DE840775C - Electronic counter - Google Patents

Description

Electronic counter 1? S already became a device for counting proposed high-frequency electrical potential pulses, the multiple grid-controlled Electron tubes includes which are coupled together so that they have multiple pairs of triggers form. Only one tube of a pair can be in a conductive state in these are located, and they also have the property that when one of the two tubes of the pair is put into the conductive state, the other tube of the pair to go out is brought. The device also includes means for transmitting the pulses on the control grids of all tubes as well as means which couple the trigger pairs together that these are brought to work in sequential order in response to the impulses with only one pair of triggers when responding to the individual impulses changes the way he works. Which in response to the impulses in succession The trigger pairs are going to work with the help of the inner tube couplings achieved, which cause the impulses, in this case positive impulses, to be weakened and thereby rendered ineffective, a non-conductive tube in a conductive state to move with the exception of the one, which of the couplings for each pulse is predetermined.

Likewise, the present invention relates to a Device for counting electrical potential pulses. It comprises several trigger-related Couples of electron tubes which are arranged so that they appear in succession Pulses applied to all tubes react, with the reaction only one pair of triggers changes its mode of operation on the individual impulses. However, the chain connections between the tubes are what ensure that the trigger pairs react in succession to the impulses, so designed, <lad the individual trigger pairs when they respond to an erratic pulse by changing their mode of operation have reacted, apply preparation potential to the next pair of triggers and make this pair of triggers react to the next impulse.

In the form of the invention as presented, there are grid controlled vacuum tubes used. The chain links extend between the anodes of the tubes of a pair of triggers and the control grids of the tubes of another pair and relocate Potential; changes that result when the tubes become conductive and non-conductive, able to control the potentials of the control grid ztr. The arrangement of the chain links takes place in such a way that only one trigger pair of the ring is prepared at a time, what is achieved is that the control grid of its conductive tube with the anode a conductive tube of another pair and the control grid of a non-conductive one Tube in connection with the anode of a non-conductive tube of another pair is brought; in all other pairs the control grid is in place at this moment the conductive tube of a pair with the anode of a non-conductive tube of a other pair and the control grid of the non-conductive tube of the pair with the Anode of a conductive tube of another pair in connection.

While the individual impulses are brought to all tubes of the ring the control grids of the tubes have potentials of such value that the individual impulses only change the mode of operation for that pair of triggers bring about what is prepared, d. H. whose tubes control grid potential values have which are suitable to enable the tubes to respond to the pulses to react.

The chain links and the trigger links between each Tubes are arranged in such a way that one made in response to an impulse Change in the mode of operation of a trigger pair brought another trigger pair to it will respond to the next pulse brought to the ring. In this way allow the connections that the with the individual trigger pairs of the ring resulting change in the way of working step by step one after the other and in Reaction to the linpulse applied to them takes place.

The combination of the trigger connections and the network of preparatory connections make it possible to create a ring which is able to react quickly to applied impulses and which is very stable in its operation. Rings with the trigger connections and the network of preparatory connections according to the invention, to which pulses were brought at a frequency of 300,000 pulses per second, had great stability in their operation, and it is believed that they are able to do so by themselves react to impulses zri whose frequencies still exceed those mentioned.

In the drawings, which show an example of a counting apparatus According to the invention, Fig. i is an illustration taken in the form of a diagram the pair connections constitute the network of preparatory connections between the tubes of the ring, Fig. z shows a circuit diagram showing the connections between the tubes of the ring illustrated, these tubes having a rubbing point of Represent information based on the decimal number system.

The ring illustrated by the drawings contains ten vacuum tubes, which are identified by the numbers o up to and including 9 for the description are.

The ring consists of high vacuum tubes, which have at least one anode, have a cathode and a control grid and are of the type which have a sharp demarcated electron current cut-off point and a low direct current anode resistance when the grid is below zero potential. In the cases in who want the ring to operate at high speed, must Tubes also have the lowest possible interelectrode capacitance.

In Fig. I, which illustrates the ring in the form of a diagram, the circles represent the tubes of the ring and bear the numbers mentioned above. The shading of the circles marked o, r, 2, 3 and 4 means that these tubes are in a conductive state. These tubes were chosen at random, to represent the zero or start position of the ring through its conductive state. Non-conductive tubes of the ring are not shaded.

each tube is operationally through with another tube of the ring Trigger connections connected which do the work of the paired tubes in the way control that at any stage of the work process in the ring the one or the other of the two tubes of the pair in conductive and the remaining tube is in the "non-conductive" state.

Wherever the term trigger is used, it means that in trigger-connected tube pairs and trigger circuits to pair the tubes are coupled so that when one tube of the pair is in the conductive state, the other does not necessarily guide, while the operation of the trigger pair, d. H. which of the two tubes is currently in a conductive or non-conductive state is located, changes by electrical impulses.

The line 61 (Fig. I) represents the trigger connection with whose Help the tubes marked with the number o and those marked with the number 5 are paired. Similarly, lines 62, 63, 64 and 65 provide the trigger connections between the tubes i and 6, 2 and 7, 3 and 8 or 4 and 9 In a way, tubes combined in pairs of triggers accept one or the other mode of operation must, d. H. that either one or the other tube of the pair is in conductive State, it is clear that become a given Point half of the tubes of the ring in conductive and the other half in will be in a non-conductive state.

1) The arrangement of the network of control connections in the ring takes place so that the conductive tubes in the ring at any stage of the operation adjoin each other in numerical order. 1> a actuation of the ring If the pulses are supplied, the tubes, which are after a through the individual impulses are in a conductive state in the ring, display a numerical value, which increases by one step when the individual impulses are received The group of conductive tubes advances step by step, which leads to it , advances clockwise around the ring lieruni, as illustrated in Fig. 1 :. will.

1) The following table illustrates the conductive and non-conductive state of the tubes in different stages of the working process in the ring, in which a different number of pulses is supplied to it. \ nnumber of Impulses tubes conductive tubes non-conductive 0 o, 1, 2, 3, 4 5, 6, 7, 8, 9 r 1,2,3,4,5 6,7,8,9,0 2,3,4,5, ) 7,8,9, o, 1 3 3, 4, 5, ( ). 7 8, 9, 0, 1 , 2 4 4, 5, 6, 7, 8 9, o, 1 , 2,3 5 5,6,7,89 0, 1 , 2.34 6 () , 7, 8, 9, o 1, 2, 3, 4, 5 7 7, 8, 9, 0 , 1 2, 3, 4, 5, 6 8, 9, o, 1,2 3, 4, 5, 6, 7 9 9.0, 1 , 2.3 4,5,6,7,, g (I ) () o, r, 2, 3, 4 5, 6, 7, 8, 9 Accordingly, after any number of pulses have started the ring from a home or zero position, a very lively set of tubes corresponding to that number of pulses will be in a conductive state. The number of pulses that have acted on the ring can be determined with the aid of a suitable means.

As will be described in more detail herein, they differ the potential values of the control grid and anodes of tubes in the conductive state of those of the control grids and anodes of tubes in a non-conductive state. This Circumstance can be used for a switching control and for the control of an additional means, such as B. a display and / or registration means can be used to a visible Display or register the information provided by the work status of the ring. As an example of some form of a feeling remedy could be use a rotatable sensing switch equipped with two arms is, inn at the same time the potential of similar electrodes in the end tubes of the to be able to test both groups of conductive and non-conductive tubes. This Switch would be able to control means which would then work if the determined potential equals the potential of two conductive or two non-conductive Tubes would correspond to which of these two groups is selected for control would.

Using the table above for the conductive and non-conductive The condition of the tubes compares and, as a controlling factor, the conductive condition of the Tubes are used, so you can see that the feeler switch, if it is in the individual Stages of operation the end tubes the group would examine for display every single digit would find a different combination of tubes. So would z. B. o and 4 represent the state for zero; 3 and 7 would indicate three Impulses have been brought to the ring; 9 and 3 would indicate the ring has received nine impulses. If the working condition in the ring indicated that If three impulses have been supplied to this, then the feeler arms would be in every digit position of the switch determine a conductive and a non-conductive tube until the digit 3 would be achieved. At this point the switch would feel tubes 3 and 7, which are both in a conductive state and a suitable display and / or Register means would control to display the number 3 and / or to register.

It will also be seen from the table above that the various How a pair of triggers works when displaying information is different Have meaning; the trigger pair, which includes the tubes o and 5, is z. B. in the conductive state of the tube o part of the representation of the digits 6 to o including, while it is part of the conductive state of the tube 5 the representation of the 7 digits r to 5 inclusive.

In the above table there is shown an arrangement in which the Tubes o, r, 2, 3 and 4 are considered as starting or zero point in the conductive state will. It should be noted, however, that the selection of this group is arbitrary and that any other group is used as a starting point can be. In order to ensure that the work process in the ring is always in the zero or starting position, suitable means are provided, such as switches in the screen grid circuits, which have the task of creating the circuits for the screen grid of tubes 5, 6, 7, 8 and 9 to interrupt, with the result that these tubes in non-conductive tubes and the tubes belonging to them o, r, 2, 3 or 4 in conductive ones Override state. As soon as the tubes o, r, 2, 3 and 4 become conductive, the The screen grid circuits of the tubes 5, 6, 7, 8 and 9 are closed again, and the ring is ready to work.

Circuits which connect two vacuum tubes in such a way that they are used as working a pair of triggers are known. They contain connections from each one Anode to a potential source via its own resistor, which causes that the potential of the anode according to the conductive or non-conductive state the tube varies. They also contain other compounds from the anode each individual tube to the control grid of the other tube in the pair, thereby achieving will that the changes of the potential in the anodes of the tubes of the pair are able to use the potential of the control grid of the other tube of the Couple to control. One on the grille of both tubes of the pair of a suitable one Pulse-generating means transmitted pulse causes the previously conductive tube of the couple becomes non-conductive. This has the consequence that the potential of your anode increases a value which, applied to the control grid of the previously non-conductive Tube, reduces the control potential of this tube and puts it in a conductive state. The tubes will stay in this working state until the next pulse hits the Control grid hits. It is a known fact that a pair of triggers act on a applied pulse reacts at high speed.

To connect the trigger pairs in a ring, use it this work step by step, and uin zii prevent all trigger pairs reacting to every single impulse, the control grids of the tubes become the trigger pairs provided with potentials which normally prevent the trigger pairs from to react to the supplied potentials, and this is achieved by the fact that these are connected to one another in a network, the arrangement of which is only in each case allows a pair of triggers to respond to an applied pulse. The network or preparatory connections, which have a suitable resistance from the Anodes of the tubes of one trigger pair to the control grids of the tubes of another Lead pair, allow the anode potentials of the first-mentioned pair of tubes change the potential of the control grid of the other trigger pair to the other Prepare a pair of triggers, apart from the fact that they also respond to the former Couple exercising a control in this way the mentioned other pair of triggers to be able to react to the next impulse brought to the ring to be able to.

As explained above, the ring consists of ten tubes connected together to form trigger pairs in the following ways: o with 5, i with 6, 2 with 7, 3 with 8 and 4 with 9. The network of preparatory connections for this one Ring is illustrated in Fig. I. The arrows point to the tubes whose grids are being influenced. Line 70 represents the preparatory connection of the anode of tube o to the control grid of tube 6. Likewise, line 71 represents the connection of the anode of tube i to the control grid of tube 7; Line 72 represents the connection of the anode of tube 2 to the control grid of tube 8; Line 73 represents the connection of the anode of tube 3 to the control grid of tube 9; Line 74 represents the connection of the anode of the tube 4 .with the control grid of the tube o; Line 75 represents the connection of the anode of tube _q to the control grid of tube i; Line 76 represents the connection of the anode of tube 6 to the control grid of tube 2; Line 77 represents the connection of the anode of tube 7 to the control grid of tube 3; Line 78 represents the connection of the anode of tube 8 to the control grid of tube 4, and line 79 represents the connection of the anode of tube 9 to the control grid of tube 5. The arrangement of these preparatory connections between the tubes of different trigger pairs is chosen so that that when every five successive tubes are in the conductive state, only one of these conductive tubes has its control grid connected to the anode of another conductive tube and only one non-conductive tube paired with a conductive tube has its control grid connected to the anode of a non-conductive tube Has. These connections have the effect that the potential of the control grid of said one conductive tube will be less positive than the potential of the control grid in the other conductive tubes. They will also have the effect that the potential of the control grid of the non-conductive tube which is in trigger connection with said one conductive tube will be less negative than the other non-conductive tubes. Under these conditions, this single pair of triggers is prepared and put in a position to be able to react to the impulses supplied, so that it will change its working state when the next impulse hits the ring. The above connections are illustrated in FIG The anode of the non-conductive tube 9 connects. With the help of these connections, the trigger pair, which contains the tubes o and 5, is prepared to react to an input pulse.

When the pair of triggers with tubes o and 5 is in its working state changes in response to an input pulse, tube 5 goes into conductive and tube o in non-conductive state. Be similar to the type given above effect these tubes in their changed state with the help of lines 75 and 7o, that the trigger pair with the tubes i and 6 for a reaction to the next, on all tubes transmitted pulse is prepared. This process of successive following preparation of the trigger pairs resulting from the change in the mode of operation other trigger pairs results, it enables the trigger pairs of the ring one after the other in endless, step-by-step succession, their working method in response to impulses supplied change.

When any number of pulses have been brought to the ring, the group of tubes that is in a conductive state becomes the value of the Total number of pulses correspond to the ring since it was in its zero position has been brought, have operated. This group of tubes can, if desired, can be used to control other means.

Due to the special combination of trigger connections and preparation network connections, that can come into use; the potential in the control grids of the conductive Tubes of the unprepared trigger pairs are made sufficiently positive so that none of these roles are significantly influenced by the negative input pulses will; Furthermore, the negative potential in the control grid of the non-conductive Tubing the unprepared trigger pairs so far above the electron flow cut-off point that the non-conductive tubes are increased by the potential changes of the anodes of the conductive tubes to which they are in trigger connection are not essential to be influenced. These two circumstances contribute to the stability of the ring Incorrect operation at.

Besides the fact that the combination of trigger connections and Preparatory network connections ensure a ring with high stability they still show that a ring arises that reacts to impulses supplied at great speed reacts, because with the help of the preparatory work the positive Potential in the control grid of the conductive tube of the prepared pair up to one Point can be lowered, which is sufficient to put the tube in a position that this reacts to the input pulses and can cause a triggering process. At the same time the negative grid potential can also be in the non-conductive tube of the prepared trigger pair are reduced so far that a slight increase in potential of the Cathode of the previous tube of the pair when the input pulse is applied on this tube a reduction in the negative grid potential of the non-conductive Tube causes and (reads the onset of the conductive state in it. This conductive state initially causes the control grid with the help of the trigger connection the other tube becomes more negative and supports the input pulse, the control grid of the pair's earlier conductive tube to the electron current cut-off point. read enables the pair of triggers to change its working state quickly. The preparatory action therefore alleviates the prepared trigger pair to the extent that this is of a state high stability goes into a state in which it is on the negative input pulses responded very quickly.

If the ring is a row of digits of an adder for multi-digit Forms amounts, suitable transfer mechanisms can be used between the individual rows of digits be set up, which have the task of each time a ring of a particular Job row has completed a work cycle, posting a one in to arrange your ring in the next higher row. Circuits The power circuit diagram for the ring chosen to explain the invention is shown in FIG. Of the innovative ring consists of ten 1 S 5 miniature vacuum tubes with battery operation. the The use of type 1 S5 tubes in the formation of the ring allows manufacture a stable, high-speed, battery-powered one Ring. However, this type of tube is not the only type that can be used in the ring consider, since in cases where battery operation is not important, every vacuum tube with a sharply defined electron current cut-off point, low direct current anode resistance (when the grid is under a potential of zero) and, if high operating speed is desired, with low inter-electrode capacitance for use in the ring suitable is.

When using the i S5 tube type, the anode of the diode part of the tube, if desired, directly to the control grid of the pentode part of the Tube to be connected. In the present circuit diagram, however, the Diode anode and its connection to the control grid are omitted as this is neither for the ring to work properly, it is still necessary to understand the ring are.

The individual potentials that are listed are related stated on earth. There is by no means the intention to focus the invention on the particular To limit potentials or the values given for resistance and capacitance, since the potentials have only been selected from the point of view for the presentation indicate suitable potentials and the capacitance and resistance for the circuit elements values given correspond relatively to the selected potentials. It is clear that other types of tubes can be used. You can also use other potentials and in this case adjust the circuit elements accordingly. The cathodes of the Type 1 S 5 tubes are heated directly. Your connections with a source for a heating potential of 1.4 volts are shown in the diagram in the usual way.

The anodes of the tubes draw potential from the pole 8o (FIG. 2), which is provided with a positive potential of 125 volts and is connected to an anode potential supply conductor 81. The anode of each tube is connected to the supply conductor 81 through a resistor of 50,000 ohms. The connection for the anode 82 of the tube o can serve as a pattern. It leads from point 83 in supply conductor 81 via resistor 84 and point 85 to the anode.

The screen grids of the tubes are having a positive potential of 67.5 Volt supplied from pole 86, to which a conductor 87 is connected. Each The screen grid is in direct contact with this conductor; the connections for the screen grids of tubes 5, 6, 7, 8 and 9, however, contain switches 88, 89, 9o, 91 and 92, which can be temporarily opened in a suitable manner, to remove the potential from these screen grids. This has the consequence that these tubes in non-conductive state and the 1 tubes o, 1, 2, 3 and 4 in conductive Override state, d. H. the ring is brought into the starting position.

The cathodes and brake grids of the tubes are directly connected to the Earth in connection.

The control grids of the tubes come with a source of negative Potential, furthermore with an input impulse conductor and with the help of the trigger connections and the preparatory network connections connected to the anodes of other tubes.

The connections of the control grid of each i tube with the negative one Potential sources are similar and are derived from the connection for the control grid 93 the tube o understandable. This stands above resistor 94 of 1 megohfn with point 95 in the negative potential supply conductor 96, which starts from i pole 97, to what negative potential of 135 volts is applied. These Connections supply the control grid with a negative control potential.

The connections between the control grids of each tube and the input pulse conductor are also similar. For them, too, a clear picture results from the connection for the control grid 93 of the tube o. Grid 93 is electrostatically coupled via point ioi and capacitor log of 5 micro-microfarads to point 103 in input pulse conductor 104, which is connected to pole 105 by a suitable pulse-generating means is supplied with negative potential pulses. These impulses represent information and cause the ring to work step-by-step. These connections enable each pulse to be transmitted to all tubes of the ring and also cause a change in the working state to occur in a prepared pair of triggers.

As mentioned earlier, the tubes of the ring are connected to form trigger pairs in which the control grid of each individual tube communicates with the anode of the other tube in the pair. The connections serve as a pattern for the connection between the tubes of different pairs, finit the help of which the tubes o and 5 are functionally coupled to form a trigger pair. They run as follows: From the control grid 93 of the tube o leads a part of the trigger connection on the points ioi and 1o6, resistor 107 1o8 log of 870 000 ohms, the parallel thereto capacitor of 2o micro-microfarads, and from there continue on the points iio and conductor iii to point 112 to which the anode 113 of the tube 5 is connected. The other part of the trigger connection between these tubes leading from the control grid 114 of the tube 5 via point 115, conductor 116, point 117, resistor 118 of 870 thousand ohms, parallel thereto capacitor iig of 2oMikro microfarad, and from there further over the points 120 and 121 and conductor 122 to point 85 to which the anode 82 of tube o is connected. It is these connections between the anodes and the control grids of the tubes o and 5 which are represented by the line 61 in FIG. They allow the changes in potential in the anodes of the tubes to be transmitted to the control grids in order to control the operation of the tubes as a pair of triggers. Similar connections connect the tubes i and 6, 2 and 7, 3 and 8 as well as 4 and g zii trigger pairs. The control grids are also equipped with finite preparatory connections which lead from the control grids of the tubes of one trigger pair to the anodes of the tubes of another trigger pair. The preparatory connections for (read the control grid 93 of the tube o, which is strongly lined in Fig. 2, corresponds to the line 74 in Fig. I. It goes from point 128 (Fig. 2) to which the anode 129 of the tube 4 is connected, and continues via conductor 130, points 131 and 132, conductor 133 and resistor 134 of 2 megohms to point ioi, to which the control grid 93 is connected of tube o to control grid 13g of tube 6; from anode 113 of tube 5 to control grid 14o of tube i; from anode 141 of tube Z to control grid 142 of tube 7; from anode 143 of tube 6 to control grid 144 of tube 2; from anode 145 of tube 2 to control grid 146 of tube 8; from anode 147 of tube 7 'to control grid 148 of tube 3; from anode 149 of tube 3 to control grid 150 of tube g; from anode 151 of tube 8 to control grid 152 of tube 4 and from anode 153 of tube g to control grid 114 of Tube 5.

The arrangement of the preparatory connections is such that at any stage of the operation in the ring only one pair of triggers is prepared, namely that the control grid of their conductive tube with the anode of the conductive tube of another pair and the control grid of their non-conductive tube with the anode communicates with a non-conductive tube of another pair. When the tubes o, 1, 2, 3, and 4 are conductive, as shown in Fig. 2, the control grid 93 of the tube o is in communication with the anode 129 of the tube 4 and the control grid 114 with the anode of the tubeg. As a result, the control grid 93 of the tube o becomes less positive than the control grids of the other conductive tubes, and furthermore the control grid 114 of the tube 5 becomes less negative than the control grids of the other non-conductive tubes. This causes the preparatory action by which this pair of triggers is enabled to react to a negative potential impulse applied to the ring. If the trigger pair with tubes o and 5 reacts to an impulse, tubes 1, 2, 3, 4 and 5 will be in a conductive state and the trigger pair with tubes Z and 6 will be prepared. In this way, each pair of triggers that reacts to a pulse causes another pair of triggers to be prepared. This results in the ring being stepped in response to input pulses. The embodiment of the invention shows that the input pulses are applied to the control grids of the tubes; however, it is in no way intended to limit the invention to this arrangement, since the input pulses can also be applied to one of the other gratings of a multigrid tube to cause the tubes of the ring to operate. Mode of operation The ring is prepared for working by applying the required potentials to poles 8o, 86 and 97 and using switches 88, 89, go, g1 in the circuits for the screen grids of tubes 5, 6, 7, 8 and g and 92 are opened briefly. The removal of this screen grid potential will cause these tubes to be in a non-conductive state. With the help of the trigger connections, these will put tubes o, 1, 2, 3 and 4 into a conductive state. This is the position of the ring, which has been chosen arbitrarily as the zero or starting position. The ring can now be put into operation by negative potential impulses.

As explained earlier in this specification, the anode stands each individual tube via its own resistor, such as 84 (Fig. 2), with a potential source in connection so that the conduction of the tube causes a drop in the potential of its anode causes. Of all those in charge at this stage of the work process Tubes becomes the tube o, whose control grid 93 is connected by a preparatory connection communicating with the anode 120 of the conductive tube .4, the only conductive one Be a tube whose control grid is connected to an anode by a preparatory connection is connected, the potential of which is reduced by the conductive state in the tube has been. The reason for this is that the control grid 93 will be less positive than the control grids of the other conductive tubes, since these grids are made by preparatory connections are connected to anodes whose potential is not determined by the conductive state of the zii tubes belonging to them is reduced.

In similar verses, among the non-conductive tubes, tube 5, the control grid 114 of which is connected by a preparatory connection to the anode 1,53 of the non-conductive tube o, will be the only non-conductive tube whose control grid is finitely connected to an anode by a preparatory connection whose potential has not been reduced by a conductive state. The result of this is that the control grid 114 will be less negative than the control grid of the other non-conductive tubes, since these grids are connected by preparatory connections to finite anodes, the potential of which has been reduced by the conductive state of the tubes belonging to them. Either of the two processes, namely reduction of the positive potential in the control grid of the conductive tube o or reduction of the negative potential in the control grid of the non-conductive tube 5 of the pair, would in itself cause the trigger pair with these tubes to be prepared for reaction to negative potential pulses . If, however, both preparatory processes are used at the same time, the preparatory effect increases and a ring is created that works extremely stable at top speed.

If the trigger pairs are prepared in such a way that the anode potential a tube of another pair is used to control the potential of the control grid of the conductive tube of the prepared pair less positive and (read anode potential the other tube of the other pair is used to control the potential of the control grid to make the non-conductive tube of the prepared pair less negative so the result is a ring with high stability, namely because on the one hand the potentials of the control grids of the conductive tubes of the unprepared trigger pairs can be made sufficiently positive and in this way the input pulses have no significant influence on the conductivity of these tubes. on the other hand can at the same time the negative potentials in the control grid of the non-conductive Tubing the unprepared trigger pairs in such a high degree over that for a lockout of the electron current necessary potential can be increased that every possible Change that is reflected in the potential of the anodes that these control grids use could be in trigger connection, does not have a significant effect on the Will exert non-conductivity of the non-conductive tubes. Either of these two processes has the tendency to (by the input impulses possibly caused incorrect operation to prevent. If both are present in the ring at the same time, secure them in double measure against incorrect operation.

When a negative potential pulse is applied to pole 105 and thus to conductor 104 with the aid of a suitable pulse generating means to effect a step in the operation of the ring, this pulse is electrostatically coupled by capacitors such as Zog, through which the control grid is electrostatically coupled to conductor Zoo are applied to the control grids of all tubes. The pulse will not change the non-conductive state in the tubes 5, 6, 7, 8 and 9, which are already provided with potential up to the cut-off point. The pulse will cause the control grids of tubes o, Z, 2, 3 and 4 to become less positive. As a result, the conductivity of these tubes is reduced by various amounts and the potential of their anodes increases accordingly. The pulse size was chosen so that the pulse, while it can reduce the conductivity in the conductive tubes uni a slight amount, is not able to overcome the positive potential in the control grids of the tubes Z, 2, 3 and 4 and they put in a non-conductive state. The only tube that can be significantly influenced by the pulse is tube o, the control grid of which had been made less positive as a result of the preparation process. Accordingly, if the pulse is applied to the control grid 93, the tube o will be affected to a greater extent than the other tubes and the potential of its anode 82 will rise to a higher positive value than the value which the anode of one of the others was previously conducting Has tubes. The potential increase in the anodes of tubes o, r, 2, 3 and 4 is transmitted to the control grids of tubes 5, 6, 7, 8 and 9, respectively, with the help of the trigger connections, and the potential increase in the anode of tube o is the only one be sufficiently large to put a trigger-connected non-conductive tube, namely the tube 5 in the conductive state. Therefore, the prepared pair of triggers with tubes o and 5 will be the only one that reacts to the impulse.

It will be remembered that the control grid is non-conductive Tubes are provided with a negative potential beyond the blocking point and that the preparatory connection the negative potential in the control grid of the tube 5 of the prepared. Couple has reduced almost to the cut-off point. This fact too is used to control the optional work of a pair of triggers, since of all Trigger pairs only in the prepared trigger pair the potential of the control grid its non-conductive tube is reduced to a value that is due to the increase in the anode potential in the tube belonging to it can be overcome in order to change the mode of operation of the couple.

The work of the pair of triggers will happen very quickly since the preparatory process the positive potential in the control grid 93 of the conductive Tube o has reduced, which enables the input pulse to initiate a trigger process, and since this also the control potential in the control grid 114 of the non-conductive tube 5 has reduced, which in turn increases the A-diode potential in the tube o enabled, the tube 5 rapidly in the conductive state zii offset. As soon as the tube 5 becomes conductive, it becomes with the aid of the trigger connection between its anode 113 and the control grid 93 of the tube o be able to cause the potential drop of their anode to the control grid 93 of the tube o is applied to the negative input potential impulse to iinterstützcii what has the consequence that the tube accelerates o to completely block the flow of electrons is driven.

This enables the combination of trigger connections and preparatory connections, <let a ring come about, which is capable is to react quickly to applied input pulses, and that this of pulses can be operated at a very high frequency.

When the trigger pair with tubes o and 5 in response to the first Impulse has changed its working state, it will remain in this position and <read pair of triggers with tubes r and 6 prepare for the next one to go into action on the impulse applied to the ring. If the trigger pairs start with tubes z and 6, 2 and 7, 3 and 8, and 4 and 9 in response to input pulses have worked, the trigger pair with the tubes o and g is prepared again, so that this pair of triggers its working state on receipt of the sixth pulse will change and the tube 5 again in non-conductive and the tube o in conductive State is brought. Similarly, further impulses become another step cause the trigger pairs to work step by step, which are determined by their respective Working method grant a display of the information, which of the total number of received Impulses.

The invention has been described in connection with a ring, which represents a series of data based on the decimal number system lies. It will be understood, however, that the ring will contain any number of pairs of tubes can and is not limited to the use of ten tubes that the ring further different impulses can be made to work to other specifications as numbers, and that the ring was eventually used as a switching ring can be used in order to transfer potentials to other means in order to improve their working methods to control.

Claims (1)

PATENT CLAIM: Device for counting electrical impulses with a A plurality of electron tubes and starting means connected as trigger pairs for Initiate conduction of one tube of each pair, with the trigger pairs one after the other in an endless chain in response to successive impulses negative polarity, which are shared on control electrodes in the tubes via individual Capacitors are applied to change their conductive state, characterized by such connections between the anode of each tube and a control electrode one tube of the pair of triggers that follows next in the chain that only a conductive tube connects its anode with a control electrode of the conductive tube's subsequent pair has connected what causes the potential of this last The control electrode is such that it is applied to the cut-off point upon receipt of the next pulse is fed back.