SU1133618A1 - Information store - Google Patents

Abstract

INFORMATION STORAGE, containing a magnetically uniaxial film, on which information storage registers are located, connected to switches of cylindrical magnetic domains, information write-erase channel, connected to information storage registers via corresponding information input-output keys, promotion channels of cylindrical magnetic domains, magnetically bound switches of cylindrical magnetic domains and with a ramified channel for sharing information, distinguished by the fact that, in order to increase the density awns information recording it contains additional switches cylindrical magnetic domains, connected to advance channels cylindrical magnetic domains, and additional channels prodvizh "; audio cylindrical magnit5 GOVERNMENTAL domains connected with additional switches cylindrical magnetic domains, and registers information.

Description

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The invention relates to computing and can be used in the development of storage devices on cylindrical magnetic domains (CMD) for external computer memory.

There are known accumulators of information (or) on CMD, containing a magnetically uniaxial film with CMD, on the surface of which the information storage registers are located.

It is known. They contain on the surface of a magnetically uniaxial film with a switchboard the information storage registers connected to the CMD switches, a record-erase channel connected to the information storage registers via the corresponding information input / output keys lj.

The disadvantage of this G is the presence of current-carrying copy and I / O busses of the CMD. This requires the use of complex technological methods for fabricating NI elements with HPC diameters of less than 2 µm, as well as the use of relatively high electrical voltage supply of the copy circuits, which hinders the increase in the recording density of the CMD information and requires a copy power supply source.

The closest technical solution to the invention is the NO on CMC 2, containing a magnetically uniaxial film on which it is located. information hrayeni registers connected to the CMD switches, the information write-erase channel connected to the information storage registers via the corresponding information I / O keys, progress channels magnetically coupled to the CMD switches and the branched information reading channel.

In the well-known NT, the DVR is copied by passive digital dividers located in the channel of the SchSchS, magnetically coupled to the CVP switches and an extensive reading channel of the DVC, which eliminates the use of conductive buses of the DVR copying as well as the power source of the copy circuits. It does not increase the recording density of CVC information, since active information I / O switches are easier to manufacture and require relatively low

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power voltage when compared with the structure of NI containing active dividers CVP 2j.

A disadvantage of the known NI is the presence of the conductor and; their busbar switches of the high-pressure cylinder I / O. In addition, the relatively low noise immunity of reading NI information on a high-pressure cylinder.

The purpose of the invention is to increase the information recording density.

The goal is achieved by the fact that NI contains additional .switches. PDCs connected to the advance channels of the high pressure cylinder and additional channels of the advancement of the high pressure cylinders connected to the additional digital switches and storage registers.

Due to the inclusion of additional 1SChC switches connected to the advance channels of a high-pressure cylinder, and additional advancement channels of the high-pressure cylinder connected to additional CVD switches and information registers, it is possible to eliminate active digital-disk I / O switches containing conductive buses by turning on the wireless switches I / O of CVDs and logic switches CM5d, formed in places of magnetic communication of additional switches of CVDs connected to the channels of advancement of Sch-Sch. This makes it possible to increase the recording density of information without having to change the structural structure of the NO and SchCH and without deteriorating its structural characteristics. In addition, paraphase output of information is carried out, which makes it possible to increase the noise immunity and reliability of reading information when two CVD readout sensors are connected to the output channels,

The drawing shows a schematic diagram of the proposed NI.

It does not contain a magnetically single film 1 with a high-pressure cylinder 2, on which 3 registers of information storage are located among ferromagnetic applications 3, connected to switches 5 of high-pressure cylinders, channel 6 of recording-erasing information with generator. 7 of recording high-pressure cylinders, switching element 8 and pushing branch 9 of channel 6, information input / output keys 10, including switching elements 11 and 12, progress channels 13 of the high-pressure cylinder, 3 connected to the CMD switches 5 at points 14 and forked information readout channel 15 at points 16 with branching points 17, generator 18 for these units (continuous CMD sequence), switching elements 19, advancing branch 20, dual CMD switches 21, consisting of switching elements 22 located at magnetic communication sites 16 and switching elements 23 connected to pushing branches 24 and 25, promotion channel 26 for reading SCH1D connected to branches 24, additional switches 27 of CMD connected to channels 13 of advancing CMD at points 28 located at locations 16 of magnetic connection, matching elements 29, additional channels 30 of advancement neither CMD connecting additional switches 27 with switches 5 of registers 4 at points 14 of magnetic connection, sensors 31 and 32 elements of tension connected respectively to channels 15 and 26, guard 33 necessary for outputting CMD from storage registers information. The number of periods of the advance elements in each of the additional switches 27 and the advance channels 30 of the high-pressure cylinder (there are two periods in the drawing) is equal to the sum of the periods of the advance elements from the points 14 of the magnetic connection to the points 28 (in the drawing over one period), from the points 28 of the channels 30 (in the drawing, applications of additional CMD switches are added, adding one control field period). The work of the proposed NI is based on the well-known method of controlling the advancement of the CMD using ferromagnetic applications and rotating clockwise and counterclockwise in the plane of the magnetically uniaxial film of the controlling magnetic field. The control magnetic field induces in the applications magnetic poles A, B, C and D, corresponding to the vector of the control field HF, which interact with the CMD and provide the motion of the latter. NI works as follows. When turning on the magnetic control field, rotating in a clockwise direction, from the generator 7 of the CM recording 8, through the switching element 8 through channel 6 with the frequency of rotation of the magnetic control field, i.e. during the control period, the recorded information is advanced in the form of the absence or presence of information CMD 2. Fill channel 6, the CMD fall either under the switching elements 12 of the input-output keys 10, or appear in close proximity (to 0.230, 75 periods of the control field) from the elements 12. If information was contained in the storage registers 4, then it falls under the switching elements 11. At the position G of the control field vector, the direction of rotation of the magnetic field changes. When rotating counterclockwise of the control of the magnetic field, the switching elements L and 12 work, which switch the CMD from channel 6 to storage registers 4 and, conversely, from storage registers 4 to channel .6. After two periods of the control field vector, the direction of rotation of the magnetic field changes again. When the control magnetic field vector rotates clockwise, the shifted switchboards fall into the initial positions of channel 6 and information storage registers 4, i.e. CMD-I1 exchange occurs. The described exchange mode of CVP is repeated; It is written two more times to write all the bits of the information sequence of the CMD channel .6 into the memory registers. The CMD information outputted from the storage registers 4 into the channel 6, upon further rotation of the magnetic field, enters the protective fence 33 and is output from the informational area of the film 1. The reverse, i.e. counterclockwise, the direction of rotation of the magnetic field causes the high-pressure cylinder to move channel 6 from left to right. At the same time, the I switching element 8 provides a short-term (not more than three periodosis) shift of the SchSch-information to the propulsive branch 9. Simultaneously with the operation of the generator. A 7, the generator 18 of recording single CMDs starts working. The latter passes the switching elements 19 and fills the channel 15 in advance mode. In the mode, the CVDs are located from the position G of the storage registers 4 for the reverse direction of rotation of the vector. Thanks to the operation of the switches 5, the channels 13 and the magnetic link 16 are located. After one and a half periods, the control fields of the CMD storage registers 4 are in positions B of channel 13, and the CMD of channel 15, the passage of branching point 17, appear in corresponding positions of B. Locate in places 16 of the magnetic connection of the CMD of storage registers 4 interact with the CMD of the channel 15, however, the switching elements 22 do not allow the latter to switch in the direction of the pushing legs 24 and the channel 26 when the vector Hz is rotated backward.

The reverse direction of rotation of the magnetic field causes the CMD channel 15 to move in the right direction to the left. In this case, the switching element 19 provides a short-term (not more than three periods) information shift into the pushing branch 20. When the control field vector is in position G, the direction of rotation of the magnetic field changes from reverse to forward. The CMD of registers 4 stored in channels 13, when the vector G is applied, interacts with the CVD of channel 15, get into the position G of channel 13 and switch channel 15 to the position G of the elements 22. If there were no CMD in the storage registers, then SCHZD channel 15 does not occur. ... After one and a half periods, the field is retracted in the forward directions and one and a half periods of the control field in the opposite direction. The CMD of registers 4 returns to their initial positions. Having switched CMD (copies of CMD register 4), corresponding to information units of registers 4 of storage j, elements 23 pass and enter forward lines 24, and uninterrupted CMD corresponding to informational registers of storage registers return to the original positions of channel 15. Upon further rotation the control field vector switched CMD passes branches 24, channel 26, and fall into the stretching element with sensor 32, into the non-switched CMD, passage 15, fall into the stretching element with sensor 31 ..

The recorded CMD reading mode is repeated two more times; 1) I read all the information sequences of the CMD, advancing along channel 15, corresponding to the information recorded in channel 6 by the CRMS information.

. Reverse rotation of the magnetic field in the readout mode of the data center due to the operation of the switching elements 11 and 12: the switching of the digital cylinders from channel 6 (if there are CMDs) in the I / O key branch 10 connected to the switching elements 12, as well as from the storage registers the key branches 10 of the input and output connected to the switching elements 11. However, after one and a half periods of the control field required to provide the read mode of the CMD, there is no exchange of data center information between the storage registers and the DVR write channel, and when changing In the direction of rotation of the magnetic field, the indicated CVPs return to their initial positions. In the mode of exchanging CVD information during cycles of reverse rotation that have lasted two periods of the control field N, due to the operation of the switches 5 in each of the storage registers, two CMDs can be switched to channels 6 and additional switches 27 of the CMD. After two periods, one of these CMDs gets into positions G of switches 27, and OTHERS - into positions G of channels 6. At the same time, the first high-pressure cylinders pass the .16 magnetic field, communication only during reverse rotation of the magnetic field and during its movement does not cause switching CVD of channel 15. When changing the direction of rotation of the magnetic field directly due to the operation of the switches 27, these CMDs pass. Additional channels 30 of the advancement of the CVP, points 14 and fall into their original positions of the storage registers 4. The second CMDs at the position G of the control field vector do not reach the locations of the 16 magnetic coupling channels and, therefore, also do not cause the switching of the CMD channel 1. When the magnetic field is directly rotated, these CMDs, like the first ones, fall into their original positions registers 4 storage. In the case of alternating read and exchange modes, switched 7 seconds. in the read mode in the branches 24 of the CMD channel 15 with the reverse rotation of the magnetic field, which begins after a period relative to the preceding period of rotation, due to the operation of the switching elements 23, they briefly enter the advancing branches 24. Dp ensuring the storage of the other, for example B or intermediate between B or B, the initial position of the control field vector contains matching elements.29 connected to the switches 27. In order to fulfill the memory operation modes on CR-Shch when using clockwise and prot in the clockwise arrows of the magnetic field it comprises a safety fence 3 Thus, the memory operation is performed with the output of paraphase.

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88 in which the main modes are provided by wireless devices of logical copying and exchange of CMD-information. In the proposed storage device, a data recording density is increased on 1DCD with a paraphase output and manufacturing technology is simplified by eliminating current copying buses and exchangeing CMDs, reading noise immunity is increased, or redundancy of output channels of CMD advancement is achieved due to paraphase output of the PLC information, it becomes possible to use The proposed structure for eliminating defective registers through the use of logical switching elements of a high-pressure cylinder.

Claims (1)

INFORMATION STORAGE containing a magnetically uniaxial film on which information storage registers are connected, connected to the switches of cylindrical magnetic domains, an information recording / erasing channel connected to information storage registers through the corresponding information input / output keys, promotion channels of cylindrical magnetic domains, magnetically coupled to cylindrical switches magnetic domains with a branched channel for reading information, distinguishing with the fact that, in order to increase the density of recording information, it contains additional cylindrical magnetic domain switches connected to the promotion channels of cylindrical magnetic domains, and additional cylindrical magnetic domain promotion channels, connected to additional cylindrical magnetic domain switches and information storage registers. With 3d X eleven