SU1166179A1 - Device for recording information - Google Patents

Abstract

A DEVICE FOR RECORDING INFORMATION, containing a storage medium, a signal recording conductor, a group of signal sweep conductors and an information erasing unit, characterized in that, in order to increase the accuracy and increase the reliability of the device, the information carrier is made in the form of a substrate with successively deposited on it on one side the first magnetic film with a regular strip domain structure, a dielectric film and a magnetostatically associated with the first second magnetic film of a magneto-optical material a regular band domain structure, the period of which exceeds the period of the domain structure of the first magnetic film, while the signal recording conductor is made in the form of a ring located on the surface of the second magnetic film, and is magnetically coupled to it, and the group of signal sweep conductors is alternate a number of annular and linear conductors interconnected in series, with the linear conductors located on the surface of the other side. These are the substrates, and the circular conductors are the joint ventures on the surface of another magnetic film and are magnetically coupled to it. 05 О5 with

Description

The invention relates to automation and computing, in particular to information recording devices on magnetic media, and can be used to record fast variable signals.

The purpose of the invention is to increase the accuracy and increase the reliability of recording information by fixing the intermediate magnetized state by the fields of the scattering of the magnetic sublayer.

The drawing shows a schematic diagram of an information recording device.

The device contains a ring current conductor 1 recording signal, (second) magnetic film 2 from a magneto-optical material with a regular band domain structure, a dielectric film 3, (first) magnetic film 4 with a regular band domain structure, a substrate 5, strip domains 6, group conductors 7 sweep the signal block 8 erase information.

The recording signal recording conductor is a circular current conductor 1 located in the plane of the information carrier. The information carrier is made in the form of an integral magnetic structure consisting of a substrate 5 and a first magnetic film 4 applied successively to it with a regular strip domain structure, a dielectric film 3 and a magnetostatically associated with the first second magnetic film 2 of magnetic optical material with a regular stripe domain structure, the period of which exceeds the period of the domain structure of the first film.

As magnetic materials that can be used in the manufacture of the information carrier, Bi-containing garnet ferrites are of the greatest interest. By varying the composition, synthesis modes and subsequent processing, they allow to obtain almost arbitrary ratios of magnetization, anisotropy, coercivity, as well as implement various types of domain structures in them while maintaining a high magneto-optical quality factor. The coercive force and magnitude of the magnetic anisotropy of the first magnetic film are selected by an order of magnitude higher than the corresponding values of the second magnetic film. As a result, when recording information, the control magnetic fields applied to the second magnetic film will not affect the domain structure of the magnetic sublayer, i.e. the first magnetic film. The magnetization of this film is chosen on the basis of the required magnitude of the magnetic fields of the scattering and the depth of the potential relief created by them.

The information clearing unit 8 is a system of electromagnets (or

Helmholtz magnetic coils), which create control magnetic fields applied to the information carrier. In the block, fields are formed for orientation.

band domains 6, bringing them to an equilibrium magnetic state and erasing the recorded information.

The group of conductors of the scanning signal recording is made in the form of a series of circular and linear conductors 7 connected

between themselves sequentially, with the linear conductors located in the plane of the information carrier on the side of the substrate, and the annular conductors on the opposite side of the information carrier. The distance between the linear conductors is small enough to ensure uniformity of the magnetic field created by the current in these conductors, near the plane of the first magnetic film. At the same time, the width of the conductors and the spacing of

are chosen such as to provide the necessary time delay for the recording signal. The size of the annular conductor is chosen on the basis of the requirements for the size of the elementary registration area.

information, i.e. storage media cells.

The recording device information works as follows.

The recorded signal using a write conductor creates a magnetic field. Well,

acting on the entire information carrier and directed perpendicular to its plane. The maximum amplitude of the field of the recorded signal is limited by the magnitude of the coercive force of the second magnetic film and the depth of the potential relief created by the fields of the diffuse domain structure of the first film. Therefore, it does not directly affect the magnetization of the information carrier. Localized recording field

Hw, exceeding the value of the field perpendicular anisotropy of the second magnetic film and directed inside the annular conductor 7 perpendicular to the film plane, and from the substrate side in the information carrier plane perpendicular to the domain boundaries of the magnetic sublayer 4, is created in the group of conductors of the recording signal sweep.

In that area of the second magnetic film on which the fields H $ and H simultaneously act in the same direction, the elementary information recording area (memory cell) is magnetised and the potential relief of the scattering fields produced by the first magnetic film is smoothed as a result of the deviation of the magnetization vector from the perpendiculars directing the plane of the film direction and placing it in the plane of the film. When recording information, a linear section is used on the hysteresis-free curve for the dependence of the magnetization of the second magnetic film made of a Bi-containing garnet on a magnetic field applied perpendicular to the film plane.

After the Hi field is turned off, the regular band domain structure is restored in the second film, but with the magnetization and symmetry of the band domains corresponding to the HS field value at the moment the H field disappears, and the potential relief of the scattered field of the first magnetic film is restored, which fixes the magnetized state elementary area of registration information. In this case, the domain boundaries of the stripe domains 6 of the second film fall into the potential we formed by the magnetic fields of the scattering of the domain structure of the first film.

and playing the role of magnetostatic traps for domain boundaries.

To register a signal as a function of time, it is necessary to ensure the movement of the localized Well field / over the volume of the information carrier during the time the signal is to be registered. The required displacement of the Nu field is achieved by transmitting a current pulse in the group of conductors of the sweep of the recording signal along a number of conductors 7. The magnetization of the elementary information recording areas will reflect the change in the recorded signal over time.

If the information carrier is illuminated with polarized light, then in reflected light, by rotating the polarization plane, it will be possible to read the form of the recorded signal.

Claims (1)

A DEVICE FOR RECORDING INFORMATION, comprising a data carrier, a signal recording conductor, a group of signal scanning conductors and an information erasing unit, characterized in that, in order to increase the accuracy and reliability of the device, the information carrier is made in the form of a substrate with one applied to it sides sequentially of the first magnetic film with a regular strip domain structure with a dielectric film and magnetostatically coupled to the first second magnetic film of magneto-optical material with bright strip domain structure, the period of which exceeds the period of the domain structure of the first magnetic film, while the signal recording conductor is made in the form of a ring located on the surface of the second magnetic film and magnetically connected to it, and the group of signal sweep conductors is made in the form of an alternating series of ring and linear conductors interconnected in series, with linear conductors located on the surface of the other side of the substrate, and ring conductors on the surface of another magnetic plate Enki and magnetically connected with her.