CA1053796A - Column accessing of elements in confined arrays - Google Patents

Abstract

COLUMN ACCESSING OF ELEMENTS IN CONFINED ARRAYS

Abstract of the Disclosure A technique for accessing interactive elements, such as magnetic bubble domains, which are in confined arrays where the elements are located with respect to one another in accordance with interactions therebetween. In order to improve the access time to any element within the confined array, means and method are provided for removing the elements in a direction substantially transverse to the direction of their translational movement within the confined array. In particular, this technique is useful for accessing columns of magnetic bubble domains in a lattice array of bubble domains. A bubble pump device is utilized to remove the interactive elements from the array. The bias field con-ditions for this pump propagation structure are the same as for the lattice.
Bubble domains can be removed from the lattice and returned to their posi-tions within the lattice.

Description

~(~53796 This application is a divisional of Canadian Application Number 215,070, filed December 2, 1974, and assigned to the same applicant.

Cross Reference to Related Patents U.S. Patent No. 3,913,079 issued October 14, 1975 and commonly assigned herewith, describes a pump propagation structure for moving interactive ele-ments, and in particular for moving magnetic bubble domains. Bubble domains confined to move in a certain direction are moved YO9-73-044 _1 ~os3796 1 in that direction by localized magnetic fields which expand

2 bubble domains, thereby forcing other bubble domains to

3 move in the preferred direction.

4 Background of the Invention Field of the Invention 6 This invention relates to techniques for improving 7 the access time in systems using arrays of interactive 8 elements, and in particular for improving the access time 9 of magnetic bubble domains in a system using a confined array (lattice) of such bubble domains.
11 Description of the Prior Art 12 The concept of using a lattice of interactive 13 elements in information handling systems was first presented 14 in U.K. Patent 1,454,451 granted March 2/77 and commonly assigned herewith. In that application, an embodiment showed a large array of 16 magnetic bubble domains confined within a rhombus shape.
17 These bubble domains interact with one another and have 18 positions within the rhombus which are substantially deter-19 mined by those interactions. In that system, access to bubble domains within the lattice array took place by serially 21 removing a column of bubbles from one of the ends of the 22 lattice. Once the first column of bubble domains has been 23 removed, the second column is then serially removed.
24 In the lattice arrangements described hereinabove, the access time to a random bi,t of information in the lattice 26 is approximately equal to (1/2) NBT, where NB is the total 27 number of bubble domains in the confined rhombus and T is 28 the basic cycle time of the system. The basic cycle time 1(~53796 1 is the time required to ~ove a bubble domain several 2 bubble diameters. For large systems, NB may be 108 3 and T may be 1 microsecond. In that situation, the 4 access time for a random bit would be 50 seconds.
The access time can be improved by decreasing 6 the block size (lattice size) and increasing the number 7 of blocks per magnetic chip. However, this approach 8 leads -to a large number of connections to the magnetic 9 chip. ' Accordingly, it is a primary object of the 11 present invention to provide a technique for extracting 12 information from a lattice of interactive elements with 13 minimum access time.
14 It i9 another object of the present invention to provide a technique for accessing interactive elements 16 within a lattice of such elements by means which provide 17 only a minimum number of interconnections.
18 It is a further object of this invention to 19 provide a technique for readily accessing information from a lattice of interactive elements wherein the 21 information sta~e can be replaced within the lattice.
22 It is still another object of this invention 23 to provide a system utilizing a lattice of interactive 24 elements including structure for moving elements within the lattice and for removing elements from the lattice 26 in a direction substantially transverse to the direction 27 of movement of elements within the lattice.

~053796 1 It is a further object of this invention to 2 provide techniques for reducing information access time 3 in systems using lattices of magnetic bubble domains.

4 Brief Summary of the Invention The column access technique proposed herein does 6 not serially move information from one end of a lattice to 7 the other for extracting the interactive elements. Instead, 8 the interactive elements are removed from the lattice in a 9 direction substantially transverse to the direction defined by the prior art lattice systems where information is put 11 in at one end of the lattice and removed at the other end 12 of the lattice. Consequently, elements can be removed from 13 interior positions of the lattice, rather than having to be 14 removed from positions at the ends of the lattice.
Means are provided for translating the lattice and 16 for extracting interactive elements from the lattice in a 17 direction substantially transverse to the direction of 18 translation of elements within the lattice. Additionally, 19 means are provided to return the extracted information into the same positions within the lattice, or for regenerating 21 the removed information. In particular, the bubble pump 22 shift register described in aforementioned U.S. Patent No.
23 3,913,079 can be utilized for removal of a column of 24 interactive elements from the lattice. After detection of the removed elements, new elements having the same informatlon 26 state can be inserted into the lattice, or the same elements 27 can be returned to the lattice.

~053796 1 Although the use of many types of interactive elements can be foreseen, a particularly good example is provided using magnetic bubble domains. Thus, the following description will be concerned with magnetic bubble domains, although other variations can be utilized.
For instance, styrofoam elements (as shown in ~I.K. Patent ~o. 1,454,451) having magnetic elements embedded therein can float on a suitable medium, such as water. These elements will interact with one another in the same manner as magnetic bubble domains and can therefore be moved on the water surface by the column accessing structure of the present invention. If the styrofoam balls are color coded, information storage and displays are readily provided.
These and other objects, features, and advantages will be more apparent from the following more particular description of the preferred embodiments.
Brief Description of the Drawings FIG. 1 is a conceptual drawing illustrating the principle of column accessing.
FIG. 2 is a detailed diagram of an overall system configuration for implementing column accessing of elements within a lattice.
FIG. 3 is a diagram of a portion of FIG. 1, illustrating the input/output of bubble domains to/from a lattice, and appears on same page as FIG. 1.
FIG. 4 is a diagram of a portion of the structure of FIG. 2, showing the structure used for nucleation, expansion, splitting, annihilation, and propagation of domains within a bubble domain pump used for column accessing.
FIG. 5 is an illustration of a portion of the structure of FIG. 2, showing in particular the apparatus used to read information taken from the lattice.

1 FIG. 6 illustrates a portion of the structure of FIG. 2, showing in particular the propagation of bubble domains within the lattice, and appear on same page as FIG. 2.
FIG. 7 illustrates a portion of the structure of FIG~ 2, showing in particular the generation and annihilation of domains at the buffer zones of the lattice.
FIG. ~ is a circuit diagram showing a bubble domain lattice using column accessing in which information removed from the lattice is returned to the same locations within the lattice by the bubble domain pump.
Detailed Description of the Preferred Embodiments FIG. 1 is a conceptual illustration showing how column accessing works. A lattice L of interactive elements 10, such as magnetic bubble domains, is held within a confinement means 12. This confinement means is any type of structure which provides a magnetic barrier to the bubble domains 10. For instance, such confinement means can be comprised of permalloy strips, ion implanted regions, and etched grooves in the bubble domain material. All of these structures are described in more detail in aforementioned United Kingdom Patent No. 1,454,451.
Buffer regions are located on the left and right-hand ends of the lattice L and are used for translation of the lattice to the left or to the right. Oonductor lines ~053796 1 can be used to move stripe domains and bubble domains in 2 the buffer regions to implement bubble domain translation 3 to the left or to the right.
4 Vertically displaced arrows 14 are used to indicate the direction of movement of columns of bubble 6 domains 10. That i8, a plurality of write stations 16 7 is provided at the top of lattice L and a plurality of 8 read stations 18 i5 provided at the bottom of lattice L, 9 in order to define a plurality of input/output ports.
Bubble domains 10 are moved in the direction of the arrows 11 to the read stations 18 ana then destroyed or returned to 12 the same locations within lattice L, after the read 13 operation.
14 In FIG. 1, it i5 noted that normal lattice trans-lation is in a horizontal direction from left to right, or 16 the reverse. However, elements are removed from the 17 lattice in a direction substantially transverse to this.
18 Also, elements can be removed from interior positions or 19 end positions of the lattice. This is in distinction with the lattice arrangement of aforementioned United Kingdom Patent 1,454,451, 21 where columns of~ bubble domains are entered into the lattice 22 along the left-hand end and removed from the lattice at 23 the right-hand end of the lattice.
24 Provision of a plurality of write stations 16 and read stations 18, together with means for propagating 26 the bubble domains along the paths indicated by the arrows, 27 produces column accessing. As the number of input-output 28 ports is increased, the amount of lattice translation 29 (along the horizontal direction) is decreased at the ~053796 ' :
1 expense of the number of chip connections. A reasonable 2 design for a system might comprise 10~ magnetic bubble 3 domains, and 8 input-output ports. This would lead to a 4 ratio of storage area/(storage area I buffer area) = 8/9.
For a cycle time of 1 microsecond, the access time to any 6 random bubble domain would be 10 milliseconds.
7 FIG. 2 8 FIG. 2 shows a detailed diagram of structure 9 required ~o implement column accessing of bubble domains within a lattice array. Individual portions of this 11 circuit will be shown in more detail in ~ubsequent 12 FIGS. 3-7.
13 In more detail, a lattice array L of magnetic 14 bubble domains 10 is confined within the confinement -means 12. Confinement means 12 is a barrier to the 16 escape of bubble domains 10 and serves to keep these 17 domains within a confined area. As is apparent, the 18 confinement barrier is also used for the columns (input/
19 output) which extend transversely to the lattice.
At the left-hand end of the confinement means 12 21 is an input means generally designated 20. The input 22 means is compri~ed of a bubble domain generator 22 which 23 provides bubble domains for insertion into lattice L, a 24 shift register SRl which moves the domains from the generator 22 to positions where they can be inserted 26 into lattice L, and a series of conductors A, B, C
27 through which currents can be passed for creation of ^` ~ ;
.

1(~5~796 1 magnetic fields which insert the bubble domains into the 2 lattice. This type of conductor input means is more fully 3 described in aforementioned United Kingdom Patent No. 1,45~,451.
An output means, generally designated 24, is 6 comprised of conductors A', B' and C'. These conductors 7 have analogous functions to the conductors A, B and C
8 in that currents through these conductors provide magnetic 9 fields for pulling domains from the lattice L. This type of output means is also well described in United Kingdom 11 Patent No. 1,45~,~51.
12 After removal of a column of bubble domains 10 13 from the lattice, shift register means can be provided 14 in the normal fashion for moving the domains to other par~s of the magnetic medium in which they exist. In 16 this drawing, shift register SR2 is located between 17 conductors B' and C' and can be, for instance, comprised 18 of conductor loop patterns for moving domains in 19 conventionally well known ways.
If desired, a bubble pump shift register of the 21 type described in aforementioned United States Patent No.
22 3,913,079 can be used to provide bubble domains 23 at the input of the lattice and for removing bubble domains 24 at the output of the lattice.
In the description to follow, the input means 20 26 and output means 24 are utilized to provide the initial 27 lattice. After an initial lattice is produced within the 28 confinement means 12, the input and output means are no 1 longer needed if other bubble domain generators are utilized, 2 or if bubbles removed from the lattice are returned to the 3 lattice.
4 A bias field source 26 provides a magnetic bias S field Hz substantially normal to the plane of the lattice L.
6 Source 26 can be any of a number of well known sources, 7 including permanent magnets, magnetic layers exchange 8 coupled to the magnetic medium in which the bubble domains 9 exist, and current carrying conductors. For instance, it may be desirable to have a different value of bias field 11 within lattice L than outs1de the lattice. Accordingly, 12 the bias field source will provide a proper bias field 13 over different regions of the magnetic sheet if that is 14 desired. Of course, if a bubble pump propagation means is used for input and output of bubble domains from the 16 lattice, a uniform field Hz can be used throughout the 17 magnetic medium. Techniques for doing this are within the 18 skill of the art and are also described in aforementioned 19 U.K. Patent No. 1,454.451.
A source 28 provides an in-plane magnetic field H
21 which can be used for various functions. For instance, 22 such a field may be used for movement of magnetic domains 23 in shift registers SRl and SR2 located outside the lattice 24 area.
Buffer zones 28L and 28R are located at the 26 left-hand end of the lattice and at the right-hand end of 27 the lattice, respectively. These buffer zones are comprised 28 of stripe domains 30 and means 32L and 32R for generation ~OS379~; , 1 and annihilation of these stripe domains. For instance, 2 32~ is comprised of conductors 34A and 34B which are 3 connected to buffer current sources 36A and 36B, respectively.
4 On the right-hand end of the lattice, means 32R is comprised of conductors 38A and 38B, connected to buffer current 6 sources 40A and 40B, respectively.
7 The operation of the generation and annihilation 8 means 32L- and 32R Will be explained in re detail later.
9 At this time it is appropriate to say that these structures 14 are used to generate and annihilate stripe domains in the 11 buffer zones 28L and 28R. This generation and annihilation 12 of stripe domains is used to translate the lattice L to the 13 left or to the right.
14 In FIG. 2, two write stations W-A and W-B are provided at the top of the lattice. At the bottom edge 16 of the lattice, two read stations R-A and R-B are 17 provided. In general, the write stations are used to 18 produce magnetic domains which in turn are used to push 19 bubble domains out of the lattice into the associated read stations. In the embodiment of FIG. 2, two columns 21 of bubble domains 10 can be pushed out of the lattice 22 into the associated read stations for detection of the 23 information carried by the bubble domains. It should be 24 noted that the generalized translation direction of the 25 lattice is from left to right or right to left, while the 26 removal of a column of bubble domains from the lattice is 27 essentially transverse to thi~ horizontal left +~ right 2 8 direction.

YO973-044 ~11-1()53796 l Each write station is comprised of a bubble 2 domain generator and a pusher for serially pushing domains 3 into a bubble domain pump. In FIG. 2, two pumps P-A and 4 P-~ are provided for moving bubble domains in two columns out of the lattice L. Pump P-A is comprised of current 6 carrying conductors 42L and 42R. These conductors are 7 connected to pump current sources 44L and 44R, respectively.
8 - Pump propagation means P-B is comprised of 9 conductors 46L and 46R. These are connected to pump current sources 48L and 48R, respectively.
ll The operation of the pump propagation means P-A
12 and P-B is explained in detail in aforementioned United 13 States Paten~ No. 3,913.079. Essentially, currents 14 in a pair of pump conductors cause expansion of domains 15 between the conductors. This expansion causes other domains 16 to move with the net result that propagation of domains occurs 17 in the column defined by the pump conductors. This will be 18 explained in more detail with respect to FIG. 3.
19 AS mentioned, each write means is comprised of 20 a domain generator and a pusher for serially pushing domains 21 into the column defined by the adjacent pump conductors.
22 For instance, write means W-A is comprised of a bubble domain 23 generator 50A and a bubble domain pusher 52A. Pusher 52A iS
24 comprised of conductors 54L and 54R, which are connected to 25 a pusher current source 56A. Generator 50A is comprised of 26 a three-legged conductor structure in which the two outer 27 legs 58 and 60 are connected to a current source 62A while 28 metal conductor 64 iS connected to ground.

YO973-044 -12~

1 Write means W-B is comprised of bubble domain 2 generator and annihilator 50B and serial bubble domain 3 pusher 52B. Generator 50B is comprised of conductors 4 which are connected to current source 62B while pusher 52B
is comprised of current carrying conductors connected to 6 pusher current source 56B. Since generator 50B is the 7 same as generator 50A and since pusher 52B is the same as 8 pusher 52A, the details of write means W-B will not be 9 further explained. Accordingly, the individual conductors of these components are not given reference numerals.
11 The operation of the write means W-A will be 12 explained in more detail with respect to FIG. 4.
13 Accordingly, at this point in the discussion, it is 14 only necessary to state that the generator 50A can be use~ to nucleate and annihilate domains, as well as to 16 split them. If properly designed, this generator will 17 provide coded bubble domains for information storage.
18 The pusher 52A will push domains in serial fashion into 19 the column defined by the associated pump propagation means P-A.
21 Two read means R-A and R-B are provided for 22 use with the associated write means W-A and W-B, 23 respectively. Because the structure of means R-A is 24 identical to that of R-B, only read means R-A will be described in detail.
26 Read means R-A is generally comprised of a 27 bubble domain serial puller 66A, a bubble domain serial 28 pusher 68A, and a bubble domain sensor 70A. Puller 66A

~OS;~796 is comprised of conductors 72L and 72R, which are connected 2 to puller current source 74A. Serial pusher 68Ais comprised 3 of conductors 76L and 76R which are connected to a pusher 4 current source 78A. Serial puller 66A moves bubble domains in serial fashion (one at a time) from the column of the 6 associated bubble pump P-A. Serial pusher 68Ais used to 7 push bubble domains, one at a time, toward the direction of 8 the Y-shaped confinement means 80A. Aswill be more clearly 9 understood later, pusher 68Ais also used to create a gradient magnetic field in the Y-shaped region defined by 11 the boundaries 80A. This in turn is used to deflect the 12 bubble domains in accordance with their wall magnetization 13 structure. Accordingly, the domains can be detected for 14 their information content by this technique.
Sensing means 70AiS illustrated as comprising 16 a conductor 82A connected to a sensing element 84A, which 17 can conveniently be a magnetoresistive sensing element of 18 the type well known in the art. A sensor current source 85A
19 produces electrical current through sensor ~lement 84A. In 20 FIG. 2, an elongated bubble domain 86iS adjacent to the 21 sensor 84A.-22 A conductor loop 88AiS adjacent to the left-hand 23 leg of the Y-shaped propagation channel while a conductor 24 loop 90A is adjacent to the right-hand portion of the 25 Y-shaped propagation path. Conductor loop 88Ais connected 26 to current source 92A while conductor loop 90Ais connected 27 to current source 94A. Conductor loops 88A and 90A are 28 used for expansion and collapse of domains in the respective 105379~

1 portions of the Y-shaped propagation channel. That is, 2 current in loop 90A will expand the domain 86 to provide 3 a maximum signal to be sensed by detector 84A. Later this 4 same conductor loop can be used to collapse the domain 86.
The operation of the read means R-A will be described in 6 more detail with respect to FIG. 5.
7 Since read means R-B is identical to read means R-A, 8 it will not be explained in detail. Corresponding portions 9 of read means R-B have the same reference numerals as those of means R-A, except that the suffix B is used.
11 A control means 95 synchronizes the operation of 12 the various components used in the system of FIG. 2.
13 Control 9S provides input trigger pulses to the pump current 14 sources 44, pusher current sources 56, 78, puller current sources 74, input/output conductors A-C, A'-C', buffer 16 current sources 36, 40, sensor current sources 85, in-plane 17 field source 28, bias field source 26, annihilate/generate 18 current sourçes 62, and current sources 92 and 94.
19 The pump propagation structure is a shift register that can be used for access ~input/output) of bubble domains 21 to and from the lattice L. Additionally, it is a one-dimensional 22 lattice itself, since the bubble domains confined in it havé
23 positions largely determined by mutual interactions between 24 the bubble domains. Conse~uently, the structure of FIG. 2 is comprised of two lattices (confined arrays) of magnetic 26 bubble domains, where one lattice is two-dimensional while 27 the other lattice is one-dimensional. Also, the first and 28 second lattices include bubble domains which are common to i(~5379~
1 each lattice, and the second lattice can be thought of as 2 intersecting the first lattice.
3 Initialization of the Lattice 4 In the embodiment of FIG. 2, an input means 20 is provided for bringing bubble domains to the left-hand 6 end of the lattice L. These domains can then be inserted 7 into the lattice by the associated conductors. The force 8 required to move the bubble domains into the lattice area 9 is that which overcomes the repulsive force of bubble domains within the lattice. If there are no bubble domains 11 within the lattice, the bubble domains which enter the 12 lattice will spread out in order to minimize the energy 13 of the lattice. These domains merely have to overcome the 14 repulsive force of the barrier 12 in order to enter the lattice area. Consequently, bubble domains can be continually 16 loaded into the lattice area until a number is reached which 17 will provide a regular lattice having a given lattice spacing 18 aO between bubble domains. For instance, m columns having 19 n elements in a column may be placed in the lattice. After this, the lattice can be slightly perturbed by further input 21 elements in order to remove any dislocations or vacancies 22 from the initially formed lattice. That is, after the 23 lattice is initially formed, additional columns of bubble 24 domains are entered into the lattice and a corresponding number removed from the lattice by the output means 24.
26 This provides a filtering action and insures that all 27 dislocations and vacancies will have translated through 28 the entire lattice area to the output end where they are 1 removed. This filtering operation may take one or more 2 cycle~ in which the lattice is totally recycled.
3 An alternate technique for achieving an initial 4 lattice o magnetic bubble domains is to first apply a large in-plane magnetic field (using source 28) to 6 saturate the magnetic medium. After this, the in-plane 7 magnetic field is released to obtain a dense, random 8 array of bubble domains. The lattice is then magnetically 9 annealed b~ a time-modulated magnetic field (produced by source 26) normal to the bubble domain material, in order 11 to obtain a regular lattice.
12 Still another technique for providing an initial 13 lattice is one which generates bubble domains at selected 14 locations in a magnetic medium. For instance, a permanent magnet having a pattern of apertures in it ~not shown) can 16 be brought into close proximity to the magnetic medium, 17 after the medium has been heated to a temperature above 18 its Curie temperature Tc. This will cause nucleation of 19 bubble domains in the magnetic sheet at locations corresponding to the pattern in the permanent magnet.
21 ~nother technique for providing an initial lattice 22 of bubble domains utilizes stripe domains which can be cut.
23 A pattern of stripe domains is produced by a magnetic field 24 in the plane of the magnetic sheet, in a well known manner.
These stripe domains are then cut to provide rows of bubble 26 domains. The cutting device is any device which produces a 27 magnetic field of sufficient amplitude in a direction 28 substantially normal to the magnetic medium. As an example, Y0973-04~ -17-10537g6 l a recording head can be moved across the stripe domain pattern 2 in sequential fashion to cut the stripes, thereby producing 3 rows of bubble domains. Another alternative would be to use 4 a plurality of conductors arranged transversely to the direction of the stripe domains. Pulsing these conductors 6 will produce magnetic fields which will cut the stripe domains, 7 thereby leading to the rows of bubble domains.
8 Steps for producing an initial lattice are known in 9 the art and are described in some detail in aforementioned U.K. Patent No. 1,454,451.
ll Operation of the Structure of FIG. 2 12 The following will be a generalized description 13 of the functions which are performed in the structure of 14 FIG. 2. The detailed operations of the various components of this structure will be explained with reference to the 16 subsequent figures which show the various components.
17 Generation and annihilation of stripe domains 30 18 in the buffer zones 28L and 28R are used to move the lattice l9 to the left or to the right. For instance, the lattice L
will be shifted to the right when stripe domains are 21 generated i~ buffer zone 28L and annihilated in buffer 22 zone 28R. A reverse operation will shift the lattice to 23 the left. This type of operation will maintain the same 24 number of bubble domains in the lattice during translation.
The lattice translation operation continues until 26 the desired column of bubble domains is situated in the 27 region between the appropriate bubble pump conductors.
28 That is, the bubble domain column to be taken from the 29 lattice must be in a proper input/output port.

YO973~044 -18-1 ~ubble domains in a selected column are then 2 moved out of the lattice by pulsing the appropriate 3 pump conductors. During this operation, the appropriate 4 bubble domain generator will produce bubble domains which are serially entered into the lattice to maintain the 6 proper spacing of elements within the lattice. The generator 7 can also provide coded bubble domains in order to replenish 8 the exact information taken from the lattice.
9 At the read end of the bubble domain pump, bubble domains are sensed and the sense signals can be sent to 11 associated circuitry, such as a computer.
12 As will be seen by reference to FIG. 8, techniques 13 can be utilized to return the original bubble domains to 14 their positions within the lattice after being removed from the lattice and read by a sensing station.
16 Additionally, it should be noted that the bubble 17 domains need not be coded within the lattice, if the lattice 18 is used for other types of applications. However, if the 19 bubble domains are coded, any type of coding can be utilized.
In the discussion to follow, the coding technique described 21 in United States Patent No. 3,~90,605 issued June 17, 1975 22 will be assumed as the type of coding used. Other types 23 of coding may utilize the hard-soft properties of magnetic 24 bubble domains (United States Patent No. 3,~99,799 issued August 12, 25 1975), right and left-handedness of unichiral magnetic bubble domains 26 (United Kingdom Patent No. 1,454,451 granted March 2, 1977), dual size 27 magnetic bubble domains (U.S. Patent No. 3,911,411 issued September 30, 28 1975), etc. All of these aforementioned patents are commonly assigned 29 herewith.

1 Description of the Various ComPonents 2 FIG. 3 shows the structure used to provide 3 input~output of bubble domains to/from a column in the 4 lattice. The lattice L is comprised of bubble domains 10 and a column therein is defined b~ the pump conductors 6 42L and 42R. Although only a portion of these conductors 7 as well as portions of other conductors are showm in 8 this drawing, the amount of detail presented is sufficient 9 to enable one to understand the operation of this component.
The serial puller 66A is also shown. This puller 11 includes conductors 72L and 72R which form a U-shaped loop 12 that i9 grounded at its mid-point.
13 In operation, bubble domains within the area 14 defined by conductors 42L and 42R will be expanded when currents flow in these conductors. Expanded domains 10-1, 16 10-2, 10-3, 10-4, and 10-5 are shown in this drawing.
17 Expansion of these domains exerts forces on other domains 18 in the column, causing movement of the domains in a 19 downward direction. ~owever, the bubble domain puller 66A
insures that bubble domains entering the lower portion 96 21 of the column propagation path defined by barrier 12 enter 22 it one at a time. As will be seen later, this provides 23 control over the reading station in order to be able to 24 detect each separate domain.
When the current in the pump conductors is removed, 26 the expanded domains 10-1 ... 10-5 shrink and other domains 27 from the associated write means W-A enter the areas that 28 the expanded domains have vacated. Thus, there is a lOS3796 1 continual downward push of bubble domains in the column 2 defined by the pump conductors 42L and 42R.
3 Because the pump propagation means is symmetrical, 4 bubble domains can be pushed upwardly in the column if such is desired. However, operation of the structure of FIG. 2 6 moves bubble domains downwardly to the read station for 7 detection thereat.
8 In the input/output operation of the column 9 accessing structure, the associated generator 50A will provide a single bubble domain each time one is required for movement 11 into the column. The associated pusher 52A will cause serial 12 movement of these bubble domains into the bubble pump structure.
13 Accordingly, use of the serial pushers and pullers insures 14 that a fixed amount of bubbles is always present in the column and that synchronization of the column accessing 16 will occur. In this manner, the control unit 95 can keep 17 track of the domains which are read from the lattice area.
18 Th~ bubble domain pump structure can be used to 19 provide a regular lattice. In this case, an array of bubble domains is produced within confinement means 12 21 through the use of a large in-plane magnetic field (several 22 thousand Oe) which is then reduced to zero. This produces 23 an array of bubble domains within confinement means 12.
24 By modulating a perpendicular bias field Hz, the array will move into a lattice configuration. At this time, the 26 bubble domain pump structure can be used to insure that a 27 proper number of bubble domains is present in each column.

~053796 1 As an example, assume that an array of 100 by 100 2 bubbles is required. This means that there will be 100 3 columns, each of which has 100 bubble domains therein. The 4 bubble domain pump conductors are used to line up a bubble domain column between the conductors. At this time, a high 6 current in the pump conductors will force all of the bubble 7 domains between the conductors to move together to create a 8 single~strip domain between the conductors. If the current 9 in the pump conductors is then reduced, this strip domain will get smaller and become a single bubble domain. The 11 generator and pusher associated with the pump conductors 12 is then activated to produce 99 domains. Since only one 13 domain was present in the column located between the pump 14 conductors, insertion of 99 domains in serial fashion will provide a column having exactly 100 domains therein.
16 Accordingly, the associated serial pusher on 17 one end of the pump propagation means and the associated 18 serial puller on the other end of the propagation means 19 can be used to define the length of the bubble domain column. Each end of the bubble domain pump can be opened 21 (to allow Pubble domains to pass) or closed (to restrict 22 movement of bubble domains).
23 After a 100-bubble domain column has been formed, 24 this column can be shifted in the lattice by using the buffer zones as described previously. At this time, another 26 column of bubble domains (which may or may not have the 27 proper amount of domains) is moved into the area between 28 the pump conductors and is treated as described previously.

1 This continues until 100 columns having 100 bubble domains 2 in each column are produced.
3 FIG. 4 4 FIG. 4 is a diagram of the bubble domain generator 50A
and bubble domain serial pusher 52A. Generator 50A can perform 6 the functions of nucleation, expansion, splitting, annihilation, 7 and propagation. Pusher 52A is used to move bubble domains 8 one at-a time to the lattice, as indicated in FIG. 4.
9 The constraining border for the bubble domain pump is indicated by the solid line 12. This confining means can 11 be, for instance, ion implanted regions of the magnetic 12 bubble domain material grooves, etc. which create a barrier 13 to restrain the bubble domains 10 within this barrier.
14 Generator 50A is comprised of a three-legged current carrying conductor structure, with the two outer 16 conductors being 58 and 60 while the inner conductor is 64.
17 Outer conductors 58 and 60 are connected to a current source 62A
18 which is not shown in this drawing.
19 Serial pusher 52A iS comprised of a U-shaped 20 conductor having portions 54L and 54R which are tied to 21 ground at their midpoint. Conductors 54L and 54R are 22 connected to pusher current source 56A (not shown in this 23 figure).
24 Generator 50A can be used to nucleate bubble 25 domains in the following way. For typical rare earth iron 26 garnet bubble domain materials, a current of 300-400 milliamps 27 in either conductor 58 or conductor 60 will create a 28 localized magnetic field adjacent to the conductor which ~ os3796 1 will nucleate a domain. At this time, the bias field Hz 2 normal to the bubble domain medium can be appro~imately zero 3 or set at the bias for operation of the lattice.
4 Once the initial domain is nucleated, generator 50A merely splits off bubble domains from it for propagation 6 to the lattice. The splitting operation is accomplished 7 by putting currents into conductors 58 and 60. This causes 8 the initial domain 100 to expand as shown in the drawing.
9 During this stretching operation, magnetic fields are established which pinch the bubble 100 at its center, 11 causing it to split. The currents used for this operation 12 are about 100 milliamps.
13 The split domain is then attracted by pusher 52A
14 by putting a current through conductor 54L. Current through conductor 54R holds bubble domains on the right-hand side 16 of this conductor during this operation. The currents 17 utilized have amplitudes of approximately 10 milliamps.
18 The bubble domains 10 are then pushed in serial fashion to 19 the lattice. By pulsing the pump conductors, the bubble domains in the lattice will be expelled as described with 21 reference ~o FIG. 3.
22 FIG. 5 23 FIG. 5 shows the read means R-A used to detect 24 domàins from the lattice which have been coded in terms of their wall magnetization rotation. This type of coding 26 is described in more detail in aforementioned U.S. Patent No.
27 3,390,605 is5ued June 17, 1975. Briefly, magnetic bubbles can 28 be made to deflect through different angles in a gradient ~o~3796 1 magnetic field normal to the magnetic medium depending 2 upon the number of rotations of their wall magnetization.
3 Thus, the propagation channel in FIG. 5 branches into a 4 Y in order to allow bubble domains to deflect into either S one of the legs of the propagation channel. Sensors 6 then detect the bubble domains and an indication is 7 obtained of the information contained within the lattice.
8 In more detail, FIG. 5 shows the serial bubble 9 domain pusher 68A which is comprised of conductors 76L
and 76R which are tied to a common ground. Conductors 76L
11 and 76R are connected to pusher current source 78A, which 12 is not shown in this drawing.
13 The sensing means 70A is comprised of a sensing 14 element 84A which is connected to a current carrying conductor B2A. In a preferred embodiment, sensor 84A
16 could be a magnetoresistive sensor which i5 operated in 17 a manner well known in the prior art (U.S. 3,691,540).
18 Current sources 78A, 85A, 92A and 94A are not shown in 19 this figure.
In operation, bubble domains 10 are pushed out 21 of the lattice by the bubble pump means and move downwardly 22 to the serial pusher 68A. This pusher allows one bubble 23 domain at a time to cross the Y-shaped region of the 24 propagation path, in order to determine the deflection 25 properties of the bubble domains. Current through 26 conductor 76R provides a magnetic field gradient in the 27 direction of the Y-shaped grooves and individual domains 28 move downwardly under the influence of this gradient field.

~05~7~6 1 Depending upon the deflection properties of a domain, 2 it moves either to the left-hand path 102 or to the 3 right-hand path 104. At this time, current is put into 4 conductor loop 90A which causes the domain 86 to be expanded. This expanded domain is detected by sensor 84A
6 and a signal can be fed to external circuitry, such as a 7 computer. After being sensed, current through conductor 8 loop 90A is reversed to collapse the domain 86.
9 A sensor is not needed to detect bubble domains moving in path 102. Since the domains were coded in a 11 prescribed way initially, any domain which moves into 12 path 102 can be detected by noting the absence of a 13 signal produced by element 84A at that time. If a 14 domain moved into path 102, it would be collapsed by a magnetic field due to current in conductor loop 88A.
16 For the reading technique of FIG. S, bubble 17 domains must be able to freely float in a gradient 18 magnetic field produced by pusher 68A. Therefore, domains 19 in paths 102 and 104 which have been sensed are collapsed before the serial pusher 68A sends another domain through 21 the gradient field. This insures that the domains deflect 22 properly in the gradient magnetic field, rather than 23 undergoing deflection due to the influence of other domains.
24 FIG. 6 FIG. 6 illustrates propagation of magnetic 26 bubble domains 10 within the lattice L. As stated previously, 27 domains 10 propagate in a horizontal direction either to 28 the left or to the right depending upon the generation and Yo973-044 -26-lOS:~7gl6 1 annihilation of stripe domains in the buffer regions 28L
2 and 28R. This translation of motion of the lattice is 3 used to place a column of bubble domains between the pump 4 conductors 42L and 42R.
For proper placement of the bubble domains 6 between the pump conductors, currents can be put in 7 individual pump conductors in order to move a column of 8 bubbles into the region between the two conductors. Thus, 9 it is possible to fine-tune the tion of the desired column of lattice bubbles which are to be removed from 11 the lattice.
12 FIG. 7 13 FIG. 7 shows a portion of the buffer zone 28L
14 including the barrier 12 and the generate/annihilate conductors 34A and 34B. These conductors are connected 16 to buffer current sources 36A and 36B respectively, which 17 are not shown in this drawing.
18 At this time it should be remembered that the 19 function of the buffer zones is to translate the bubble domain lattice to the left or to the right. This is done 21 by the controlled generation and annihilation of stripe 22 domains in the buffer zones on either side of the lattice.
23 Initially, the entire area surrounded by the 24 confinement barrier 12 contained a perfect lattice. At this time, current is put into conductors 34A and 34Bo 26 These currents will create magnetic fields which will 27 squeeze the bubble domains located between conductors 34A
28 and 34B. The bubble domains thus squeezed will merge into ~05~7~6 1 a stripe domain 30 which will remain between conductors 34A
2 and 34B.
3 At the same time the cvnductors 38A and 38B in 4 buffer zone 28R are energized in tha opposite direction in S order to collapse the row of bubble domains which is 6 located between them. Consequently, the entire lattice is 7 now arranged such that it can be shifted to the right by 8 one column width. To do so, current is passed through 9 conductor-34B in a direction which attracts the stripe domain between conductors 34A and 34B to the right-hand side of 11 conductor 34B. During this operation, a current in the 12 proper direction in the left-hand conductor 34A may be used 13 to aid movement of the stripe domain to the right.
14 Additional stripe domains may be created between conductors 34A and 34B by applying currents of approximately 16 400-500 milliamps in these conductors. The localized 17 magnetic field produced between the conductors will nucleate 18 domains between these conductors. If the currents through 19 the conductors are reduced, these domains will expand to the length of the lattice in order to form a new stripe domain.
21 Conti~nued nucleation of stripe domains in the 22 left-hand buffer zone and collapse of bubble domain rows 23 in the right-hand buffer zone will produce a number of 24 stripe domains 30 in the left-hand buffer zone. At this time, the lattice is shifted to the left and one-half of 26 the stripe domains created in the left-hand buffer zone are 27 collapsed by applying large currents to the conductors 34A
28 and 34B. This creates a large ma~netic field for annihilation Y0973-044 -~8-~05379~

1 of domains between these conductors. At the same time, new 2 stripe domains are being generated on the right-hand side 3 of the lattice.
4 - This operation continues until approximately one-half of the stripe domains initially produced in the 6 left-hand buffer zone have been collapsed and a corresponding 7 number of stripe domains have been formed in the right-hand 8 buffer zone. Thus, an arrangement is obtained having equal 9 amounts of stripe domains in both the left-hand buffer zone and the right-hand buffer zone.
11 The number of stripe domains required in the 12 buffer zones depends on the size of the lattice and on the 13 number of input/output ports. That is, there must be a 14 sufficient number of stripe domains to be able to move all bubble domains within the lattice to a column for accessing.
16 Generally, for a lattice containing 100 columns of 100 17 bubbles, with 1 input/output column at the center of the 18 lattice, about 50 stripe domains will be required in each 19 buffer zone. However, if there are two input/output column accessing ports spaced 1/3 and 2/3 of the distance 21 from th~ ends of the lattice~ then 34 stripe domains will 22 be required in each buffer zone.
23 The stripe domains have approximately the 24 same width and spacing as the bubble domains within the lattice. Therefore, it can be readily calculated how 26 many stripe domains are needed for a lattice of a given 27 size in a given area, with a given amount of input and 28 output column acces~ing ports. The fundamental principle 105~796 1 is that the buffer zones should have sufficient numbers 2 of stripe domains to insure that all bubble domains will 3 be able to be translated to a column for accessing from 4 the lattice. During this translation operation, the total number of stripe domains in both buffer zones 6 remains constant.
7 FIG. 8 8 FIG. 8 illustrates a lattice system in which 9 column accessing is used to remove bubble domains from the lattice. However, this system differs from that 11 shown in FIG. 2 in that the bubble domains removed from 12 the lattice are returned to the lattice after being sensed.
13 Whenever possible, the same reference numerals 14 will be used for the embodiment of FIG. 8 as were used for the other embodiments. Therefore, a lattice L comprised 16 of magnetic bubble domains 10 is present within the 17 confinement means 12. The confinement means also defines -18 a closed loop propagation path generally designated 106.
19 This propagation path is used to ve magnetic bubble domains around the lattice for re-entry therein after being 21 sensed. Additionally, propagation pump conductors 42L
22 and 42R are provided for moving bubble domains into and 23 out of the lattice L. The bubble domain pusher 52 is 24 provided as well as a bubble domain generator/splitter/
collapser 50.
26 On the other side of the lattice, a bubble 27 domain puller 66 is provided as well as a bubble domain 28 serial pusher 68. Bubble domain pusher 52 and bubble ~053796 1 domain puller 66 can be selectively opened and closed 2 to allow the bubble domains to move into and out of the 3 lattice L.
4 A bubble domain sensor 70 i8 provided and in addition, bubble domain puller/pushers 108A and 108B
6 are also provided. Pushers 108A and 108B are used to 7 move magnetic bubble domain-~ which have been deflected 8 by a gradient field produced by pusher 68. Accordingly, 9 they move magnetic bubble domains in the two propagation paths 102 and 104 into the closed loop 106 so that other 11 bubble domains can be detected.
12 In operation, the entire loop 106 can be 13 filled with magnetic bubble domains. This means that 14 application of current to the pump conductors 42L and 42R will expand domains in the lattice, thereby causing 16 domains to be moved to the pusher 68. This pusher allows 17 one domain at a time to move in the gradient magnetic 18 field. AccQrdingly, a domain in that field will move 19 either into path 102 or path 104 depending upon its wall magnetization state. Sensor 70 is then used to 21 detect the aomains after which they are moved further 22 along their respective paths by either pusher 108A or 23 pusher 108B. These pushers are synchronized so that the 24 relative order of the bubble domains is retained as they proceed toward closed loop 106. That is, by alternately 26 pulsing pushers 108A and 108B, the same order for magnetic 27 bubble domain movement will be provided.
28 By repeatedly pulsing conductors 42L and 42R, 29 domains within the lattice L will be sent to the read YO973-044 ~31-105;~796 1 station, detected, and then returned to their proper 2 places back in the lattice.
3 If the loop 106 is not initially loaded with 4 magnetic bubble domains, generator 50 can be used to provide domains for pushing other domains out of the 6 lattice and around the loop 106. For instance, it may 7 be desired to push twenty-five bubble domains at a time 8 out of the column of the lattice to be accessed. To do 9 this, pusher 52 is closed (that is, current in this pusher prevents bubble domains in the lattice ~rom moving 11 upwardly past pusher 52) and puller 66 is opened (that is, 12 no current flows in puller 66 so that bubble domains can 13 exit from the lattice in a direction toward this puller).
14 At this time, puller 66 is closed and pusher 52 is opened. A nucleated domain produced by generator 50 is 16 then split and placed in the column where domains have 17 left. Twenty-five new domains are produced by generator 50 18 which are pushed by pusher 52 into the column, thereby 19 replacing the twenty-five domains which have been removed from the lattice.
21, .Pusher 52 is then closed and puller 66 is opened 22 in order to repeat the operation for another twenty-~ive 23 domains. This continues until all domains within the 24 lattice column to be accessed have been removed from the lattice and detected. The bubble pump conductors are 26 then utilized to move domains around closed loop 106 until 27 the original domains within the lattice are returned to 28 the same positions within the lattice.

105;~796 1 Synchronization of the various functions performed 2 by the different components in the structure of FIG. 8 can 3 be accomplished by an external control means such as that 4 described with respect to FIG. 2. Such circuitry is well known in the electronics art and utilizes clocking and 6 timing pulses for triggering current sources used to activate 7 the various components.
8 In the operation of column accessing in accordance 9 with the present invention, bubble domain spacing within the lattice is established in a manner which allows a 11 column of bubble domains to be removed from the lattice.
12 That is, enough lattice flexibility exists such that a 13 desired column of bubble domains can be moved by the 14 bubble pump conductors into and out of the lattice. For instance, a lattice constant (center-to-center domain 16 spacing) of approximately 2 bubble diameters can be 17 utilized, in a typical lattice system.
18 What has been described is an improved technique 19 for accessing interactive elements contained within a lattice of such interactive elements. These interactive 21 elements can be any type of elements which tend to repel 22 one another. A particularly useful example is comprised 23 of a lattice of magnetic bubble domains. The present 24 accessing technique can remove columns of the interactive elements from the interior of the lattice, rather than 26 having to translate the column to be accessed to one end 27 of the lattice. That is, the interactive elements are 28 removed from the lattice in a direction substantially ~OS3796 1 transverse to the usual translation direction of elements 2 within the lattice.
3 The interactive elements within the lattice can 4 be moved in the lattice by conventional means or by using end buffer zones for shifting the lattice in two directions.
6 Whatever the means for moving the lattice, a column of 7 bubble domains in the lattice can be quickly accessed, 8 detected, and returned to the lattice. As an alternative, 9 the detected elements can be annihilated and the information rewritten into the lattice by other qimilarly coded inter-11 active elements.

.. ~ .

Claims (4)

The embodiments of the invention in which an exclusive properly or privilege is claimed are defined as follows:

1. An apparatus, comprising:
a lattice of interactive elements confined in a region where said elements interact with one another, translation means for translating said lattice while substantially retain-ing the size of said lattice and the relative positions of said elements within said lattice with respect to one another, said translation means including buffer zones on opposing ends of said lattice, said buffer zones containing further interactive elements.

2. The apparatus of claim 1, further including means associated with each said buffer zone for changing the number of interactive elements therein.

3. The apparatus of claim 1, where said interactive elements are magnetic bubble domains.

4. The apparatus of claim 3, where stripe magnetic domains are located on opposing ends of said lattice.