JPS6141072B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a magnetic bubble element that uses the presence or absence of a magnetic bubble as a single domain wall domain as information.

Magnetic bubble elements are produced in batches as bubble chips, and the chip configuration, magia minor loop configuration, was published in the magazine "Scientific Electronics American" in June 1971.
(Scientific American), Volume 224, No. 6, No. 78
Pages 90 to 90, especially proposed on page 90. Various chip configurations have been proposed based on this chip configuration, but recently a chip configuration (odd/even configuration) in which odd-numbered minor loops and even-numbered minor loops are placed in separate blocks has been proposed. (abbreviated) is used. This configuration was created in July 1978.
It is described in the magazine "Nikkei Electronics" published on the 10th, issue 190, page 40. The odd/even number configuration makes it possible to continuously write and read one bit from the chip for each rotation of the rotating magnetic field.
This chip contains two mager minor loop configurations that are functionally independent but have slightly different configurations. Therefore, even if two chips with slightly different configurations, each including one mager/minor loop configuration, are combined, a chip equivalent to an odd/even configuration chip can be obtained. Furthermore, since chips with approximately half the area can be used, it is expected that the overall yield will be improved.

However, since the two chips to be combined are of different types, two types of chips must be prepared.
The drawback is that this is accompanied by a price increase.

An object of the present invention is to provide a magnetic bubble element which can be realized at a low cost by using two chips of one type and which is equivalent to an odd/even chip structure.

Next, the present invention will be explained with reference to the drawings.

FIG. 1 shows a magnetic bubble element 10 as a conventional odd/even chip. Among the N (N is an even number) minor loops as bubble movement path loops, the odd-numbered minor loops 1-1, 1-3,
..., 1-(N-1) to the lower block, even-numbered minor loops 1-2, 1-4, ..., 1-N
is distributed to the upper block. Further, in the lower block, there is a transfer-in gate 121 that connects the bubble transfer path 111 and the minor loops 1-1, 1-3, ..., 1-(N-1) and the transfer path 111. , bubble movement path 131, minor loop 1-1, 1-3, 1-(N-1) and movement path 1
Replicate/Transfer to combine with 31
An out gate 141, a bubble generator 151 on the moving path 111, a bubble detector 161 on the moving path 131, and a dummy detector 171 are provided.

On the other hand, the upper block has a bubble movement path 11.
2 and minor loop 1-2, 1-4,..., 1-
Transfer-in gate 112 and bubble transfer path 132 that connect N and transfer path 112, and a replicate/transfer gate that connect minor loops 1-2, 1-4, ..., 1-N and transfer path 132. An out gate 142, a bubble generator 152 on the travel path 112, a detector 162 on the travel path 132, and a dummy detector 172 are provided.

Minor loop 1-(N-
1) up to the position on the moving path 111 opposite to (N
_G +1) bits away from the generator 152;
The position of the moving path 112 facing the loop 1-N is N _G bits away. On the other hand, the distance from the position on the moving path 131 facing the minor loop 1-1 to the detector 161 is N _D bits away, and the distance from the position on the moving path 132 facing the minor loop 1-2 to the detector 162 is ( N _D +1) bits apart.
Using such a magnetic bubble element 10 enables the following operations.

First, the operation during writing will be explained. Generator 151
If a single conductor 153 is provided in common as a conductor for the generators 151 and 152, and an N-bit information string is written in the same way from the generators 151 and 152, one bit per revolution of the rotating magnetic field, the When the first information bit reaches the position opposite to the minor loop 1-1 on the movement path 111, the second information bit reaches the position opposite to the minor loop 1-1 on the movement path 112.
Reach the position opposite 2. In this way, all the odd-numbered information bits reach the positions opposite the minor loops 1-1 to 1-(N-1) on the moving path 111, and at the same time all the even-numbered information bits reach the positions opposite the minor loops 1-1 to 1-(N-1) on the moving path 111. Minor loop 1-2~1 on 112
- Reach the position opposite N. Immediately after this, transfer-in gate 121 of the lower block
By passing a current through the conductor 123 provided in common to the transfer-in gate 122 of the upper block, the odd-numbered information bits of the information string are transferred to the minor loops 1-1 to 1 of the lower block.
1-(N-1), and the even-numbered information bits of the information string are stored in the minor loop 1-(N-1) of the upper block.
2 to 1-N.

Note that before storing the information string, the replicate/transfer out gates 141 and 14
Minor loops 1-1 to 1-(N-
1) and the information that you want to delete from minor loops 1-2 to 1-N are moved to the movement path 131 and movement path 132, respectively.
It is necessary to transfer the data to the detector 161 and the detector 162 and erase it.

At the time of reading, by passing a current through the conductor 143, copies of the information to be read from the minor loops 1-1 to 1-(N-1) and the minor loops 1-2 to 1-N are moved to the movement path 131, respectively. Road 132
Output to. Since the positions of detector 161 and detector 162 are shifted by one bit as explained earlier, the duplicated information is transmitted between detector 161 and detector 1.
62 is reached alternately. Therefore, the detector 16
1 and the detector 162, it is possible to detect one bit of information per revolution of the rotating magnetic field.

In an actual magnetic bubble element, the values of N=140, N _G =3, and N _D =40 are used as described in Document 1. However, N, N _G , and N _D are not limited to these values.

As shown in FIG. 1, the magnetic bubble element 10 includes two mager-minor-loop blocks that are functionally independent but differ only in the positions of the generator and detector. For magnetic bubble elements that are produced in bulk, the smaller the chip area, the better the yield. Therefore, if the lower block and upper block are each realized using separate chips, and these two pieces are combined, the magnetic bubble element 10 can be obtained with high yield. However, in this case, two types of chips are required, resulting in an increase in price. The magnetic bubble element of the present invention solves these problems, and the details thereof will be explained below.

FIG. 2 shows a magnetic bubble element 20 of the present invention.
This element has N/2 (N is an even number) minor
Loops 2-1 to 2-N/2 are provided. A bubble movement path 21 is arranged on the left side of the minor loops 2-1 to 2-N/2. Near one end of the moving path 21, a generator 251 and a generator 252 are installed.
are located adjacent to each other. Transfer-in gate 22 controls the transfer of information from movement path 21 to minor loops 2-1 to 2-N/2.
On the other hand, a bubble movement path 23 is arranged on the right side of the minor loops 2-1 to 2-N/2. Travel route 2
Near one end of 3, a detector 261 and a detector 262 are provided adjacent to each other. Furthermore, a dummy detector 27 is provided closer to the outer periphery. Replicate/Transfer Out Gate 24
has a control function to copy and transfer information from the minor loops 2-1 to 2-N/2 to the movement path 23, or to transfer it as is.

In this element 20, the generator 251 outputs a minor signal.
The position on the moving path 21 corresponding to the loop 2-N/2 is N _G bits away, and the position on the moving path 23 corresponding to the minor loop 2-1 to the detector 261 is N _D bits away. Next, it will be explained that an element equivalent to the magnetic bubble element 10 of FIG. 1 can be constructed by using two such magnetic bubble elements 20.

FIG. 3 is a wiring diagram for constructing an element functionally equivalent to the magnetic bubble element 10 of FIG. 1 by using two magnetic bubble elements 20 of the present invention shown in FIG. 2. One terminal of the generator 252 of the lower magnetic bubble element 301 and the upper magnetic bubble element 30
One terminal of the generator 251 of No. 2 is connected with a conducting wire 35, one terminal of the detector 261 of the magnetic bubble element 301 and one terminal of the detector 262 of the magnetic bubble element 302 are connected with a conducting wire 36, and further, Transfer-in gate 2 of magnetic bubble element 301
One terminal of the conducting wire 321 for 2 and the magnetic bubble element 3
Conductor wire 3 for transfer-in gate 22 of 02
21 with a conductive wire 322, and the conductive wire 341 for the replicate/transfer out gate 24 of the magnetic bubble element 301 and the conductive wire 341 for the replicate/transfer out gate 24 of the magnetic bubble element 302. By connecting each of one terminal with a conductive wire 342 and connecting each dummy detector 27 of the magnetic bubble element 301 and magnetic bubble element 302 with a conductor 37, a magnetic bubble element equivalent to the magnetic bubble element 10 of FIG. A magnetic bubble element can be obtained.

FIG. 4 shows a second embodiment of the magnetic bubble element of the present invention. This element 40 is provided with N/2 minor loops 4-1 to 4-N/2. A bubble movement path 41 is arranged on the left side of the minor loops 4-1 to 4-N/2. Travel path 41
A generator 451 and a generator 452 are installed at one end of the
are located adjacent to each other. At the other end of the moving path 41, a detector 461 and a detector 462 are provided adjacent to each other. Furthermore, dummy detector 47
is located near the outer periphery. The means 42 for coupling the minor loops 4-1 to 4-N/2 and the travel path 41 is a replicate/transfer out gate or a replicate/swap gate.
It is a gate.

Two such magnetic bubble elements 40 are arranged side by side, the conductor for the generator 452 of one element is connected in series with the conductor for the generator 451 of the other element, and the conductor for the detector 461 of one element is connected in series with the conductor for the generator 451 of the other element. If the conductors for the detector 462 of the element are connected in series, the conductors for the coupling means 41 of both elements are connected in series, and the conductors for the dummy detector 47 of both elements are connected in series, the magnetic bubble element of FIG. A magnetic bubble element similar to No. 10 is obtained which is capable of continuously writing and reading one bit per revolution of the rotating magnetic field.

Means 4 for coupling the magnetic bubble element 40 in FIG.
2, when a transfer-in gate is used, the moving path 41 may be formed into a loop, and an eraser may be provided in that portion. At this time, the generator 451 and the generator 452 are given the function of an eraser,
The eraser can also be omitted.

Two terminals are provided for each of the two generators included in the magnetic bubble element 10 in FIG. 1 and the magnetic bubble element 40 in FIG. 4, but one terminal of each is shared, making a total of three terminals. It can be done. The same can be said about the terminals of the detector. In these elements, the generators are adjacent on the travel path, but one of the two travel paths containing one generator is configured to be merged, and the distance from each generator to the merging point is Even if they differ by one bit, the same purpose can be achieved.

The magnetic bubble element of the present invention has been explained above, but
In various magnetic bubble elements realized by a combination of functional elements such as gates, the magnetic bubble element of the present invention can be obtained by arranging a generator and a detector adjacently. Furthermore, a connected magnetic bubble element as shown in FIG. 3 can also be obtained by manufacturing a chip containing two magnetic bubble elements 10 as described above and performing wiring within the chip. The same can be said of the magnetic bubble element 40.

[Brief explanation of the drawing]

Figure 1 is a schematic diagram of a conventional magnetic bubble element, Figure 2 is a schematic diagram of a conventional magnetic bubble element.
The figure is a schematic diagram of a magnetic bubble element according to the first embodiment of the present invention, FIG. 3 is a connection diagram of two magnetic bubble elements according to the present invention shown in FIG. 2, and FIG. FIG. 2 is a schematic diagram of a magnetic bubble element as a second embodiment. In Fig. 2, 2-1 to 2-N/2 are minor loops as bubble movement path loops;
1 and 23 are bubble transfer paths, 22 is transfer path.
24 is a replicate/transfer out gate, 251 and 252 are generators in adjacent positions, 261 and 262 are detectors in adjacent positions, and 27 is a dummy detector. In FIG. 4, 4-1 to 4-N/2 are minor loops, 41 is a moving path, 42 is a means for connecting the minor loops 4-1 to 4-N/2 and the moving path 41, 451 and 452 are generators located at adjacent positions, 461 and 462 are detectors located at adjacent positions, and 47 is a dummy detector.

Claims (1)

[Claims] 1. A magnetic bubble element comprising a travel path loop, a generator and a detector provided in the travel path and coupled to the travel path loop by a coupling means, wherein the generator and the detector are A magnetic bubble element characterized in that two magnetic bubble elements are provided at adjacent bit positions. 2. The magnetic bubble element according to claim 1, wherein the moving path provided with the generator and the moving path provided with the detector are separate moving paths. 3. The magnetic bubble element according to claim 1, wherein the generator and the detector are provided on the same movement path. 4. The magnetic bubble element according to claim 3, wherein the movement path is loop-shaped and includes an eraser. 5. The magnetic bubble element according to claim 4, wherein the generator also serves as an eraser.