DE1943287A1 - Magnetizing district propagation arrangement - Google Patents

Description

TVESTERlT ELECTRIC COMPANY, INC. >. A. J. Perneski 3

NEW YORK, N.Y. 10007, USA

Magnetizing district propagation arrangement

The invention relates to a magnetization Ward reproduction arrangement with a sheet of magnetic material can be moved in which magnetization-walled areas, a source of magnetization of areas in the sheet and the sheet accompanying reproduction device.

A single-walled magnetization area is a magnetization area which is surrounded by a single, self-contained area wall which defines the boundary between the magnetization area encompassed in this way and the surrounding areas of the opposite magnetization polarity. The delimitation of such a single-walled area is independent of the boundaries of the sheet in whose plane the area is moved; a two-dimensional movement of the area in the sheet is therefore possible. In The Bell System Technical Journal, Volume XLVI, No. 8, October 1967, pages 1901 ff., A shift register operation is explained in which single-walled regions in sheets of rare earth ortho rites are used.

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Numerous reproductive methods for moving single-walled districts have been developed. A typical magnetic sheet "" in which single-walled domains can be moved is characterized by a preferred direction for the magnetization which is out of the plane of the sheet. For the following description it is assumed as a convention that the magnetization of a single-walled region runs in the positive direction along an axis running perpendicular to the plane of the sheet, while the magnetization of the rest of the sheet is oriented in the negative direction along this axis. Accordingly, a single-walled district can be represented as a plus sign enclosed by a circle, the circle representing the district wall. A discrete conductor in the form of a circular loop on the surface of the sheet creates a field which is positive or negative along that axis, depending on the sign of the current flowing in the loop. Such a loop, which is in a slightly offset position with respect to a district, generates an attractive (positive) field when it is pulsed. The district "sees" this field (actually a field gradient) and moves in response to a position of minimum energy. By pulsing consecutively offset loops, the area can be moved to any position within the sheet.

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These propagation loops allow logic operations between neighboring districts, using interaction effects between specific, LOiG selected districts. However, the loop ^{geometry of the conductors: 1} requires a greater minimum distance than would be required if the constraint of discrete propagation conductors were eliminated.

There are also methods of maintaining a reproduction of single-volume districts without discrete propagation has been developed. A covering of a magnetically soft Materials, e.g. 3. Pernalloy, defines a reproductive channel for districts in a suitable magnetic Sheet. The topping is a pattern in the form of successive ones Rod and T-links that guide a moving and repeating magnetic pole configuration, which hold an attraction for the districts. A magnetic field that rotates in the plane of the sheet (transversely) causes the pole pattern to change in such a way that ee districts be attracted from entrance to exit positions. Although such an arrangement is easier to manufacture than an arrangement that uses discrete port planters requires and enables increased fan density they are unable to perform all of the LC-ik functions, the rr.it -.ion discrete ladders reachable siiK ,.

lahlreicli. LO ^ -M-'Ciaisse are aus-erroti ^ et v.-orden, ilt: to combine the advantages of both arrangements. For example allows a single lei ~ 3r: * ür ^ econ Fort-

¹ Π P 8 '. 0/1 5 3 5

BAi ORlQiNAL

planting channel together with a Permalloy covering prescribed geometry certain logic operations but requires highly non-discrete propagation ladder.

Regardless of the mode of reproduction and the associated logical possibilities it is important that districts in the magnetic sheet for propagation can be introduced controllably. However, a typical sheet of magnetic material requires that is suitable for the propagation of single-walled regions and is magnetically saturated in the negative direction, Thousands of oersteds to create a single walled district. On the other hand, movement requires one District only a few Oersted.

In order to avoid excessive demand for power, methods have been devised to isolate a district from a district source at low levels of power comparable to those required for district propagation, that is, in the fourth of some Oersted, Belgian patent 703 811 describes such an arrangement in which an area of positive magnetization is defined by a current in a conductor which designates the area. A hairpin-shaped input conductor which overlaps this area can be used to generate a field to separate part of the area in response to an input pulse of the appropriate polarity. 0 09810/1635

The problem of generating single-walled areas with relatively low field strengths as well as with missing ones Entrance or area designating conductors is according to the invention for a magnetization region propagation arrangement of the type described in the introduction in that the reproductive device a field source for generating magnetic fields in successively different orientations in the plane of the sheet, as well as at least one magnetic layer on the sheet, which is on the Magnetic fields are effective in causing moving magnetic pole patterns to pull domains of magnetization away from the source in a first direction and that the source has an input magnetic layer responsive to the magnetic fields, simultaneously is effective to pull domains of magnetization away from the first direction.

The invention is explained below with reference to the exemplary embodiments shown in the drawing; show it:

Fig. 1 is a schematic representation of a propagation arrangement for single-walled districts with an entrance designed according to the invention,

Fig. 2 to 8 schematic partial views of the

Input part of the arrangement according to FIG. 1 for the representation of the magnetic states 009810/1636

the same to a rotating cross field during operation as well as the orientations the field for generating these states,

Fig. 9 is a schematic representation of a multiple

channel district propagation arrangement with a plurality of inlet arrangements and

10 to 15 are schematic partial views of alternative input arrangements.

In one embodiment of the invention, a new single walled district is created when an existing district is stretched and then separated into two districts in response to a rotating transverse field by the controlled movement of an additional district, through one end of that district, or through a field , which is supplied by a suitably arranged Permalloy lining. In one embodiment , a single-walled district propagation channel in a magnetic sheet is defined by rod-shaped and T-shaped permalloy linings.

A permalloy disk with a single-walled area permanently assigned to it shows pole patterns that point to a Rotating field in the plane of the sheet move around in a first direction. The bar / T pattern is of a geometry to produce poles which extend in a second direction, likewise on such a direction

Rotating field towards, move away from the disc. A district, 0 09810/1535

of the attractive poles along the circumference of the Disk folds, v / ird along both the rod / T-arrangement as well as the S ehe.Ib emn fang ε stretched until the end of the area that is stretched around the disc practically describes a full circle. At this In this place, the district is divided into two districts, one of which follows the rod / T arrangement and the other runs around the disc and again, as before, is stretched.

1 shows a district propagation arrangement 10 with a sheet 1, in which single-walled districts can be propagated.

An Ilehrzahl channels for district propagation; are defined by rod-shaped and T-shaped coverings 13 and 14, which run between input and output positions. The domains are moved by following the attractive pole concentration points that are generated in the coverings in response to a rotating magnetic oil field. The rotating field source is indicated schematically by the circuit block 1b and can have two mutually perpendicular groups of coils, which are arranged along the dashed lines B and B ¹ and with sine waves or pulses in the correct mutual: -; Phase relationship: are applied under the control of the control circuit 17. The entrance to the lancing canal in Fig. Lines gels ^ e.ie has a Femalloy disk 15. Sin District D is 0098 10/1535

provided that it is permanently assigned to the disc 15 and around the circumference of the same on the rotating cross field appealing, moved around. A demagnetized sheet which is exposed to a field of sign suspended to contract districts, has a number of districts for this purpose.

FIGS. 2 to 8 show the magnetic states of the input while the transverse field passes through a single Cycle through. Fig. 2 shows the state when the transverse field H the - as an arbitrary starting orientation assumed - direction to the left, as shown by the arrow in FIG. 2. Positive Magnetic poles therefore accumulate in the left part of the disk 15, and the negative poles in the right part. For one Disc on top of sheet 11 draw positive poles according to the agreement made a district. If the disk is on the underside of the sheet 11, then negative poles pull one District. The same goes for the bar / T pattern, which is on the same or opposite side of the Sheet 11 as the disc may be. District D is shown as being below the positive poles. Fig. 3 shows the transverse field directed downwards. The resulting magnetic pole concentration is then like through the plus and minus signs are shown. The district moves accordingly into the lower part of the disk 15th

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Pig. 4 shows the direction of the field going to the right. The strongest positive pole is located now at the right outer end of the projection 16 of the disk 15. However, there are more positive ones Pole on the right edge of the disc. The district then takes the position and location shown.

In Fig. 5 the transverse field is directed upwards. If the field is in this orientation, then Both the next rod 13 and the disk 15 have a strong pole distribution, which leads to the attraction of the District D leads. As a result, the district is stretched. This delming continues when the field changes continues to rotate in the counterclockwise direction, as shown in FIGS. The special one The contour of the district shown in these figures results from the repulsive effect of the negative poles on disk 15. Fig. 7 shows the shape of the district at the moment in which the District will split into two districts.

FIG. 8 shows the initial region in an advanced position on a T-pavement member 12 while region D 'is in the position shown for region D in FIG. Of course, the names of the districts are arbitrary and the mechanism of the district division is not yet fully understood. It is clearly observed, however, that a district remains assigned to disk 15 and from 0098 10/1535

this one more district on a rotating one Cross field produces v / ir-d.

The same transverse field also provides the moving pole patterns that attract the (created) districts along the reproductive canal. A propagation along the channel but requires typically a field of 10 oersteds or more, while a district input, as is illustrated in Fig. 2 to 8, ψ typischerweice requires more than 20 oersted.

The difference in the required amplitudes of the uuerfeldes for input and propagation provides the mechanism for the selective introduction of districts. Therefore only the District propagation in a field of about 10 Oersted continues, unless a district that represents a binary one, for example, is desired. To introduce the desired area, the amplitude of the rotating field is then set to around 20 oersteds increased for the next cycle. The amplitude can then be reduced again to save power will.

The transverse field can of course be changed appropriately, for example by a change in the mutual phase relationship of the Source 16 of Figure 1 generated sine waves or by an overlap of pulses if pulse methods can be applied. 009810/1535

The amplitude of the rotating field need not be high during the gan /.- η cycle during which the introduction of a district is desired. A region can be stretched Y-is to around the point shown in FIG. 6 with a comparatively low transverse field amplitude. From the point shown in FIG. 6, -nn the higher amplitude is required. Accordingly, the higher amplitude is ideally necessary in a quarter of the cycle. Source 16 in FIG. 1 is believed to contain the appropriate apparatus for operation in this manner under the control of a control circuit 17 connected to source 16.

In the foregoing is the selective introduction of a single-walled district for synchronous longitudinal movement of a reproductive canal has been explained. It is also evident that the presence and absence of a district can be taken at a position under consideration to identify a binary one or display a binary zero. An information-representative pattern of such areas becomes a starting position in the area shown in Fig. 8, the attractive pole patterns along the reproductive canal following.

The starting position, which is shown in Fig. 1, is defined by a conductor loop 19, which is a

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Terminal of the channel includes. The conductor 19 lies between an interrogation pulse source 20 and earth. A conductor loop 21, which also surrounds the same terminal, lies between the consumer and earth. Each time a rotation of the transverse field generates the magnetization state of FIG. 3, the source 20 pulses the conductor 19 to generate a field which collapses the regions in the terminal location. If there is an area in the terminal when the collapse field is applied, a pulse is generated in ψ conductor 21 for detection by circuit 22. The source 20 and the circuit 22 are connected to the control circuit 17 for synchronization and control purposes.

For the various power sources provided here and circuits can use any devices to work the procedure described here able to sine.

The selective imports of a monovalent district in a. Fcrtpfie-i'-zungckanal (shift register channel) in the absence of large conductors at the entrance is now described ^T -; orc.G: i. The introduction of a district into a selected one of many channels can also be achieved in accordance with the present invention.

The geometry of its pavement determines the amplitude of the rotating transverse field that the districts like

described erzeurt. The geometries for the ΤΑη-: ετ ^ -ε ~ 0098 10/153 5

BAP

η.

lining can be designed so that the amplitude of the '-iuerf sides then determines the channel in which a district will be introduced.

Fig. 9 shows a sheet 1'lü in which a Ketrzahl Propagation channels a, b, ... η, are defined by an alternative rod / T-pad arrangement. Each of these Channels has an entrance layer of different geometry on the one opposite to the rod / T-3 layers Side of sheet 110, each entrance covering works essentially like this in conjunction has been explained with FIGS. 2 to 8, however, the exact shape of the expanding region on a case-by-case basis Case may be different.

The entrance pavement for the channel is rectangular in shape and approximately 3.2 microns thick. A region that moves along the circumference of the pavement in response to a rotating transverse field is subdivided as described if the amplitude of the transverse field is increased to at least about 20 oersted.The entrance surface to channel b, on the other hand, is 1.3 micrometers (13,000 angstroms ) thick washer. This surface creates districts as described when the cross-field is increased to 50 Oersted. The entrance surface of the channel η has the shape of a cross, is 5,800 angstroms thick and works at about 40 oersteds. It is then evident that the introduction of a region into channels a, b and η from a suitably timed change from about 7 to 20, 40 and 50 respectively persted _Q in, the amplitude of the cross-field

for the selective introduction of the district depends.

In fact, a district in a selected channel finds itself across a field area instead of. Through careful selection of the entrance surface geometry different combinations of channels can be selected for a district subdivision, if a field is provided in an appropriate area for each of the selected channels will.

"As explained above, single-walled districts are able to perform movements in two dimensions. The horizontal channels of FIG. 9 can therefore be oriented vertically with similar results. In addition, horizontal and vertical channels can be realized with a generalized covering pattern, which allows for district movement in the X and Y directions. Districts can be introduced at desired locations in such an arrangement for movement to selected channels.

It is further possible according to the invention to divide districts in more than one channel from a given one Entrance covering to be introduced. This possibility arises from the fact that the amplitude of the transverse field in the ideal case only during the fourth part of a Cycle needs to be increased. During various quarter cycles this amplitude can be increased to

Districts, as described, in. Accordingly oriented

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IS

Lead channels in j "

The I «'i; 3. 10 to 13 show an example of an execution horn in which joysticks are selectively introduced into a number of channels C1, C2 ... The magnetization region confi-ration int for each channel is similar to that in the fi £. 2 to c shown,. "In district v; is generated in each Kanrl depending on the amplitude of the rotating field or not, v; hen the field during the last quarter uc £.". "" IluG ideally oriented ict, b; vcr eic - Orientation runs in the direction of the selected channel.

The distance a ε Hinpanjebelacec together with ""; steered, iin ^ litudcriänderunren of a rotating Γ-uerfeldes supplies a combination of Vei ^ -. 'iiiillchunvc-Mö ^ licii-I: ^ri ite: i, which has a considerable flo;: iu.LIit ^ t at the. - "irkcer :: '^ Uli;" for transportation; in aur ^ ev / ΓΌ: *; ". * -."! -n :: un "^ channels with missing :: ^ zxZ ^ s. sl- ^ ern

The ^ rfin;: '; nr is on the basis of one around si'? ".: herself: swiveled." E :: irkoi? :: \ vj ; r ^ euf; "unr a Teilurv / eriäutc-rt vrordon. 2ε s.". ο. "; Y-? rs" »3hen., da .: ^ en · -; 3o:.: Än ", \: er.n them like that

a 7cld en

cer i? iiu :: -, .jr-II ". I ^ r.ss ?? _eld can also au-"? change; :: ..e "::. A'elic-fort wei";. - :: i, .'example times, Fi _L; . 7 ■ :: '- · .: _v _; -: -. V-richelt an ^ edeu "L6"; c £ r. ^ Cliteck 15 ·, which has a rsrr.r.ir.cy-Bxab on cer ge ^ iiu :: 'den rod / T-Ancrdnuii'cn ~ e .-: "eir'ilj-e rl iahenden page c:? lilattss 11 represents.

-e- StrJ · Γ ' hct PlusDole to his:. · lower part. Da ·: 0 9 8 1'ü / 15 3 5

however, this rod lies on the back of the sheet 11, positive poles repel the districts, and a This creates field to support the district collapse.

Its arrangement of three parallel bars (Fig. 14) can also be used to create areas in practically the same way, provided that the arrangement creates the appropriately oriented pole configurations and thus fields when a transverse field is applied. In Fig. 14, the rods 15 ″ are made of a material with a relatively low coercive force, while the rod 15 'is made of a material of high coercive force. A region D, which is in the position shown in FIG. 15, grows into the position corresponding to FIG. 14, specifically in response to a 'field H1 of an amplitude which is not sufficient to switch over the rod 15', but is sufficient, to generate the pole configuration shown. In Fig. 15, the amplitude of this field is then ernöht on H2 'above the necessary) for switching the rod 15 value. As a result, the district is divided into two districts, D and D1, based on this new pole configuration.

Such fields are generated in a way that / with cover the requirements of a rotating cross-field effective to that effect on District D. to let the rod 15 "oscillate up and down between successive divisions during the District D1 follows an assigned bar / T arrangement to a starting position.

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Claims (3)

Claims 1. Magnetization district propagation arrangement with
a sheet of magnetic material in which
single-walled magnetization domains can be moved, a source of magnetization domains in the sheet
and a propagation device attached to the leaf, characterized in that the propagation device (13, 14, 16, 17, B, B ') is a field source
(ΐο, Β, Β ¹ ) for generating magnetic fields in successive different orientations in the plane of the sheet (11), as well as at least one
magnetic layer (13, 14) on the sheet (11), the
is effective to the effect of the magnetic fields, moving magnetic pole patterns for pulling away magnetization areas (D) from the source (15) in a first
Direction and that the source has an input magnetic layer (15) which, in response to the magnetic fields, is simultaneously effective to
Pulling domains of magnetization away from the first direction. 2. Arrangement according to claim 1, characterized in that the magnetic fields are rotating transverse fields and that the Singangs magnetic layer (15) generates pole patterns that move along their circumference, responding to the transverse fields. 009810/1535 3. Arrangement according to claim 2, characterized in that the source is one of the input magnetic layer (15) assigned single-walled magnetization district (D) and, in response to the concurrent Attraction of the magnetic pole pattern in the magnetic layer (13, 14) and the input magnetic layer is gas expandable. 4 «Arrangement according to one of claims 1 to 3, characterized in that the field source (16, 3, B ¹ ) can be controlled to vary the intensity of the magnetic fields. 0098 10/1535 Blank page