DE1921063U - MAGNETIC LOGICAL ELEMENT. - Google Patents

Description

P./L342 793-17.65

Dipl.-Ing. Egon Prince,

Dr. Gertrud Hauser ** °° Munich godmother *, the - L JuJl «65

. ^>. «· Ti · Ernsbergersirasse vt

ipl.-lng. Gottfried Leiser

Patent attorneys Telegrams ι Labyrinth Munich

Telephone: 83 15 10 Postal check account ι Munich 117078

P 21 4-74- / 21 a Gbm

The Plessey Company Limited

Our reference: P 1614

Magnetic logical element

The innovation relates to a magnetic logic element with a body having at least two holes Made of magnetic material with a rectangular hysteresis loop.

Such cores are known. They are used to build up logical Elements that are used as switching (gate or information storage devices can be used and their mode of operation is based on the fact that a closed magnetic Circle is set to states that result from magnetic saturation in one sense or another. The rectangular hysteresis loop has the effect that the remanence flux that prevails after the setting becomes the saturation flux essentially the same. -

The task underlying the innovation is to create a facility of this type that works for you

Hi / sto operation

High speed operation as both a switching device and an information storage device suitable, in which the stored information is retained when reading.

The above aim is achieved according to the innovation by means of a core of the type identified at the outset, the characterized in that the body is provided with at least one set of three holes, wherein two of these holes each have a larger closed flow path in the core, while the third hole is in part of the core, the two larger ones Flow paths is common, and wherein the holes are sized and arranged such that after setting of saturation flows in the larger flow paths - depending on the relative direction of these saturation flows, a smaller one closed flow path in the common part of the core surrounding the third hole over at least a part its length is either unsaturated or saturated.

The innovation also creates one using the innovation according to the invention Core composed magnetic logical element. This is characterized by the fact that for each Hole in the core there is at least one winding penetrating the hole. The term "winding" is intended here both a single turn winding and

its equivalent, a straight line, through a hole in that Include conductor passing through the core.

In its simplest form, according to the innovation Logical element by means of metered holes in a core made of magnetic material with a rectangular hysteresis loop realize, one of which is "considerably smaller than the" other two and is located between them ". A query winding and an output winding are preferably threaded through the smaller hole, and that created in this way between the two windings Coupling is a puncture of the magnetic ■ state it is the material that forms the smaller plus path that runs around the opening. The facility works thus essentially as a switch that changes the coupling between the interrogation winding and the output winding, according to the conditions set in the device by the directions of those set in the outer loops Saturation flows can be set. The previous ones and other:. Features of the innovation are given below explained in more detail on the basis of various exemplary embodiments of logical elements according to the innovation, which are shown in the drawing. In the drawing show:

Fig.1 shows the shape and proportions of a core for a simple embodiment of an innovation-compliant logical element,

fig.2

Pig.2 the core of Fig.1 with its associated windings along with; the flow picture which, when the nucleus is set in one of its possible states, is in sets the core, -.

Fig.3 is a view similar to Fig.2 showing the core in shows his other state

4 shows the core in the state according to FIG. 3, during a Reading,

5, 6, and 7 modified embodiments of the core for use in differently designed facilities and

8 shows the core-winding arrangement for a further embodiment. form of establishment.

The core shown in Figure 1 for a logical element consists of a body made of magnetic material 1o with a rectangular hysteresis loop (e.g. a ferrite material),

and
in which three holes 11, 12, / 13 are formed. The core 10 has a uniform thickness throughout. The three holes are arranged one behind the other, and the two holes 11 and 12 have the same radius, while the middle hole 13 has a significantly smaller radius and is located in the middle between the outer holes 11 and 12. The material surrounding the outer holes 11 and 12 forms two major flow paths of constant width * W. The core is designed so that the four surrounding the central hole 13

! Bearing-

Partial circles also have the width ¥, as can be seen in Pig.1. The smaller hole 13 surrounds a smaller one Core flow path whose width is smaller than W and whose position and puncture can be seen from the following description result:

Pig.2 shows the core with the windings necessary for its puncture as a simple gate or storage device. According to Pig.2, the core has the following windings: a "0" control winding 14, which is threaded through the larger holes 11 and 12 in opposite directions ^: an "I" control winding 15? which is threaded through the holes 11 and 12 in the same direction, and an interrogation winding 16 and an output winding 17? both of which are threaded through the central hole 13.

To set the device shown in Pig.2 in its "0", "locked" or "gate-closed" state, ^{a current pulse is sent through the "O tf} control winding 14" which is sufficient for the two larger magnetic paths that are closed After the end of the drive pulse, the core remains in the state shown in Pig.2, in which independent closed flux loops are present in the two larger positive paths, due to the rectangular hysteresis loop of the same material

is

-, 6 - ■■ '. "- ■■■ :.

this flow is essentially equal to the saturation flow. The geometry of the core is such that the material of the Kernes, which the "two larger river paths have in common, and in which the smaller hole 13 ″ is located, is essentially fully saturated. If a small reading pulse is now applied to the reading winding 16, the The flux state of the parts of the magnetic circuit which form the smaller flux path surrounding the hole 13 does not change.

the, and / consequently, will not produce a significant output signal the output winding 1? submitted ·

3 shows the state of the core after setting in the "conductive," 1 "or" gate open state "by means of a through the "1" -adjusting conductor 15 sent through current pulse. It turns out that the course of the river in the middle part of the core is divided and forms a loop, which surrounds all three holes. From the core geometry it follows that the material that forms the smaller flow path that the Center hole 13 surrounds, .flussfrei and therefore in one neutral magnetic state. If the core is queried by means of an impulse sent to the reading winding 16 is applied and has a value such that the flux it induces in the smaller flux path, the Does not interfere with the flow of the flow in the larger flow paths, then the flow in the smaller flow path can follow the interrogation pulse, and therefore an output signal is generated in winding 17,

V "/

It should be noted that the query is provided that the amplitude of the interrogation signal is appropriately limited, the condition of the core as a whole is not compromised and consequently a non-destructive reading of the condition the information represented by the core is available. The interrogation signal need not be an impulse. It is also suitable an oscillating current of some suitable frequency. On the part the interrogation circuit, the circuit functions as a switch that turns the loop between the interrogation or reading winding and the output winding closes when it is set to the "1" state (Fig. 3 and 4) and opens the circuit, when it is in the "0" state.

The duration of the actuating pulses is not essential, provided that the Sire Amplitude is at least so large that both Main flow paths are driven into saturation. Since the response speed of the two main flow paths to the applied Field is proportional, you can go through. Use proportionately large actuating impulses that are sufficient to drive the paths far into saturation, a rapid operation of the Achieve establishment. In this regard, the device shown in the drawing brings a considerable advance compared to similar institutions, their correct functioning depends on the precise quantitative setting of the size the actuating impulses depends.

As an example, let it be stated that a facility which the

un-

had approximate proportions that are in the. ; ". Fig.1-4
of the drawing, and was made from a magnesium / manganese ferrite with a rectangular hysteresis loop and a coercive force of 2 Oersteds by applying a
Field of approximately 8.6 oersted was set on each flow path over a period of 0.1 microseconds. The distinction between the conductive state and the blocked state for an interrogation signal of 100 KHz "coupled between the winding 16 and the winding 17 was approximately 1 o: 1.

FIG. 5 of the drawing shows a modified core 20 which can be used in the configuration of the logic element shown in FIGS. 1 to 4. This core differs from that shown in Fig.1 in that the central part which receives the small hole 15 is enlarged to essentially twice the original width and that two additional
Holes 21 are provided leading from the outer edge of the core
have a distance corresponding to the common width W of the outer pitch circles. The function of the holes 21 that are not with
Windings of any kind are equipped, consists in delimiting the outer flux path for the "1" state of the core more precisely. This allows an accurate estimate of the dimensions of the smaller flux path around hole 13 and thus more precise control of the currents which can be controlled through the readout winding and output winding.

The proportions shown in Fig. 1 and 5 are suitable for single

element-

element facilities and are not very critical. Form ; Λ; the core can be varied within wide limits without noticeably affecting the operation of the device » For example, Figures 6 and 7 show core shapes in which the Holes 22, 23 defining the main flow paths have different dimensions. The only essential requirement that must be observed is that the small Opening 24- surrounding flow path for the reading winding and the Exit swissklung should be smaller than each of the river paths, that run around the larger holes. \

A disadvantage of the arrangement described so far is that that in the blocked state of the device a certain residual coupling between the reading winding 16 and the output winding 17 is present. This coupling is compared with of those who use the surrounding magnetic circuit occurs, small, but it can nevertheless interfere with the differentiation of the device under certain circumstances. This disadvantage becomes - at the expense of a slightly larger one Complexity due to the arrangement shown in Figure 8 of the drawing overcome. Here, too, it is a question of one simple bi-stable memory or a peeling device, whereby the ferrite core 3o but with three larger holes 31, 32 and 33 and with two larger holes between each adjacent one lying smaller holes 34 · and 35 is equipped. The two Adjustments are threaded through all three larger openings. The "O" position winding 36 runs through the three holes

-holes alternately in opposite directions, while the "!" - adjusting conductor 37 & i ^e first "penetrates two holes 31 and 32 in the same direction. The difference between the" (! "- state and the" 1 "state of the core is thus limited to the footpath surrounding the larger opening 31 and the associated smaller opening 34-, while the plus path running around the other smaller opening 35 remains in its saturated state at all times. The reading winding 38 runs through the two smaller holes 34- and 35 in opposite directions , while the output winding 3o passes through the two smaller holes in the same direction.

The three holes 31? 32 and 34- form a logical device, which functions exactly as previously described with reference to FIGS. 1 to 4-, while the three holes 32, 33 and 35 form a dummy or balancing device for eliminating the residual coupling. -

When the device is in its locked or "O ^u" state and a read pulse is applied to the read winding 38, the holes 34 and 35 have the same size but oppositely directed couplings to the output conductor 39 in this state, the ^T ated zero, and there is the effect of a Selbstlcomp ens ation before. located at the device, there is in its "1" state, the emitted toward a Ableseimpuls

bene output signal from the normal magnetically coupled Output signal minus the small residual coupling in the compensation hole 55 · This small reduction in the output signal is usually acceptable as the effective elimination the coupling in the locked state gives a 'considerable overall improvement in the distinction.

The institutions benchmarked so far are obviously suitable for use in logic circuits and data processing devices as switches, gates or bistable devices. The physical design is not limited to that shown in the drawing. In particular in cases where a large number of facilities are required, one can benefit from this in terms of economy Space and material requirements arrive that one extends the principle according to Fig. 8 and each of the larger holes in the core assigns to neighboring logical elements, i.e. between neighboring dividing logical elements. A storage device exhibiting this principle would therefore have one for each stored message unit for receiving one require a large and a small hole sufficient core material body.

Protection claims

Claims (2)

J93-3.7.65 Dipl.-Ing. Egon Prince Dr. Gertrud Hauser βοοο Munich-Pa.ing, - 2nd J »'«; pl.-lng. Gottfried Leiser EmSber8er5traSSe η Patent Attorneys Telegrams ι Labyrinth Some Phone: 83 15 10 Postal Check Account ι Munich 117078 P 21 47 4/21 a Gbm The Plessey Company Limited Our reference: P 1614 Claims for protection 1. Core for a magnetic logical element with a at least two holes having bodies made of magnetic material of a rectangular hysteresis loop, characterized in that, that the body (1o) is equipped with at least one set of three holes (11, 12, 13), two (11, 12) each of these holes has a larger closed footpath in the core, while the third hole (15) is in part of the core, the two major flow paths is common, and wherein the holes (11, 12, 13) are dimensioned and arranged such that after setting of Saturation flows in the larger flow paths depending on the relative direction of these saturation flows a smaller closed one Plus path in the common part of the core surrounding the third hole (13) over at least part of it Length is either unsaturated or saturated. 2. Magnetic logic element, characterized by a core according to claim 1 and for each hole (11, 12, 13) in the core at least one winding (14, 15, 16) penetrating the hole. Hi / sto