DE1238505B - Magnetic data storage - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

GlIc

German class: 21 al - 37/60

Number: 1 238 505

File number: B 56004IX c / 21 al

Filing date: December 23, 1959

Opened on: April 13, 1967

It is known in the art of electrical data processing and exploitation to have an indication in magnetic material with high remanence properties by encrypting the information in store binary form and the two possible directions of the remanence property of a magnetic Element arbitrarily assign the two possible values of a binary information element. It is generally desired that such stored indication be in the form of an electrical signal is recoverable. Two main ways have been found to do this, technically and economically to be able to perform. In one case (for strip, drum and disk storage) the magnetic material moves quickly past a scanning or reading head, in its windings Voltages are induced which represent the state of magnetization of the magnetic material. Such a procedure does not usually destroy the information stored in this way, it however, has the disadvantage that a movement lying within very narrow mechanical tolerances at a fairly high speed and that of the desired specification usually some access time must be allowed to get to the head. Fixed or static Memories with a large number of magnetic elements are usually used, if not it can be foreseen which particular information is required at a certain time and a arbitrary access is therefore highly desirable. The conversion of such stored magnetic Data in an electrical signal is usually done by applying a field to the magnetic element which brings the element to saturation in the direction of the field. if the element was retentive in the opposite direction, becomes the one associated with that inversion strong flux change in the conductors coupled to the magnetic element create a voltage induce. This type of reading of the stored information brings the magnetized element always in the direction of the reading field and therefore destroys the stored information. There are many processes for which the same information is required repeatedly. To do this a memory To be able to use with destructive reading, a regeneration of the read memory contents must be carried out be carried out, which simply consists in the fact that the information just read outside is saved and then re-recorded. There is time and an appropriate device for this Magnetic data storage

Applicant:
Burroughs Corporation, Detroit, Mich. (V. St. A.)

Representative:

Dipl.-Ing. H. Kosel, patent attorney,

Bad Gandersheim (Harz), Braunschweiger Str. 22

Named as inventor:

Robert Lloyd Gray Jr., Broomall, Pa. (V. St. A.)

Claimed priority:
V. St. v. America December 24, 1958
(782 914)

necessary. This procedure is therefore undesirable, but it is a tolerable evil Given the great advantages of random access and the high speed of operation, the can be achieved through the use of static memories. It is currently common practice to be complete Providing computing systems with different types of magnetic storage, and this fact is probably the best evidence that no particular type of common data store is any is significantly superior to others.

Up until now, it was customary to use separate pieces of magnetic material for the individual bit elements or memory cells Materials to use, usually ring-shaped cores, to store binary in static To save information. Such a known memory element for querying without loss of information is the so-called Transfluxor, it consists of an essentially ring-shaped piece of magnetic Material that is magnetized essentially in a ring shape in two different directions can be and in which a limited sub-area in the middle of the annular magnetic flux path for reading is used. A major disadvantage of these known memory cells is that a subsequent re-reading from the memory cell is only possible after the limited sub-area has passed Application of an external magnetomotive force of suitable polarity to the earlier magnetization state is fed back, including additional windings, driver devices and logic circuits.

709 549/283

become necessary. Furthermore, a non-destructive query with the coercive force is not possible with toroidal cores reaching impulses possible, whereby only undefined molecular parts of the nucleus are remagnetized will. In addition, a memory arrangement is known which provides non-destructive reading made possible by the action of mechanical force on the storage material. All of these known However, what devices have in common is that they do not have a compact structure of the individual memory cells (Bit elements) allow.

The use of elongated pieces of magnetic material with a capacity for a number of information elements in a single piece is also known. In general this will be the delimitation lines between the various sections of such a piece of magnetic material, which are used to store various items of indication through the magnetic fields determined, which are brought into effect from the outside on the magnetic material. It was recognized as necessary, between the various information elements corresponding adjacent sections to leave enough space so that the magnetic fields that are brought into effect to only as influencing such a section have no effect on the adjacent section. These elongated Elements allow a compact structure, the reading methods that have become known for them up to now but always cause the destruction of the stored information.

It is therefore an object of the invention to provide a static magnetic memory for the compact structure of the individual bit elements, d. H. to create the individual memory locations from which the inscribed Can read out information non-destructively, with the circuit complexity for the memory cells should be reduced.

The subject of the invention is thus a magnetic data storage device, consisting of a lengthwise Body of magnetic material with a substantially rectangular hysteresis loop a storing magnetization device of known construction, which magnetizes with the body Material is operatively connected to a storage portion thereof in a first direction of polarization to magnetize, which represents a first indication value, and to this section of the Material to magnetize in the opposite second polarization direction, which is a second Represents indication value from an interrogation magnetizer of known construction, the associated with the piece of magnetic material, and from an indication evaluation device of known art Construction that changes the magnetic flux in the magnetic material when the Inquiry magnetizer displays.

The characteristic feature of the data memory according to the invention is that the interrogation magnetization device only in a limited part of the memory section during an interrogation process generates a magnetic field whose field strength exceeds the coercive force of the limited part and thereby magnetizes the limited part in a predetermined direction, while the magneti- 6g Sizing direction of the remainder of the memory section is essentially unaffected, and that the remainder of the storage section in the limited part generates a magnetic field, the field strength of which is the coercive force of the limited part also exceeds and the direction of magnetization of the limited part on Controls the end of a query process.

Thus, according to the invention, a single piece of magnetic material is used to store a plurality of nondestructive reading elements used with the value of each stored Elements can be changed at will. All the advantages of random access, density, high operating speed of the static memories are maintained. Because of the query process The rest of the group will automatically control the limited part after the query the known devices required additional circuit elements to reverse this to a limited extent dispensable. In the drawing shows

F i g. 1 shows a data storage device according to the invention for storing four binary data elements and for non-destructive reading of the stored data;

Fi g. 2 a, 2 b and 2 c illustrate for better Explanation of the principles of the operation of the invention schematically a development of a section of the material shown in Fig. 1, specifying the magnetic fields brought into effect and the resulting directions of magnetization.

In Fig. 1, 21 α and 21 b denote the conductors around which strips 22 a and 22 b of magnetic material are wound, which essentially have a preferred direction of magnetization along their length and an essentially rectangular hysteresis loop (curve of the magnetic flux density as a function of the magnetic Field strength). Such a material is known and can for example consist of a molybdenum-nickel-iron alloy (ζ. Β. 4% molybdenum, 79% nickel, 17% iron) which is not annealed after the last rolling. The convenient shape of this material is a strip 0.003 mm thick and 0.425 mm wide. The winding takes place in such a direction that the length of the strips 22 a and 22 b extends helically around the axis of the corresponding central conductor 21 α and 21 Z). The direction of easy or preferential magnetization is therefore also helical about these central axes. At two different points in the longitudinal direction of the wrapped units 21 a, 22 a and

21 b, 22 b are wound around the same the coils 23 a and 23 b. In addition, around the conductor 21a and strip 22 α or from conductor 21b and strip

22 b existing units, essentially between the ends of the winding of the coil 23 a, the coil 24 a wound, which can be located outside or inside the coil 23 α or between the turns of the same. The basis of the invention is that the coil 23 α, a magnetic field of uniform direction over a portion of the strips 22 a and 22 b is to generate larger including, as that portion of the strip 22α, 22b and the same, via which the coil 24 α generates a magnetic field. In other words, when the coil 23 conducts α current, it generates a magnetic field over a portion of the strips 22 a, 22 b, and when the coil 24 conducts α current, it generates a magnetic field only on a part of this portion.

In the F i g. 2a, 2b and 2c, that portion of the strip 22 α is shown, which is in the effective field of the coil 23 α . It is simply the unwound strip 22 a shown, which represents an elongated body. This representation has the convenient property that the axis or direction of easy magnetization appears as a straight line, so that the direction of magnetization also appears as a direction along this line.

Fig. 2a illustrates the specified section of the strip 22 a, with all parts of this section are magnetized in the same direction as indicated by arrows 101 α, 102 α and 103 α is. This effect occurs when through the coil

23 a a magnetic field component is brought into effect, which is directed to the right and the is greater than the coercive force of the material of the strip 22 a.

Fig. 2b illustrates a state which is identical with that of Fig. 2a, with the exception that the direction of magnetization of the middle part of the section shown the strip 22 a designated b by the arrow 102, opposite to the direction is that shown in FIG. 2 a is indicated by the arrow 102 a. This effect is created when current passes through the coil

24 a, a magnetic field is brought into effect, which is opposite in its direction to that which is brought into effect by the coil 23 α to the effect shown in FIG. 2a to generate the illustrated state. In the case of the one shown in FIG. 2a, there is a substantially continuous magnetic flux along the entire length of the section of the strip 22 a, which is mainly present within the strip 22 α, so that practically no magnetic flux occurs between the strip 22 α and the boundary lines between 101 a and 102 a or between 102 a and 103a leaves. In contrast, the embodiment illustrated in Fig. 2b state results in the presence of magnetic poles at the boundary lines between the arrows 101a, 102 b or between the arrows 102 b, 103 a. This physical fact can be expressed differently by saying that the magnetic flux represented by the arrows 105 leaves the strip 22 a at the boundary between the arrows 101 a, 102 b and returns at the boundary between the arrows 102 b, 103 α . According to known physical principles, in this state the middle part of the section of the strip 22a, indicated by the arrow 102 b, is subjected to the action of a magnetic field of insufficient amplitude, which tends to turn the magnetization of the middle part in the direction according to arrow 102 a . If a magnetic field component comes into effect in the direction indicated by the arrow 104 due to the passage of current through the coil 24a, a certain amplitude of this field component will be sufficient, in view of the presence of the fields indicated by the arrows 101a and 103a, to magnetize the central part to reverse, so that the state illustrated in Fig. 2a is restored. Are other hand, if the state of the illustrated portion of the strip 22a is as in Fig. 2c, in which all parts of the Streifenabschnits magnetized in the same sense indicated by the arrows 101 b, 102 b provided b and 103, the The same amplitude of the magnetic field component indicated by arrow 104 is not sufficient to reverse the magnetization of the central part of the section of strip 22 a, because the fields indicated by arrows 101 b and 103 b counteract this reversal. It is true that the conditions illustrated by Figures 2a and 2c, in which all parts of the portion of the strip 22a are magnetized in the same direction, result in the presence of some magnetic flux from the extremities of the strip portion passing through the space outside of the strip 22 a returns. However, since the extreme ends of the illustrated section of the strip 22 a are relatively far removed from the ends of the middle section indicated by the arrow 102, the magnetic field generated in this way at the middle part will be negligibly weak. It is a known fact that the demagnetizing effect of the poles of a bar magnet on the center of such a magnet becomes weaker as the bar magnet is made longer. A similar situation exists here. After the above explanation of the physical phenomenon under consideration, the mode of operation of the device according to the invention can now be described in more detail. The entire section of the strip 22a shown in FIGS. 2a, 2b and 2c is used to store a certain element of a binary indication by magnetizing this section accordingly by passing current through the coil 23 α. If, for the sake of simplicity, the expressions "1" and "0" are used to denote the two possible values of an item of information, the in FIG. 2a as the state "1" and that in FIG. The state shown in FIG. 2 c is referred to as the state "0" of the strip section. These two represent states which correspond to the recorded information. To determine which information is recorded in this manner, a Ablesefeldkomponente the direction of arrow 102 b (Fig. 2b, 2c) brought into effect by current is passed through the coil 24 α. The magnitude of this field component is sufficient so that in the case of a strip section (FIG. 2 a) in the "1" state, the magnetization of the central part thereof is reversed. 2 b state shown is reached. There is a substantial change in the flux through the central part of the strip section, so that a voltage is induced in all conductors connected to the central part. If, on the other hand, the strip section is in the "0" state, the action of the reading field on the magnetization of the strip section will only have a negligible effect, which, due to the very small change in the flux, only brings the central part from the remanent to the saturated state and into the induces only a very low voltage with the same connected conductors. The state of the strip section which was in the "0" state before reading will therefore be essentially unchanged after reading.

These two states are illustrated by Figure 2c.

The reading process described did not destroy the stored information, as did the status of the

Strip section after reading shows the overlap amounting to a third of the strip width

after whether a "1" or a wound up before reading. For the coils 23 a and 23 b are

"0" was stored is different. For a 40 turns of a wire with a diameter

stored "1" changes the reading process, wound at least 0.28 mm, so that the total length

At least temporarily, the magnetic state of the 5 of the winding is approximately 12.7 mm. For the

Strip section, as can be seen from the differences between coils 24 a and 24 ft, are ten turns of one

between Figs. 2a and 2b results. If the wire with a diameter of 0.125 mm

Coercive force of the strip 22 a wound sufficiently low, so that the total length of the winding un-

is, the field strength of the danger in the »1« state is 1.58 mm. These coils are among the

remaining outer parts of the strip section io coils 23 a, 23 b wound and relative to the relevant

Sufficient magnetic field formed, the central part fenden coils essentially centered. The wires

the same immediately after cessation of the action are isolated with a usual enamel. The distance

the reading field component again in the origin between adjacent ends of the coils 23 α and

borrowed state "1". However, it is 23 b is about 2.5 mm.

It is possible to embody the invention with materials as well. In order to illustrate the principles of the invention in an embodiment which is less complicated and which has such a high coercive force, that this spontaneous return does not occur. One of those for modern arithmetic and data processing restoring operations, which is desirable without knowledge of the machine, are shown in FIG. 1 stored information can be carried out, different coils are arranged in such a way that they return the strip to the state it had 20 using certain devices to choose from before reading it. This restoring process of special strip sections for the recording of consists simply in the fact that by passing information through the combined action of different currents through the coil 24 a, a field composition of magnetic field components is made possible. It is nent that is brought into effect, which is possible for the reading field, a resulting magnetic field in the essential component directed in the opposite direction and of small size along the helical direction of the direction. As has been described above in connection with the device of the easy magnetization of the strip 22 α, FIGS. Due 2a as the coil 23 a, a Magnetdem state shown in Fig. 2b overall in the state field component is produced which essentially measure FIG., But with the inlet 30 along the central axis of the conductor 21a or 21b of the stand in F i g. 2c of the strip section shown and by not changing by passing current through it. It goes without saying that a magnetic field recovery process can be generated at the same time by the conductor 21 α between one another component around this conductor. A subsequent reading can be carried out. The current which flows from earth through the coil 23a and there is no reason for the restoring field to emerge again as something at the ungrounded end generates something other than a special part of the entire discharge, therefore according to FIG. 1 at the left-hand sections of the reading field, from this point of view the strips 22a and 22b are a magnetic field which is bipolar. But it can also be a back storage is directed to the right end of the figure. If the field component are provided, which during the current passing through the coil the correct whole operation of the device, but which has 40 strength, this magnetic field component will not be sufficient during the reading process from the reading field alone to the strip 22 α or the component is overcome. Such a constant strip 22 b to magnetize. If, however, an active field can be obtained by ent- current flowing from earth through the conductor 21 α and at the left end of the conductor 21 α, which is not continuously earthed, a current of a fixed strength is again passed through an additional coil, 45 exiting this current is a magnetic field com which is wound together with the reading coil 24a, component around the conductor 21 α. By using continuously a current through the coil regulating the thickness overcome the α through the conductor 21 through 24 is passed α, but sired magnetic field component current as large by the through continuous current, the passing of the same Erdie same coil Ableseimpuls- right or will. Be from any point of view that it is 50 together with the Magnetfeldkomaus the reading process described above does not decompose the component coil 23 α disturbing the inside of this coil, because it is not necessary for the exhaust section of the underlying strip 22 a from a zulesen Carry out a process that can magnetize from the particular »0« to the state »1«, depending on the values of the information read off. The magnetic field component generated by the coil 23 a is not sufficient on its own to magnetize any absences, ie for a time of 1 to 1.5 microsection of the strip 22, and the Seconds for the reading and restoring process, from the magnetic field component generated below through the conductor 21 α, the current specified below is preferably sufficient dimensions alone are used. It should be noted that the operation at a few high speeds 60 does not suffice to magnetize the section of the strip 22 a lying outside the coil 23 α, in particular the use of somewhat larger dimensions, especially the one essentially inside the coil 23 b , while for operation at higher speeds, the section of the strip 22 a. It is therefore preferred that dimensions are reduced as much as possible to the coincident current through the coil 23 α as proportionally as possible. Send the medium-, α around the through conductors 21 and 216 hinleren conductors 21 a, 21 b are made to allow copper wire 65 through-currents, those Abeinem mm diameter of 0.14. The strips 22 a, cuts the strip 22 a and 22 b on the inlet 22b are 0.003 mm thick and 0,425 mm wide. You stood to magnetize "1", which lie within the effective field generated by either without overlap or with up to two the coil 23 α.

Individual information elements or binary digit "1" signals can be applied to conductors 21α and 21 &. As the above explanation indicates the presence or absence of coincident currents in the coils 23 a or 23 S, the recording or non-recording of "1" in the portions of the strips 22 a and 22 b determine which of the respective coils by the fields to be influenced. The in F i g. The arrangement shown in FIG. 1 can be viewed as consisting of two "words" each consisting of two binary digits. It follows that the reading current, which goes through the coil 24 a to earth, reads the information stored in the left-side sections of the strips 22 a and 22 b , the signals as induced voltages at the ends of the conductors 21 α and 21 b appear while the reading current acting on the coil 24 b reads the information stored in the right-hand sections of the strips 22 a and 22 b , the signals again appearing as induced voltages at the ends of the conductors 21 α and 21 b. It also follows that an oppositely directed current in coil 23 α, which is sufficiently stronger than the coincident current, will reverse the "0" state of the left-hand sections of strips 22 a and 22 & (FIG. 1), whereby the known operation of deleting the word stored in these strip sections is carried out.

A modern data processing machine can operate at extremely high speeds, but the acquisition costs are considerable. Often times, economy requires that certain parts of the device perform a number of different functions at different times, these functions either being chosen so that the same device performs functions that cannot logically be performed simultaneously or with controls being provided so that the execution electrical signals corresponding to a function received signals to conductors 31a and 31b. If the information source 102 is not to function as such, it forms a relatively high shunt impedance between the conductor 31a and earth or between the conductor 31b and earth, so that a large part of the currents is not diverted as a result of the reading process in the Conductors 21a and 21 & induced voltages flow. According to the signals received from the control signal source 101 via the line 203, the column and erase pulse source 203 delivers a coincident current of a certain polarity and strength or an erase current of opposite polarity and lower strength via the conductors 33 α or 33 b either to the coil 23 a or 23 b, depending on the particular control signal received. Since at least four possible functions come into consideration, these control signals can be encrypted pulses that are transmitted over a single line, or the line 203 can be replaced by several separate conductors that separately carry a signal to perform a specific function. However, any other known combination of conductors and signals can also be used. The information evaluation device 104 receives the stored information when the same has been read from the memory in the form of electrical signals. The device 104 is connected to the control signal source 101 by the line 204 so that it can function accordingly when the control signal source 101 causes the reading of stored information as a result of actuation of another associated device and so that it is ineffective or insensitive to the relatively high voltages that occur during the Information recording process on the conductors 31 α and 31 b come into effect, as well as against any voltages that are generated during an erase process. Upon receipt of the appropriate

35

is postponed until a non-consistent 40 control signals from the control signal source 101 via the function to be brought has ended. Since such a line 205 brings the reading and restoring measure a power source 105 either

Subdivision of the function to a large extent an ad hoc characteristic of a particular computing machine training and since these and other embodiments of the invention extend to a large number Applicable by machines that require data storage are by rectangular Devices are shown in the box, the functional capabilities of which are described below and whose training is largely known. In a modern adding machine, however, the elements used to perform these functions, also to perform others Functions are used. In addition, the device, which is a particular rectangular Performs functions assigned to boxes, does not appear as a single unit in a modern calculating or data processing machine, but can be distributed throughout the machine.

power source 105 either on the coil 24 ″ via the conductor 34 α or on the coil 24 b via the conductor 34 b a reading current pulse of certain polarity and strength to effect and (either immediately after the reading current pulse has ceased or, if desired, a little later) a restore pulse from the Reading current pulse of opposite polarity and lower strength. As can be seen from the explanation of FIG. 2, the reading pulse must have sufficient strength to reverse the sense of magnetization of the central part of a particular strip section in spite of the opposing magnetic field which is formed by the end parts of the strip section. On the other hand, the restore pulse must be so much weaker that it restores the original sense of the magnetization of the central part of the particular strip section if it (and only if it)

55

The teaching of the invention is carried out through the use 60 of that of the end portions of the strip section

the function box clarifies.

The control signal source 101 generates according to the logical needs of the computing or data processing machine At the right times signals to the results described below to achieve. The information source 102 supplies the binary information to be recorded and contributes to it The magnetic field formed by the control signal source 101 via the line 202 is supported.

A typical operation of the process shown in FIG. 1 is the following:

The control signal source 101 causes the column and erase pulse source 103 via the line 203, to send an erase pulse via the conductor 33 α through the coil 23 α to earth, from where the same to Source 103 returns. Simultaneously or immediately

709 549/283

11 12

bar subsequently sends the column and erasing is used, of course, sufficient pulse source 103 has an erase pulse are held weakly on the conductor, so that no risk be-33 b through the coil 23 b to the ground, from where the same is that he any Sections of the strip returns to source 103. Each of these quenching currents returns to the "0" state, which is already (and generates pulses when passing through the relevant 5 correctly) in the "1" state of the magnetization fende coil a magnetic field that is located after the left. In practical operation, the choice side of the figure will be directed and this alternative method will have such strength from the relative that its component will depend along the direction of cost and the ease of control tolerances of easy magnetization of the inside of the coil as well as various other factors Sections of Strips 22a and 22b io The invention relates primarily to the action greater than the coercive force of these strips. DA proper strengths of the magnetic fields on which is bedurch causes the inscribed within the coil parts of the strip, which is already on α-ver 23 and 23 b past four strip portions has been carried out in various ways. However, when magnetized in a direction that a component in the left-hand side portion of the strip 22a has a “1” component toward the left-hand side of FIG. In Fig. 15 is to be stored, conductor 21a via conductor 31a to the information source is drawn from the earth by consistency with the above description, this direction is arbitrarily drawn to the state "0" - 102 a recording current pulse of such is assigned. The whole magnetic memory therefore contains "0" strength drawn that it is drawn around the conductor 21a or is erased. A little later, the control sends a circular magnetic field that combines with the signal source 101 via the line 203 a signal to the field of the coil 23 α in order to generate a resultant column and erase pulse source 103, which causes a component to be generated along the direction that this from the earth via the solenoid 23 α and direction of the slight magnetization of the left-hand side the conductor 33 α draws a coincident pulse, the portion of the strip 22 a, which has stronger strength than the erase pulse, so that ker is than the coercive force of the strip and into the resulting magnetic field which runs through the coincident direction in such a way that it magnetizes this section of the pulse around those sections of the strips of the strip 22a in the "1" direction. 22 'and 22b is generated, which are essentially within the The strength of the drawn by the conductor 21a on the coil 23 α, a component along the drawing current is limited, so that the direction of the easy magnetization of these same at other sections, in particular the strip sections which are weaker than the section of the coercive force of the strip lying within the coil 23 b. At about the same time the magnetic field generated by the strip 22a a component sends the control signal source 101 over the line along the direction of the slight magnetization of the 202 a signal to the information source 102, which causes the strip 22a, which is smaller than the coercion that this from the earth through the conductor 21a and 21b tivkraft of the strip. The b within the coil 23 via the conductors 31a and 31 b recording pulses 35 pulls exposed portion of the strip 22 a remains, therefore, in that correspond to the information elements "1", deleted, or "0" state. In this way, the to be recorded at this point in time or to be stored in the left-hand sections of the strips 22 a and. It is assumed that the word to be stored 22 b optionally records the information consisting of the binary digits 1 and 0, a “1” in the section on the left-hand side. It is more natural for the ninth stripe 22a and a "0" in the left-hand section which changes to the section of the stripe 22b are. Since the required method described above, a record "0" is already recorded in the correct section of the strip 22 b voltage of signals in the other sections of the recorded, the conductor 21 b need not cause a strip and also that the number is drawn to will. Since the coincident current of the coils along a certain strip and in the coil 23 α explicitly made weaker 45 conductor arrangement can be significantly increased in order to be sufficient to achieve a larger data storage capacity without assistance, magnetization of those within the coils as well as that to change the number of stripes and Leiteranord-strip sections, the state "0" remains voltages can be increased within the coils of the strip 22 b exist. to allow the simultaneous storage or reading of a larger number of binary digits. Proposal, no current flows through the conductor 21 b departures After perform the desired information in the in, is the characteristic of the F i g. 1 shown data memory recorded data source 102 so that they are "1", should now bring the AbSignale in the left-hand side into effect, by cutting the strips 22 a and 22 b in the manner described above through the relevant conductor 55 information can be read. The control signal source draws current from the earth, but at the same time sends current 101 on line 204 to the indication out to earth through those conductors on which a value device 104 sends a signal that causes "0" to be recorded to ensure that it is responsive to voltages on the conductors weak magnetic field is generated which appear to the inlet 31a and 31b. The control signal source 101 was "0" seeks to preserve from destruction 60 also sends to the reading and Rückspeicherstromwo the same in the strip 22 b already exists. source 105 a signal that causes them to This alternative has the advantage that it represents an effective pulse of sufficient amplitude by the sam applicable measure, which sends the conductor 34 a and the coil 24 a to earth, sharpness somewhat reduced with which the coincident from where it returns to its source. The impulse is kept within its maximum value by means of impulses. This impulse is applied to the central parts of the must, that is to say, it reduces somewhat the sections of the strips 22 α and 22 b on the left side of the formation, creating tolerances of the overall system. The current that generates the magnetic field that is directed to the left of the figure to ensure compliance with the "0" state and its component along the

Direction of easy magnetization of the central parts of the two strip sections is greater than the coercive force of the strip. Assuming now that the "within the coil 23 a lying strip 22a in the" - is retentive direction, and that the strips lying b within the coil 23 22 b in the "O" direction retentive, the magnetization direction of the the middle part of the section of the strip 22 a reversed, with the middle part from the remanent flux density in the "1" direction (which for materials with a substantially rectangular hysteresis loop is approximately as large as the saturation flux density) to the saturation flux density in the direction » 0 «passes over. Such a change in flux induces α voltages in the coils 23 α and 24 a and in the conductor 21. The voltage induced in the conductor 21a appears on the conductor 31a and is accepted by the data evaluation device 104 as an indication of a stored "1". The middle part of the section of the strip 22 b lying within the coil 23 α is subjected to the same magnetic field as the middle part of the corresponding section 22 a. However, since in this section of the strip 22 b a remanent magnetization in the "O" direction is already present, the only effect of the Ablesemagnetfeldes is to produce a small flux change corresponding to a transition from the remanence to saturation. This generates only a very low interference potential on the conductors 21 b and 31 b, which has no effect on the data evaluation device 104. Therefore, the device 104 records that at this time on the conductor 31b, no voltage is received, which logically corresponds to the reception of a "O" signal. In this way, the numbers 1 and 0 are read and evaluated.

The strip section with magnetization in the "O" direction remains unchanged by the reading process, but the strip section whose outer parts have magnetization in the "!" Direction has a central part with magnetization in the "0" direction (according to FIG. 2b), if the field of the outer parts alone is not sufficient to return the middle part in the "!" direction when the effect of the reading field ceases. Therefore, something before the next reading process (and preferably immediately after the effect of the reading pulse has ceased) the reading and restoring current source 105 must draw a restoring pulse from the earth via the coil 24 a and the conductor 34 α, which is weaker than the reading pulse. The field generated when this pulse passes through the coil 24α, together with the fields of the outer parts of the left-hand section of the strip 22a, will therefore be sufficient to return the central part of this strip section in the direction "1" of the magnetization (according to FIG. 2a) . However, in view of the counteracting fields of the outer parts of the left-hand section of the strip 22 &, the restoration field generated in this way will not be sufficient to reverse the magnetization of the central part of this strip section in the "1" direction (according to FIG. 2c). The strip sections that contain a magnetically stored "1" can therefore be completely returned in the direction of "1" of magnetization without changing the "0" direction of the strip sections that contain a magnetically stored "0".

So far, the processes of deleting, recording and saving information in have been selected Parts of the memory described, the reading from selected parts of the memory and the restoring. All of these functions must be performed when using the memory. Special Attention is drawn to the new fact

ίο steered that the reading and the restoring process can be repeated any number of times without using an external memory must, in order to enable the restoration of the information destroyed during the reading process. The described The reading process leaves a record of the magnetically stored in part of the strip Information as it was before the reading process. The restore process will not executed to replace information that was destroyed

ao and have disappeared from memory.

Since the physical operation of the invention is fundamentally more dependent on the magnetizing fields than on the particular device used to generate these magnetizing fields, those skilled in the art will be able to suggest a large number of different ways of applying the principles set forth above. During the described recording process, a current can act on the coil 23 α which is sufficiently stronger than the specified coincident current to magnetize all the strip sections within the coil in the "!" Direction. In addition, an optional recording can be achieved by b from the information source 102 via the conductor 31 through the conductor 21 b to the ground, a pulse of such strength is sent that the circular magnetic field generated by the same round b around the conductor 21, the magnetization of the inside of the coil 23 α lying portion of the strip 22 & in the "1" direction will prevent. However, the strength of the field will not be sufficient to change the magnetization of the sections of the strip 22 b lying outside the coil 23 α. It is also possible to arrange an additional coil whose magnetic field extends over the entire effective length of the strip and conductor unit. A direct current of such magnitude can pass through this coil as to provide the required restoration field at all central portions of all strip sections. A similar effect can be achieved in that a direct current of the appropriate direction and strength passes through the coils 24 α and 24 b during the entire time, with the exception of the time of the action of the reading pulse. Many equivalent modifications are available to adapt the invention to various situations in which its advantages are brought to bear in another embodiment other than that described above.

This can be done in practice by using magnetic materials with a sufficiently low coercive force a restoring field can be dispensed with at all, with the exception of that which is caused by the external Sections is created on the middle part of a strip section. Such a material can in the in F i g. 1 can be used with the simple modification that the Reading and restoring power source 105 logical

wise is changed into a reading current source 105 and therefore only reading pulses in the manner described, but does not provide any restoring power. The non-linearity of the magnetic characteristics of the eligible materials and the somewhat intricate geometric arrangement make it up extremely difficult to mathematically determine the minimum ratio of the total length of the element section to the Calculate length of the middle part that this self-restoration for material with a certain maximum remanent flux density and coercive force. For a specific geometric Arrangement, however, there is a general principle that the said ratio decreases, when the ratio of the maximum remanent flux density to the coercive force increases. This increase but must of course be achieved either by using another material or by changing the properties of the material through some physical treatment, there it is a physical characteristic of the material. It has been found that self-restoration is experimental occurs in the following circumstances:

Reference is made to the particular elements shown in FIG. The conductor 21 α is a tungsten wire with a diameter of 0.15 mm, which is brought to a diameter of 0.15625 mm by a coating. The coating consists of an iron-nickel alloy with a preferred direction of magnetization which runs essentially helically around the longitudinal axis of the conductor 21 α . This coating corresponds to the ferromagnetic material 22 a. The angle between the preferred direction of the ferromagnetic material and the central or longitudinal axis of the conductor 21a is between 76.2 and 79.8 °. This area is calculated from the direction of the field that exists during the formation of the ferromagnetic material. The winding 24 α consists of ten turns of insulating wire with a diameter of 0.125 mm and a length of 1.58 mm. The length of the coil 23 α is 12.7 mm, and the distance between the adjacent ends of the coils 23 α and 23 b is 2.54 mm. The coercive force of the magnetic material was measured to be 6.34 oersteds. Under these circumstances, it was found that by the action of a current of 0.4 amperes on the winding 24 a, the central part of the magnetic material of the conductor 21 a, ie the part lying essentially within the winding 24 α , in approximately 0.5 Microseconds is switched, so that there is an output voltage of 30 mV at the ends of the conductor 21a. It has also been found that this process can be repeated as often as desired without an intervening restore process. Such an attempt is typical for the only possible type of implementation of the self-restoring, because the switchover or the change in flux can only be detected by observing induced voltages.

Although the magnetic strip directed towards a conductor is convenient for explaining the invention, because the explanatory settlements of F i g. 2 a, 2 b and 2 c are possible to work in terms of Operation of the invention also the magnetic conductor with a helical direction of the slight magnetization generated by mechanical twisting, and all facilities at which one or more current-carrying conductors have a magnetic field component parallel to the direction the slight magnesiation of a ferromagnetic element. Always be doing by reversing of the flux induces stresses in only one part of this element and the remaining parts of the Elements maintain the direction of their magnetization. Such an element can be a section a larger piece of ferromagnetic material

ίο be. A middle conductor made of non-magnetic Material clad or otherwise covered with a ferromagnetic material that has a substantially rectangular hysteresis loop and a direction of easy magnetization, which runs essentially helically around the axis of the central conductor, can therefore directly replace the unit consisting of conductor 21 α and strip 22 α, which is shown in FIG. 1 is shown.

The magnetic fields created by coils and by

ao currents are generated which pass through straight conductors, can be calculated fairly accurately according to known formulas, and their resultants can be determined by simple vector addition. Sufficient for the specified dimensions Currents of a few milliamperes to generate magnetic fields of the strength of the usual coercive force of a strip from molybdenum-nickel-iron alloy. Because the special coercive force of ferromagnetic Material is subject to certain fluctuations as a result of changes in processing, the special values of the current used and the permissible tolerances of these values for the particular limits of the coercive force to be used. As is known the helical arrangement of the magnetic flux around the central conductor creates a multiple Concatenation between the flux in the strip and in the middle conductor so that the voltages of the read Signals are tens or even hundreds of millivolts, if desired by known ones Facilities with no smell and no other difficulties associated with amplification connected by signals of much lower amplitude can be amplified.

Claims (11)

Patent claims: 1. Magnetic data storage device with an elongated body made of magnetic material with im essential rectangular hysteresis loop, with a storing magnetization device, which is operatively connected to the body to a selected storage portion thereof to magnetize in a first polarity direction representing a first data value and around that portion of the body in the opposite second, representing a second data value To magnetize polarity direction, further with one connected to the body Inquiry magnetization device, and with a data evaluation device for determining Changes in the magnetic flux in the body when the interrogation magnetization device acts, characterized in that the interrogation magnetization device only in a limited part of the memory section during an interrogation process Generates a magnetic field, the field strength of which exceeds the coercive force of this limited part and thereby magnetizing the limited part in a predetermined direction while doing it the direction of magnetization and the state of magnetization of the remainder of the memory section leaves essentially unaffected, and that the S remainder of the memory section in the limited Part generates a magnetic field, the field strength of which is also the coercive force of the limited part and the direction of magnetization of the limited part at the end of an interrogation process controls. 2. Magnetic data storage device according to claim 1, characterized in that the limited part of the storage portion of the magnetic material is a central part. 3. Magnetic data storage device according to claim 1 or 2, in which the storing magnetization device consists of a coil lying outside the magnetic material, the central axis of which is essentially parallel to the central one Axis of the material and which extends over a predetermined section of the Material extends, and in which the interrogation magnetizer from a also there is a second coil lying outside the magnetic material, the middle one Axis also runs essentially parallel to the axis of the material, characterized in that that the interrogation coil extends only over a portion of the portion of the magnetic material. 4. Magnetic data storage device according to claim 3, characterized in that the length of the second Coil is no more than a quarter of the length of the first coil. 5. Magnetic data memory according to one of claims 1 to 4, characterized in that the magnetic material has a preferred direction of easy magnetization and that the mutually opposite first and second polarization directions are preferred along this Direction runs. 6. Magnetic data memory according to one of claims 1 to 5, characterized in that the magnetic material surrounds a central conductor which extends in the longitudinal direction of the central Axis of the magnetic material extends. 7. Magnetic data storage device according to claim 5 or 6, characterized in that the preferred Direction of easy magnetization essentially helically around the central one Axis of the magnetic material runs. 8. Magnetic data storage device according to one of claims 1 to 7, characterized by a regenerative magnetization device, which after actuation of the interrogation magnetization device causes a magnetic field to act on the limited part of the magnetic material, which supports the magnetic field that by remanent magnetization of the remainder of the section in the second polarization direction is generated, and which the limited part in the remanent state in the second polarization direction returns, but does not magnetize it in the second polarization direction, when the magnetic field counteracts that caused by remanent magnetization of the rest of the Section is generated in the first polarization direction. 9. Magnetic data storage device according to one of claims 1 to 7, characterized in that the interrogation magnetization device can be actuated after the interrogation in order to access the limited Part of the magnetic material to bring about a magnetic field, which is the magnetic field supported by remanent magnetization of the remainder of the section in the second polarization direction is generated, and which returns the limited part to the remanent state in the second polarization direction, however, the same is not magnetized in the second polarization direction when the magnetic field counteracts that by remanent magnetization of the rest of the section in the first Direction of polarization is generated. 10. Magnetic data storage device according to one of claims 1 to 7, characterized in that that the ratio of the coercive force to the remanence of the magnetic material is sufficiently low and the limited part is small enough relative to the remainder of the section for that to happen the rest of the section generated magnetic field when in the second polarization direction is magnetized, the limited part upon completion of the operation of the interrogation magnetizer returns to the remanent state in the second polarization direction. 11. The magnetic data storage device of claim 10, wherein the portion of the magnetic Material has a predetermined length, characterized in that the limited part extends only over a fraction of the predetermined length which is sufficient is small so the field strength of the remanent magnetization of the section in the second The direction of polarization generated magnetic field in this part exceeds the coercive force of the same. Considered publications:
German Auslegeschrift No. 1 007 086,
486, 1070 680; Austrian Patent No. 195 670;
"Frequency", Vol. 11, No. 1, 1957, pp. 19 to 27. 1 sheet of drawings 709 549/283 4.67 © Bundesdruckerei Berlin