HU190771B - Magnetic bubble extending-detector network - Google Patents

Abstract

The aim and the object of the invention are to develop a gap-free domain memory constructed from elements, which has a high storage density, can be provided with favorable start-stop properties and can be manufactured economically using conventional technology. The network consists of elements with a substantially broken line (the shape chevron, V, U, C) as well as hook-shaped turning elements, the elements being directly connected to each other, and each element having at least one width, which breaks the line of movement of the domains different section that forms in this part of the period of the rotating magnetic field for the Domaenen after passing through the Domaenen through this section, the way back magnetic lock.

Description

BACKGROUND OF THE INVENTION The present invention relates to a magnetic bubble stretching / detector network which allows the bubble to be moved, stretched and detected (read out) perpendicular to the direction of movement by a magnetic field rotating on a network of actuators. The invention is advantageously applicable to bubble memory devices used in digital computers.

As is known, magnetic bubble memory consists of a thin magnetic layer in which bubbles can be created and moved: motion detection elements formed by photolithography applied to a thin magnetic film on the surface of the layer, whereby magnetic fields rotating in the plane of the moving element from the place of storage to the place of detection, ie reading. The readout circuit is generally the same structure as the actuators. Before detection, it is advisable to stretch the bubbles into strips to obtain a larger signal than read. It is expedient to extend the extension perpendicular to the direction of travel so that the speed of detection is not reduced relative to the movement. The most commonly used stretch-detector network is usually a closely spaced V-shaped, so-called. consists of chevron actuators. Bubbles that move along these chevron columns and form a linear charge through these elements can extend up to a few hundred times their original length. The stretching network is followed by a detector formed on the stalk or by connecting the ends of the chevron elements below each other. Due to the diffused magnetic field of the bubble passing through the detector, the resistance of the detector changes, so that the presence or the bubble of the bubble changes. lack of readable. In order to eliminate the magnetoresistive noise generated in the detector due to the magnetic field rotating in the plane, a so-called. they also use false detectors. This detector is separated by a protective ring from the rest of the container to prevent bubbles from entering the dummy detector. By connecting a detector with the same geometry and pseudo-detectors to the weighbridge, common mode noise from the rotating magnetic field can be greatly reduced. In practice, a stretch detector network made up of the most widespread chevron actuators has serious drawbacks. While during the development of the actuators the asymmetric C-shaped and / or with the formation of asymmetric chevron elements, the gap between the actuators was approx. to increase the bubble diameter by half, thus reducing the photolithographic resolution requirement, while the adjacent columns of chevron elements in the stretch detector network could only be increased by half the bubble diameter while significantly increasing the period of the elements. However, the extended period stretch-detector network malfunctions at high motion-reading speeds because the finite mobility of the bubble may not be able to follow the progressive magnetic line loading in increasing increments, and its operating range - the magnetic field interval at which the device operates - narrowest memory items reported. When used in conjunction with the recently used non-slip actuators, the situation is exacerbated. The size of the smallest element in these actuating elements has increased to a bubble size and thus achieves a much higher storage density than slotted elements. In order to have a consistent lithographic resolution requirement for all memory components in conventional bubble memory, the gap between the columns of the stretch detector network made up of chevron actuators should be further increased. This objective cannot be achieved by a stretch-detector network constructed from conventional actuators.

U.S. Pat. No. 4,094,004 discloses a gap-less stretching detector network made of actuating elements capable of overcoming the above disadvantages. The need for photolithographic resolution of the bubble stretch detector network obtained by interconnecting conventional chevron actuators has been reduced. The smallest actuator size became two-thirds of the bubble diameter. However, closing the gap would also have eliminated the mobility of the network, since up to a millimeter the gap allowed the direction of the rotating magnetic field to reverse, i.e. the inhomogeneity of the network. Therefore, in order to fill in the role of the gap, an inhomogeneity and thickness gradient had to be created in the spacer under the permalloy elements. The repetitive thickness gradient in the spacer allowed the bubbles to be moved, stretched and detected. However, the development of such spacer gradients is extremely complex and practically different from the current well-established economical technologies. The disadvantages of the described chevron slit stretch detector network are that the photolithographic resolution requirement is poor at high rotating magnetic field frequencies and has a small operating range. The main disadvantage of a gapless detector network is that it requires extremely sophisticated technology other than known methods and has a low yield due to the application of newer levels of photomass.

It is an object of the present invention to simultaneously eliminate all of the above-mentioned difficulties and to provide a magnetic bubble stretch detector network having a high storage density, i.e. small space requirement, having the most commonly used rotating magnetic field and having good lithography -290771 mek resolution, high production yield and economical production. It is a further object of the present invention to provide a magnetic bubble stretch detector network compatible with 691/80. Bubble Container as described in U.S. Pat. No. 4,900, as well as the slit-tolerant usymelic stretching elements currently in use, both in operation and in the manufacturing process.

The present invention is based on the discovery that the object of the present invention is simply solved by connecting adjacent stretching elements of the stretching network of the stretching detector network without a gap and prior to the location of the adjacent stretching elements in the bubble or gap. in the path of the strip domain, the stem of the stretching element is thinned.

The magnetic bubble stretching detector network of the present invention is formed from a single crystal non-magnetic carrier slice, an epitaxially grown magnetic layer carrying magnetic bubbles and bubble strips, and incrementally extending in the direction of the magnetic bubble or bubble strip. containing columns and a bubble detection network. In front of the point of intersection of the adjacent actuators of the stretching network, the shaft of the actuating elements is thinned along the path of the magnetic bubble or magnetic bubble strip, and the stretching network and the bubble detection network consist of increasing number of actuating elements in half direction.

Preferably, two adjacent bubble detector networks are formed, one of which is a detector network and the other is an edge detector network of the same geometry, and the arms of the actuators are alternately connected.

It is also desirable that the first and second legs of the actuator elements of the bubble detection network are alternately connected by a top link and a link link by the links below, such that the link link is directly connected to the thinning.

It is also desirable that the pseudo-detector is separated from other parts of the magnetic bubble container by a protective ring made of actuating elements.

The invention will be described in more detail on the basis of a drawing in which the known and bubble stretching detector network of the known and the invention are some examples. embodiment.

In the drawing it is

Figure 1 illustrates a known non-magnetic magnetic bubble stretch detector network; the

Fig. 2 is a sectional view of a spacer spacer of the known non-gap magnetic bubble stretch detector network; the

Fig. 3 is a view of a gapless magnetic bubble stretch detector network according to the present invention; the

Fig. 4 shows a preferred embodiment of a non-slip magnetic bubble stretch detector mesh according to the present invention.

The structure and operation of the known gapless bubble stretch detector network are illustrated in Figures 1 and 2. The known non-gap magnetic bubble stretching detector network is made up of Chevron 10 actuators placed above and next to each other. The actuating elements 10 are made of air-magnetic material, e.g. permalloy is made by photochilithography on the surface of the magnetic bubble carrier material 11. The actuating elements 10 are made of a layer of magnetic garnet by a non-magnetic, e.g. gadolinium gallium garnet (GGG) slice is produced by epitaxial growth. The first 12, the second 13 and the third, etb. The columns contain a growing number of Chevron 10 actuators, which together form a magnetic bubble extension network. The magnetic bubble extension network gradually stretches the magnetic bubble strips 16 from the inlet direction 15 and leads them to the detector 17. The actuating elements 10 are disposed on the blister carrier 11 by inserting a spacer 18 formed by the incline shown in Fig. 2. The spacer 18 repeats in the same period as the period of the actuator and its thickness gradually decreases in the direction of movement of the magnetic bubbles 16. The actuating elements 10 are of the same width and of the same length, which ensures a high movement speed. The spacer 18 is higher at the leading edge 20 of the columns than at the leading edge 21, thereby creating a thickness gradient. The spacer 18 is made of a non-magnetic material, e.g. It can be made from SiOj and absolutely necessary for the operation of the network.

In operation, the rotating magnetic field generator 22 generates a counter-clockwise rotating magnetic field 25 in the plane of the network 24. Assuming negatively charged magnetic strips 16, the bubbles are located at the leading edge 20 of the actuator 10 on the network 24. When the rotating magnetic field 25 is positioned vertically 26, positive attractive poles are formed at the inlet and outlet edges 20 of the network 24, whereby the magnetic blisters 16 pass into such positions. As the rotating magnetic field 25 continues to rotate, the magnetic bubbles 16 move downward in the direction of the spacer 18 and, at each revolution of the magnetic field, a moving element λ advances a period. Such a wedge-shaped spacer 18 thus operates without gaps, however, the design of such a special spacer 18 thick-319077 gradient requires extremely sophisticated technology that is nein compatible with the currently used dual-mask bubble production methods. Due to the application of newer levels of photomassage, the yield of the method is significantly lower than that of conventional dual-mask technologies.

In the non-slit magnetic bubble stretch detector network according to the invention, the rotating magnetic field 30 in FIG. The negatively charged magnetic bubble 32 can be stretched into a magnetic strip 37 as a result of extremely strong magnetic positive poles 44 formed at the first and second access edges 34 and 35 of the stretching network 33 by the horizontal positive direction of the rotating magnetic field. This process λ actuator is repeated twice per period. The extent of stretching, the increase in the number of actuators 39 in the bubble extension columns 38 following expansion, is determined by the mobility of the actuator material. The stretch we use for λ / 2 half-periods is one actuator 39 for each of the bubble-stretching columns 38, e.g. There may be more at the top of 34 first and 35 second inlets, but with high mobility bubble carriers. On the network 42, the fully extended magnetic bubble strips 37, which are in the direction of movement of the bubble 43, enter a bubble detection network 40 connected at alternating ends of the elements. After detection, depending on the organization of the bubble memory, the magnetic bubble strip 37 is now either contracted and sent back to storage, or retrieved from the network 42 and destroyed, using a similar pattern of stretching but now using λ / 2 half-periods.

The operation of the network 42 is based on the discovery that on rotating magnetic fields 39, columns formed from interconnected actuators 39 in the direction of the bubble 43 generate and move as well as linear magnetic charges, such as the like. on Chevron distribution networks. In accordance with the present invention, instead of a gap between the columns, the asymmetry necessary for the operation of the network 42 is formed by reducing the width of one of the legs of the actuators 39, thereby preventing the magnetic bubbles 37 from rebounding. A line of negative poles 36 formed by the horizontal rightward rotation of the rotating magnetic field 30, which strongly repels the magnetic stripe 37, creates the asymmetry required for operation on the stretching network 33. When the rotating magnetic field 30 is inverted, this repulsion prevents the magnetic strips 37 from rebounding. On the actuators 39, a break is made in the path 45 of the magnetic bubble 32 by cutting out the outer side 46 of the actuator 39, thereby forcing the magnetic bubble strip 37 to a short path 47 directed to the rear, thereby creating a repulsive 36 negative poles. In the bubble stretching columns 38 formed of each of the actuators 3'J, these cut-outs are located underneath each other in a single line, thus preventing the magnetic bubble strip 37 from rebounding. Although the figure shows a stretch-detector network constructed of V-shaped actuators, the described recognition can also be applied to other actuators.

Of course, slots between the actuator lines interconnected in the motion direction of the bubble 43 are non-slit, so that the detector connections 50 can be formed. These slots have parallel and unidirectional poles so that the slit size can be larger than the bubble size. Detector thoracolines are introduced into the bubble detection network 40 via terminals 49.

The preferred embodiment of the non-slip magnetic bubble stretch detector network of the present invention, shown in Figure 4, is comprised of a single entry actuator 39, a two-column stretching network 33 and a bubble detection network 40. During operation, the magnetic bubble 32 from the inlet direction 31, after being fully rotated counterclockwise by the rotating magnetic field 30, is positioned at the exit edge 54 of the first stretching column 51, where it is in the form of an extended magnetic bubble strip 37. That stretched me out. After three complete rotations of the magnetic bubble strip 37 in counterclockwise rotation of the rotating magnetic field 30, it is positioned at the leading edge 55 of the bubble detection network 40 through the first stretching columns 51, 52, and the bubble detection network 40. In this embodiment, the bubble detection network 40 is formed from a single column by alternating between the tip 58 of the actuators 39 and the first leg 56 and the second leg 57 respectively. The repulsive negative pole array 36 prevents the magnetic bubble strip 37 from returning to the peaks 58 of the bubble detection network 40. The peak couplings 59 and the stem couplings 60 provide good network mobility. The detected magnetic bubble strip 37 is sent from the network 42 in the downstream direction 41. It is fed through the terminals 49 of the bubble detection network 40. The resulting magnetic bubble stretch detector will only give a bubble signal at about 180 ° intervals of the rotating magnetic field 30, thus providing a way to detect bubbles at every spin. In this embodiment, the pseudo-detector is to be separated from the rest of the bubble storage by a protective ring. Preferably, the protective ring can also be formed from the actuating elements 39.

-4190771

The bubble detection network 40 may also be formed by other connections of the actuator members 39.

As will be appreciated above, a magnetic bubble stretching detector network may be constructed from the actuator elements 5 of the present invention, or other actuator elements of the present invention designed according to the principle of operation described. These bubble motion-free networks perform the bubble stretching and detection functions as well as conventional rose-bubble stretching detection devices, and in addition, the photolithographic resolution requirements are much lower than the slit networks.

The graph periodicity of the new network in the direction of motion is not necessarily large, so it is better suited for high-speed detection than previous networks. 20

A further advantage of the stretch detection network according to the present invention is that the yield is significantly increased during its preparation, due to the elimination of the narrow-gauge gap. The smallest part of the net is the thin open end of the base member, which may be the same or even larger bubble diameter. Using 1 μια contact photolithography and chemical etching, 1 µm diameter bubbles can also be stretched and detected by the new network.

A further advantage of the magnetic bubble stretch detection network of the present invention is that its manufacturing technology is compatible with known slit-tolerant asymmetric actuators 35 and 691/80. actuators for use with a magnetic bubble storage device as described in Hungarian Patent Application Serial Number.

The magnetic bubble stretch detector network 40 of the present invention is advantageously used in bubble memory devices used in digital computers.

Claims (4)

PATENT CLAIMS CLAIMS 1. A magnetic bubble stretch detector network comprising a crystalline non-magnetic carrier slice epitaxially grown on this slice, a magnetic layer carrying magnetic bubbles and bubbles, and a magnetic bubble on the magnetic layer. consisting of a stretching grid and columns of columns comprising a growing number of linearly actuated fractured actuators in the forward direction of the bubble strip, characterized in that the magnetic bubble (32) is disposed in front of the intersection of the stretching grid (331) the shaft of the actuating elements (39) being thinned along the path (45) of the magnetic blister strip (37), and the stretching network (33) and the bubble detection network (40) of the increasing number of actuating elements (39) in the direction of motion of the magnetic blister available. Magnetic bubble stretch detector network according to claim 1, characterized in that it consists of two adjacent bubble detector networks (40), one of which is a detector network and the other is a false detector network of the same geometry, and the actuators (2) 39) the legs are alternately connected. Magnetic bubble stretch detector network according to Claim 1 or 2, characterized in that the first and second legs (56, 57) of the actuating elements (39) of the bubble detection network (40) are alternately top-connected. (59) and are connected by a linkage (60) such that the linkage (60) is directly connected to the thinness. Magnetic bubble stretch detector network according to claim 2 or 3, characterized in that the edge detector It is separated from the other parts of the magnetic bubble container by a protective ring built up of 45 actuating elements (39).