DE1162410B - Information store and process for its manufacture - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Boarding school Class: H 03 k

German class: 21 al -37/06

Number: 1162410

File number: J17885 IX

Filing date: March 29, 1960

Opening day: February 6, 1964

The invention relates to a memory device using magnetic films and to a method to manufacture such a device.

An information storage device that uses a thin magnetic film as bistable surfaces Storage elements were used in a paper entitled "A Compact Coincident-Current Memory ”by A.V.Pohm and S.M. Rubens and published in the“ Proceedings of the Eastern Joint Computer Conference «published in 1956. Each storage element consists of one Nickel-iron alloy film deposited on a glass substrate. The ladder who the Carrying switching currents are strips that are arranged close to the outer surface of the film.

A great advantage of thin magnetic films is their short switching time. The theoretical switching time of a typical film is on the order of 10 ~ ⁸ seconds. It is evident that the rise and fall times of the switching currents must be very short in order to obtain practical switching speeds which approach this theoretical minimum. The rise and fall times of such short pulses are determined more by the self-induction of the switching conductors than by the properties of the pulse generator that generates the switching pulses.

A disadvantage of the known magnetic storage elements is that relatively long Sahalt pulses are required for switching. To this In this way it is necessary that the pulse generator must be capable of generating pulses with a current intensity of 1 amp and a duration of 100 microseconds or less to produce. This requirement forms the limit of the practicability of the current switching techniques.

In accordance with the present invention, there is provided an information storage device in the form of a thin magnetic film with one or more switching conductors proposed, which are arranged densely on one surface of the film, characterized in that that a non-magnetic, electrically conductive deposit layer is provided close to the opposite face of the film, with the required Switching currents and the inductance of the switching conductors Throw significantly reduced.

The current flowing in the switching conductor generates a magnetic field that generates eddy currents in the conductive backing layer. This is synonymous with the formation of a mirror image of the conductor in the depository layer, that is, a "virtual magnetic image", analogous to the information store and process
Manufacturing

Applicant:

International Computers and Tabulators Limited, London

Representative:

Dipl.-Ing. W. Cohausz, Dipl.-Ing. W. Florack
and Dipl.-Ing. K.-H. Eissei, patent attorneys,
Düsseldorf, Schumannstr. 97

Named as inventor:

Edward Michael Bradley,

Stevenage, Hertfordshire (UK)

Claimed priority:

Great Britain of April 3, 1959 (No. 11 384) -

known optical phenomena. This "virtual magnetic image" causes an amplification of the magnetic. Field in dlera film and a reduction in the inductance of the switching conductor. The resulting gain in the film allows the fern to be switched at a lower amperage that contributes only a little more than half the amperage for the same film without the use of a conductive backing layer.
The backing layer can be made with sufficient mechanical strength that it acts as a supporting base for the film.

The invention will now be described using an example and with reference to the drawing, in the

F i g. 1 in exploded perspective form a schematic representation of a vacuum evaporation device shows that is suitable for making a magnetic film storage element is,

F i g. Figure 2 shows a partial cross-section through a magnetic film storage matrix;

F i g. Figure 3 shows a partial plan view of the film magnetic storage array and

F i g. 4 a Teösohnitt of a modified form a magnetic film storage array.

In one embodiment of a magnetic film storage element, the pad itself consists

409 507/177

from a plate made of commercially available electrolyte aluminum of 99.5% purity. The surface of the The substrate on which the film is vapor-deposited must be very smooth. Any surface roughness caused a deviation from the desired magnetic properties of the deposited film.

The surface of an aluminum plate was found to be microscopically smooth and so was the deposit of a magnetic film with a hysteresis loop that makes it magnetic Makes storage element suitable. If necessary, the surface quality of the panels can be modified by chemical or electrolytic mirror finish can be improved. The relatively soft surface of aluminum makes it possible to obtain a smoother surface than with glass. This boils down to that a higher proportion of the film evaporated onto aluminum those magnetic properties which are within the required tolerances.

The film is vapor deposited in the way that is also used for glass substrates. The document 1 (Fig. 1) is suspended over a crucible 2 which is a suitable magnetic alloy, e.g. B. 80:20 nickel-iron alloy, contains and is located within an evacuable container, which is through a bell jar 3 and a base plate 4 is formed. The pad 1 is preferably on a Temperature in the range from 250 to 400 ° C. due to electrical heating elements 5 during the vapor deposition preheated to maintain the required magnetic properties and uniformity and to improve the adhesiveness of the vapor-deposited film to the substrate. A magnetic field of about 80 Oersted is during the vapor deposition by the electromagnet 6 together with a another set (not shown), which is arranged on the other side of the pad, applied to to produce an anisotropic film with a substantially rectangular hysteresis loop. The alloy in the crucible is cooked by a high frequency induction heating coil 7, so that the Condense vapors on a surface of the pad. An electrostatic field is used for polishing the substrate by ion bombardment prior to the deposition of the film by applying a suitable AC potential to a pair of ion bombardment electrodes 8, only one of which is shown, generated. The entire structure of radiators on the base plate 4 is surrounded by a heat shield 9. The thickness of the vapor deposited film can be in the range 1500 to 10,000 Å, depending on the the particular alloy used and the required coercive force value. The composition the alloy can range from 80:20 nickel-iron to 85:15 nickel-iron vary.

Drive and readout conductors can be vapor-deposited onto the film in the same way that they are was used to deposit the magnetic film, or can be printed using known printing methods, which are used in printed circuit technology. The ladder can also consist of thin strips of foil or wires that are attached to the surface.

A plan view of part of a magnetic memory matrix including a vapor-deposited film on an aluminum base is shown in FIG. 3 shown. A cross section along the line AA is shown in FIG. 2 shown.

The use of an electrically conductive surface creates an electrostatic shield, the allows two magnetic films to be arranged relatively close to one another without any interference phenomena. The aluminum base 1, which can be approximately 1 mm thick, carries the magnetic films 10 and 11, which are evaporated on opposite surfaces. Each film is in a separate Operation using the device of FIG. 1 vaporized. The magnetic films are covered by a thin layer 12 of insulating material, e.g. B. from shellac varnish to the reading ladder 13 isolate from the film. One end of each reading conductor is conductive with the base 1 connected so that the pad acts as a return path for the reading current. This structure sees a reading loop with a very small cross-section, which reduces any interference pulses that may be interspersed.

Each of the drive conductors 14, made up of two turns of wire, is at right angles to the readout conductors 13 arranged. Another set of drive ladders 16 are placed over the reading ladders 13 and is separated from these by insulation layers 15. The selective application of drive current pulses in the drive conductors 16 along with the application of drive current pulses in one of the drive conductors 14 allows parts of the film 10 to be switched to characters of a binary word to represent. Large current pulses of opposite polarity applied to conductor 14 switch the parts of the film alone that correspond to a binary word to a zero state. The reset each part generates pulses in the adjacent reading loop.

The metal backing significantly reduces the inductance of the drive conductor, which makes it possible to receive a current drive pulse of short duration. A well-known ferrite core with an outside diameter of 1.27 mm has been successfully used to generate drive currents in the drive conductors. However, the main advantage achieved by using a metal backing is that it is required Driving current to create a field of a predetermined strength in the film compared to a design that uses a glass backing is significantly reduced.

It has already been explained that eddy currents in the backing layer as a result of the generation a magnetic field can be induced by the switching current flowing through the drive conductor and that these eddy currents in turn generate a further magnetic field ("virtual magnetic image") produce. It can be found that eddy currents only during the change of the original magnetic field are generated. It follows that when the drive current is stable Value is reached, the induced magnetic field also becomes stable and the eddy currents are extinguished. Therefore, there is a limit to the time in which the "virtual magnetic map" exists can before it fades to zero.

It was found that in practice the amount of decay of the "virtual magnetic image" is such that there is no noticeable drop in an arrangement which provides a drive current used for half a millisecond,

which is applied to a typical drive ladder using a 1 mm thick pad. The amount of decay of the imaging field is determined by the strength and conductivity of the substrate influenced. Practically - however - must be the important effect of the strength of the magnetic imaging field must be observed at the end of the drive pulse. It was found that working of the storage element is significantly improved if at the end of the drive pulse the imaging field has not decayed to more than 25% of its maximum value as long as the drive pulse lasts. As an example, it was found that the imaging field decays by about 10% in 0.2 microseconds, if an aluminum pad with a thickness of 0.015 mm is used.

If the conductive backing layer is relatively thin, it will lack the mechanical required Strength to support the magnetic film. A modified form of the structure is therefore in Fig. 4 shown. A glass plate is used as a rigid base 17 provided. One surface of the glass plate is covered with an aluminum layer 18 which can be generated by vacuum evaporation or by electrolytic deposition. the Layer 18 can also consist of a thin film that is attached to the glass by a suitable adhesive process, after the magnetic film is evaporated on the layer, is attached. One Layer 19 of silicon monoxide is deposited on top of the conductive layer, and a magnetic one Film 10 is evaporated onto the silicon monoxide layer. The film is covered with a shellac layer 12 covered.

The sense ladder 13 and the drive ladder (not shown) are in the same manner as described above arranged.

It was found that the intermediate layer made of silicon monoxide to maintain uniform properties of the magnetic film.

The magnetic film storage devices can be operated with very short switching times. It can be expected that the generation of eddy currents in the substrate as a result of the change of the magnetic field associated with the switching of the film tends to reduce the switching time of the Increase film significantly. However, it has been found that such an increase does not occur, and it is also not sufficient for the practical usability of the devices for storage purposes to affect. For example, there was no measurable increase in switching speed for a Film that is switched at 40 millimicroseconds detected.

The particular structure described above is for memory matrix parts with a continuous Film provided. However, the film can also be etched or vapor-deposited through a cover panel to create individual areas for each memory location on the matrix. The usage a conductive backing layer is also applicable to separate magnetic storage elements, the z. B. are required for the construction of circuits with logical properties.

Aluminum is very suitable as a backing layer because it has good conductivity and can be produced with a very good surface smoothness. However, it can be stated that other metals, e.g. B. silver or copper, can be used for the backing layer.

It can also be seen that the increase in the field in the film that affects the "virtual magnetic imaging «is only obtained if the drive conductor is designed in this way is that the magnetic field is noticeably non-uniform. For example, only the effect in the case of the arrangements described achieved in which a flat surface is used, the magnetic film and where the drive conductors are on the opposite side of the electrical conductive layer. These conditions are not, for example, in other known devices met in which a film is deposited on a rod or a pipe and in which the drive conductors are wound around the rod or tube in the form of a coil. In these cases the coils can be viewed as solenoid turns, and a drive current constant in the Coils flowing would create a uniform field that interacts with the rod or tube. Therefore, a "virtual magnetic image" is created on the opposite of the drive conductors Side of the memory film not generated.

Claims (11)

Patent claims: 1. Information storage device in the form of a thin magnetic film having a or a plurality of switching conductors disposed close to one face of the film thereby characterized in that a non-magnetic electrically conductive backing layer (1) close to the opposite face of the film (10, 11) is provided. 2. Information storage device according to claim 1, characterized in that the backing layer in the form of a metallic plate (1) of sufficient strength is used to serve as a base for the film. 3. Information storage device according to claim 2, characterized in that the Hmterlegungsschicht (1) Made of high purity aluminum. 4. A method for producing the information storage device according to claim 1, characterized characterized in that a backing layer (18) in the form of a vapor deposition layer an insulating pad (17) is applied. 5. A method of manufacturing an information storage device according to claim 1, characterized in that the backing layer is used in the form of a metallic foil which is adhesively attached to the base (17). 6. The method according to claim 4, characterized in that the magnetic FUm (10, 11) is vapor-deposited onto an insulation film (12), which in turn is applied to the backing layer (1). 7. The method according to claim 4 to 6, characterized in that the magnetic film (10, 11) is made by vacuum evaporation of a nickel-iron alloy. 8. The method according to claim 7, characterized in that the surface on which the Film (10, 11) is evaporated, on a temperature temperature in the range from 250 to 400 ⁰ C is preheated. 9. The method according to claim 8, characterized in that the surface on which the Film is vapor deposited, is polished by ion bombardment prior to vapor deposition. 10. Information storage device according to claim 2 or 3, characterized in that the backing layer (1) has a pair of magnetic films (10, 11) placed on opposite sides Surfaces are vapor-deposited and at least one drive conductor (14) is magnetically coupled to both films. 11. Information storage device according to one of claims 1 to 3 and 10, characterized in that that an elongated scanning conductor (13) adjacent to one surface of the magnetic Film is arranged and one end of the reading conductor is conductive with the backing layer (1) is connected, the reading conductor and the backing layer together forming a reading loop which comprises a portion of the film. 1 sheet of drawings 409 507/177 1.64 © Bundesdruckerei Berlin