrupter 11 is over a grid current limiting resistor 18 on the one hand by a coupling capacitor 10 with the Anode of the tube 1 and on the other hand connected via a resistor 19 to a voltage divider. The latter consists of resistors placed across the anode voltage source of the interrupter 11 2O · and 21. The control grid of the interrupter 11 is also via the resistor 18 to the anode of a diode 22 and the cathode of a diode 23 connected.

The cathode of the diode 22 is positively biased with respect to its anode via resistors 24, 25 and 26 and also connected via a capacitor 27 to a connection terminal 28 for negative start pulses.

The. The anode of diode 23 is negatively biased and connected to the secondary winding of a feedback transformer 29 connected. Its primary winding is in the screen grid circuit of the pentode 1 and is connected to a voltage divider consisting of resistors 30, 31 and 32 with decoupling capacitors 33 and 34. The one mentioned The primary winding is from a rectifier cell 35 to suppress negative output pulses of the Feedback transformer bridged.

The operation of the circuit described so far is as follows: The interrupter 11 is initially live and the voltage drop occurring at the anode resistor 17 and fed to the catching grid of the pentode causes the last-mentioned tube to be blocked. The anode voltage of the pentode 1 then corresponds to the DC control voltage E ₁ as a result of the limiter circles with the diode 8. The control grid of the pentode ι has only a low positive potential due to the grid current flowing through the resistor 3 and the grid current limiting resistor 4. The screen grid voltage of the pentode 1 is relatively high.

If the terminal 28 is a negative start pulse and the diode 22 of this Switching tube 11 is supplied, the tube 11 is blocked. As a result, the reverse voltage on the catching grid of the pentode 1 is removed, and this becomes live. The resulting voltage drop across the anode resistor 7 is via the Coupling capacitor 10 fed to the control grid of the interrupter 11 and causes this Tube remains blocked from the start impulse.

Immediately after the trapping grid of the pentode 1 is triggered, the anode voltage of this tube decreases in a linear time ratio until the limiter diode 9 is reached when the voltage E _{2 is reached}

becomes conductive and a further decrease in the anode voltage is not possible.

It should be noted here that a diode is not required to determine a minimum anode potential is because the tube ι naturally has a minimum anode potential determined by its setting having.

If the anode voltage of the pentode no longer decreases, the screen grid current increases, ίο which quickly decreased when the pentode ι was triggered, again due to the control grid voltage, which continues to increase at constant anode potential by discharging the integrating capacitor 2. This increase in the screen grid current is im discussed embodiment for initiating the return of the interrupter 11 to the starting position used.

The increasing screen grid current of the tube 1 generates on the secondary winding of the feedback transformer 29 a positive pulse, which is transmitted via the diode 23 to the control grid of the interrupter 11 is supplied so that the interrupter 11 becomes live.

This results in a decrease in the grid voltage of the pentode 1, so that its anode voltage increases; this increase is transmitted via the coupling capacitor 10 to the control grid of the Interrupter 11 transmitted, which leads to a further increase in the voltage drop across the anode resistor 17 leads etc. The described cumulative effect causes the quick release of the Interrupter 11 and rapid locking of the pentode 1.

The anode voltage of the pentode 1 increases until the maximum diode 8 is energized, whereupon the initial position of the tube 1 is reached again. A sawtooth with a period of time which is determined by the circuit and can be set by E ₁ is normally taken from the anode of the switching tube 11.

The minimum anode voltage E _{2 of} the pentode 1 is normally set with a fixed value, while the. DC control voltage E _{1 is} normally variable. The latter determines the level at which the discharge of the integration capacitor 2 begins and consequently the time interval between the start and the return to the original position; a change in the DC control voltage E ₁ thus causes a change in the width of the sawtooth.

If the time interval is small, the voltage E ₁ deviates slightly from the voltage E ₂ , so that during the return to the original position the maximum anode voltage occurring across the diode 8 is reached so quickly, as has been determined, that the cumulative described Effect, the interrupter 11 is not able to fully return to the starting position.

The return of the interrupter 11 in the The fully current-carrying position is then partially due to the significantly slower discharge of the Coupling capacitor 10 together with stray capacitance causes undesirable inaccuracies with regard to the time interval of the sawtooth voltage generated.

In order to largely counteract this disadvantage, according to the invention, in the circuit described so far, a coil 36 is switched on in the connecting line between the integration capacitor 2 and the control DC voltage source E ₁ and in series with the limiter diode 8.

As a result of this measure, when the circuit is returned to its initial position at the moment when the limiter diode 8 is energized, the anode voltage can temporarily exceed the DC control voltage E _1. This guarantees that the cumulative effect lasts long enough to cause the interrupter 11 to trip completely.

The coil 36 should be dimensioned in such a way that very shortly after the circuit has been reset to its original position, namely before the occurrence of the next following start pulse, the pentode 1 has an anode voltage corresponding to the DC control voltage E _1.

Claims (3)

Claim: Device for generating a sawtooth voltage during a time interval that is dependent on a control voltage and, if desired, can be set, which contains the following elements: 1. an integration circuit comprising a pentode (1) with an integrating network (2, 3) contains its integration capacitor (2) represents a feedback capacitor lying between the control grid circuit and the anode circuit of the rentode, whose coating connected to the anode circuit is connected to the control DC voltage source (.E ₁ ) via a diode (8) which limits the too maximum potential of this coating, 2. a grid-controlled, normally current-carrying interrupter (11), whose anode with the catching grid of the mentioned pentode (1) is coupled in such a way that 'the pentode (1) normally Is blocked, 3. a coupling capacitor (10) located between an output electrode of the pentode and an input electrode of the interrupter to return the interrupter (11) 'and the pentode (1) to their starting position when the interrupter (11) is blocked and the pentode (1) is energized is made, characterized in that to support the return of the switching tube (11) to the starting position in the connecting line between the integration capacitor (2) and the control DC voltage source (E ₁ ) and in series with the limiter diode (8) is a coil (36) . For this purpose ι sheet of drawings © 609 620/381 9.56 (609843 3.57)