DE1946653C3 - Link circuit with magnetic cores - Google Patents

Description

Magnetic cores with a rectangular hysteresis loop are used extensively to build gates for linking binary variables. The advantages of such cores are, among other things, their almost unlimited service life, their long life Reliability, as well as the link result in their ability wedge to be able to save.

When a plurality of logic circuits with magnetic cores to be linked vari- ¹ S blen common or separate Eingabewicklungcn be zugrfüh.t, where they affect the magnetic core in question, respectively in the same direction of magnetization. If the resulting field strength generated by the input variables exceeds the saturation field strength of the magnetic core, the core is remagnetized. The signal that occurs during such a reversal of magnetization by induction or the signal that occurs during an interrogation, i.e. when the core is influenced in the opposite direction of magnetization on a reading winding, then represents the output signal corresponding to the logical link Message processing, 1967 edition by K. S tei η buch, pp. 425 and 426.)
With such a coincidence logic, it is very difficult to ensure the coincidence of the input signals fed to the cores, since at least some of these input signals are the read signals of other cores, so that their time course depends heavily on the tolerances of the cores used, the temperature and the length of the Wiring are dependent.

In a solution that circumvents these problems of coincidence logic, those supplied to the cores are used Input variables are not used to magnetize the cores

^s ° Sieren, but to prevent the magnetization reversal by Einschreibimpulse. In this case, the write-in pulses are generally shorter than the input variables. In addition to avoiding the difficulty inherent in the coincidence principle, such a NOR logic also has the advantage that even when adding up the glitches caused by magnetization of nuclei from the remanence state to the saturation state associated with the same logic state, an incorrect result is not obtained

may have the consequence that they are not able to reverse the magnetization by the usually zeillich longer write-in pulse and thus the delivery of a signal corresponding to the non-fulfilled NOR condition to prevent.

It is also already known to have several such NOR gates to assemble into circuit arrangements, with the help of which more complex logical connections can be carried out. Both

the query windings as well as the read windings of the cores of the individual NOR gates connected in series. In this way, the interrogation of the individual cores takes place at the same time and the read signals of the individual cores are linked according to an OR function. (See Steinbuch, “Taschenbuch der Message Processing ", 1967, p. 428). With such an interconnection, only such Build up logic circuits whose output signal is the result of an OR operation. which means that the number of links that can be implemented using this technology is limited.

The circuit arrangement according to the invention is not subject to this restriction. The invention relates to namely also a circuit arrangement for linking binary variables that consist of similar There are logic elements, each using a magnetic core with a rectangular hysteresis loop are constructed, each of which has separate windings from the variables to be linked and of interrogation pulses in one direction of magnetization and of write-in pulses, their pulse duration is shorter than that of the shortest variable to be linked, in the other direction of magnetization is excited, so that on its reading winding a NOR operation of the inm supplied variables corresponding Read signals occur that are in accordance with the invention this circuit arrangement is characterized in that, in a first clock phase, one part of the magnetic cores Aofrageimpulse and the other part of the magnetic cores write-in pulses and to a second Clock phase the queried magnetic cores write-in pulses and the previously applied with li-write pulses Magnetic cores interrogation pulses are supplied, and that the read signals of all magnetic cores of logic elements as a variable to be processed and acting against a writer excitation only are passed on to magnetic cores of such logic elements, their query during each other clock phase takes place.

In the circuit arrangement according to the invention, the NOR principle with its initially mentioned Advantages are retained even if the type of links to be implemented am The output of the circuit arrangement is other than an OR operation of the result variables of the rest Part of the circuit arrangement requires links, as will be explained in detail will.

The following is a structure based on 9 figures and the mode of operation of the circuit arrangement according to the invention and its variants are explained in more detail.

F i g. 1 shows the hysteresis loop of magnetic cores as used in the circuit according to the invention will;

F i g. 2 shows a known basic NOR gate;

F i g. 3 shows a construction diagram of the circuit arrangement according to the invention;

4 shows the known NOR gate according to F i g. 2 in a different display mode, which is also used for the other embodiments of the circuit arrangement according to the invention is used;

F i g. 5 shows an embodiment of the invention Circuit arrangement for realizing the OR link;

F i g. 6 shows an embodiment of the invention Circuit arrangement for realizing the UN D link;

F i g. 7 shows the circuit arrangement according to the invention configured into a bistable multivibrator;

K i g. 8 shows a circuit arrangement for compensation of interference signals occurring in the circuit arrangement according to the invention;

9 shows a circuit arrangement for amplification of the cores of the basic gates of the circuit arrangement according to the invention, or the

ίο pulses emitted by these nuclei.

Fig. 1 shows a rectangular hysteresis loop of magnetic cores as they are used to build the circuit arrangement according to the invention. The positive remanence state + Br of such nuclei is assigned the binary value 1 and the negative remanence state - ßr is assigned the binary value O.

In FIG. 2 shows a basic gate which is known per se and is constructed using such a magnetic core and which is used to link the variables supplied to it in accordance with a NOR function. The magnetic core of such a NOR gate is symbolically represented here by a vertical, strongly drawn line and denoted by M. This magnetic core carries an interrogation winding n \, a reading winding η 2, which is connected in series with a diode D , a writing winding /? 3. and a number of logic windings η 4. Due to the different angular position of these windings symbolizing the core bar intersecting short Striehe indicated that ciiese windings partially have different winding direction, the polling winding η 1 and the logic windings η 4 have the same winding sense, so that the them / The impulses generated influence the magnetic core in one and the same direction. The polarity of the pulses supplied to these windings is directed in such a way that they influence the magnetic core in the direction of the negative remanence state - Br assigned to the binary value Ü. The write winding η 3, on the other hand, has opposite winding directions. so that with the same polarity of the write pulses, magnetization takes place in the opposite direction, namely towards the remanence state + Br . The write pulses fed to the write winding π 3 are shorter in time than the shortest pulses occurring on the logic windings.

An interrogation pulse continuously interrogates the core via the interrogation winding, so that it is then always in the remanence state - ßr. In the pauses between the interrogation pulses, the core is excited by a write pulse that is also continuously applied via the write winding π 3 in the opposite direction towards the positive remanence state + Br . The logical connection of the variables supplied to the logic windings π 4 comes about because the write pulsesc and the pulses to be combined influence the magnetic core in opposite directions of magnetization at the same time. The logic signals to be linked influence the magnetic core in such a way that they prevent a reversal of magnetization from the remanence state - Br, in which the core is after the query. If no other hand Logiksigna Ie, so the core is through the Einschreibimpuls ir the positive remanent magnetization reversal + Br In this magnetic reversal can on the sense winding due to the blocking action of the diode D keir flow stream, whereby the 'Jnimagnctisierung with rc

relatively little writer excitement can go ahead. The diode also has the advantage that Störsirömc suppressed caused by tension can be, if necessary, with the 1st reading winding to be connected logic windings are induced in further cores.

In the last-mentioned case, the query pulse following the scribing pulse results in a reversal of magnetization from the Rcmancn /./ state + Br to the negative Rcmanenzz.usland - Br , with a pulse corresponding to binary word 1 being emitted on the reading winding. Such an impulse occurs only then. if a signal corresponding to the binary value 1 is not applied to any of the logic windings, which corresponds to the result of a NOR operation. Since the logic signals influencing the core always only magnetize it from the negative remanence state - Or to the negative state of saturation - Bs , interference pulses supplied by other cores, even if they add up to a total interference pulse of large amplitude, cannot lead to a false signal, since the in every write pulse that lasts longer than interference pulses, a remagnetization into the remanence state + Br is still achieved. In addition, as already mentioned at the beginning, the difficulties that occur with a remagnetization as a result of the coincidence of supplied pulses are avoided here.

On the basis of FIG. 3 it will now be explained in more detail how the individual basic gates are to be connected to one another in the circuit arrangement according to the invention and how they are to be operated. In the case of the FIG. 3, which contains the three NOR gates CI to G 3, is an example that was not designed with a view to realizing a specific logical link, but is primarily intended to serve as a clear illustration. The cores of the three NOR gates G 1 to G 3 are provided with the same type of windings as the NOR gate according to FIG. 1. Interrogation pulses supplied by a central interrogation pulse source are supplied via two interrogation lines A 1 and A 2 and write pulses supplied by a central write-in pulse source are supplied via two write lines 51 and S 2 . The interrogation winding π 12 of the gate G 2 is inserted into the interrogation line A 1. The interrogation windings η II and η 13 of the gates G 1 and G3 are inserted into the interrogation line A 2. Correspondingly, the write line 5 1 contains the write-in winding η 32 of the gate G 2 and the write line 52 contains the write-in windings π 31 and π 33 of the gates G 1 and G 3. The read windings π 21 of the gate G 1 is via the diode D 1 connected to the logic winding π 42 of the gate G 2. The reading winding π 22 of the gate G 2 is connected to the logic winding π 43 of the gate G 3 via the diode D 2. The reading winding η 23 of the gate G 3 can either be used to emit output signals or be connected in a corresponding manner to the logic windings of a further core. The logic winding π 41 of the gate G 1 is connected either to a signal input or to the read winding of a further core, not shown here.

The interrogation pulses fed to the interrogation lines A i and A 2 or the write pulses fed to the write lines 51 and ⁶ S 52 each occur at different clock phases. Due to the above-described connection of these lines with interrogation or writing windings, the core of gate G 2 is always interrogated in a first cycle phase, whereas the interrogation of the cores of gates G 1 and G2 takes place in the second interrogation phase. The same applies to registered mail; the core of gate G2 becomes the first write-in phase and the cores of gates G 1 and G 3 are written in for the second write-in phase. In connection with the connection of read windings with logic windings of other cores described above, it can be seen that read signals are always passed on as logic signals to those cores that are queried for the other interrogation phase or that are written in for the other write clock phase. This, however, results in the freedom of movement in the construction of sound arrangements / in the implementation of any logical connections.

Before now to the explanation of some exemplary embodiments the sound arrangement according to the invention which are used to implement an OR link and an AND link or show the behavior of a bistable multivibrator, FIG. 4 is a representation of the Basic Gatier used here explained, which ensures greater clarity than the representation wayc the basic gate in Figs. 2 and 3.

The magnetic core of a NOR basic gate is also symbolized in FIG. 4 by a vertical, strongly drawn line. The remanence state + Br. Or the binary value 1 is assigned to the upper end of this line and the remanence state - Br. Or the binary value O is assigned to the lower end. The interrogation and the write-in windings are represented by an arrow running in the direction of this line, the direction of which indicates that the pulses supplied to the corresponding winding magnetize the magnetic core towards the respective magnetization state. The arrow symbolizing the query winding is pointing! that is, in the downward direction, while the arrow symbolizing the writing winding is upward. In contrast to the other arrows, the arrow for the interrogation winding is also filled in to indicate that the interrogation pulses cause a considerably stronger excitation than the other pulses. The logic windings η 4 are also shown by arrows running in the direction of the core bar, which point downwards and in which the lines belonging to the windings are indicated. The reading winding is symbolized by an arrow pointing to the right from the core bar, the associated lines also being indicated. In order to identify the cycle phase of the pulses that are fed to these windings or emitted by these windings, the core bar is divided into two halves by a horizontal line. The arrows for the query winding π 1 and the reading winding η 2 are in the upper half, which is assigned to the one clock phase, and in the lower half, which is assigned to the second clock phase. are the arrows for the write coil η 3 and the arrows for the logic windings η 4 located.

In FIG. 5 is shown a circuit arrangement using the symbology described above, the two for implementing an OR operation Variable serves This circuit arrangement containing the two cores E and A. the two moieties to be input variables e 1 and e 2 the logic windings are supplied n4 £ of the core E The read signal of the core E that on the read winding π 2Ε

is output, the logic winding π 4.4 is fed to the core A as the only logic signal. As the arrangement of the arrows for the query weightings η I F. and η [A or for the visual winding η II: and /? 34 shows in different halves of the cores, the cores are queried or written in at different clock phases.

If one or both of the input signals c I and t'2 assume the binary value 1, they prevent a reversal of magnetization of the magnetic core / "from the magnetization state - Br, in which it was moved by the previous interrogation pulse, into the magnetization region + Br. Ks becomes When this core F. is subsequently interrogated, no read signal is sent to the logic winding π4Λ of core A. However, this has the consequence that when it is inscribed for the / long write-down phase, magnetization is reversed from the magnetization state - Br to the magnetization addition + Br Inquiries for the second interrogation cycle phase, a pulse corresponding to the binary value 1 is emitted via its reading winding η 2.4, which indicates that the ODLR condition was met The core H emits a read signal, the writing of core 4 is prevented and during the query e does not distort a read pulse of the core 4. which corresponds to the output of the binary O.

In FIG. b shows an exemplary embodiment of the circuit arrangement according to the invention, which is used to implement an AND link. The circuit arrangement contains the two magnetic cores FA and F.2. the logic windings of which »4 /:" 1 and n4 /; '2 are fed to one of the input parameters c'I and c 2 to be linked, as well as the magnetic core .4. to whose reading winding η 2A the output signal is emitted. The reading windings »2 / ^r l and η 21: 2 of the cores /: 'l and F.2 are connected in parallel and their ungrounded connection is connected to the logic winding n4 4 of the core .4. The two cores /: "1 and E2 become the same first Query clock phase queried and written to the same first Einsehreibaktphasc. The core .4 is written or queried for the second write or read clock phase. When the AND condition is met. So if both F. input variables el and ο2 assume the binary value 1, none of the cores c 1 and ο 2 are unimagnetized and accordingly the core A does not receive a logic signal, which in turn has the consequence. that it is remagnetized by its write-in pulse into the magnetization state + Br and then magnetized back into the magnetization state - Br for the second interrogation cycle phase, so that a pulse corresponding to the binary value 1 is emitted via the read winding π 24 of the core A. For all other value combinations of the input signals e 1 and e2, a logic signal is fed to core A from core Ei or from core E2 or from both cores, which logic signal prevents writing and thus the emission of an output signal.

In the case of the FIG. 7, the basic gates are connected to one another in such a way that a circuit arrangement with bistable behavior is created, which is switched from one input signal to the one stable state and from the other input signal to the other stable state. The circuit arrangement contains the two magnetic cores A 1 and A 2. whose logic windings n4A 1 and n4A 2 are each fed to one of the input variables el and c 2. The logic windings of these cores are also with the reading η 2A 1 or /; 2Λ 2 of the other core connected. For example, if the core A 1 is written in, it emits a read signal in the first clock phase of the interrogation pulse. that prevents the writing of the core 4 2. This

When it is queried, the core cannot emit either the core .4 1 blocking or an output signal to the output i \ 2 , so that the core A 1 is rewritten when the next write pulse occurs. In this way, the core .4 1 is magnetized continuously back and forth and thus continuously emits pulses at its output a 1. which corresponds to a stable state of the circuit arrangement. This permanent reorganization of core .4 is only prevented when an input variable with the binary value 1 is fed to its logic input /)4.4 1. The core A 1 is then blocked and accordingly does not emit a read signal. so that the core 4 2 is now magnetized and continues to block with its read signal core .4 I, even if its input signal c 2 has meanwhile assumed ilen binary values. Have more write-in and read pulses, therefore a continuous remagnetization of the core .4 2 and hence the delivery of Leseinipulsen on its output. · (2 a result which corresponds to the second stable state. In a corresponding manner, is controlled by a logic signal c2 with the binary value 1 at tier logic winding η 44 2 of the core, 4 2 the arrangement is switched back to the first stable state.

As already explained above, audio signals.

the non-enrolled for example, by the magnetization of magnetic cores from Rcnianenzzusiand - Hr in the saturation / ustand - sss arise not affect the NOR basic gate in a disturbing manner, as they nuclei such gates also only by Remanen / condition in the corresponding Siitiigungszustand magnetize and As a result of their short period of time, a reversal of magnetization of the magnetic core due to the write-down pulse that persists over time cannot prevent them. Such interference pulses could have a disruptive effect only in the case of the basic gate emitting the output signal. / .. B. when the ^{basic gate delivering 1} output signal controls a trigger stage. A further embodiment of the circuit arrangement according to the invention makes it possible to avoid such an occurrence of interference pulses, as shown in FIG. 8 shows, for this purpose the reading winding η 2a of the magnetic core Aa of that basic gate which outputs output variables and which is shown as the only one in this figure, with the reading winding π 2k :

Compensation core K connected in series. De winding sense of the two reading windings is chosen here so that when the compensation core K and the output core Aa are queried. the same query cycle phase takes place the resulting Le tensions counteract each other and take a break. Since the compensation core K is only influenced by interrogation pulses, that is to say it is only magnetized before the remanence state - Br into the saturation state - B , only such pulses are compensated sated. which with appropriate magnetization of the Au? gabekemes Aa arise, but not the Nutzirr pulse. which stood by remagnetization from remanence / t - ßrcles <\ usEabckcrnes Aa in the Sattigunes / i

609 637/1 (

ίο

stund - ß.s arise.

In the above-described exemplary embodiments of the circuit arrangement according to the invention, it may be necessary to amplify individual currents supplied to the cores of this circuit arrangement or output by them. An amplifier that can be used universally is particularly suitable for this purpose, as shown in FIG. 9 and is described below. The pulses to be amplified are fed to the auxiliary windings η 1 of a magnetic core Kv . The output winding ns of this magnetic core is connected between the base and the emitter of a transistor Tr which operates without a DC voltage supply and whose emitter is grounded. In the collector circuit of this transistor, the drive signals of the magnetic cores to be influenced by the amplified pulses and a collector resistor are arranged, the resistance of which depends on the use of the amplifier, i.e. on whether it is to be used as an interrogation pulse amplifier, as a write pulse amplifier or as a cable driver. These alternative configurations of the collector circuit are indicated by dashed lines. The following correspond here: Use as query pulse amplifier and collector circuit A. Use as write pulse amplifier and collector circuit B. and use as cable driver and collector circuit C. If the amplifier is only used to adapt / .. B. to DTL technology, the collector circuit is in accordance with Variant D designed. In the case of use as a write pulse amplifier, a coil with inductance is inserted into the collector circuit of the transistor Tr , which flattens the start edge of the write pulses and thus contributes to the fact that the write pulses are outlasted by the read signals from the magnetic cores, which serve as blocking signals .

If the circuit arrangement according to the invention consists of a number of Grundgatlergruppen that do not have to process binary variables at the same time, the interrogation pulses can instead be sent through a central one Query pulse generator by query pulse generators assigned to the individual groups which are made switchable and only deliver query pulses as long as the relevant one Basic tag group to be linked variable are supplied. In this way the total Reduce the energy to be used for querying.

For this purpose 2 sheets of drawings

Claims (5)

9 46 653 claims: 1.Circuit arrangement for processing binary variables, which consists of similar logic elements, which are each constructed using a magnetic core with a rectangular hysteresis loop, which has separate windings of variables to be processed and of query pulses in one direction of magnetization and of write-in pulses whose pulse duration is shorter as that of the shortest variable to be processed, is excited in the other magnetization direction, so that read signals corresponding to a NOR operation of the variables supplied to it occur on its read winding, characterized in that one part of the magnetic cores (C 1, G 3) interrogation pulses and the other part of the magnetic cores (G 2) write-in pulses and, in a second clock phase, the interrogated magnetic cores (Cl, G3) write-in pulses and the magnetic cores (G 2) previously applied with write-in pulses, interrogation pulses, and d ate the read signals of all magnetic cores of logic elements, as variables to be processed and counteracting a writer excitation, are only passed on to magnetic cores of such logic elements, which are queried during the respective other clock phase (e.g. B. F i g. 3). 2. Circuit arrangement according to claim 1, characterized in that it consists of two basic gates (A 1, A 2) , each of which is supplied with one of two input variables (e 1, c2), and that the read windings (n2A 1, η 24 2) the pulses emitted by this basic gate are passed on to the other basic gate as a logic variable as well as emitted as output variable (a 1, Λ 2), whereby a bistable flip-flop circuit is formed, each delivering two inverse output variables, which is controlled by the input variables (el, el ) is placed in one or the other stable state (FIG. 7). 3. Circuit arrangement according to claim 1 or 2, characterized in that the write-in pulses for all basic gates can be supplied from a central write-in pulse source. 4. Circuit arrangement according to one of the preceding claims, characterized in that the reading winding of the magnetic core of that basic gate (Aa). the output variable is connected in series with the reading winding (n 2k) of a compensation core (K) made of soft magnetic material and controlled only by interrogation pulses. that the read voltages of the two cores that arise during the interrogation counteract one another (FIG. 8). 5. Circuit arrangement according to one of the preceding claims, which consists of a number of There is basic gate groups that do not process input variables at the same time, characterized in that that the interrogation pulses are supplied by switchable interrogation pulse generators that only provide query pulses as long as the variable to be linked to the relevant basic gate group are fed. b. Circuit arrangement according to one of the preceding claims, characterized in that the interrogation and write pulses of the basic gates as well as the read signals of basic gates emitting output signals are passed on via the Koliektorkreis of a transistor amplifier (Tr) controlled by dc voltage potentialfrci, for which purpose they are each fed to the control winding of a magnetic core (Kv) with a rectangular hysteresis loop assigned to the transistor amplifier in question Output winding (ns) is inserted into the base-emitter circuit of the transistor (Fig. 9).