DE1033347B - Phantastron circuit for generating saw tooth-shaped voltages - Google Patents

Description

GERMAN

The invention aims to improve the stability of sawtooth-shaped, by a so-called Phantastron circuits generated voltages with regard to their duration and their amplitudes.

In phantastron circuits, it is known that the sawtooth-shaped voltages are caused by the discharge of a capacitor achieved via a resistor, the strength of the discharge current with With the help of a negative feedback circuit constant is obtained, which is applied to the terminals of the capacitor A correction voltage can be applied with the aid of a pentode tube. The end of the sawtooth-shaped character is achieved by disconnecting the anode current at the moment where the anode voltage has become sufficiently low compared to the screen grid voltage, which is the so-called transit effect results.

At this point in time, the shield electrode and the retarding grid stop the flow of electrons, which normally intended to reach the anode. The anode voltage then rises to a potential which is either the potential of the positive terminal of the supply current source or below it can lie and is applied to the anode, for example via a diode tube. The anode stays on this potential until the moment when an appropriately supplied synchronization pulse the restoration of the anode current and the start of a new work cycle.

The steepness of the sawtooth-shaped character, i.e. i.e., the drop in anode voltage in unit time by the values of the capacitor and the resistance of the discharge circuit as well as by the The level of the supply voltage of the tube is determined and largely independent of the characteristics of the tube used. The amplitude and thus the duration of the sawtooth-shaped character depends on the other hand, with otherwise the same conditions, the distribution of the electrode current between the anode and the screen grid of the tube and can therefore vary from one tube to the other. if If a great accuracy is desired for the amplitude and the duration of the character, the substitute can be used the tube by another tube of the same type make a new regulation of the circuit necessary.

The previously common designs of phantastron circuits, whether they work with screen grid coupling or with cathode coupling, have the disadvantage that there is an indeterminacy with regard to the duration of each work cycle due to the presence of a temporal residual part between the base of the sawtooth and the again increasing exponential part of the curve , there between the two moments, where on the one hand the Phantastronsdialtung to generate
of sawtooth-shaped tensions

Applicant:

Compagnie Francaise Thomson Houston, Paris

Representative: Dipl.-Ing. C. elements, patent attorney,
Deggendorf, Krankenhausstr. 26th

Claimed priority:
France October 24, 1952

Jacques Maurice Boisvieux, Nogent-sur-Marne,

and Jacques Chaumeron, Paris (France),

have been named as inventors

Operating point the curvature of the current-voltage characteristic of the anode of the pentode tube is reached and on the other hand, the potential of the quenching or braking grid falls below the cathode potential, a certain amount Time span, which depends on the tube used and therefore on the.

changes one to the other tube.

For the Sanatron, a circuit that reduces this residual time to a minimum is already known, in which (cf. "Electronic Time Measurement", p. 125, Fig. 5,10) a transformer is attached to the screen grid of a tube for converting the screen grid Occurring pulse is connected to a different and opposite pulse and the screen grid current, when you reach the lower end of the linear part of the characteristic curve, increases, resulting in a pulse that further increases the potential of a diode tube and thus also the potential of the control grid a brings the tube to earth potential.

According to the invention is now in a way different from this Sanatron version in a Phantastron circuit for the generation of sawtooth-shaped characters a great stability of the mode of operation and great accuracy in the amplitude and duration of the character with simultaneous

809 559/348

avoidance of the need for a new regulation of the circuit when changing tubes achieved by that the sawtooth-shaped anode voltage drop of a tilt tube in the way with a DC voltage is compared as a reference potential that a diode or a triode is then live, when the anode potential falls below the reference potential, whereby a negative pulse is used as a »comparison pulse« is generated, which is switched to the braking grid of the tilting tube and thereby the The anode current of the tilting tube is interrupted.

For example, the drawing illustrates several embodiments of the switching arrangement according to the invention.

Fig. 1 shows the application of the invention in a phantastron circuit for generating sawtooth-shaped Voltages with a precisely defined size of duration and amplitude; . Fig. 2 allows the application of the invention recognize a phantastron ao circuit working with frequency division;

Fig. 3 shows a simplified embodiment of the circuit according to Fig. 1 again.

According to Fig. 1, the pentode 1, the resistors 2, 3, 4 and the capacitor 5 form the known one Phantastron circuit with cathodic negative feedback. The one consisting of resistors 6 and 7 The voltage divider is used to raise the screen grid of the tube 1 to a suitable direct voltage potential bring to. The capacitor 8 is a decoupling capacitor. The resistor 9 allows, if necessary take a square pulse at terminal 10, which has the same duration as that at the Anode occurring sawtooth voltage and which is therefore determined with the same accuracy.

The sawtooth voltage taken from the anode of the tube 1 is applied to the grid of the triode 11 fed through a capacitor 12. The tube 11 is connected as a cathode amplifier Cathode resistor 13 a sawtooth voltage is obtained, which is that at the anode of the tube 1 generated is the same. The grid bias of the tube 11 is determined by a resistor divider circuit 14,15, 16 and the grid leakage resistance 17 of the tube 11 is connected to the connection point 18 of the Resistors 14 and 15 connected.

At the connection point 19 of the resistors 15 and 16 there is a potential which is used as a reference level serves to limit the sawtooth voltage. Namely, if the potential of the cathode of the Tube 11 falls below the potential of point 19, the diode tube 20 supplies current and a voltage appears at the terminals of resistor 21. The appearance of this voltage produces at point 22 a negative pulse which is fed to the braking grid of the tube 1 via the capacitor 23. This braking grid is on the other hand connected to a bias voltage source via a resistor 24, which is formed, for example, by the voltage divider 25, 26.

The negative pulse fed to the braking grid of the tube 1 causes a reduction in the anode current of tube 1 and continues to call for an acceleration of the occurrence of the transitory effect as a result of the voltage drop, which on the screen grid of the tube 1, the enlargement of the Caused screen grid current, which is due to the reduction of the anode current. The amplitude of the sawtooth-shaped signal is thus only determined by the voltage divider 14, 15, 16 Reference level established, which on the one hand the middle potential and on the other hand the lower The potential of the sawtooth trace is determined. The amplitude is independent of the characteristics of the various tubes used in the circuit.

With a phantastron circuit working with division of the frequency of the pulse train by 11 in the manner of Fig. 2, its return after its initial or waiting state between the (n- 1) -th and the η-th pulse according to the pulse triggering the sawtooth-shaped character must take place, the new sawtooth-shaped character is caused by the first pulse, which follows the return of the Phantastron circuit in its initial or waiting state. The duration of this return is fixed and depends only on the size of the anode resistance and the connecting capacitor between the anode and the grid. In order for the return to take place between the (n - 1) th and the η th pulse, it must begin at a point in time that is all the more precisely defined, the larger the number η , ie the shorter the time interval between the (»-) -th and the w-th pulse opposite to the repetition period of the sawtooth-shaped characters.

The stabilization method described with reference to Fig. 1 is accordingly for a circuit also applicable according to Fig. 2 and is thereby advantageously using the synchronization pulses even carried out to determine the end of the sawtooth-shaped character. To this According to Fig. 2, the purpose is the pentode tube 27 with the capacitors 28 and 29 and the resistors 30 and 31 connected to a phantastron circuit with screen grid coupling. The mean screen grid voltage is determined by the voltage divider 32, 33, and the resistor 34 is used, if necessary take from it a square pulse of the same duration as the sawtooth-shaped character. The cathode of the tube 27 is connected to earth and the retarder grid is connected to a resistor 35 connected bias voltage source formed by the voltage divider 36, 37.

The pulse train whose frequency is to be divided is applied to terminals 38 'with negative polarity introduced. They are fed to the anode of the tube 27 via the diode tube 39, the cathode of which via the discharge resistor 40 to a bias voltage source formed by the voltage divider 41, 42 connected. The cathode of the triode 43 is connected to the anode of the tube 27 and the anode of the tube 43 applied via the anode resistor 44 to a positive voltage source, which for example can be formed by the voltage divider 45, 46. The capacitor 47 is a decoupling capacitor. The grid of tube 43 receives from the clamp 48 'from via the capacitor 48 also a pulse train whose frequency you want to divide, but which is supplied here in the form of positive pulses and the tube 43 attempts to open periodically. The leakage resistor 49 of the grid of the tube 43 is connected to the supply current source of the anode. The voltage divider 45, 46 is so> set that the potential at the point 47 'something is above the minimum potential reached at the anode of the tube 27 by the sawtooth-shaped mark that she delivers. The cathode of tube 43 is thus negative with respect to the anode of this tube only towards the end of the linear part of the sawtooth-shaped character. From that moment on calls

the first positive pulse applied to the grid of tube 43 indicates the supply of current and the occurrence of a negative pulse at the anode of the tube. This impulse, which the braking grid of the tube 27 is supplied via the capacitor 50, the occurrence of the transit effect in the tube 27 has to Sequence and determines the beginning of the return of the Phantastron circuit in its waiting state.

This moment of return is therefore determined with accuracy, since it only depends on the steepness of the sawtooth-shaped characters and the size of the resistors 45 and 46 and inevitably coincides with the moment of arrival of one of the pulses of the pulse trains to be divided. If (n - p) is the ordinal number of this pulse, the value p can be determined with the help of the electrical quantities of the components 29, 30 and 31 of the phantastron circuit and the values of the resistors 45 and 46 so that the return of the phantastron circuit to its waiting state ends after the (n- 1) th pulse and before the η th pulse. Under these conditions, the operation of the frequency dividing circuit is independent of the characteristics of the tube 27.

Figure 3 illustrates a simplified embodiment the circuit according to Fig. 1 for the case in which the sawtooth voltage of the Phantastron circuit with a high impedance can use. The tubes 51 and 64, the resistors 53 to 58 and 61 to 63 and the capacitors 52, 59 and 60 agree with the corresponding switching elements corresponds to Fig. 1. The sawtooth voltage is drawn directly from the anode of the tube 51 transmitted to the cathode of the diode tube 64 without being switched through a cathode amplifier To run intermediate tube. The anode of the diode tube 64 is through the resistor 65 with a Voltage divider 66, 67 connected, the middle point of which is the limit potential of the sawtooth-shaped Character. The diode tube 64 operates in the same way as the diode tube 20 of Fig. 1.

In Figs. 1 and 3 on the one hand and in Fig. 2 on the other hand, phantastron circuits are for example shown in which the coupling circles are different. Of course, the type of feedback can be according to the invention also in any other type of phantastron application Find.

Claims (3)

Patent claims: 1. Phantastron circuit for generating sawtooth-shaped voltages, characterized in that that the sawtooth-shaped anode voltage drop of a tilting tube is compared in this way with a DC voltage as a reference potential is that a diode or a triode is then current-carrying when the anode potential falls below the reference potential, whereby a negative pulse is used as a "comparison pulse" is generated, which is switched to the braking grid of the tilting tube and thereby interrupts the anode current of the tilting tube (Fig. 1). 2. Phantastron circuit for generating sawtooth-shaped voltages on a low-resistance Impedance according to Claim 1, characterized in that the comparison pulse between the anode of the pentode tube (1) and the supplying diode (20) an impedance matching stage of the type of a cathode amplifier (11, 13) is switched on (Fig. 1). 3. phantastron circuit according to claim 1 in further development of a frequency divider, characterized in that the pulse train to be divided acts on the phantastron circuit at two different points (38 'and 48') with opposite polarities in such a way that a negative pulse with the ordinal number n , which acts on the anode of the Phantastron (27) via a diode tube (39), triggers the sawtooth voltage and a positive pulse with the ordinal number n + p causes the sawtooth voltage to be inhibited when the anode potential of the Phantastron (27) drops below the reference potential (Fig. 2). Considered publications:
"Waveforms", McGraw Hill Book Co., New York, 1949, p. 203; "Electronic Time Measurement" by B. Chance et al., McGraw Hill Book Co., New York, pp. 124 ff .;
»Radio · Mentor«, 1952, pp. 067 to 072. 1 sheet of drawings © 809 559/348 6.58