DE951458C - Arrangement for generating voltage surges in succession in telecommunications, in particular telephone systems - Google Patents

Description

The subject of the main patent is a circuit arrangement, the task of which is to time deliver successive voltage surges to a plurality of outputs. To this end two groups of contact means are provided which, in order to match with a given number of contact means to achieve the greatest possible number of exits, cooperate in terms of coordinates. In In one embodiment, cam contacts are specified as the contact means, their control cams to comply with a prescribed chronological sequence of closing times, for example can be arranged offset from one another on a common control shaft. as Decoupling elements at which the voltage surges that can be removed from the outputs are tapped, resistors are used, each of which is in series with a guide. With coincident control a single guide is blocked by a contact means of each of the two groups, which creates the desired output voltage surge at the associated resistor. In a second embodiment find electron tubes as the contact means of one group Application that uses a transformer on the anode side with the appropriate grid-side control

output shock waves to the guide wire located at the relevant transformer.

The additional patent gives a further training which is particularly advantageous in certain applications the circuit arrangement described above. It is characterized in that in front of the outputs serving as decoupling transformers are connected in series with decoupling directional conductors on the one hand to the cathodes of the ίο serving as contact means tubes of the first Group, on the other hand to the anodes of the tubes serving as contact means of the second group are connected, the anodes of the tubes of the first group to the positive pole of the operating voltage source and the cathodes of the tubes of the second group connected to their negative pole and that pulse voltages are supplied to the tubes for control.

With reference to the drawings, the essence of the circuit arrangement according to the invention in various Embodiments are explained. In detail shows

Fig. Ι an embodiment using high vacuum tubes,

2 shows the connection of a control circuit which is favorable for the intended purpose, 3 and 4 exemplary embodiments using gas discharge tubes.

The figurative representation was in all cases to the extent necessary for understanding limited.

In the exemplary embodiment according to FIG. 1, high vacuum tubes are used as contact means, the total number of which is divided between the tubes of the two groups T1 a ... T1 m and T 2a ... T 2η . The operating voltage is fed to the circuit arrangement via the terminal labeled + Ub. In the idle state, all tubes are blocked by grid biases Usp. These are fed, for example, to the tubes T2a ... Tzn via grid resistors; in the case of the tubes T ι a ... T 1 m of the other group, their sources are shown graphically as batteries. That, in view of the periodicity of the control voltages to be supplied, other means, such as. B. i? C-members can be used to generate automatic grid biasing, will not be discussed in detail here, since it does not belong to the invention. The transformer Traa ... Trmn serving as decoupling elements, the secondary-side terminals of which represent the outputs of the circuit arrangement, with their associated decoupling directional conductors Rl τ aa ... RIx mn are connected to the two groups of pipes by coordinate-like wiring so that each individual transformer each with two very specific tubes, one of which is the. Group Tia ... Tim, the other belonging to group T2a ... T2n, is in series. Only when these two tubes are unlocked on the grid side, which can be achieved by supplying control voltages Us _1, which in the present case are expediently pulse voltages, does a current flow through the primary winding of the transformer designated by these two tubes Impulse to decrease allowed. If the unlocking duration of the two tubes is not the same, the pulse on the output side thus has the duration of the shorter of the two unlocking pulses. The decoupling directional conductors in series with the transformers prevent the formation of other low-resistance circuits, also containing transformers, in addition to the one desired circuit, which would give rise to faulty, simultaneous impulses at several outputs.

In order to generate pulses that appear one after the other at the individual outputs, it is necessary to control the tubes with pulses in a very specific way. A suitable scheme of the control voltages can look like this, for example, that the tube T2a is unlocked until all the tubes of the other group Tla ... Tim have been unlocked once one after the other in chronological order. Then, while the tube T2a is blocked at the same time, the next tube in this group, namely Tab, is unblocked and while this tube is carrying current, each tube in the group Tτα ... Tim is unblocked once etc. a tube in one group carries current until all tubes in the other group have been unlocked once, after which the current-carrying state is transferred to the next tube in the first-mentioned group. It does not matter which of the two groups of tubes the longer pulses required for this and which the shorter pulses are supplied to which.

The above-described scheme of control voltages can expediently be implemented by counting chains connected as ring counters, the position of the currently active level of one counting chain advancing by one level after the other counting chain has counted completely once. All arrangements are suitable as counting chains for this control, in which the following stage is activated after receiving a counting pulse and each stage has its own output terminal, which allows the pulse voltage Us required to control no of the associated tube serving as contact means to be taken.

In Fig. 2, the interconnection of the circuit arrangement according to the invention with two such counting chains Zi and Z 2, the stages with Zia ... Zi m and Z2a ... Z2n are shown. The pulse generator IG serves as the clock, the output pulse of which has a frequency equal to the counting frequency of the counting chain Z1 and whose stages are fed in parallel. At the same time, the frequency divider T is controlled by this output pulse, the division ratio of which is equal to the number of stages in the counting chain Zi and whose output pulse is used to control the counting chain Z 2. A saving of the frequency divider is

possible if the one used to control the counting chain Z2 required pulse can be taken from a stage of the counting chain Zi.

On the basis of the above illustration of the structure and the mode of operation of an exemplary embodiment The advantages of the circuit arrangement according to the invention can now be demonstrated.

The circuit arrangement according to the invention initially allows much higher pulse frequencies to work than is possible with arrangements controlled by means of mechanical contacts are. It also embodies the transition from quiescent current to that explained below Open-circuit principle.

While in the circuit arrangement according to patent 897 853 in the pauses of the output pulses through each directional guide that is permeable in these time intervals through the associated Resistance limited current flows and with appropriate contact actuation through the switched on Voltages of this current flow are blocked. causing a voltage surge at the resistor occurs, flows in the circuit arrangement identified above only during the output pulse duration, so during the working period, electricity. As the duration of the shorter, one tube each supplied control pulses is always small compared to the duration of their pulse pauses, results from this a considerable saving in electricity. Closely related to the transition from quiescent current to the operating current principle is the question of the load capacity of the output voltages or the internal resistance of the individual outputs. This is in the circuit arrangement according to the main patent essentially determined by the resistance associated with each output. This must however, large compared to the passage resistance of the associated directional conductor to be during the Pulse pauses at the output terminal because of the imperfect short circuit through the Directional conductor to keep residual stress as low as possible. A consideration of this condition therefore always leads to outputs with relative

4-5 high internal resistance and the associated low load capacity of the output voltages.

In contrast, the circuit arrangement according to the invention does not include the above-mentioned Quiescent current principle resulting demand, gone.

For the internal resistances of the outputs only the internal resistances of the tubes are decisive always in pulsed operation with high vacuum triodes and with high vacuum triodes in the case of suitable ones Levels are very low. The high achievable at the primary windings' of the transformer Voltage drops also allow down-transforming transformers in many cases use that! in addition, a considerable reduction in size of effective intienal resistance.

A further improvement in this direction is obtained if the high vacuum tubes are used instead Gas discharge tubes, which are known to have an almost negligible direct current internal resistance, be used. Compared to the circuit arrangement according to FIG. 1, however, if desired, both sets of tubes. without the grid-side interconnection of transformers to control, certain modifications are necessary, otherwise the gas discharge tubes very high requirements with regard to the ignition mechanism, which is complicated when connected in series their tolerances would have to be set. To solve this problem, it is advisable to the electrodes of the tubes of both 7g that are connected to one another via the output transformer Bring groups to certain potentials by auxiliary resistors, which are chosen so that each tube can be ignited separately, regardless of whether the tube with which it is connected it is supposed to close the circuit for a particular transformer at the same instant is ignited.

In FIG. 3, the gas discharge tubes Via ... V, shown as grid-controlled current gates, are equipped on the cathode side with resistors Ria ... Rim of this type. Each tube in this group can thus be ignited by applying a suitable voltage to its control electrode, even without a tube in group V2a ... V-zn burning. Such resistors, which would then have to be connected between their anodes and, for example, the positive pole of the operating voltage source, could also be provided for the tubes of this group. The directional conductors Rliaa .... RIimn serving for mutual decoupling of the outputs serve here at the same time to suppress a current flowing continuously through these resistors and the transformers. In this case, an extinguishing device would have to be provided in the common operating voltage supply for both groups to extinguish burning tubes.

Due to the fact that only a single tube burns in each group, it is also possible to combine the resistors provided for the independent ignition of their tubes in a group and at the same time use them for extinguishing. Such an arrangement is shown in Fig. 3 in connection with the tubes of group V 2a. .. V 2η shown. The operating voltage + Ub is fed to these tubes via the common resistor Rs. The anodes of the individual tubes are connected to this resistor with an interposition of an IC element via the directional conductor Rl 2a. . . Rl 2 η connected for the purpose of mutual decoupling, which is necessary for a clear identification of an output transformer. The .RC elements consisting of the resistors i? 2ß ... R2% and the capacitors C2a ... C2n , each of which is assigned to a tube, are used in conjunction with the resistor i? 3 common to all tubes to cancel the each burning tube when igniting the following. The resistance of the resistors J? 2ö ... R 2 η is chosen so that when burning a

Tube at their respective associated resistance voltage drop greater than the difference between the ignition and operating voltage of the tubes of this group; so it's up to everyone non-ignited tube of this group has a voltage that leads to ignition when unlocked on the grid side is sufficient. If another tube is ignited, the tube that has not yet been charged closes Capacitor at the moment of ignition practically its

ίο Short parallel resistor, which means that there is hardly any voltage drop across it at first and thus the voltage that is behind resistor R 3 and fed to all tubes is momentarily reduced to the burning voltage. The voltage on the already burning tube falls below the value required to maintain the gas discharge, since the capacitor belonging to this tube is still on the

The voltage created by the resistance is charged, which extinguishes this tube. The size of the Capacitor as a function of its parallel resistance, i.e. the discharge time constant to choose so that the one lying on the tube

he voltage during the deionization time has not yet reached the minimum required for firing. The known extinguishing effect is thus achieved through the resistance R 3 in cooperation with the individual i? C elements.

When using this method, care must be taken that during the time interval in which the resistor i? 3 is effective in the manner described above, i.e. during the transition of the current-carrying state from one to the next tube of group V2a ... V 2η , no tube of the group Via .. ..Vim is burning, since every burning tube of this group forms a low-resistance shunt to A3 and would therefore cancel its effect. By controlling the extinguishing device L , however, this requirement can easily be met. It also makes it seem expedient to switch on the tubes of the group Fid ... Fiman the counting chain with a higher counting frequency.

The simultaneous use of canceling circuits in both tube groups would be without further Precautions the very low internal resistance of the outputs of the without this measure Increase the circuit arrangement quite considerably, since then one of the two will each be in a group common resistances of tubes always to a low-resistance shunt and thus a Avoid being rendered ineffective by a burning tube of the other group z, u in series with the Tubes of his group and the output transformers would have to be.

Fig. 4 shows a circuit arrangement whose outputs, despite the simultaneous use of Quenching circuits in both tube groups very

Have such low internal resistance. Since this, as stated above, with the original Circuit arrangement can not be realized, this is a pulse amplifier stage in the Upstream way that for the internal resistance of the outputs no longer one of the two Quenching resistors, but rather the pulse amplifier stage with its low output side Internal resistance is decisive.

With this circuit arrangement, too, it is advisable to connect the tubes of the group Vi a ... V 1 m to the counting chain with a higher counting frequency. The resistor R 3 serves, as described in connection with FIG. 3, as a quenching resistor of the tubes of group V2a ... V2η, whose anodes are connected to it with the interposition of the resistors i? 2ö ... R2n and capacitors C 2 a . .. C 2 η existing i? C elements are connected via the decoupling directional conductor Rl 2 a ... Rl 2 η ; the operating voltage source is connected between the terminal marked + Ub and the general negative pole. Via the tubes ... V in are connected for the purpose of the operating state of the tubes of the group V2a ... V 2 n independent ignition cathode side via the Widerständet ι α ... Rim to the negative pole. They receive their anode voltage via the resistor R 4, to which they are connected, since no decoupling is required at this point, without the interposition of directional conductors. This resistance in connection with the RC elements on the cathode side consisting of the aforementioned resistors Ria ... Rim and the capacitors Cia ... Cim achieve the desired extinguishing effect in this group of tubes. When a tube of group Via ... Vim is burning (and thus, as stated above, a tube of group V2a ... V2ti is burning at the same time), its cathode is at a voltage that results from the burning voltage of the tube of group V2a that is just burning . . . V2n and the voltage drop on the primary side of the transformer determined by the two tubes; the relevant cathode-side capacitor charges to this voltage. The resistor R 4 is to be chosen so that the voltage on the non-ignited tubes of the group Via ... Vim is not lowered below the minimum value required for ignition. To ignite another tube of the group mentioned, the full voltage behind R 4 is available for this, since its cathode is kept at ground potential by the resistor assigned to it. When igniting, this tube lowers the voltage between the anodes of all tubes in this group and the common negative pole to the burning voltage, since its capacitor is initially still uncharged and its parallel resistor is practically short-circuited. In connection with the capacitor voltage of the tube that is just burning, the voltage applied to it is thereby lowered, at least during the deionization time, below the minimum value required to maintain the gas discharge and thus this tube is extinguished. The resistance R 4 has a value comparable to the resistance i-3.

The above-described effect of the resistor R 3 is retained in this case even when a tube from the Via ... V im group burns, since the resistance of the circuit parallel to A3 is now determined by the resistor R 4. The mode of operation of R 4, on the other hand, remains unaffected, since during the time intervals in which R 4 takes effect, there is always a tube of the group ■ V 2 a. . . V 2 η burns.

Deviating from the arrangement described above, the desired extinguishing effect can also be achieved for the tube group Via ... Fim by placing the RC elements required for this in the anode lines of the individual tubes; the mode of operation of this arrangement corresponds to that shown in connection with the tubes of group V 2 a ... V 2 η . A note as to when one or the other arrangement should advantageously be used will be given later.

Arrangements of this type would allow output pulses of the desired type to be generated, but because of the resistor R 4 located in the primary circuit of each output transformer, these would hardly be able to withstand loads.

In order to reduce the internal resistance of the output terminals to the desired low value again, a pulse amplifier stage equipped with the high vacuum tube Γ 3 and connected as a cathode amplifier is connected via its output-side capacitor C 3 and directional conductor i? 13 connected to the anodes of the tubes of the Via ... Vim group. The directional conductor bias, which is generated, for example, by the voltage divider R 5, R6 , is selected so that the directional conductor remains impermeable even when a tube in this group is burned. Only with positive control of the cathode amplifier through its input Ui supplied pulses, which are expediently taken from the pulse generator IG ₁ serving as a clock, possibly with the interposition of a delay device and whose maximum duration may be equal to the time interval between the repeated activation of the resistor R 4 , does the total voltage exceed of the directional conductor bias and the output voltage of the cathode amplifier is the counter voltage on the directional conductor. This makes the directional conductor permeable and the new circuit

Cathode amplifier output - one of the tubes Vi - output transformer - one of the tubes V 2

closed. The output pulse of the cathode amplifier is transmitted to the output transformer through this circuit; Instead of the resistance R 4 , which was initially decisive for the internal resistance of the outputs, there is now the very low internal resistance of the cathode amplifier on the output side, as a result of which the outputs of the circuit arrangement again have the desired low internal resistance. Every impulse occurring at an output terminal is made up of 2 parts, namely the one part that already occurs when a tube of the groups Via ... V im and V2a ... V 2 η is burning, is hardly load-bearing and whose amplitude when the consumer is switched on is essentially determined by the voltage divider ratio resulting from the resistance value of R 4 and the consumer resistance, and a second part, which corresponds to the output pulse of the cathode amplifier and whose load capacity is determined by its output-side internal resistance. In cases in which the first-mentioned pulse part interferes, which in itself only occurs with a very small amplitude when the output is loaded due to the high voltage divider ratio, it can be controlled by an amplitude limiter connected between the output transformer and the output terminal of each output, which consists of a suitable voltage Uv biased directional conductor Rl4aa ... Rl4mn , can be suppressed in a simple manner, while the pulse part originating from the cathode stage exceeds the bias voltage and is transmitted to the output terminal without being weakened.

Of course, the cathode amplifier can also be connected with direct current coupling to the anodes of the tubes Via ... Vim . In this case, the capacitor C 3 and the voltage divider formed from the resistors R 5, i -6 are omitted. The directional conductor bias originally supplied by this voltage divider is now applied to the directional conductor as cathode quiescent voltage of the tube T 3, which in this case carries quiescent current, which can be set to the correct value by means of a grid bias.

The upstream connection of a pulse amplifier stage offers the possibility of using extinguishing circuits in both groups, the advantage of generating pulses at the outputs, the duration of which can be as short as the control pulses supplied to the shorter group of tubes, since the shortest possible duration of the output pulses is no longer due to the Gas discharge tubes are determined on the basis of their ionization and deionization times. It depends on the duration of the shorter pulses supplied to the control grids of the tubes of one group and the duration of the pulses supplied by the pulse amplifier stage whether the extinguishing circuit assigned to the tubes of the group Via ... V im in the embodiment with the anode-side or the cathode-side i? C limbs is preferable. In general it can be said that the more the difference between the duration of the two pulses mentioned, the anode-side arrangement of the i? C-elements becomes more advantageous, since in this case the capacitors increasingly short-circuit their parallel resistances, but with a cathode-side arrangement by shunting to the Output circuits would also consume pulse power.

This possibility offered by the upstream connection of a pulse amplifier stage can also be used in connection with a circuit arrangement according to FIG. 1 equipped with high vacuum tubes. A case of interest here is e.g. B. before when the one in the arrangement according to Fig. Ι the duration of the output pulses determining counting chain due to its circuit characteristics emits longer ίο pulses than are required by the consumers. To suppress to long these unwanted pulses, it is sufficient in the operating voltage supply of the circuit arrangement of FIG. Ι before the anodes of the tubes Tia ... Tim insert a resistor, whereby the amplitude due to the voltage divider action of this resistor together with the respective load resistance in is reduced to an extent sufficient for many applications. If necessary, prestressed directional conductors that act as amplitude limiters can also be connected between the output transformer and the output terminals. The tubes of the two groups Ti a ... Ti m and T 2.0, ... T 2n thus serve to mark the desired output transformer, while the narrow useful pulses are transmitted via a dedicated cathode amplifier, the output of which, as shown in FIG a directional conductor to the anodes of the tubes T ι a. .. T ι m is switched to the tubes of this group and thus to the outputs.

In summary, the mode of operation of the two circuit arrangements explained above can be represented in such a way that the two tube groups T ι a ... T ι m or Via ... V im and T2a. . .T2fi or V 2, a. . .V zn to high-resistance, low-power-requiring marking of the desired output transformer are used, to which the pulse amplifier stage then transmits the power with low resistance. This principle of separate marking and pulse transmission is carried out in such a way that, by inserting a resistor in the operating voltage supply, the outputs receive a high internal resistance, which is set to the desired low value during the duration of an upstream pulse amplifier stage, which simultaneously supplies the output pulses is reduced.

Finally, it should be noted that the circuit arrangement according to the invention is by no means to the control scheme on which the description is based, consisting of long and short Impulses composed, is bound. In the same way, for. B. a control scheme application find, accordingly, pulses of the same width are fed to both tube groups counting chains can also be taken. This scheme allows the two counting chains supply the same control pulse supplied by the pulse generator, but is subject to the condition, that the numbers of the tubes in both groups are not an integral, common divisor have (e.g. 7: 5).

In FIGS. 3 and 4, which serve to explain the description, the exemplary embodiments show the circuit arrangement according to the invention when using gas discharge tubes these gas discharge tubes are represented by the switching symbols for electricity gates with control grids. However, the use of gas discharge tubes is not limited to power gates alone; Rather, all types of gas discharge tubes equipped with ignition electrodes can be used are used insofar as they are the result of the intended use of the circuit arrangement Meet the requirement of sufficient current carrying capacity. Furthermore, in the above Figures show two exemplary embodiments of the circuit arrangement according to the invention, of which each unites several distinctive features. It should be noted that their use is not restricted to the combinations given here, but rather that these features rather, within the scope of conventional circuit technology, also to circuit arrangements with those shown Figures deviating structure can be summarized.

Claims (14)

Patent claims: i. Circuit arrangement, preferably for telecommunications, in particular telephone systems, for the generation of voltage surges occurring at separate outputs, successive voltage surges through coordinate-like cooperation of two contact means, each of which belongs to its own group of the same contact means, with the contact means of both groups being interdependent cyclically Sequence are operated, according to patent 897 853, characterized in that in front of the outputs serving as decoupling elements (Tr) are connected, which are connected in series with decoupling directional conductors (Rl 1) on the one hand to the cathodes of the tubes serving as contact means of the first group (Ti, Vi), on the other hand, are connected to the anodes of the tubes of the second group (T 2, V 2) serving as contact means, the anodes of the tubes of the first group (Ti, Vi) to the positive pole of the operating voltage source (+ Ub) and the Cathodes of the tubes of the second group (T 2, V 2 ) are connected to their negative pole (-), and -that the tubes (Ti, Vi, T2, V 2) are supplied to control pulse voltages (Us). 2. Circuit arrangement according to claim 1, iao characterized in that the tubes serving as contact means are high vacuum tubes (Ti, T2) are. 3. Circuit arrangement according to claim 2, characterized in that in the positive pole of the operating voltage source (+ Ub) An operating voltage supply leading to the anodes of the tubes of the first group (Ti, Vi) is inserted a resistor (R 4) which is higher than the load resistors and means are provided for controllably reducing the internal resistance on the output side. 4. Circuit arrangement according to claim 1, characterized in that the contact means of the first (second) group of high vacuum tubes (Ti-T2) and the contact means of the second (first) group of gas discharge tubes (V2-Vi) are used, with ignition and extinction of the gas discharge tubes ( Vi, V2) is effected by unlocking and locking the high vacuum tubes (Ti, T2) . 5. Circuit arrangement according to claim t, characterized in that the tubes serving as contact means are gas discharge tubes (Vi, V2) . 6. Circuit arrangement according to claim 5 for the operating state of the tubes of the other group (V 2 -Vi) independent ignition and extinguishing of the tubes of the one group (V ι-V2), characterized in that in each case between the to the transformers (Tr) with Enikoppelrichtleitern (Rl 1) leading electrodes of the tubes of one and / or the other group (V ι-V2) and the associated pole of the operating voltage source (+ 'UB / -) resistors (Ri ~ R 2) are connected and each with such Resistors equipped group in the common, to the other electrodes leading operating voltage supply (+ UbI -) a device (L) for extinguishing ignited tubes is placed. 7. Circuit arrangement according to claim for the operating state of the tubes of the other group (V2-V1) "independent ignition of a single tube of the .ein group (Vι-V2) with simultaneous extinguishing of an already burning tube (Vi-V2) of this one group, thereby characterized that the tubes of this one group (V1-V2) the operating voltage ('+ UbI -) is fed via a common series resistor (R4.-R3) and in series with the tubes of this group of parallel circuits of one resistor (R1- R2) and a capacitor (Ci -C 2) existing i? C elements (R1C1-R2C2) are connected, whereby when igniting a tube (Vi-V2) while burning another tube (Vi-V2) of this group in cooperation with its i? C element (RiC 1-R2C2) the voltage on this tube is lowered below the burning voltage so that, if the common series resistor (R4-R3) and the individual i? C elements (R1C1-R2C2) are connected the electrical leading to the transformers (Tr) with decoupling directional conductors (Rl 1) that of the tubes are connected, between the common resistor (R 4-R 3) and the individual RC Glitder (Ri Ci-R 2 C 2) a directional conductor (Rl 2) is inserted that the transformers (Tr ) with decoupling directional conductors (RIi) leading electrodes of the tubes of the other group (V2-V1) the operating voltage (+ UbI -) for the purpose of independent ignition of these tubes is supplied via resistors (R2-R1) , and that in this other tube group (V2-Vi ) Means are provided which prevent the common previous resistance (Ä4-.R3) of one group from becoming ineffective as a result of the formation of a shunt caused by burning pipes of this group (V2-V1). 8. Circuit arrangement according to claim 7 for preventing a shunt by burning a tube of one tube group (JVi-V2) to the resistor (R3-R4) located in the common operating voltage supply of the tubes of the other group (JV2-V1 ), characterized in that that an extinguishing device (L) is provided in the operating voltage supply of the first-mentioned tube group (Vi-V2) , which is controlled in such a way as a function of the control voltages (Us) supplied to the tubes (JVi-V2) that it is activated before the other group takes effect associated common resistor (R3-R4 ) extinguishes the burning tube (V1-V2) in its group. 9. Circuit arrangement according to claim / for preventing a retroactive effect of one tube group (JV1-V2) on the function of the 95 'in the common operating voltage supply of the tubes of the other group (V2-V1). resistance located (R3-R4), characterized in that in the common operating voltage supply of the first-mentioned tube group (Vi V2), a resistor (R4-R3) is comparable to the resistance (R present in the common operating voltage supply of the other tube group (V 2-Vi) 3-i? 4) is inserted and means 105 are provided for controllably reducing the internal resistance on the output side. 10. Circuit arrangement according to claim 3 or 9 for reducing the internal resistance on the output side, characterized in that a cathode amplifier (with tube Γ 3) is provided, the output of which via a directional conductor (Rl 3) to the anodes of the tubes of the first-mentioned group (Ti, Vi ) is switched, whereby the directional conductor (RIz) is biased by supplying a voltage so that it is only permeable when burning a tube of the first group (T i, Vi) and simultaneous positive control of the cathode amplifier (with tube T 3). 11. Circuit arrangement according to claim 10 for suppressing unwanted output pulse parts, characterized in that biased between the secondary windings of the transformer serving as decoupling elements (Tr) and the associated output terminals Richtleiter {Rl 4) are switched on as an amplitude limiter. 12. Circuit arrangement according to one of the preceding claims, characterized in that for controlling the tubes of one and / or the other group (T 1, Vi-T 2, V2) their control electrodes are connected to the outputs of a decadic counting chain (Zi, Z 2) are switched, which are switched on by pulses from a common pulse generator (IG) in mutual dependence. 13. Circuit arrangement according to claim 12 when using two counting chains, characterized in that one counting chain (Zi, Z 2) to the. Pulse generator (/ G) and the other (Z 2, Zi) to a stage of the former Counting chain is switched on. 14. Circuit arrangement according to claim 10 and 12, characterized in that the cathode amplifier (with tube Γ 3) is connected to the pulse generator (IG) via a delay device. 1 sheet of drawings