DE1948377B2 - Binary signal processing circuit - with magnetic hysteresis cores each read by two consecutive pulses to avoid affecting adjacent cores - Google Patents

Abstract

The binary signal processing circuit consists of identical logic circuits having magnetic cores with rectangular hysteresis loops that pass from one remanence state to another when writing in or reading out. The read pulses are applied for periods that are sufficiently short for a core magnetisation in the appropriate remanence state not to reach saturation at first but only when a second smaller pulse following the main read pulse is applied to the core. This smaller pulse amplitude is not sufficient to cause changes in the magnetisation of adjacent cores.

Description

The invention relates to a circuit arrangement for processing binary variables consisting of similar There is logic link, each using a magnetic core with a rectangular Hysteresis loop are established, which when the

Linking condition during a write-in process _s j _n (j _e n one of its two remanence states and during the subsequent interrogation process is magnetized again by an interrogation pulse to the original other remanence state, whereby it emits a read signal, and such read signals when the linkage condition is met other such links should be able to contribute.

The logic elements that make up circuit arrangements for processing binary variables are often constructed using a magnetic core with a rectangular hysteresis loop, as they have a number of advantages, such as unlimited service life, high reliability, storage capacity, and integrating properties that are beneficial in the event of malfunctions Ausv / irker In known logic elements of this type, _{the magnetic core is magnetized in one of its two remanence states during the writing process either by coincidence of the variables to be} linked with a writing pulse, or such reversal of magnetization is prevented due to the opposing effect of the coincident pulses. A subsequent interrogation pulse magnetizes the core back to its original remanence state, if it has been remagnetized beforehand, and a read signal is then output. If the reading signals of logic elements operated in this way are to be fed to downstream cores as variables to be processed further, special measures must be taken to ensure a temporal coincidence of such reading signals with the other signals that also determine the writing process. In the event that write-in pulses are supplied to all cores from a central pulse source, this difficulty can be avoided according to a known solution (Steinbuch, Taschenbuch der Nachrichtenverarbeitung, Edition 1967, page 428) in that the write-in pulses are basically shorter than the shortest of the possible expected read pulses are made.

It has also already been proposed (DT-OS 19 47 615) for a circuit arrangement for processing binary variable in which the logic elements of the same type are NOR elements, the write-in pulses not to be supplied from a central point, but rather by means of the read signals of these logic elements Controlled modules of the same concept, whose read signals represent the write pulses and the the desired short one by reducing the number of turns of the reading and control windings accordingly Have duration. In the case of logic elements written in this way, the write-in pulses carry the write-in pulses for the logical connection with, which simplifies the wiring, because in such logic elements the write winding is identical to a control winding. aside from that This type of control has the advantage that not all of the cores that do not have them in the reverse direction influencing variable to be processed are supplied, are written, so that a total of one less energy is required for the central delivery of interrogation pulses, resulting in a saving of interrogation pulse amplifiers leads.

The invention now specifies a circuit arrangement in which, on the one hand, the Zeitlirhp Coincidence of the pulses involved in the writing of the individual logic elements ensured is, and also has the advantages of the mentioned proposed solution the use of modules for the decentralized generation of write-in pulses brings with it, can also have, but without the need for such additional modules will.

For this purpose, the circuit arrangement described at the outset is characterized according to the invention: that interrogation pulses are supplied with such a short duration that thereupon a magnetization in the saturation area corresponding remanence state is initially not reached, but by a the auxiliary pulse immediately following the interrogation pulse is set to such a small amplitude, that read pulses linked with this are not sufficient to remagnetize downstream cores.

As will be explained further below, the shortening made according to the invention has Interrogation pulses compared to known circuit arrangements in which the interrogation pulses the magnetic cores Magnetize to saturation, the advantage that the length of the out for further processing used the read pulse regardless of component tolerances, temperature or wiring length and on the number of downstream devices controlled by the read signal of a core Cores is. In this way, however, read signals can also be written in without further measures downstream cores and thus as a contributing variable to the linkage, without the coincidence with read signals from other cores which may move the core in the opposite direction of magnetization have to influence is in question.

As embodiments of the circuit arrangement according to the invention, an exclusive-or element, a bistable multivibrator, a frequency divider and a binary counter are specified.

In the following, the structure and mode of operation of exemplary embodiments of the invention Circuit arrangement explained in more detail with reference to 10 figures.

The F i g. 1 shows an example of a known logic element from which the inventive Circuit arrangement is assembled.

The F i g. 2 shows the symbolic representation for such a linkage, which is also used for representation of the individual embodiments is used.

The F i g. 3 shows the hysteresis loop of the cores used for the logic elements.

The F i g. 4 to 7 show exemplary embodiments of the invention Circuit arrangement for processing binary variables, namely FIG. 4 an exclusive OR element, the F i g. 5 a bistable multivibrator, the F i g. 6 a frequency divider and FIG. 7 a binary counter.

In the case of the FIG. 1, which is known per se, is a NOR element. It contains a magnetic core Λ / which is rectangular in shape Hysteresis loop should have, and that of a vertical, strongly drawn out Line is symbolized. This magnetic core (protrudes a series of windings through short that the Magnetic core symbolizing line under 45 ° intersecting lines are indicated. By inclination of this Strokes to the right or left will be different

Winding sense of the windings indicated. The lines intersecting the core horizontally indicate the supply lines of the individual windings.

The magnetic core M carries an interrogation winding η 1, an oppositely wound reading winding η 2 to which the diode D is connected, a write winding π 3, which is also wound in the opposite direction for the interrogation winding, and a number of logic windings π 4, the direction of which in turn is opposite to that of the write winding η 3 is. The number of turns of the read winding is chosen so that the read pulses emitted have at least the same amplitude as the write pulses. The NOR link comes about because the core can only be written in, and thus a read signal can only be output during the subsequent query, if none of the logic windings is supplied with a variable with the binary value "1". The diode blocks the circuit of the reading winding η 2 when writing and suppresses interference currents up to their threshold value, which are induced when variables are fed to the logic windings.

! n of FIG. 2 is the logic element according to FIG. t shown in simplified symbols. The magnetic core M is illustrated here again by a vertical, strongly drawn line. The upper end of this line is assigned the positive remanence state of the magnetic core + Br or the binary value "1" and the lower end is assigned the negative remanence state of the core - Br or the binary value "0". The core windings are shown here in the form of arrows. The query winding π 1, the writing winding η 3 and the windings π 4, to which the variables to be processed are supplied, i.e. all windings are supplied via the pulses that contribute to the remagnetization of the core, run in this representation in the direction of the line symbolizing the magnetic core. Depending on whether the impulses influencing the magnetic core through them cause magnetization in the direction of the remanence state + Br, the arrowhead is directed upwards or downwards. The arrow, which is intended to represent the reading winding, via which only pulses are emitted, points away from the core bar. Since the interrogation pulses are supplied from a central point and are constantly present, no feed lines are drawn in the arrow symbolizing the interrogation winding; this arrow is also filled in, which indicates the particularly large pulse amplitude of the interrogation pulses The center of the core bar marked can also be used to identify the position in time of the pulses supplied to the windings or emitted via them. So you can see. that the interrogation pulses and the read pulses linked to them on the one hand and the write pulses and the variables to be linked on the other hand occur during different time periods.

Based on the F i g. 3, which shows a hysteresis loop as the magnetic cores of the logic elements used to build the circuit arrangement according to the invention according to FIG. 1 and FIG. 2, the operating mode on which the circuit arrangement according to the invention is based is explained in more detail.If the magnetic core of a logic element of the circuit arrangement according to the invention has been written, it is in the positive remanence state + Br . In contrast to known arrangements, however, according to the rule according to the invention, the duration of the transfer pulse is so short that the remanence state -Br corresponding to magnetization in the saturation range is initially not reached. I. E. so that the interrogation pulse has already ended before the steep left part of the hysteresis

lü loop is run through. It then arises, for example, in FIG. 3, a remanence state Bx , although the interrogation pulse has such a large amplitude that the magnetic core is heavily overdriven. The magnetic core then acts primarily like a transformer, so that the read pulses linked to the interrogation pulses are independent of the core properties and the output load of the core and have essentially the same duration as the ablation pulses. It can

ίο therefore read pulses supplied by different cores can be linked to one another without further ado by influencing another core, without that special measures would have to be taken to ensure their temporal coincidence.

As the F i g. 3 shows, after interrogation with shortened interrogation pulses, a magnetic core is in an undefined remanence state Bx. The next interrogation pulse would therefore deliver a second read signal, albeit of a lower amplitude. So that the cores are in a clear remanence state after each query, an auxiliary pulse is therefore fed to the magnetic core immediately after the query pulse occurs, which controls the magnetic core beyond the steep part of the hysteresis loop. After the auxiliary pulse has subsided, the negative remanence state - Br is established in any case. On the other hand, the amplitude of this auxiliary pulse is kept so small that the read pulses associated with this auxiliary pulse are not sufficient to remagnetize downstream magnetic cores, i.e. they cannot falsely simulate the presence of a useful pulse.

As an exemplary embodiment of the circuit arrangement according to the invention, an exclusive OR circuit is first described with reference to FIG. The circuit arrangement according to FIG. 4 contains two logic elements with the magnetic cores £ 1 and E 2, which are queried at the same time a The logic windings π 14 and η 24 of these magnetic cores are connected in parallel and thus both contribute to the delivery of result variables. The input variable e 1 affects the magnetic core £ I a π Einschreibwicklung 13 ir Einschreibrichtung and the magnetic core E2 via one logic π winding 24 which is connected to the winding 13 of the core π EX connected in series opposite to the A direction of writing. The input variable e2 , however, influences the magnetic core £ 1 via the logic winding π 14 against the writing direction and the magnetic core £ 2 via the writing winding π 23 in the writing direction. Each of the two magnetic cores £ 1 and £ 2 is thus the direction of an input variable in Enrollment and ent from the other input variables influenced each of Einschreibrichtung If Diesi input variables, as explained above question by Ab generated nen Magnetker not shown by others, do not need further action

Men be provided in order to ensure their temporal coincidence when acting on the two magnetic cores. The circuit arrangement according to FIG. 4 only supplies an output signal if only one and only one of the input variables takes the binary value "1". Only in these two cases is the writing of one of the two cores E 1 and E 2 by one of the two input variables e 1 and e2 not prevented due to the blocking effect of the respective other input variable. One of the two cores then sends a read signal to the common output a. If, on the other hand, both input variables assume the binary value "1", writing is prevented due to the blocking effect of one input variable, or if both input variables assume the binary value "0", neither of the two cores is written due to the lack of a write excitation. In both of the last-mentioned cases, there is no reversal of magnetization of the cores during the query and therefore no read pulse is emitted.

In FIG. 5 describes an embodiment of the circuit arrangement according to the invention in the form of a bistable multivibrator with dynamic input, that is, such a multivibrator that is switched from one stable state to the other stable state in response to each input signal at one and the same input. The circuit arrangement according to FIG. 5 contains an exclusive OR circuit with the magnetic cores and A, as shown in FIG. which is followed by a further link with the magnetic core R. The magnetic cores E and A of the circuit arrangement are interrogated for a first interrogation cycle phase, while the magnetic core R is interrogated for a second interrogation cycle phase, which is indicated by the different positions of the arrows symbolizing the interrogation windings for the magnetic cores E and A on the one hand and for the magnetic core R on the other hand. The read signals supplied by the magnetic cores E and A via the read windings π 12 and η 22 influence the magnetic core R via its write windings nR3 in the write direction. The read signal of the core R emitted via the read winding nR2 represents one input variable of the exclusive OR gate formed by the cores E and A , so it influences the magnetic core A via the write- in winding π 23 in the write direction and the magnetic core £ via the winding π 14 in blocking. The input variable e1 which effects the switching of this circuit arrangement acts on the magnetic core £ in the writing direction and on the magnetic core A counter to the writing direction. Both the read signals from cores £ and A and the read signal from core A3 can be used as output signals.

In one of the two stable states of the circuit arrangement, none of the cores is written, so no read signals are emitted in response to the interrogation pulses. If the magnetic core £ is now written by the input variable e 1, this core sends a write pulse to the core R when it is queried, which in turn writes the magnetic core A when it is queried. In the case of further inquiries, the magnetic cores A and R write themselves in alternately and accordingly emit alternate read signals. This second stable state of Schaltungsanord- & 5 voltage as long adhered to turn a one output signal e 1 occurs, the core can now £ are not enrolled because it is blocked by the core R forth. On the other hand, the core A is blocked and accordingly no longer sends a write-in pulse to the core R. With this, however, all of the: cores remain in the non-registered state until the cycle starts again with a renewed input pulse; repeated.

A tilting stage of the aforementioned type could per se also be different using only two Clock phases queried magnetic cores are built, of which one of the recorder excitation for each supplies the other. Due to such feedback, however, the occurrence of minor, For example, temperature-related disturbances lead to the flip-flop in the stable The state is switched in which both magnetic cores are alternately written in and read out.

The F i g. 6 shows an exemplary embodiment of the circuit arrangement according to the invention in the form of a four-stage frequency divider. Its second to fourth stages 52 to 54 are formed by bistable flip-flops, as shown in FIG. 5 have been described. The interrogation of the cores of these stages takes place in such a way that cores of the same order of successive stages are interrogated for the respective other clock phase. If, for example, cores £ 2 and A 2 are queried for the first clock phase and core R 2 for the second clock phase at stage 52, cores £ 3 and A 3 for the second clock phase and core A3 for the first at the following stage 53 Cycle phase queried. The cores of the following stage 54 are then queried again at the same clock phase as the cores of the same order in stage 52. The read windings of those cores of the stages that carry the input winding used for writing are each connected to the input winding used for writing of the corresponding core of the next stage, as well as to the input winding used to block the core queried at the same clock phase. So the reading winding of the core £ 2 of the stage 52 is connected to the input winding of the core £ 3 which is used for writing and to the input winding of the core A 3 of the stage 53 which is used for blocking. The same applies to the connection of the read winding of core £ 3 of stage 53 with the input windings of stages £ 4 or A 4 of stage 54. In stages 52 and 53, the read signals of cores £ 2 and £ 4 also provide the output signal of the Step. For stage 53, whose core £ 3, as explained, is queried at a different clock phase such as cores £ 2 and £ 4, a secondary core H 3 is also provided for clock conversion of the output signal, which is written in by the read signal from core £ 3 and is queried simultaneously with the £ 2 and £ 4 cores.

The three bistable flip-flops 52 to 54 are preceded by a pulse scaling stage to which the input pulses are fed and which suppresses every second input pulse. This pulse scaling stage contains three magnetic cores £ 1. Λ 1 and LX. The input pulses are fed to the core £ 1 in the write direction. This core is queried for the first clock phase. Its read signal excites the core A 1 of this reduction stage, which is also queried for the second clock phase in the write direction. The read signal of this core A 1 writes the third core L 1 of the reduction stage and the core £ 2 of the first bistable multivibrator of the frequency divider. The read signal of the core L 1 of the reduction stage blocks the core

609528/361

A 1 and at the same time represents the output signal of this frequency divider stage.

If initially none of the cores El, A 1 and LX of the reduction stage 51 is written, a first input pulse at the input F first writes the core E 1, which in subsequent query cycles also the writing of the cores A 1 and L 1 and the delivery of a Read signal at output / 72. By interrogating the core L 1, however, the core A 1 is blocked, so that when a second pulse occurs at the input F, only the core E1 is written in and accordingly no output signal is emitted via the output / 72 either. Since the core A 1 is no longer blocked, a third pulse at the input F again causes all three cores to be written in and an output signal to be emitted.

The read signal of the core A 1, which is also only emitted in response to every second input pulse, but occurs in the second interrogation clock phase, is fed to the core E 2 of the stage 52 as a write signal. This works on the basis of FIG. 5, thus leads to a further pulse reduction in a ratio of 1 to 2, so that an output signal is emitted at the output F / 4 supplied by it only after every fourth pulse. The same applies to the further scaling through stages 53 and 54, at whose outputs F / S and F / 16 output signals are emitted on every eighth input pulse and every 16th input pulse.

In FIG. 6 the two cores Mi and M 2 are also shown, which are interrogated at different clock phases and apart from the interrogation windings each carry only one reading winding. The read winding of the core M 1 is connected to a blocking winding of the core A3 of the stage 53 and the reading winding of the core M2 is connected to a blocking winding of the cores A4 and R2 of the stages 54 and 52, respectively. Since the nuclei MX and M2 do not receive any write excitation, they only emit signals of low amplitude, which correspond to the respective magnetization from the negative remanence state of these nuclei to the negative saturation state. The aforementioned supply as blocking signals to the cores of the bistable multivibrators labeled R ensures that the respective feedback of cores A 2 and R 2, A 3 and R 3 as well as A 4 and R 4 does not lead to unwanted switching of these in the event of temperature-related disturbances Tilt stages leads

In FIG. 7 shows another embodiment of the circuit arrangement according to the invention in the form of a three-stage binary counter. B. at stage S1 the cores G 1 and A 1, to a first clock phase and the third z. B. N t can be queried at a second clock phase.

The read signals of these first two cores G 1 and A 1 each act as blocking signals for the third core JV1. The reading designa! of the third core N 1 magnetizes the first core Gi in the writing direction and the second core A 1 in the reverse direction. The / wide core A 1 and the third core JV1 are each written by a central write pulse source, which is symbolized by arrows without lead lines drawn in the relevant halves of the core bars.

Most cores G2 and G3 of the stages 52 and 53 and a transfer magnet core Ü each supplied as a locking signal. Transmission magnetic core Ü, that too! Written by a central write-in pulse source, interrogated at a first clock phase, all third cores / V1 to / V3 of stages 51 to 53 in the write direction are magnetized with its read signal. A probed to a second clock phase magnetic core serves to receive the counting pulses Z, which is magnetized by ίο the counts against the Einschreibrichtung and the read signal, all the first cores G 1 to G 3, the stages of the counter and the carry core Ü magnetized opposite to the Einschreibrichtung.

As long as the described counter takes the counter reading O, all cores of the stages labeled N emit a read signal for the second interrogation clock phase, which blocks the cores labeled A of the same stage. These cores Λ 1 to Λ 3, the read windings of which form the outputs a 1 to a 3 of the stages, do not emit any read signal in the following. The same applies to the cores G 1 to G 3, since they are blocked by read pulses from the core Z.

The occurrence of a counting pulse results in the blocking of the core Z, which accordingly does not emit a blocking pulse to the cores C 1 and to the transfer core U when it is queried. The core G1 is therefore written by the read signal from the core JV1, the cores G 2 and G 3, however, are still blocked, specifically by the read signal from the core JV1 or N2. In the subsequent interrogation of the core G 1, the core JVi is blocked so that it can no longer emit a read signal when it is interrogated. The consequence of this is that when it is interrogated, no more blocking signal is sent to the core AX and this is written in by the central write-in pulse and, when interrogated, emits an output signal via the Auseane a X , which sets the second counter status.

When a second counting pulse occurs, the blocking excitation supplied by core Z for cores Gl to G 3 is no longer available. However, only the core G2 from the core / V2 is written in, since the core NX likewise does not supply any blocking excitation to the write-in winding of the core G 2. The cores G 1 and G 3, on the other hand, are not written in, the core G 1 not because the core JV1 does not supply any write-in excitation, the core G 3 not because the write-in excitation supplied by the core JV3 is compensated for by the blocking excitation supplied by the core JV2

When it is interrogated, the core G 2 emits a read signal which, together with the central write-in pulse, writes the core Ni of the previous stage against the blocking excitation supplied by the core A 1

so that the stage 51 is put back into the state corresponding to the binary value "0" during the subsequent interrogation cycle. The read pulse of the core G 2, on the other hand, blocks the core JVZ, whereupon corresponding to the described in connection with the stage 51

to which processes the core A 2 is inscribed and emits an output signal when it is queried via output a 2. This is the third counter status set

The occurrence of a third counting pulse and thus the elimination of the blocking excitation supplied by the core Z for the cores Gl to G 3 has the registered of the kernel Gl. The core G 2 cannot be enrolled, since it is only from the core JVl

a blocking excitation is supplied and the core G 3 cannot be written because the writing excitation supplied by the core Λ / 3 is compensated for by the read signal of the core N 1. The read signal 5 emitted by the core G 1 in the subsequent interrogation blocks the core Ni of this stage, so that the latter in turn no longer emits a read signal when it is interrogated and thus no longer prevents the core A 1 of the stage 51 from being written. Output signals are now emitted both via output a 1 and output a 2, with the result that the fourth counter status is set.

From the steps explained above, it follows that the cores marked G can only be written when the steps in front of the step to which they belong assume the set state, that is, the state corresponding to the binary "!" - state and that they then initiate on the one hand the setting of the own stage and on the other hand the deletion of the previous stage, i.e. its switchover to the one corresponding to the binary "O" state.

According to this principle, the binary counter described counts the occurrence of further · counts up to an eighth count position from which he by the Lesesi gnal of the core T, who had been enrolled for the first time after the occurrence of the eighth count throughout the Zählvor Ganges, returns to the Counter state 0 is reset.

In the above-described Ausführungsbei play the circuit arrangement according to the invention were the individual links of at least one of the variables to be processed in lockj direction influenced. The advantages caused by the query according to the invention occur naturally even if the variable to be processed is also in the writing direction, the cores of the link fungsglieder influence and when they meet m a write-in impulse or with another in egg Variables affecting the writing direction process the magnetic reversal of the core during the writing phase permit.

For this purpose 2 sheets of drawings

Claims (7)

Patent claims: 1. Circuit arrangement for processing binary variables consisting of logic elements of the same type consists, soft each using a magnetic core with a rectangular hysteresis loop are built up, if the link condition is met during a write-in process in one of its two remanence states and during the subsequent query process magnetized again by an interrogation pulse to the original other remanence state is, whereby it emits a Lcsesignal, and such read signals when the fulfillment of the Linkage condition in each case other such linkage members should be able to cooperate, d a through characterized in that interrogation pulses are supplied with such a short duration, that thereupon the remanence state corresponding to a magnetization in the saturation range initially but not achieved by an auxiliary pulse immediately following the interrogation pulse such a small amplitude is set that the read pulses associated with this for magnetization reversal downstream cores are not sufficient (Figs. 4 to 7). 2. Circuit arrangement according to claim 1 for linking two binary variables in the form of an exclusive-OR function, characterized in that it consists of two logic elements whose magnetic cores (£ 1, £ 2) are queried simultaneously and their reading windings (n 12, π 22) both contribute to the delivery of the result variable (a) , and that both input variables (el.e2) magnetize one magnetic core in the writing direction and the other magnetic core in the opposite direction via separate windings (nl3, π 14, η 23, η 24) For which they are supplied in such a way that their effects on one and the same nucleus are directed in the opposite direction (FIG. 4). 3. Circuit arrangement according to claim 2, characterized in that its output (a) supplies the write-in excitation for a third magnetic core (R) which is queried at a different clock phase and its read winding (nR 2) the input variables for one of its inputs (e2 ), so that it works as a bistable multivibrator, the switching of which is effected by the switching variable supplied to the other input (e 1) (FIG. 5). 4. Circuit arrangement according to claim 3, characterized in that it is part of a chain of similar stages (S 2 to 54) forming a frequency divider, in which cores of the same order of successive stages are queried for the other 5S clock phase and in each case the read winding of the input winding a core carrying a stage (£ 2, £ 3, £ 4) is connected to the input winding of the following stage and for those of these cores (£ 2, £ 4) that are queried for the first clock phase, also the output signal (F / 4, F / 16) of the stage, but with those of these cores (£ 3), it delivers the write excitation for an auxiliary core (H3) assigned to the same stage (53), which is queried for the first clock phase and which emits the output signal of the relevant stage via its read winding and whose first frequency divider stage (52) is preceded by a pulse scaler stage (51) for suppressing every second input pulse (FIG. 6). 5. Circuit arrangement according to claim 4, characterized in that the pulse reduction stage (51) contains three magnetic cores (£ 1, A 1, L 1), of which the first (£ 1), to which the pulses (F) to be reduced, are fed, and the second (/ 4 1), which emits the input signal for the first stage (52) of the chain, magnetizes the subsequent core (A 1, L 1) in the writing direction, and the third (Ll), whose read signal also the output signal (F / 2) of the stage, the previous second core (Λ 1) magnetized in the opposite direction and that the first (£ 1) and the third core (L 1) are queried for the first clock phase, the second core (A 1) however, is queried for the second clock phase. 6. Circuit arrangement according to claim 4 or 5, characterized in that two compensation cores (M 1. M2) are additionally provided, to which only query pulses are fed to different clock phases, and the compensation pulses via their read winding lengths for each query to such third cores ( R 2, /? 3, R 4) of frequency divider stages (S 2. to 54) deliver which are queried for the other clock phase that these nuclei are excited against the writing direction (Fig. 6). 7. Circuit arrangement according to claim 4 and 5. in the form of an η-stage binary counter, characterized in that the stages which are identical to one another each consist of three magnetic cores (G, A. N) , of which the first two (G. A) to a first clock phase and the third (N) are queried for a second clock phase, of which the first two (G. A) magnetize the third with their read signals in each case opposite to the writing direction and the third (A) with its read signal the first ( G) magnetized in the writing direction, and of which the second (A) and third (N) are each written by a separate central write pulse source that the read signal of the third core (N) of the stages the first cores (G) of all subsequent stages as well as one for the first clock phase queried transfer magnetic core (Ü) magnetized against the writing direction that the read signal of the first cores (G ^ of the stages the first cores (G) of all previous stages in writing direction magnetized, that the read signal of the transfer magnetic core (V) magnetizes all third cores (N) of the stages in the writing direction, and that a magnetic core (Z) , which is queried for the second clock phase and which is magnetized by the counting pulses against the writing direction, is used to receive the counting pulses and whose read signal magnetizes all first cores (G) of the stages of the counter as well as the carry magnet core (LJ) against the writing direction (F i g. 7).