DE2451535A1 - CIRCUIT FOR THE TRANSFER OF MAGNETIC DOMAINS IN TWO DIRECTIONS - Google Patents

Description

? Rj> pfW -. / .. v '-: i 29/31 _{n 1ί;} , _η9 , 2451535

TME = Oi--. "H ^ N 82 37 P 164024

^lHLiU '·· > EM-2018

SPERRY RAND CORPORATION, New York, N.Y./U. S.A.

Circuit for the transmission of magnetic domains in two directions

The invention relates to two separate magnetic elements with a common conductor in the coupling section of a transmission circuit.

In United States Patent No. 3 "714.639p-st an arrangement for transmission described, the main shortcoming of which is that the transmission circuit between the metallic conductor in the form of a loop and one in the immediate vicinity, magnetically soft element in the shape of the dollar symbol, which is provided in the transmission area, must be provided with an insulation. This requirement is because the element in the shape of the dollar symbol would otherwise short-circuit the metal loop. During production, such a necessary insulation is linked to an additional work step that costs time and is expensive is, as well as the efforts to make a so-called "bladder accumulator" a common product.

The invention is therefore based on the object one in two opposite Directional transmission link between a larger and smaller loop of a data processing system indicate that is easy and economical to produce.

According to the invention, an adaptable arrangement is provided, from which the data in a data processing device is easily transferred from its large loop to its smaller loop can.

509832/0659

The invention is based on the use of a conductive metal coating, the see immediately above two separate, differing magnetic Elements in a magnetic domain applying transmission circuit is arranged. This arrangement with a direct contact is made possible by the fact that the metal coating is in contact with the relevant magnetic elements at a single point, see above that an electrical short-circuit of the conductor with the help of the current-carrying magnetic circuit is excluded "

An embodiment of the invention is shown in the drawing and is explained in more detail below. Show it

Figure 1 shows the entire data processing arrangement in which the invention is applied,

FIG. 2 shows the circuit for transmitting information between the larger and smaller loops of a data processing unit systems in both directions and

FIG. 3 shows a section to illustrate the effect of the field gradient.

FIG. 1 shows the overall structure of an organized mass storage device 10 in which the invention is used. In its preferred embodiment, the mass storage device 10 is thin Platelets of a monocrystalline Orthoferrite or garnet formed or dejected as a film. During the preparation of the latter, the precipitation is so influenced that the easy Axis comes to lie perpendicular to the surface of the plate. Then the plate is subjected to a bias magnetic field perpendicular to the surface Hn subject to a closed one in the film Wall has a stabilizing effect in such a way that cylindrical domains with closed walls are formed. Through the absence or presence a domain is represented by a binary zero or one.

509832/0659

The mass storage 10 contains a larger loop 12 for binary information in which the data circulate one after the other; with others In words, the loop 12 is an endless tape or shift register with circulating binary data stored at the location of a Generator 14 enter. Depending on your request, the information will be read out from the larger loop 12 at a D station 16.

For example, the larger loop 12 at a point in time the bit composition 11011 may be present from the bits 1 are reproduced by the domains next to smaller loops A, B, D and E, while the bit 0 by the lack of a Domain opposite a smaller loop C is represented. To facilitate data storage in the smaller loops and the In order to be able to better handle data in the larger loop, bit aggregation must be carried out to and from the larger loop 12 of the mass storage device 10 are transmitted. The data can e.g. B. fixed values, such as the sine of an angle or for the calculation of a programming Subroutine that is to be temporarily stored in the smaller loops. For this reason, the Data simply from the larger loop 12 to the smaller loops A to E or vice versa can be transmitted.

In particular, the invention is directed to the area enclosed by dashed lines, each of which has a section of the larger and smaller loop 12 and D in which there is a transfer of a magnetic domain in the form of a binary one. Although not explained, the remaining information is transferred in a similar way.

In connection with the JTigur 2, the structure and the way it works the bi-directional transmission circuit with magnetic Domains explained, in which a section of the larger loop 12 consists of several soft magnetic T-pieces A, C and F and soft-

509832/0659

magnetic rods B and G is made. The smaller loop D is made up of magnetic elements I, J and H. Soft magnetic Y elements D and E form the coupling parts between the larger one Loop 12 and the smaller loop D. The T-pieces,! Elements and rods of the larger and smaller loops are made in the given case by the fact that the plate 10 with thin coverings is provided in the form of Permalloy films.

A conductive metal coating β is arranged over the permalloy films, the field gradient of which, together with a magnetic field H _R running in its plane, enables the domains to be transferred from the larger loop to the smaller one. It consists, for example, of gold which is deposited electrically on the permalloy films and the wafer 10. In the arrangement of the metal covering β, with regard to the pattern of the permalloy films, it should be noted that the metal covering may only touch the Y-elements provided as coupling parts or the other thin coverings made of permalloy films at one point. It is significant that a short circuit across the pattern of the permalloy films, which is a current-carrying element, to the metal coating β cannot occur. This fact is significant in that when the conductive metal coating is made of gold, the latter can be applied directly over the pattern (without the inclusion of an insulating separating layer).

It is now assumed that a binary one is to be transmitted from the larger loop 12 to the smaller loop D as a magnetic domain. Normally, a domain propagation with the cooperation of a counterclockwise rotating magnetic field H _R in the plane of the plate is used during access. The field that works in conjunction with the pattern of the soft magnetic tees and vertical bars causes the magnetic domains to propagate

the
in Figure 2 from right to left, / so from the T-piece A over the rod B, the T-piece C, the Y-elements D and E, the T-piece F to the

509832/0659

Bar G runs when the information is alone in the larger loop 12 is transmitted, of which the films listed are only a section form.

In detail, this transfer now takes place as follows. The magnetic field rotating in the plane is built up by two orthogonally arranged magnetic coils (not shown), which are driven by sinusoidal currents of the same size but out of phase. In the plane in to 36O ⁰ rotating magnetic field which rotates in the illustrated here Äusführungsform counterclockwise formed.

A magnetic domain is located at a point 4 of the T-piece A in the larger loop 12, where the numbers of the topping are the digits indicate where positive poles arise when the vector of the rotating magnetic field is in the upper left corner of the figure 2 compass position shown. If, when the magnetic field revolves counterclockwise, the vector is position 1 of the compass reached, the magnetic polarity of a point 1 of the T-piece A is positive. In other words, they become free from the magnetic field Poles formed at the junction of the T-piece, which are thus called Digit 1 is positive. Assuming the domain is a negative magnetic charge, it will shift from site 4 to site 1. As soon as the vector of the magnetic field reaches position 2 of the compass, a point 2 of the T-piece A is positively charged and to this the domain transferred. When the rotating magnetic field on the compass changes from position 2 to position 3, the moves Domain from site 2 to site 3 on rod B. Upon reaching of positions 4, 1 and 2 in this chronological sequence, positions 4, 1 and 2 of the T-piece C become positive from the rotating magnetic field charged, and the magnetic domain continues its shift to the left, ending at point 2.

609832/0659

While the magnetic field continues its counterclockwise rotation in the plane, position 3 of the! Element D between positions 2 and 3 of the compass becomes positive. This can be seen in the lower section of the Y-element D, which approximates a right-angled section. The negatively charged Domäne.wandert therefore, the T-piece C to point 3 of the Y element is from the point D. 2 Similarly, a point Y 3+ of the element E _s positive if the magnetic field in the vector representation between the positions 3 and k , the domain migrating from site 3- to site 3+, since the latter is more positive than the former. From there, the displacement of the domain continues via the positions 4> 1 and 2 of the T-piece F to the left to a position 3 of the vertical rod G.

So from the previous description you can learn how a magnetic one Domain the larger loop 12 with the participation of a pattern of soft magnetic coatings under the control of a magnetic field runs through in the same plane.

Assuming the state according to FIG. 1, the data should in the form of a bit composition 11011, which is determined by the presence or absence magnetic domains are reproduced, are transferred to the smaller loops A to E. In the description that follows it is made clear how a single bit stored in the larger loop 12 is brought into the smaller loop D. will.

Such a transfer takes place with the cooperation of the in the plane rotating magnetic field and a current I in the conductive metal coating ß with the help of the coupling Y element D instead. In the period in which the current I flows through the metal coating ß, the vector of the rotating magnetic field occupies a position in which transitions the domain from position 3 to position 4 of the Y element D. The transfer now takes place in the following way.

509832/0659

As soon as the vector of the rotating magnetic field has reached the position in which it coincides with the leg of the Y-element D, the domain shifts from the point 2 of the T-piece C to the point 3 · of the Y-element D. At this point in time the domain still circulates as bit 1 in the larger loop 12. If it is determined that it should be branched into the smaller loop, a pulsed current I ₀ , which creates a magnetic field H ₀ , is applied during the period in which the vector is between positions 3 and 4. As should be remembered, the sole transmission of the domain within the larger loop also took place in this period of time.

The vertical component of the magnetic field H (FIG. 3a), which results from the current I in the conductive metal coating β, causes a field gradient which is opposite to the domain movement across the width of the metal coating. As is known, a closed domain wall shifts in a field gradient from the areas of a strong bias field to the low bias field. The field gradient caused in this way by the current I (FIG. 3b) acts to the effect that the field gradient at the point 3+ (FIG. 2) of the Y element E, which is caused by the stray field of the positive magnetic poles at this point 3+, during the Y element E is magnetized by the rotating magnetic field H _R , is nullified.

Consequently, the resulting field gradient at the point 3+ of the Y element E is almost zero or goes negative. This field gradient is formed from the sum of the magnetic field strength Η _β , which is directed downwards, and the magnetic field H, which is directed upwards on the right side of the conductive metal coating and downwards on the left side, as is the case with an application the ampere 'see rule (Figure 3b) recognizes. In order to shift the domain, however, a certain proportion of a positive field gradient must be impressed on it. As the field to which the domain is subject, roughly

509832/0659

is zero, the domain shift from position 3- to Digit 3 + · In other words, as a result of the application of the current I, the movement in the larger loop is ended.

As the rotation continues in the plane, the magnetic field reaches the Position 4 of the compass, whereby positive poles are formed at position 4, as by the vertical position of this right-angled Section can be recognized. At the same time, site 3- becomes less positively charged, causing the negatively charged domain will take place 4 of the Y-element D. The pulse-shaped one Current I is shortly before the point 4 of the Y element D is reached

switched off by the vector of the rotating magnetic field. That I If the vector of the magnetic field rotates further, the domain is shifted up to a point 1+.

With the further rotation of the magnetic field, a point 2 forms one Rod J off positive poles, and the domain is promoted from position 1+ to position 2. Now the domain is under the participation " of the coupling element D transferred into the smaller loop D.

From now on the domain runs in the smaller loop of the place 2 of the stick J to a point 3- of a stick H, while the rotating vector continues between positions 2 and 3 of the compass. This domain shift is due to the formation of positive poles at position 3-. You can also do this easily recognize from a normalization of this lower section of the rod H. When the rotating vector gets to position 4 of the compass, the domain shifts from position 3 to position 4, at which poles are induced. This shift is due to the fact that the Digit 4 is more positive than digit 3-. As the magnetic field continues to rotate, positive poles become 1 and negative poles are formed in the vicinity of point 4, which is the cause of a shift from point 4 to point 1.

509832/0659

The shifting of the domain continues up the smaller loop D (not shown) where similar rods and H-shaped elements are juxtaposed. Finally the domain returns over the rod H and dwells in its positions 1, 2 and 3 ⁺ > in a position 4 of the rod I and in a position 1- of the Y element E.

Finally, the information should be transferred from the smaller loop to the larger ones are transmitted back via the Y element E, which follows happens:

After the domain has arrived at position 1- of the Y element E, the current I is fed to the conductive metal coating ß. As a result, the field gradient produced at point 1+ is almost zero. As already said, such a field gradient prevents the shift to position 1+. Just before the rotating vector of the magnetic field one When the position corresponding to point 2 of the Y element E is reached, the pulsed current I is switched off. The one in the conductive metal coating flowing current I prevents further domain movement

inside the smaller loop.

Because of the rotation of the magnetic field in the plane, therefore, becomes the domain Via the coupling Y element E with digits 1-, 2 and 3+ to digits 4, 1 and 2 of the T-piece F into the larger loop and through a normal propagation of the field to point 3 of the rod G is transmitted.

Although in the illustrated, preferred embodiment of the invention at least two legs of the coupling Y-shaped elements have the same length, such can advantageously also be used come, the three legs of which each have a different length.

509832/0659

Claims (5)

PATENT CLAIMS 1. An arrangement for the transmission of a binary one reproducing domain with a single wall in layers of a magnetic material from a first closed loop formed from soft magnetic elements in a second such loop using a magnetic field rotating in its plane, characterized in that between the two self-contained loops (12; D) two identical coupling aids (D *, E) are arranged, on which a conductor (ß) is directly attached, which with the help of a time-measured current signal (I) supplied to it along the coupling aids ( D ^f , E) builds up a magnetic gradient which, during the rotation of the magnetic field circulating in the plane, transferred the domain from the first loop (12) to the second loop (D) or vice versa 2. Arrangement according to claim l _s, characterized in that the two coupling aids (D *, E) are approximately Y-shaped elements and two of their legs have a greater length than the third. 3. Arrangement according to claim 2, characterized in that that the Y-shaped elements are arranged on their flat base that their two legs of larger Lengths that form an obtuse angle, facing each other slightly offset. 4. Arrangement according to claims 2 and 3, characterized in that the conductor (ß) over one of the two Legs of greater length of the Y-shaped elements is attached. 5. A method for operating the arrangement according to claim 2, characterized in that for transmission - 10 - 509832/0659 the domain from the first loop to the other or vice versa '' Current signal (I) is applied to conductor (ß) during the period in which the vector of the rotating magnetic field falls into the obtuse angle of the one leg with the greater length and is formed by the leg with the shorter length. - 11 509832/0659