DE1549060C - Magnetic matrix memory with a magnetizable sheet - Google Patents

Description

The invention relates to a magnetic matrix memory made of a magnetizable sheet over which two sets of parallel conductors arranged at an angle one above the other and against each other and against the sheet are electrically isolated, the conductor intersections each having a bit storage location in the adjacent Sheet is assigned.

A data memory is known from US Pat. No. 3,196,416, in which on a polished Surface of an aluminum plate is a magnetic material as a thin film of uniaxial anisotropy is vaporized. Above this film there are two sets of lead ladders, namely one set of parallel ones Digit conductor and above that a set of word conductors running perpendicular to the latter, their longitudinal axes parallel are placed on the easy axis of the film. The digit conductors are made from an aluminum foil made that this film on the surface of a very thin, insulating film, for. B. made of polyethylene terephthalate 0.02 mm thick, glued on and subjected to a light etching process. This structure is then anodized to leave a very thin, insulating layer on the digit conductors which eventually comes into contact with the thin magnetic film of uniaxial anisotropy brought and possibly cemented. The word conductors are similar on one with A copper-lined surface of a circuit board formed from synthetic resin that rests against the underside of the polyethylene terephthalate film that carries the digit conductors. For inscribing a word, the corresponding word conductor is excited, and at the same time a pulse is fed to the digit conductors, which is dependent on reflects a binary one or zero from its polarity. To read the contained in memory Bits, a pulse is sent to the word conductor, which stimulates the magnetization at the memory locations in the or counterclockwise. As a result, the digit conductors now act as scanning conductors a pulse is induced, the polarity of which indicates whether there is a bi-

Nary one or zero was inscribed. Normally the im Information contained in the memory is deleted by reversing the direction of the magnetization, so that a rewriting of this information becomes necessary. By applying a reading pulse If the amplitude is lower than that of the write pulse, the information can also be read out in a non-erasing manner will.

A distinction in amplitude between the non-erasing and erasing readout of Storage spaces of a thin film of uniaxial anisotropy is difficult for practical reasons can be achieved, since the thin film can accommodate numerous bits and accordingly a sufficient one Should have expansion.

As is known from Swiss patent specification 416 745, in the production of a larger, coherent, ferromagnetic film made of 80% Ni and 20% Fe can be expected that the easy axis of this film receives a certain curvature or distortion that at the edges of the film is greatest. If one assumes the constancy of the interrogation pulse, the amplitude of the depends at the respective memory location when interrogating the induced signal on the size of the distortion of the easy axis at the location of the storage space concerned, since the magnetization is one of the distortion the easy axis and thus the location of the storage dependent, larger or smaller rotation learns from the interrogation pulse. Because of this phenomenon, the size of the interrogation pulse for the non-erasing readout must be adhered to very precisely. If it exceeds a certain amplitude, there is a risk that at least some memory locations will be read in an erasing manner. At a If a certain threshold value is undershot, it is at least when some memory locations are queried hardly possible to distinguish the information signal from the noise.

The invention is therefore based on the object of specifying a memory of the type specified at the beginning, in which the magnetization of the recording medium is neither rotated for reading out the storage locations still needs to be modified in any other way.

This object is achieved according to the invention in that each conductor of the magnetizable sheet adjacent set has a coating of a material of high magnetic permeability, in which a gap is formed on the side facing the sheet, which a magnetic writing resp. Read head represents, and that for non-erasable reading of the bit storage locations on the drive ladders of the The outer set of applied pulses was the almost circular flux induced across the gap in the coating is interruptible or closable.

French patent 1,379,699 discloses a matrix memory made from a metallic wire mesh known, in which several parallel storage wires with a copper or aluminum core are provided, which is coated with a thin, ferromagnetic, anisotropic film. The to These storage wires perpendicularly running conductors are surrounded with a magnetic substance, which only those parts are missing that are in direct contact with the storage wires. On these An insulating pad is inserted at the points of contact, which is perpendicular to the two Electrically separates wires from each other.

This known memory also has the same problem of differentiating between amplitudes a larger and smaller interrogation signal for erasing or non-erasing readout. the thin, ferromagnetic, anisotropic film is only broken down into numerous, narrow, parallel strips, each wrapped around a wire as a core ίο.

An embodiment of the invention is shown in the drawing and will be described in more detail below described.

It shows

Fig. 1 is an end view of a clad conductor; which is arranged in such a way that information is written into or from a magnetizable sheet can be read out,

F i g. 2 the clad conductor between a conductor and the magnetizable sheet,

F i g. 3 a circuit diagram of the overall system,
F i g. 4 the magnetizable sheet with two marks,

F i g. 5 including an end view of the lead ladder an isolation,

F i g. 6 is a picture of a portion of the plated Ladder,

F i g. 7 shows a section from the memory in which dummy lines are used to influence the noise signals be used, .and

F i g. 8 wave trains of the essential signals.
In Fig. 1 shows one end of a conductor 11 with a copper core 13 on which a ferromagnetic coating 15 made of a nickel-iron alloy of approximately 80% Ni and 20% Fe is plated. A groove or channel 17 is carved or etched into it, which groove passes through the cladding and runs along the core in the axial direction. This channel 17 acts like the gap in an ordinary read head.

The conductor 11 (Fig. 1) is rectangular in shape, although other shapes, e.g. B. a circular, are possible, which result in a shorter magnetic path. When in the rectangular head the groove is scratched, the tolerances do not need to be very precise because even one is off-center lying groove is still arranged in such a way that the magnetic flux from an underlying dipole is conducted with the desired smallest magnetic impedance. If, on the other hand, the groove of a circular wire would run off-center, a high impedance occurs.

According to FIG. 1 a magnetizable sheet 19 is also covered with an iron oxide layer 20, although other materials which present a magnetizable surface are also useful. In the shift A dipole 21, which is produced, for example, during writing, is indicated, of which a magnetic one Flux 23 goes out, which penetrates the ferromagnetic coating 15 of the conductor 11, as indicated by a dashed line Line is indicated. Accordingly, the copper core 13 is surrounded by this flux, and at a change in flux induces an electrical voltage in the core.

According to FIG. 2, an electric current passes through a conductor 25 in the direction of an arrow 26 and builds up a magnetic flux which, according to the right-hand rule, around the strip 25

reaches around as indicated by dashed lines 27. As this enters the coating 15, its magnetization is axially aligned with the clad conductor 11, as shown by a dotted area 29. The paths of the magnetic vectors or of the flux 23 which runs around the circumference of the conductor and is generated by the dipole 21 are thus interrupted, so that the flux 23 around the core 13 is suppressed. When the current flow in the lead conductor 25 is terminated, the magnetic vectors in the area 29 return in the initial direction, whereby the closed flux is built up again in the ferromagnetic coating 15 and a flux change d Φ is caused, which induces an electrical voltage in the core 13.

The dipole 21 in the magnetizable sheet 19, which is located under the channel 17, can thus be perceived that an electric current is sent through the conductor 25 and interrupted will; This allows the magnetic flux emanating from the dipole to form a magnetic circuit close and induce an electrical voltage in the electrically conductive core 13. For a dipole of In the specified direction, the induced electrical voltage at the beginning of the flow through the conductor (in F i g. 8 called drive strips) passing impulse has one polarity and at the end of this impulse the opposite polarity. If the dipole has the other sense of direction, these are of course both polarities reversed, as in FIG. 8 (induced 1 signal; induced 0 signal).

The conductor 25 is electrically insulated from the clad wire 11 with the aid of an insulating layer 24.

The orientation of the dipole can therefore be perceived because of the magnetic flux in the 0- or 1-direction induces an electrical voltage that generates a current in one direction or the other brings forth. The system can of course be operated so that only the ones are recorded and the zeros are suppressed.

In the circuit diagram of FIG. 3, a plurality of plated conductors 31 to 35 are provided, the groove of which corresponds to magnetizable sheet 19 is adjacent. The central core 13 (Fig. 1 and 2) of this conductor is connected to gates 37 for selecting the bit line. The latter will depend on the Signals from an electronic data processing device 41 arriving via a cable 39 open or closed. In this device 41 there is a decoding circuit which acts as an address generator acts and selects certain lines in the cable 39, which in turn one or more Gate are operated. The gate or gates chosen are with the ladders assigned to him or her 31 to 35 connected. When information signals are induced in the plated conductors 31 to 35, You can therefore enter the data processing system through the selected gates and cross-connections 42 to 46 Device 41 arrive, in which they are further processed.

As noted, in FIG. 3 only the five clad conductors 31 to 35 and six treble conductors 47 through 52, although these numbers are arbitrary. On a broken line 53 you can additional drive strips can be inserted.

If the writing is to take place, the appropriate gate 37 is selected, and switched on by one Write signal generator 40 will send a current in one of the two possible directions to the selected Head 31 to 35 fed. With the exception of the lead wire, under which a bit is written is to be, all drive conductors are energized when writing, causing the writing process everywhere except of the selected conductor is blocked.

In the magnetizable sheet 19 are 54 to 58 at all places that go through the intersection of the lead conductor 47 and the plated conductors 31 to 35 are set, information is stored. From the data processing Device 41 sends a control signal to cables 39 and 59 to indicate that the gates associated with the five plated conductors 31 to 35 are ready to let information through, and that the leading conductors allow the reading of the positions 54 to 58. A current flows for this purpose only through the conductor 47, and a voltage pulse is generated in all clad conductors 31 to 35, because at the places 54 to 58 the circumferential magnetic flux is reduced. In Depending on the control signals, the signal transmitted in the head conductor 47 is terminated, so that the Magnetic flux is restored in the clad conductors at positions 54 to 58 and thus an electrical one Voltage of opposite polarity in the conductors 31 to 35 is induced. The relationship between the applied and induced signal is shown in FIG. These signals are induced through the gates 37 of the data processing device 41 for the purpose of amplification and further processing fed. The information stored in locations 54 through 58 in sheet 19 usually consists of multiple ones and / or zeros to represent the special character. When reading is done of course no deletion; After reading, the information still remains in the magnetizable sheet 19 and can therefore be read out several times in the manner explained.

The system has a randomly distributed access, because any three conductors can be selected can. If the memory is expanded by additional plated conductors, the number of which corresponds to that of the bits of a word to be processed, only certain sections of the plated conductors need to be scanned to get the desired pieces of information (the sufficient number of bits for a word) from the magnetizable Read sheet 19.

The data processing device 41 is programmed in such a way that information is provided at positions 54 to 58 can be enrolled. In this case control signals are sent through the cable 39 to the gates 37, which are opened so that ones can be written there. Other control signals run through cable 59 such that drive conductors 48 to 52 receive power. Through this Currents, the magnetic flux generated by the write currents is prevented from completely tracing its path runs through, so that in all places except those under the conductor conductor 47 with the help of magnetic flux no information can be inscribed.

In other words, the drive current from the signal generator 40 would flow through the appropriate one Gate 37 and the plated conductor 31 to earth 60. It tries to send information to all Enroll in places 54, 61, 62, 63, 64 and 65. If the strips 48 to 52 are energized, whereby the vectors in ferromagnetic coating 15 at locations 61 to 65 axially of clad conductor 31

are oriented, the flow generated by the write current does not find a continuous path in the coating 15 ; therefore, the dipoles at positions 61 to 65 of sheet 19 are not oriented in accordance with the flow of the write current. The drive conductor 47 is not excited, however, and the magnetic flow of the write current actually sets the dipole at position 54 accordingly.

In the second step, the gates 37, which are connected to the places, are written in the zeros are to be opened, and the write current is from the write signal generator 40 in the opposite Direction supplied so that the information can be written to the other places can. During this second step, the drive strips 48 to 52 are also energized to release the Write information under this strip to block.

If the magnetizable sheet 19 is to be replaced or removed, it is important that the new sheet is precisely aligned with the locations under the plated memory conductors so that information can be removed from or written to the sheet. There are various ways of doing this, but the simplest method is as follows: According to FIG. 4, two markings 67 and 68 are provided which form a portion of the magnetizable sheet 19 which is magnetized along a straight line. If the sheet 19 is accommodated in a holder 69 (not shown in FIG. 3), the sheet must be brought into the correct position on the clad conductors for correct reading, which can be done with the aid of a gear 70. The holder can be moved automatically or by hand. In the first section of this process, the sheet holder is moved vertically until the horizontal, magnetizable marking 67 comes under a plated conductor 71. This can be accomplished in that the operator presses a button on a control panel 72, as a result of which an alternating current signal is fed to the conductor conductor 50, for example. When this occurs, the operator shifts sheet 19 vertically until a signal is given from conductor 71 as soon as marker 67 appears below him. This signal is visible on a display device on the switchboard 72. The operator then presses another button which terminates the AC signal and causes the drive conductors 49, 50 and 51 to receive a pulse in sequence. As soon as the marking 67 is aligned under the groove of the plated conductor 71, three pulses are perceived on the display device. Several impulses can also be used to better eliminate an inclined position. (If the mechanical arrangement works precisely, there is no need to check the inclination.)

As soon as the blade 19 is adjusted in the vertical direction, the operator shifts via the transmission 70 reinsert the sheet holder 69 so that the sheet 19 is adjusted in the horizontal direction. In this In this case, an alternating current signal is again produced via the switchboard 72 and, for example a lead conductor 73 is supplied. Once the vertical mark 68 gets under the clad conductor 74, becomes an AC signal in the display device

noticed. Thereafter, the AC signal is terminated and the drive conductors 76, 73 and 75 receive the One pulse at a time. If the vertical mark 68 is under the groove of the clad conductor 74, just aligned, has arrived, are

pointing device detected three pulses, and the sheet 19 is set correctly for reading.

In Fig. 5, the lead conductor 25 used for the preferred embodiment is shown in detail. Its copper core 18 is surrounded by a plated coating 16 made of a ferromagnetic material. Accordingly, the magnetic flux generated by a passing through the core 18, electrical Current generated is concentrated on the low impedance web in the coating 16.

ao There is an insulating strip under the lead conductor 25 24

According to FIG. 6, in a preferred embodiment of the clad conductor, the ferromagnetic coating 15 is from the core 13 at certain intervals

which has been removed. The distances match the distances between the drive ladders so that the magnetic flux from the drive ladders effectively prevents incorrect information from being read out. When writing, the electric current passes lengthways through the plated conductor. The magnetic flux built up by the writing current finds a path with a low impedance in a continuous coating 15 even in the areas not under the drive conductors, and thus erroneous information can be written between these fixed areas, leading to the problem of crosstalk leads. In addition, the magnetic flux from the areas next to the sides of the drive conductors can be inclined, so that a field is created even below the drive conductors, which results in incorrect writing. Because the ferromagnetic material of the coating 15 is removed at intervals to limit the storage locations (FIG. 6), the magnetic flux of the read current that is supplied to a data storage location is concentrated in the remaining coating 15 and can be effectively used by the electrical current of the Treible ladders are blocked. Thus, the registered letter can be carried out without the slightest disturbance.

In Fig. 7 conductors 113 and 115 are standardized plated conductors, to which a blind conductor 111 belongs. The latter is connected to the conductor being read, so that noise signals generated by the capacitive coupling between a conductor conductor and a clad conductor are canceled from the similar signals generated in the blind conductor. In the illustrated embodiment, the dummy conductor 111 is selectively connected to the clad conductors 113 and 115 . In a different arrangement, a separate blind conductor is provided for each clad conductor.

1 sheet of drawings

209 534/452

Claims (12)

Patent claims: 1. Magnetic matrix memory consisting of a magnetizable sheet, above which two sets of parallel Heads arranged at an angle one above the other and against each other and against the sheet are electrically isolated, the conductor intersections each having a bit storage space in the neighboring Sheet is assigned, characterized in that that each conductor (11; 31 to 35; 111, 113, 115) of the set adjacent to the sheet (19) a coating (15) made of a material of high magnetic permeability, in which on the side facing the sheet (19) a gap (17) is formed, which is a magnetic Read or write head represents, and that for non-erasable reading of the bit storage locations (21) of the drive ladders (25; 47 to 52) of the other set applied pulses of the Gap (17) in the coating (15) induced, almost circular flow (23) can be interrupted or closed is. 2. Memory according to claim 1, characterized in that the magnetizable sheet (19) is arranged exchangeably in a holder (69). 3. Memory according to claim 1, characterized in that the gap (17) in the coating (15) is a groove arranged along the axis of the associated conductor (11). 4. Memory according to claim 1, characterized in that the conductors (31 to 35) to the Points of intersection are arranged orthogonally to the lead ladders (47 to 52) (FIG. 3). 5. Memory according to claim 1, characterized in that the magnetizable sheet is a Has base (19) on which a layer (20) of iron oxide is arranged as a magnetizable layer is (Figs. 1 and 2). 6. Memory according to claim 2, characterized in that the replaceable, magnetizable Sheet (19) for its vertical adjustment a marking (67) in the form of a horizontal has magnetized portion (F i g. 4). 7. Memory according to claim 2, characterized in that the exchangeable, magnetizable Sheet (19) for its horizontal adjustment a marking (68) in the form of a vertical having magnetized portion. 8. Memory according to claims 6 and 7, characterized in that an additional plated Conductor (74) for reading vertical marking (68) and another plated conductor (71) are provided for reading the horizontal marking (67) and that with these Clad conductors (71, 74), the vertical conductors (73, 75, 76; 47 to 52) form intersections (FIG. 3). 9. Memory according to claim 8, characterized in that both with that of the vertical Labeling (68) associated, clad conductors (74) and the associated driveline conductors (73, 75, ' 76) as well as with the clad conductor (71) assigned to the horizontal marking (67) and the associated drive ladders (47 to 52) a switchboard (72) for scanning the markings (68, 67) is in connection, of which the correct position of the magnetizable sheet (19) can be displayed is. 10. Memory according to claim 9, characterized in that with the holder (69) of the exchangeable, a mechanical adjusting gear (70) is coupled to the magnetizable sheet (19), which conveys the sheet (19) into its correct position. 11. Memory according to claim 1, characterized in that that the material of the coating (15) of high magnetic permeability in separate, along the ladder (31 to 35) located sections is divided and that the Treibleiter (47 to 52) with these material sections of high permeability the intersection points (54 to 58, 61 to 65). 12. Memory according to claim 1, characterized in that the drive conductors (25; 47 to 52) have an almost right-angled, electrically conductive core (18) on three sides is surrounded by a material (16) with a high magnetic permeability, while the fourth side is covered with an electrically insulating material (24).