DE1237636B - Electronic selection circuit - Google Patents

Description

Electronic selection circuit Addendum to the additional patent: 1 215 777 The electronic selection circuit described in the additional patent 1215 777 is used to solve the problem of designating the first free device in a defined order by supplying a potential from a plurality of devices, any of which can be occupied , which differs from the other equipment supplied potentials by its height. The selection circuit can thus take the place of known voters. Their most important advantage is the fact that the same time is always required for any dialing process, regardless of which position in the order of the devices the device finally designated by the dialing process occupies.

This electronic selection circuit includes one of the number on it connected facilities corresponding number of switching stages. Every facility supplies the level assigned to it with a potential, the level of which corresponds to the current occupancy the facility. According to the two possible states, namely free and occupied state, these potentials can therefore be assigned two values, namely as free and occupancy potential. As in the individual stages and in cooperation of the stages only potential differences are effective and are evaluated no restrictive conditions with regard to the absolute values of these potentials. These absolute values can thus be used jointly for all levels in accordance with the outer Conditions are specified under which the selection circuit has to work. The selection circuit leads to the designation of the device determined by a dialing process this institution has a potential for designation, which in its height differs from all other facilities supplied, neutral potential deviates.

Each switching stage has a test input to which the associated device transmits the potential indicating its current occupancy status, and one Designation output, which you can use to send your associated facility the supplies the potential used to designate them. In addition, each switching step has to have a coupling input and a coupling output, with the coupling input supplied potential the own switching stage can be influenced while it by means of the potential emitted via the coupling output is able to respond to others To influence switching stages. According to the two values that the Accept the test input supplied and the potential given by the designation output can, namely free and occupied potential or designation potential and neutral Potential, the potentials of the coupling input and the coupling output can also be used take two values each.

This switching stage is according to claim 2 of the additional patent mentioned above characterized by their mode of action as follows: The potential of the designation output only then takes a certain (designation potential) of the two values (designation potential, neutral potential) if the input to the test input and the coupling input Potentials have certain values (free potential, release potential); when occurring of the specific potential value (designation potential) at the designation output the potential occurring at the coupling output the complementary value (blocking potential) of the potential supplied to the coupling input (release potential); the potential the coupling output then assumes approximately the value of the potential of the coupling input, when the potential of the coupling input indicates the occurrence of the specific potential value (Designation potential) at the designation-preventing value (blocking potential) LIS L 'CI owns. As already mentioned, select circuits are daisy-chained usually formed by the same switching steps, while except for the basic function of designating a single free facility at the same time the desired defined designation sequence is also obtained. If those Name order of case should be changed on a case-by-case basis, to z. B. as possible the same occupancy frequency for all of the selection circuit To achieve operated facilities is, as already proposed, the derailleur first to close to a ring circuit. To with such a ring circuit then determine the zero point from which the respective designation sequence is to be expected, it has already been suggested that each switching stage be provided with an additional one Equip entrance and additional funds and this additional entrance of those Switching stage a specific, in particular one corresponding to the release potential Supply potential, depending on the arrangement of the chosen Switching stage either the first or, if the arrangement is different, the last in the sequence of names should be. Above all, this measure permits, in contrast to one likewise already proposed arrangement working with contacts electronic means of fixing of the zero point and thus to achieve a high working speed.

The means for supplying the means used to determine the zero point in each case in a single switching stage of the selection circuit consist essentially of a number of memories of any type corresponding to the number of switching stages, one of which is in a certain state, that of the other Memory deviates. This one memory feeds the potential that defines the zero point to the switching stage assigned to it and records the position at which the zero point was in the last marking process or at which position it should be in the subsequent marking process. The arrangement and operation of this memory made as a function of the scheme, the location of the datum from case to case to be changed according to different possibilities. A particularly expedient scheme of this type is to change the position of the zero point so that that switching stage which, in the course of a labeling process, has supplied labeling potential to the device assigned to it, is made the last in the labeling sequence for the following labeling process.

The object of the present invention is now to provide a switching stage to create a selector circuit that is interconnected with the same switching stages results in which the zero point by electronic means according to the above Scheme is changed. This switching stage has the properties mentioned at the beginning and has additional means for the electronic determination of the zero point, an additional input for supplying the zero-defining potential and a memory which is used to store the zero point position and which is in the one its two stable positions emits the potential that defines the zero point and with its exit to the additional entrance and with its entrance to a second one Coupling input is switched. According to the invention, this switching stage has the additional Features that when the specific potential occurs (designation potential) at the designation output to the supply of the potential that defines the zero point The additional input used is supplied with the potential that defines the zero point and the delivery of a upon transition of the certain potential (designation potential) of the designation output to the other value (neutral potential) at a second Coupling output occurring potential is prepared for tilting a store suitable for the position that emits the potential used to establish the zero point is, and that before the end of the delivery of the specific potential (designation potential) at the designation output the memory possibly located in that position, in which it emits the potential that is used to establish the zero point, in the other Location is transferred.

A selection circuit made up of switching stages identified in this way retains its original basic function unchanged; the change of the zero point is done in such a way that the switching step that occurs in the course of a labeling process emits labeling potential, during this labeling potential release makes itself the first switching step in the designation sequence, regardless of at which point the zero point was at the beginning of this labeling process. To This switching stage would then end the designation potential release the following switching step to the first in the sequence of names by pressing the for Storage of the zero position serving memory of this following switching stage in that position tilts in which it emits the potential that defines the zero point.

The additional features mentioned above can, as already mentioned, already proposed switching stages of various kinds by adding additional Funds are awarded without the original switching steps arrangement and have to be changed functionally. However, it can also be used without a larger one Difficulty specifying new switching steps, which also dim additional features exhibit. To implement the switching steps to be added to already proposed Means like for the realization of new switching steps are in the first place, like in The additional patent mentioned at the outset, derived from the theoretical Handling of switching tasks known "basic logic components" such as "and" circuit, "Or" circuit etc. are available.

As a memory to be provided in the switching stages with two stable layers A wide variety of flip-flops can be used, although higher for reasons Response speed and low control power requirement electronic multivibrators the preference is to be given.

In the following, a switching stage according to the invention is described with reference to the figures as an exemplary embodiment, which is based on a switching stage as it has already been proposed. In this exemplary embodiment, the additional features are obtained by additional means. In detail, FIG. 1 shows a switching stage according to the invention in a partly symbolic representation and FIG. 2 shows an extension of the arrangement according to FIG . 1, also in partly symbolic representation.

Since the previously proposed switching stage, which is assumed, remains completely unaffected in its original mode of operation by the additional means and its arrangement in itself has no effect on the operation of the switching stage, it is sufficient to use them without going into details of their arrangement on the To define potential relationships at their inputs and outputs. - For the sake of simplicity, for this definition as for di - c further description of the two values that can take each potential is referred to as "positive" and "negative" potential. These two designations always relate to an average value to be formed from the two values, which is mutually dependent on other potentials supplied to the switching stage, such as e.g. B. transistor biases, is to be selected; they are therefore to be regarded as relative values. As a borderline case, one of the two potential values can also disappear, which means that the relevant input or output then receives or emits no defined potential at all. However, since this borderline case only represents a simplification in terms of arrangement and can always be traced back to the case of a suitably defined potential, it is no exception.

In the case of the original switching stage St contained in the exemplary embodiments shown, the neutral potential of the designation output z and * the potential which may be supplied to the additional input n and determine the zero point are negative; accordingly, the designation potential of the designation output z is positive, while the potential supplied to the additional input n disappears (or assumes a positive value) if the switching stage is not the first in the designation sequence. The potential relationships at the test input p, coupling input kl and coupling output k2 can be disregarded since they have no influence on the additional means described below. With regard to the bistable memory already mentioned, it is assumed that its output v emits positive potential in the idle state and that the memory tilts into the working position by supplying a positive potential or pulse to its input k 3 , in which its input v emits negative potential. The storage tank Sp is tilted back into the rest position by supplying a certain potential to the input r.

F i g. 1 shows an embodiment of a switching stage, which is composed of an already proposed switching stage St with test input p, first coupling input kl, first coupling output k2, designation outputz and additional inputs, a bistable memory Sp with inputs k3 and r and outputv, an inverter and other additional means . The additional input n of the switching stage St is via a guide Eq. connected to the output v of the memory Sp and the designation output z to the input of the inverter I. The output of the inverter I is connected to the additional input n by means of a directional conductor G2; In addition, it is connected via a directional conductor G 3 on the one hand via a resistor R 1 to the positive pole of a voltage source U1 and on the other hand via a capacitor C 1 to a second coupling output k4.

When the switching stage is idle, the designation output z carries the negative neutral potential which is fed to the input of the inverter 1 and at the output of which results in a positive potential which is approximately equal to the positive potential supplied by the voltage source U1. The directional conductor G3 thus lies between two points of approximately the same potential, remains practically ineffective and the capacitor C 1 is charged to this positive potential.

If the positive designation potential occurs at the designation output z of the switching stage St due to the supply of free potential to the test input p and the release potential to the coupling input kl, then the output of the inverter I receives a negative potential. Simultaneously with the occurrence of the designation potential, as will be explained in detail later, a potential appears at input r through which the memory Sp, which may be in the working position, is tilted into the rest position. The negative potential of the inverter output corresponds to that of the original switching stage St for fixing of the zero point and has a double effect. On the one hand, it lowers the potential of the additional input n to this negative value via the permeable directional conductor G2. Thus, the switching stage generated even the laying down of the zero point serving potential and allowed to n take effect at the entrance, regardless of whether the reference output z before the occurrence of the term potential of the memory Sp the input n such a negative potential due to its Working position supplied or not supplied due to its rest position. In the context of a selection circuit made up of such switching stages, this means that only a single switching stage can ever emit designation potential, that only in this switching stage alone the additional input n receives the negative potential defining the zero point. In this way, the labeling sequence is clearly defined in such a way that the switching stage emitting labeling potential makes itself the first in the labeling sequence. On the other hand, the directional conductor G3 becomes permeable due to the negative potential of the inverter output, whereby the potential of the connection point of resistor R 1 and directional conductor G 3 , originally held at a positive value by the voltage source U1, is reduced to the negative value of the potential of the under the influence of the resistor R 1 Inverter output is lowered. The capacitor C 1 is thus also discharged by this potential difference, as a result of which a negative pulse (which remains ineffective) occurs at the second coupling output k4. In the context of a selection circuit made up of such switching stages, this capacitor discharge represents the preparation for the potential output required for tilting a storage tank.

If, after the end of the labeling process, the positive labeling potential of the labeling output z changes back into the negative neutral potential, then the output potential of the inverter I assumes the positive value again. This means that the negative potential that defines the zero point disappears at the additional input n, as a result of which this switching stage is no longer the first in the designation sequence in the context of a selection circuit. In addition, the previously existing lowering of the potential of the connection point of resistor RI and directional conductor G3 is canceled again. This point again assumes the positive potential determined by the voltage source U1, as a result of which the capacitor C 1 is charged and a positive pulse occurs at the second coupling output k4 which is suitable for tilting a memory Sp into the working position. In the context of a selection circuit, this means that the memory Sp of the following switching stage is tilted into the working position, the input n of this switching stage supplies negative potential and thus makes this switching stage the first in the sequence of names.

The task of the directional conductor Gl is to prevent disruptive interactions between the possibly negative output potential of the inverter I and the output potential of the memory Sp, which is always positive at this point in time; In a similar way, the directional conductor G2 prevents the output potential of the inverter I, which is positive in the idle state, from influencing the possibly negative output potential of the memory Sp and thus the determination of the zero point. The directional conductor G3 in connection with the resistor R 1 and the voltage source U 1 is in principle not required; however, the fact that in the electronic flip-flop circuits to be preferably used as memory Sp at the control input negative pulses can occur as a result of the reaction of the flip-flop circuit, this sub-arrangement is generally necessary. The directional conductor G3 prevents such a negative pulse from reaching the additional input n of the original switching stage St via the capacitor Cl and the directional conductor G2 and thus influencing the definition of the zero point.

As can be seen without further ado, forms the output potential of the inverter I always the complementary value of the potential of the designation output z of the original Switching stage St. This means that, if necessary, an additional designation output can be connected to the inverter output be switched on, its potential for solving control tasks stands.

In the arrangement mentioned earlier, which can be used as switching stage St, the designation of the device assigned to the switching stage can be made by retroactive effect on the potential supplied by this device to the test input p of the switching stage. This property remains unchanged even if this already proposed switching stage is expanded in the manner described above.

The interconnection of the above with reference to FIG. 1 described switching stage with similar switching stages to a selection circuit takes place in such a way that a ring circuit is formed from all switching stages, in which the first and second coupling input kl and k3 of each switching stage to the first and second coupling output k 2 and k4 of the respective preceding Switching stage is switched.

As mentioned, the memory Sp the switching stage of a selection circuit when the designation potential occurs be tilted into the rest position at the designation output z of a switching stage, since of at this point in time the designation potential of this switching stage via the inverter takes over the determination of the zero point. This gives the possibility of the Tilting back of the memory in the working position due to the designation potential to have it done by yourself. The designation outputs z or the outputs are for this purpose the inverter I of all switching stages via a mutual decoupling ensuring To summarize mixing gate, the output of a possibly reversing polarity Amplifier is led to the reset inputs r of all switching stages.

As can be readily seen from the general selector function, the characteristic property of the first switching stage of a ring circuit of such switching stages in the designation sequence is that their function is independent of the potential supplied to their coupling input kl or, in other words, that it is also at blocking potential at its coupling input k 1 is able to provide designation potential. This property is based on the supply of the potential that defines the zero point to its additional input n. This can now have the consequence that a switching stage which is remote from the zero point defined by the tilted memory emits designation potential as a result of a high response speed, so that it becomes the first in the designation sequence and then receives blocking potential from a switching stage which is closer to the memory that is not yet tilted in its rest position, but which responds more slowly, this switching stage likewise emitting designation potential and thus also making itself the first in the designation sequence. However, since the switching stage, which responds more quickly, can no longer be blocked by blocking potential, a breach of the basic selector function and thus a double assignment would be the result of inevitable manufacturing deviations.

The occurrence of such disturbances can be prevented in a simple manner that the delivery of the designation potential at the designation output z does not result in the occurrence of the zero point at the additional input n immediately but with a certain delay, since the zero point occurs up to the occurrence of the determining potential, the switching stage can still be blocked by blocking potential at the coupling input k 1 . Such delay devices are characterized by extremely low complexity, but in a number of cases delays are undesirable for various reasons.

F i g. 2 shows an extension of the switching stage according to FIG. 1, in which the possibility of the occurrence of the mentioned double assignments is excluded by a control circuit that works without delay. With the arrangement otherwise unchanged, a resistor R 2 is inserted between the designation output z of the original switching stage St and the input of the inverter I. The switching stage receives a third coupling input kl "which is connected to the input of the inverter I via a directional conductor G4 and to a third coupling output k2" via a directional conductor G5, which in turn is connected to the output of the inverter I via a directional conductor G6.

The third coupling input k 1 ' and the third coupling output k 2' each have either a negative blocking potential or this negative blocking potential disappears, which in terms of effect corresponds to a (positive) release potential.

If the designation output z of the original switching stage St has the positive designation potential, then the output potential of the inverter I is negative and occurs via the permeable directional conductor G 6 at the third coupling output k 2 'as blocking potential, while it is from the third coupling input kl' through the blocking directional conductor G5 is kept away. Another prerequisite for the occurrence of the negative potential at the inverter output is that there is a positive release potential at the third coupling input kl`. If, on the other hand, negative blocking potential is fed to the third coupling input kl ', a positive marking potential occurring at the marking output z is lowered to the negative value of the blocking potential of the third coupling input k l' under the influence of the resistor R2 and the then permeable directional conductor G4, whereby the output potential of the inverter maintains its positive value. This means that the inverter I is not able to supply the additional input n with the negative potential that defines the zero point, so that the switching stage is unable to make itself the first in the sequence of names. Furthermore, the negative blocking potential of the third coupling input kl 'also reaches the third coupling output k2' via the permeable directional conductor G 5 , whereby it is kept away from the output of the inverter I by the blocking directional conductor G 6 .

The interconnection of such switching stages according to FIG. 2 to a selection circuit takes place in such a way that, in addition to those in connection with F i g. 1 relating to the first and second coupling inputs and coupling outputs, the third coupling input kl 'of each switching stage is connected to the third coupling output k2' of the following switching stage in the sense of the sequence of names. In contrast to the wiring of the first and second coupling inputs and coupling outputs, via which the switching stages are interconnected to form a ring circuit, the switching stages are only combined into a chain circuit with regard to the third coupling inputs and coupling outputs.

The mode of operation of the on the basis of F i g. 2 shown expansion of the switching stage according to FIG. 1 in the context of a selection circuit constructed from such extended switching stages can be represented in such a way that of switching stages that compete in the aforementioned sense with regard to the designation potential output and especially with regard to the definition of the zero point, the switching stage which, due to manufacturing variance, has its own input fastest n supplies the negative potential defining the zero point and thus makes itself the first in the sequence of names, at the same time supplies its third coupling output k2 ' blocking potential, which thus reaches the previous switching stage and via this to all the preceding switching stages in the sense of the chain circuit formed by the directional conductor G 5 and in these prevents the inverter from emitting the negative output potential required for establishing the zero point.

Correspondingly, the same behavior results if, in contrast to the interconnection of the switching stages described above with regard to the third coupling inputs and outputs, the third coupling input kl 'of each switching stage is connected to the third coupling output k2' with the exception of a single one of the preceding switching stage in the sense of the sequence of names, with respect to these third coupling inputs and coupling outputs likewise only one chain circuit is formed. Regardless of the interconnection of the switching stages selected in each case with regard to this chain circuit, the third coupling output k2 ' remains unconnected in a single switching stage, at which the negative output potential of the inverter 1 of the switching stage emitting the marking potential occurs during each labeling process via the chain circuit from the directional conductors G5. This negative potential can be used indirectly or, if necessary, also directly to tilt the one accumulator Sp, which is in the working position, into the rest position, whereby in connection with the arrangement according to FIG. 1 mentioned mixer is superfluous.

Otherwise, those in connection with the arrangement according to FIG. 1 possible measures, such as connecting an additional designation output to the inverter output, unchanged also for the arrangement according to FIG. 2.

Switching stages of the type described above have a function of which arrangement is used as the original switching stage St in the Usually the property that the delivery of the designation potential only takes place as long as than free potential is supplied to the switching stage. In some cases, however, it is desirable the designation potential delivery over the time-limited for certain reasons Maintain free potential supply addition. To this property of the switching steps with as little additional effort as possible has already been proposed at least one of the two values (designation potential, neutral potential) of the Potential of the designation output or a potential corresponding to this In addition to supplying the test input with correct polarity with such an amplitude that the potential of the labeling output (labeling potential, neutral potential) and the potential of the coupling output (blocking potential, release potential) of changes the potential originally supplied to the test input (free potential, occupied potential) is independent. This measure can very generally in the case of those described above Switching stages can be used without further ado. It is included to reduce effort possible that the inverter provided in the arrangement already proposed simultaneously also the tasks of the provided in the embodiments described above Inverters takes over.

Claims (2)

Claims: 1. Switching stage which has a test input and a first coupling input for supplying potentials and a designation output and a first coupling output for supplying potentials, the supplied and output potentials of which can essentially assume two values and in which the output of a labeling potential takes place at the designation output only when free potential and release potential are supplied to the first coupling input and test input, according to claim 2 of additional patent 1215 777, in which separate means for electronically defining the zero point and an additional input for supplying the zero point defining potential are provided and the one for Storage of the zero point serving, in which one of its two stable positions is assigned the potential defining the zero point, the output of which is connected to the additional input serving to supply the zero point defining potential and its input a second coupling input is connected, d adu rch gekennzei chnet that when a certain potential (designation potential) occurs at the designation output (z) the additional input (n) serving for the supply of the zero-point-defining potential is supplied with the zero-point-defining potential and the output of a at the transition of the specific potential (designation potential) of the designation output (z) to the other value (neutral potential) at a second coupling output (k4) is prepared potential that is used to tilt a memory (Sp) into the potential used to determine the zero point dispensing position is suitable, and that before the end of the dispensing of the specific potential (designation potential) at the designation output (z) the memory (Sp), which may be in the position providing the potential serving to determine the zero point, is transferred to the other position. 2. Switching stage according to claim 1, characterized in that the potential occurring at the second coupling output (k4) is generated from the potential of the designation output (z) or a potential corresponding thereto. 3. switching circuit of claim 1 or 2, characterized in 'that the signal appearing at the second output coupler (K4) has potential Impulsfonn. 4. Switching stage according to claim 3, characterized in that the second coupling output (k4) is preceded by a capacitor (C1). 5. Switching stage according to claim 4, using a memory which, when tilting, has a reaction to the potential causing it to tilt, characterized in that between the capacitor (C 1) and the source which emits the potential causing the tilting, a directional conductor (G3) is inserted and the connection point of capacitor (C1) and directional conductor (G 3) is connected to a voltage source (U1) via a resistor (R 1) . 6. Switching stage according to one of the preceding claims, characterized in that the zero point-defining potential which is supplied to the additional input (s) when the specific potential (designation potential) occurs at the designation output (z), from the specific potential (designation potential) of the Designation output (z) or a potential corresponding to this is generated. 7. Switching stage according to claim 6, characterized in that the means used to supply the zero-defining potential to the additional input (s) are controllable. 8. Switching stage according to claim 7, characterized in that a respective active or passive control of the means which are used for supplying the zero point localizing potential serving third switching input (kl # provided or coupling output (k2), whose potentials two values (blocking potential, release potential) can assume that when blocking potential is supplied to the third coupling input (kl ') the additional input (n) is not supplied with a potential that defines the zero point and that blocking potential is supplied to the third coupling output (k2) and that when supplying the zero point festlegendem potential (k2 ') blocking potential is supplied to the additional input (s) to the third switching output. 9. switching stage according to one of the preceding claims, using a switching stage which serves for fixing the zero potential at the additional input and the certain potential (designation potential) have different polarity at the designation output, dad urch characterized in that an inverter (I) is inserted between the designation output (z) and the additional input (n). 10. Switching stage according to claim 9, characterized in that the memory (Sp) and the output of the inverter (I) a respective isolator (Gl, G2) is inserted between the additional input (s) and the output. 11. Switching stage according to claim 9 or 10, characterized in that the means (I, R 2) serving to generate the zero point fixing potential from the specific potential (designation potential) of the designation output (z) are controllable. 12. Switching stage according to claim 11, characterized in that the input of the inverter (I) via a resistor (R 2) to the designation output (z) and via a directional conductor (G4) to the third coupling input (k l ') and that the third coupling output (k2 ') is connected via a directional conductor (G5) to the third coupling input (k l') and via a directional conductor (G 6) to the output of the inverter (I). 13. Switching stage according to one of claims 9 to 12, characterized in that an additional designation output is connected to the output of the inverter (I). 14. Switching stage according to one of claims 1 to 6, characterized in that the occurrence of the zero point fixing potential at the additional input (s) is delayed compared to the occurrence of the specific potential (designation potential) at the designation output (z). 15. Selection circuit containing switching stages according to one of claims 1 to 7, characterized in that at each switching stage the first and the second coupling input (kl, k3) is connected to the first and the second coupling output (k2, k4) of the respective preceding switching stage . 16. Selection circuit according to claim 15, characterized in that a mixing gate is connected on the input side to the designation outputs (z) or the additional designation outputs of all switching stages and on the output side, optionally with the interposition of an amplifier, in all switching stages to inputs (r) of the memory (Sp) which are used to supply a potential to transfer the memory (Sp) into the position in which they do not emit the potential used to establish the zero point. 17. Selection circuit containing switching stages according to one of claims 8 to 14, characterized in that at each switching stage the first and second coupling input (kl, k3) to the first and second coupling output (k 2, k 4) of the respective preceding switching stage are switched and in each switching stage with a single exception the third coupling input (kl ') is connected to the third coupling output (k2 # of the respective preceding switching stage. 18. Selection circuit containing switching stages according to one of claims 8 to 14, characterized in that at of each switching stage the first and the second coupling input (k 1, k 3) are connected to the first and the second coupling output (k2, k4) of the respective preceding switching stage and for each switching stage, with a single exception, the third coupling input (kl ') is connected to the third coupling output (kT) of the respective following switching stage is switched 19. Selection circuit according to claim 17 or 18, characterized in that a Uschgatter is connected on the input side to the designation outputs (z) or the additional designation outputs of all switching stages and on the output side, if necessary with the interposition of an amplifier, in all switching stages to the inputs (r) of the memory (Sp), which is used to supply a potential for transferring the memory ( Sp) serve in the position in which they do not emit the potential used to establish the zero point. 20. Selection circuit according to claim 17 or 18, characterized in that on the third coupling output (k2 ') not connected to the third coupling input (kl') of another switching stage, optionally with the interposition of an amplifier, the inputs (r) of the in all switching stages Memories (Sp) are connected, which serve to supply a potential for transferring the memory (Sp) into the position in which they do not emit the potential used to establish the zero point.