DE1234262B - Arrangement for realizing the logical OR-BUT function - Google Patents

Description

Arrangement for implementing the logical OR-BUT function In electronic devices for message processing, the toroidal cores made of a magnetic material with a nearly rectangular hysteresis loop, which have been used for a long time to store information, are increasingly being used for switching purposes due to their high operational reliability and long service life , d. H. used to realize logical functions. In the meantime, magnetic toroidal cores have become known, the main flow path of which is divided into two auxiliary flow paths by a number of openings. With the help of such toroidal cores, logic circuits can be built which, compared to the circuits with ordinary toroidal cores, have fewer elements and, in particular, operate more reliably because there are no additional elements in them, whose service life is generally significantly less than that of the magnetic cores, for coupling the Magnetic cores are required.

The well-known logic circuits with magnetic toroidal cores, whose Main flow path is provided with openings, but have the disadvantage that in them for realizing logical functions of more than two variables in general more than one toroid is necessary. The object of the invention is to create logic circuits with such a ring to create cores which also functions of several variables in a mag net: core. realize and thus build up easier and smaller and work even more reliably.

In an arrangement for realizing the logical OR-BUT function with the help of one made of a material with an almost rectangular hysteresis loop Ringl, - erns, whose main flow path is through one of the number of single-input windings corresponding number of openings in an outer and an inner auxiliary flow path is divided, this Auf-Glabe is essentially solved according to the invention by that each of the input windings area the outer and inner auxiliary flux path, respectively the opening assigned to it in a first direction and in the area of all others Includes openings in the second direction and supplied operand signals of equal strength each of which is able to re-magnetize the inner auxiliary flux path, and that a reset winding the main flux path in the second direction and one Output winding comprises the main flux path or at least the inner auxiliary flux path.

According to the invention, an advantageous embodiment consists in that the arrangement for realizing the sum of three binary operand digits alongside the openings assigned to the three operand input windings have an additional opening Has opening in the main flow path, in the area of which the outer or inner auxiliary flow path from all operand input windings in the first direction and from a bias winding is included in the second direction, and that the bias winding such a flux produces that they cancel the effect of all but one operand input winding can.

Further advantageous details of the invention are evident from the claims in conjunction with the exemplary embodiments explained below with reference to the drawings. It shows F i 1 an OR-BUT circuit with two inputs, F i g. 2 the hysteresis loop of the magnetic material used, F i - 3 a circuit with multiple coincidence, F i g. 3 a that to F i g. 3 associated block diagram, FIG. 4 a full adder with two toroidal cores and FIG. 4 a a second embodiment of the transfer core of FIG. 4th

In Fig. 1 shows a magnetic core circuit which can perform the OR-BUT switching function and which, in its operation, illustrates some of the principles on which the invention is based. The circuit contains a core 10 made of magnetic material, which is provided with openings 12 and 14 on its longitudinal axis. The openings 12 and 14 are preferably located in the middle of the circular main footpath through the valley and divide the core material into two circular magnetic circuits or flux paths, one of which is preferably between the inner circumference of the core and a circle delimited by the innermost parts of the openings and the other are mainly between the outermost parts of the openings and the outer periphery of the core. In describing this and the other embodiments, these flow paths will be referred to as the inner and outer flow paths, respectively.

Inputs have been made to the circuit of FIG. 1 is applied by two pulse sources 16 and 18 which are controllable to send pulses which generate a current flow in the direction shown in two input winding means 20 and 22. Each of these winding means is passed through both openings 12 and 14 in such a way that each surrounds the parts of the outer flux paths adjoining the openings. Each winding means is guided so that it surrounds these parts of the outer flux paths with oppositely directed turns, and both are wound so that the winding means 20 has a sense opposite to that of the winding means 22 with respect to the outer flux path adjacent to each opening. Thus, when the pulse generator 16 is actuated to cause a current to flow in the indicated direction in the winding means 20, a clockwise MCC is applied to the part of the outer flux path adjacent to the opening 12, and a MCC active in the counterclockwise direction is applied to the portion of the outer flow path adjacent to the hole 14. Upon actuation of the pulse generator 18 , the winding means 22 applies a counterclockwise MCC to the portion of the outer flux path adjacent to the opening 12 and a clockwise MCC to the portion of the outer flux path adjacent to the port 14, prior to any logical switching operation the flow in the core must be reset to the same direction. For this purpose, a reset winding 28 is provided which is excited by a pulse source 30 which, when actuated, applies a pulse to the winding which causes a current to flow in the direction indicated. Since the winding 28 encompasses the entire cross-sectional area of the core, the passage of current through it exposes the entire core, including the inner and outer flux paths, to an MMK which is effective in one direction and which here acts counterclockwise. F i g. 2 shows the known rectangular hysteresis loop that is obtained when the flux density B versus magnetic field strength H for a core made of magnetic material is recorded, as it is suitable for the implementation of the invention in practice and with respect to which the operation of the cores in this and the other illustrated embodiments will be described below. The pulse applied to winding 28 by pulse generator 30 is large enough to saturate core 10 with counterclockwise magnetic flux as indicated by arrows 26 regardless of its initial state. This saturation state is on the hysteresis loop of FIG. 1. Shown at a and the remanence state in this direction, which the core assumes at the end of the reset pulse, at b. Now if the core is in this state, i. i.e., when the entire core is in a remanent state of counterclockwise flux density, input pulses can be applied to winding means 20 and 22.

Assuming first that a pulse source 16 is actuated to apply a pulse to the winding means 20 and that the winding means 22 is not energized, the portion of the external flux path adjacent to the opening 12 will be subjected to a clockwise MFC, and the the part of the outer flow path adjoining the opening 14 is subjected to an MMK which is effective in the counterclockwise direction. In order to make the mode of operation of this and other exemplary embodiments more understandable, it is considered expedient to cite two of the basic principles which govern the switching processes in multipath cores of the type described in this application. The first principle is that when the whole core is initially saturated in one direction and a MFC is applied to either the inner or outer core half so that the generated magnetic flux is opposite to the initial direction of flow, a flux reversal in the inner part of the Kerns takes place; if the applied HMI generates a magnetic flux in the same direction as the one initially existing, no flux reversal occurs. The second principle, which is an extension of the first, is as follows: If the core is initially saturated in one direction and MMKs are applied to either the inner or outer core half at different locations of the core, a flux reversal only occurs in the inner core half when the magnetic flux generated by at least one of the applied NIMKs is opposite to the initial saturation.

Based on these principles, it can be seen that the MMF applied by that portion of the winding means 20 which includes the external flux path at a location adjacent opening 14 which is in the same direction as the initial magnetic flux is ineffective in causing flux reversal cause. However, the portion of the winding means 20 passed through the hole 12 applies an MFC of the opposite sense which is effective to establish a localized state of flux saturation in the clockwise direction indicated at 32 in the core material surrounding the opening. By establishing this localized state of saturation, the magnetic flux in the inner core part remote from the opening 12 is reversed. The direction of flow in the outer part of the core remains unchanged, so that a kidney shape effect, as indicated by the arrows 34, is achieved in the part of the core that is remote from the opening 12. Outputs from the circuit of FIG. 1 are formed on a winding 38 which surrounds the entire cross-sectional area and thus both the inner and outer flux path at a location separate from the openings 12 and 14. Since this winding comprises the inner path, it produces an output which appears on a terminal 40 when the input winding means 20 is energized. The operation is similar if initially the magnetic flux throughout the core extends in the opposite direction of the g clockwise and the pulse generator 18 is operated by a pulse to the winding means 22 to be applied during reaches the winding means 20 no pulse. Through the application of a pulse, the winding means 22 becomes effective to provide a counterclockwise MMK to the outer flow path at a point adjacent to the opening 12 and a clockwise MMK to the outer flow path at one to the opening 14 to create an adjacent location. Therefore, a localized clockwise saturation field is established in the core material surrounding the opening 14, and the magnetic flux in the core parts outside this saturated area is made kidney-shaped in the same way as when the winding means 20 is energized. The only difference is the position of the kidney pattern which is erected in the core part separated from the localized saturated area, namely with exclusive excitation of the winding means 20 around the opening 12 and with exclusive excitation of the winding means 22 around the opening 14. The output winding 38 comprises the core at a point where a reversal of the internal flux path occurs in both cases, and thus a precondition for an OR-BUT selection is fulfilled in that an output at terminal 40 is produced when one of the input winding means is exclusively energized. If the whole core is initially retentive in the counter-clockwise direction and no input pulse is applied to a winding element for a certain period of time, there is no output at terminal 40, and the second precondition for the logical OR-BUT operation is fulfilled. If, finally, both the inner and the outer flux path are initially retentive in the counter-clockwise direction and the winding C, are simultaneously excited, these windings apply the same and opposite MMKs to the outer flux path by means of 20 and 22, namely to the points adjacent to openings 12 and 14. Since the pure MMK applied to each point is now equal to zero, no localized magnetic field is established, there is no flux reversal, and no output is generated at terminal 40, which means that the third precondition of the OR-BUT logic is fulfilled, i.e. that is, no output will be produced if both input windings are energized simultaneously.

Note that the FluBänderungen which produce the more outputs to the terminal 40, in each case, ge occur in the inner flow path, and for this reason, the output winding means can be so guided through a correspondingly mounted Hole that it only comprises the inner core portion. Furthermore, according to the basic principles described above, the input winding means can be arranged so that they surround the inner flow path at points adjacent to openings 12 and 14, or both winding means can be guided through the openings so that they form part of the inner flow path, which adjoins the one opening and a part of the outer flow path which adjoins the other opening. In the arrangement of the input winding means, the only conditions are that one winding means, when energized, applies an MNIK opposite to the saturation direction to one flux path at a location adjacent to the one hole and that the other, when energized, applies one similar MMKs apply to one of the flux paths at a point adjacent to the other hole and that the winding means, when excited at the same time, apply the same and oppositely directed MMKs to the surrounding Flußpiad next to each opening. It should also be pointed out that the operation is independent of the original magnetic flux remanence in the whole core; so can z. B. the core can originally be reset to remanence clockwise by winding 28, in which case the polarity of the output pulses generated at terminal 40 is reversed.

As stated in the explanation above, the circuit of FIG. 1 effective to generate output pulses at terminal 40 in accordance with the OR-BUT logic function at the time the input pulses are applied. A logical output pulse, which - represents the timing of the application of the inputs, can also be generated later, since the core effectively stores the logical result of the input information. If neither input is energized or both inputs are energized at the same time, core 10 maintains counterclockwise remanence. When only one input is excited, the flux in the inner flux path is reversed, and when the input pulse ends, the core assumes a steady state in which there is a clockwise remanent flux field around one of the openings 12, 14 and the remainder of the core assumes a remanent kidney-shaped state, as indicated by the arrows 34. The core can then e.g. B. can be queried by energizing the Rückstellwic1-ment 28. If no or both input winding means have been energized and the core in the remanent state is b, causes the at application of a pulse to the coil 28 Ninik produced only a slight change in flux, as indicated by the segment ba e in. However, if either of the winding means alone has been energized , the MMK applied by winding 28 will cause a flux reversal in the inner path. This flux reversal is sensed by output winding 38 and results in the generation of an output signal at terminal 40.

F i g. 3 shows a further logic circuit which is constructed in accordance with the principles of the invention and can be used to illustrate a third principle on which the invention is based. The core 50 of FIG. 3 is provided with three inlet openings 52, 54 and 56. Six input winding means lead to the circuit of FIG. 3. Each of them has only one turn that surrounds the core at the point of one of the openings. These windings have the reference numerals 58 a, 58 b, 58 c, 60a, 60b and 60c. Each input winding is connected to one of the six input pulse generators 62 which, when actuated, apply pulses to the associated windings with such a polarity that a current flow is effected in the indicated direction. Outputs for the circuit are generated at an output terminal 63 which is connected to a winding 64. This leads through the opening 66 in the core 50 in such a way that it only surrounds its outer flow path. The circuit CC according to FIG. The logic implemented in FIG. 3 is in the block diagram of FIG. 3 a shown, where the input and output lines corresponding to the input and output windings of F i g. 3 are numbered. According to FIG. 3 a circuit comprising the three AND circuits of the input windings are connected to the inputs each as two connected, and an OR circuit to which the outputs of the three AND circuits are connected as inputs. It can therefore be seen that an output C ZD is only created at terminal 63 when two of the inputs connected to the same AND circuit are excited, ie. h, when any combination of input signals comprising signals simultaneously either to the wires (windings) are applied c 58 a and 60 a or 58 b and 60 b, or 58 c and 60..

In order now to complete the operation of the circuit of FIG. 3 to make C el C easier to understand for the implementation of this logic circuit, a third principle underlying the invention should be mentioned here: If an aanzer core is initially saturated in one direction C C, 9 and MMKe in the inner and outer If the flux path are applied at the same location in such a direction that the magnetic flux is completely reversed UMC, MMKs applied in the same direction to the inner and outer flux paths at different locations do not affect the direction of flux reversal. Before the initiation of the logical operation, the no 50 is reset by a pulse generator 68 which, when actuated, causes a current to flow in the direction indicated in a reset winding 70. This reset winding now applies a sufficiently strong MMK to the entire core to bring the core into a counter-clockwise remanence state regardless of its initial state (see arrows 72). This state is shown in FIG. 2 shown at b . Each of the input windings is guided through one of the openings in such a way that when the connected pulse generator 62 is actuated, the winding applies a clockwise MMK to the inner or outer flux path it encompasses. According to the first and second principles described above in connection with the mode of operation of FIG. 1 , such a MNIK is effective to establish a localized saturation field around the opening through which it passes. These localized fields are constructed in a clockwise direction, as indicated at 58d, when one or more of the coils 58a are energized 58b and 58c, and in the Geggensinn of the watch-hand when one or more windings 60 a, 60 b and are energized C 60. Thus, when an input signal is applied separately to one of the six input windings, a localized field of saturated flux is established around the opening through which that winding passes and the flux in the inner flux path of the core portion separated from the opening is reversed . Since the out ang winding 64 only grasps the outer flux path uni-9 ZIS, no essential output is then generated at the terminal 63. The same is the case if more than one input winding is energized, as long as both windings passing through the same hole, which comprise the inner and outer flux path at the point in question, are not energized at the same time. It can e.g. B. all three windings 58 a, 58 b and 58 c O are energized at the same time. In this case, a nearly saturated flow condition arises in a clockwise direction around openings 52, 54 and 56 and only the internal flow path in the partial core remote from these openings is reversed. The same is true when all three windings 60a, 60b and 60c or combinations of windings such as 58a, 60b and 60c are energized at the same time. The only difference is then in the direction of the saturated magnetic flux around the openings.

However, when the core 50 is returned to counterclockwise remanence and two input windings comprising the inner and outer flux paths at the same location are energized simultaneously, e.g. For example, the windings 58 a and 60a, each of them defines a MMK in a different direction at the localized path around the opening. As a result, the MMKs, which operate both clockwise with respect to the longer inner and outer flux paths around the core, are effectively applied to those paths and, being strong enough, cause flux reversal along both the inner and outer sides also of the outer river path. Since the winding 64 comprises the outer flux path, an output voltage is then induced in this winding and an output signal is generated at terminal 63. This flux reversal throughout the core is caused when signals are applied to two input windings which encompass the inner and outer portions of the core at the same location, regardless of whether inputs are applied simultaneously to one or more of the other windings not. According to the above-mentioned third principle, when the windings 58 a and 58 b are excited at the same time, the flux in the inner and outer flux path is reversed and an output is generated at terminal 63 , whether one or more of the other input windings are excited at the same time or not.

As with F i g. 1 , an output representing the logical combination of previously created inputs can later be created by applying an interrogation pulse z. B. be generated in the form of a reset pulse applied to the winding 70 to the core. Now, if no two windings passing through the same opening have been energized at the same time by the inputs or no inputs have been applied, the magnetic flux in the external flux path will maintain the initial counterclockwise direction and the application of a reset pulse to winding 70 will not cause any substantial change in flux therein Path, and therefore no noticeable output is produced at terminal 63 . However, if any two windings passing through the same opening have been energized at the same time so as to reverse the flux in both the inner and outer flux paths, subsequent energization of winding 70 will reset both paths clockwise again, 9 C creating a voltage induced on nickel 64 and manifested on terminal 63.

F i g. 4 shows a circuit which can implement the logic circuit to be fulfilled by a binary full adder. In the circuit according to FIG. 4, the inputs are applied by the signal sources 90 c, 90 y and 90 x, and the outputs are generated at a sum output terminal 92 and at a carry output terminal 94. According to the rules of binary addition, an output on terminal 92 and no output on terminal 94 is produced when a signal is applied from one of the input signal sources alone; no output is produced at terminal 92 and an output is produced at terminal 94 when two of the input signal sources are simultaneously applying input pulses, and outputs are produced at both output terminals when all three input signal sources are simultaneously applying pulses. The circuit uses two multipath cores 96 and 98 as switching elements. The core 96 extends the necessary circuitry to produce the required sum outputs at terminal 92 and is referred to as the sum core. No 98 executes the logic circuit that is required to create the necessary carry outputs at terminal 94 and is called the carry kernel.

The Eingangssignalquellen90c, 90x and 90y are three sets c of windings 96, connected 96x and 96y, which are inductively coupled to the sum of core 96, and three coil sets 98e, 98x and 98y, which are inductively coupled to the carry-nuclear 98th The c by the sources 90, 90y and 90x applied input pulses have a polarity such as to cause a current to flow in the direction shown in each of these windings. The sum core 96 has four openings 100, 102, 104 and 106 through which a corresponding one of the input windings 96c, 96x and 96y in each set passes so as to surround the outer flux path at the four locations adjacent to these openings. Thus, for purposes of illustration, it can be assumed that each winding set contains four windings and that each winding includes the external flux path at a different one of openings 100, 102, 104 and 106 .

In preparation for the logical operation, both the inner and the outer flow path of each of the cells 96, 98 are returned to a clockwise stable remanence state, as the arrows 108 indicate. This reset is carried out by a signal source in the form of a pulse generator 110 which, when actuated, applies a pulse to each of two reset windings 112 which causes a current to flow in the direction indicated. Each of the winding sets 96c, 96x and 96y comprises two windings which, when excited, apply to the outer flux path at a location adjacent to two of the openings, and two windings which, when excited, apply to the outer flux path at one Place an MMK clockwise on the other two openings towards the neighboring point. Another winding 114 is passed through the opening 106 so that it surrounds the outer flux path at this point. This winding is energized by a signal source in the form of a clock pulse generator, 116, which applies a pulse of such polarity as to cause current to flow in the indicated direction in winding 114 during each input time interval simultaneously with the application of pulses by signal sources 90e, 90x and 90y will. The arrangement is such that the MMK applied by winding 114 is effective in a clockwise direction and is approximately twice that applied by one of windings 96c, 96x and 96y . If it is now assumed that the NDvIK applied by the various windings is negative (-) if it runs clockwise and thus in the direction that a magnetic flux is in the direction of the initial remanence state, and positive (+) if it runs in the opposite direction :, runs in the clockwise direction and thus in the direction that the direction of the initial remanent flux is reversed, the operation of the circuit can be better understood with the aid of the table which, using this designation system, shows the direction of each winding on each of the indicates four openings applied MMK. Since the MLC applied by winding 114 is twice that applied by each turn of the three input windings, it is represented by two units in the negative direction, while the MLCs applied by each winding are represented by one unit in each direction . MNIK attached to the outer river path around the openings 100 1 102 1 104 1 106_ Winding 96 c ..... - 1 - 1 + 1 Winding 96x ..... + 1 - 1 - 1 Winding 96y ..... - 1 + 1 - 1 + 1 Winding 114 ..... As previously stated, it is necessary to produce an output at the sum terminal 92 when one of the input winding sets is energized alone and when all three are energized simultaneously, and to produce no output when no input winding set is energized and when two input winding sets are energized simultaneously . First, note that if no inputs are applied to the input windings during an input time interval, the only MNIK applied to the core is the clockwise (-) effective MNK through winding 114 to the outer flux path at one of opening 106 adjacent Position is created. In accordance with the principles set out above, this MMC is ineffective to cause a flux reversal in the inner, or outer path, and therefore no voltage is generated on the output winding 120 which the sum output terminal 92 is connected to. If all three sets of input windings 96e, 96x and 96y are energized at the same time, then. it can be seen from the table that the pure MMK applied to the outer flow path at opening 106 is effective clockwise and thus has the correct direction to reverse the flow in the outer path. A localized state of saturation of flux is then established around this opening and causes a flux reversal in the portion of the inner flux path surrounded by winding 120. Therefore, a voltage is induced in winding 120 and an output signal is generated at terminal 92 . According to the table are the fields that are applied to each of the other openings' when -three inputs are simultaneously applied, and thus adversely effect in the clockwise direction so that they are ineffective alone to cause a flux reversal in the inner or outer flow path. - If only one of the input winding sets is energized alone, a localized area of the flux saturation is built around one of the openings around, and the voltages applied to the other openings fields are either close to zero or clockwise (-) effect. If z. B. only the Wicklun-en 96 c erre - t be attached to the opening 100 e-scale ID MMK is negative, the negative at 102 to 104 positively and thus effective to establish a localized saturation state around this opening , and at 106 is negative, as is negative through the winding 114 and twice as large as the voltage applied to this point through the winding 96 c. The operation is similar when only one of the input coil sets is energized alone, namely, a localized saturation field is established around opening 100 when windings 96x alone are energized and around opening 102 when windings 96y alone are energized. In any case, the establishment of the localized saturation field causes a flux reversal in the inner flux path in the core part surrounded by the winding 120. As a result of this flux reversal, a voltage is generated on winding 120 and an output signal is generated on terminal 92.

When two of the sets of input windings are energized at the same time, the pure I # MK applied to each of the four holes is either negative or near zero, and neither the inner nor the outer flux path experiences flux reversal, and on winding 120 no output is formed. If z. For example, the windings are energized c 96 and 96x at the same time, the voltage applied to the outer flux path at the openings 100, 104 and 106 pure MNIKe equal to zero, and at the opening 102 is negative. Thus, if any two sets of input windings are energized at the same time, neither the inner nor the outer flux path will experience a flux reversal in the portion of the core enclosed by the winding 120, and there will be no output at the terminal 92.

As previously stated, it is necessary that an output be generated at the carry output terminal 94 when signals are simultaneously applied from any two or all three pulse generators 90e, 90x and 90y . This logic circuit is carried out by the carry core 98 . Both the inner and outer flux paths of this core are initially reset to a stable, clockwise flux retentive state by the reset pulse applied to reset windings 112 by pulse generator 110. The no 98 has three openings 126, 128 and 130 through which the input windings are passed, and a further opening 131 through which an output winding 132, which is connected to the transmission terminal 94, is guided so that it encloses only the outer flux path . There are three sets of input windings and each set contains two windings. The two windings in the first set are labeled 98e, those in the second set are labeled 98x, and those in the third set are labeled 98y .

In the switching operation of this core is described above in connection with the operation of the logic circuit of Fig. 3 described principles. Each of the input windings is passed through one of the three openings, namely one winding in each set is arranged in such a way that it encloses the inner flux path at a point adjacent to one opening, while the other winding the outer flux path at one of the other openings, surrounding area. The Impulsgeneratoren90c, 90y and 90x apply signals of such polarity that a current flowing in each of the windings 98 c, 98 x and 98 y in the specified direction is effected. The windings are arranged in such a way that each anti-clockwise MMKe applies to the path it encompasses at the location of the opening through which it passes. For example, when energized, the windings 98 x apply a counterclockwise MCC to the outer flux path at a point adjacent to the opening 126 and a counterclockwise MCC to the inner flux path at a point adjacent to the opening 130. If only this set of windings is energized, localized saturation states are established around each of these openings and cause a reversal of the magnetic flux in the inner flux path of the core part. Since the output winding 132 only surrounds the external flux path, there is then no output at terminal 94. Similarly, if either of the other two input winding sets is energized alone, localized saturation conditions will be established around the two openings through which the windings pass and only the magnetic flux in the internal flux path will be reversed and no output will be provided at terminal 94. However, when any two winding sets are energized at the same time, the clockwise effective MMKe be applied to both the inner and the outer flow path at the location of one of the openings in the opposite direction, and since the applied MMKe voltages by the energized windings at the locations of the other Öff- operate in the same direction, the magnetic flux is reversed in both the inner and outer flux paths. An output is now created on winding 132 which comprises the external flux path and is manifested on terminal 94. If z. B. the windings 98x and 98y are energized simultaneously, anti-clockwise effective MMKe are applied to both the inner and the outer flux path at the location of the opening 126 , an anti-clockwise effective NMK is applied to the outer flux path at one of the Opening 128 is applied adjacent location, and a counterclockwise effective MMK is applied to the inner flow path at a location adjacent to opening 130. The MMKs applied to both paths at a point adjacent to the opening 126 are therefore in accordance with the third principle, which is described in connection with the description of the embodiment of FIG . 2, effective to induce flux reversal in both the inner and outer flux paths. The same is true if any two sets of input windings are energized at the same time, counterclockwise MMCs are applied simultaneously to both the inner and outer paths at the location of the one opening, and the flux in the whole core is reversed. When all three sets of windings are energized simultaneously, the inner and outer flux paths are exposed to counterclockwise effective MMKe at the location of each of the three openings, causing flux reversal in both the inner and outer flux paths, and since the output winding 132 the outer Path, an output at terminal 94 is then generated.

F i g. 4 a shows another exemplary embodiment of a core circuit which can carry out the circuit functions required to generate the carry outputs of a full adder. Corresponding parts in the two figures have corresponding reference numbers to facilitate the explanation. The reset and output switching arrangement is the same as in the embodiment of FIG. 4, and the main difference between the two embodiments is that the multipath core 140 of FIG. 4a has only two openings 126 and 128 through which the sets of input windings 98x, 98y and 98c pass. Two windings 98x are provided, each of which is passed through one of the openings so that they surround the outer flux path at a point adjacent to this opening. One winding 98y runs through the opening 126 in such a way that it encompasses the outer flux path at a point adjacent to this opening, and another winding 98y runs through the opening 128 such that it encloses the inner flux path at this opening. The single winding 98c is passed through the opening 126 and only surrounds the inner flux path. As before, the windings are coiled in such a way that when energized they each operate to apply a clockwise MMK to the flux path enclosed at the location of each hole through which they pass. If only one of the excitation winding sets 98x or 98y localized saturation states are openings around both built around, and c in the sole energization of the coil 98 creates a localized saturation state only around the opening 126 around. In any of these three cases, only the magnetic flux in the internal flux path is reversed and no output in winding 132 is indicated. If either of the winding set 98x or 98y and the winding 98 c energized simultaneously effective MMKe be applied to both the inner and the outer flow path at the location of the opening 126 in the counter-clockwise direction, and when the windings 98 x and 98 y are energized simultaneously, counterclockwise MNIKs are applied to the inner and outer paths at port 128. Thus, if any two of the three input winding means are energized at the same time, the magnetic flux is switched all zero and an output is induced in winding 132. When all three input winding means are energized simultaneously, anticlockwise effective MMKs are again applied to the inner and outer flux paths at port 128 and the magnetic flux is switched all around and an output in winding 132 is induced. In any of the operations described above, if two or more windings are energized simultaneously to simultaneously apply anti-clockwise NDvIKs to both flux paths at one of the ports, a counterclockwise MNIK will also be applied to one of the paths at the other port created. However, as mentioned above in connection with the principles underlying the invention, when MMKe is applied in this manner, the magnetic flux is reversed in both the inner and outer flux paths.

Since both cores 96 and 98 in the circuit of FIG. 4 as well as the other exemplary embodiment for the in FIG. 4 a can be brought into various stable states, if the combination of the input pulses is such that an output is generated at the connected output terminal, these none store the result of the binary addition of the input pulse generators 90c, 90y and 90x Information signals. The outputs, which represent the binary addition of the inputs applied during any given time interval, can thus be reproduced later in the same way as with respect to the circuits of FIG. 1 and 3 has been described, namely by energizing the reset winding.

Although, as shown, the sum and carry cores in the circuit of FIG. 4 and also of the other exemplary embodiment of the transfer core from FIG. 4 a are applied individually to the three winding sets surrounding each no, it should be clear that the winding means connected to the same pulse sources can be connected in series. So z. B. the connection of the winding means 98 x to the source 90 x can be omitted and the winding means are connected in series with the winding means 96x, in which case the earth connection of the winding 96x is also omitted. The winding means 96c and 98y may similarly be in series with the winding means 96 c and y are switched 96th

It should be noted that both the embodiment according to FIG. 4 a as well as the similar arrangement according to FIG. 4, which performs the logic necessary to generate the carry outputs, in that it can be referred to as majority logic function circuitry in that it generates an output only when input pulses, r, are simultaneously applied to at least a majority of the input waves.

It should also be noted that the circuit is roughly the same Manner could be actuated if the bias winding 114 is constantly through a, direct current source would be excited.

It should also be noted that the OR-BUT circuit of FIG . 1, which is a two-input circuit #, can be expanded to any number of inputs according to the principles of the invention, the only limitation being the physical size of the core. This is illustrated in the implementation of the core 96 of FIG. 4. If in this arrangement the windings 96c, 96x and 96y only ran through the openings 100, 102 and 104 and the opening 106 and the clock pulse winding 114 were omitted, this arrangement would be an OR-BUT circuit with three inputs, in which a Output at terminal 92 is produced when one of the sets of input windings 90c, 90x or 90y is energized alone, and no output is produced when one or two or more of the winding sets are energized. The explanation for this operation lies in the fact described above that when one of the input winding sets is energized alone, an area of localized saturation is established around one of the openings 100, 102, 104, causing a flux reversal in the internal flux path which has an output on winding 120 induced. If two or more of the input winding sets are energized simultaneously, the pure MMKs applied to the outer flux path at openings 100, 102, 104 are either zero or negative and there is no flux reversal in the portion of the core enclosed by the Wickjung 120. It should also be noted that both in FIG. 4 in a full adder as well as in the modification explained above as an OR-BUT circuit with three inputs, which can be routed to one of the openings through the core 96 so that they enclose either the inner or the outer flux path. Since the output winding 120 in the operations described only senses changes in flux in the inner flux path, this winding can be guided through a corresponding opening in such a way that it only encloses this path.

Claims (2)

Claims: 1. Arrangement for realizing the logical OR-BUT function with the aid of a toroidal core consisting of a material with an almost rectangular hysteresis loop, the main flow path of which is divided into an outer and an inner auxiliary flow path by a number of openings corresponding to the number of input windings, characterized that each of the input windings comprises the outer or inner auxiliary foot path in the region of the opening assigned to it in a first direction and in the region of all other openings in the second direction and receives operand signals of the same strength, each of which is independently capable of the Umzumag gnetisiert inner auxiliary flux path, and that a restoring effect comprises the main flux path in the second direction and an output winding the main flux path or at least the inner auxiliary flux path. 2. Arrangement according to claim 1, characterized in that it has an additional opening (106) in the main flow path, in the area of which the outer one, in addition to the openings (100, 102, 104) assigned to the three operand input windings, in order to realize the sum of three binary operand numbers or inner auxiliary flux path is encompassed by all operand input windings in the first direction and by a bias winding (114) in the second direction, and that the bias winding generates such a flow that it can cancel the effect of all but one operand input windings. 3. Arrangement according to claim 2, characterized in that a further toroidal core (98) of the same type is provided for the formation of the transfers occurring when the sum of three binary operand digits is realized, the outer and inner auxiliary flow path of which is in the area of the openings (126 , 128, 130) is encompassed by one input winding each of one of the possible operand input winding pairs in the same direction and whose output winding is only linked to the external auxiliary flux path. 4. Arrangement according to claim 3, characterized in that instead of three openings in the main foot path for the three possible operand input winding pairs only two openings (126, 128) are provided that in the area of one opening the outer and inner auxiliary flow path of each one input winding of an operand input winding pair is included and that the same operand input winding pair in the region of the second opening jointly comprises the outer auxiliary flux path, while the inner auxiliary flux path is surrounded by the third operand input winding penetrating this opening. Older patents considered: German Patent No. 1029 414.