JP2705598B2 - Magneto-optical storage method and apparatus - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magneto-optical recording device, and more particularly to a magneto-optical recording device capable of rewriting information. 2. Description of the Related Art As a rewritable magneto-optical storage device,
A recording medium having a perpendicular magnetic film is irradiated with a laser beam, the magnetization direction is reversed by the absorption of the light energy to record and erase information, and the polarization plane rotation of reflected light from the recording medium is detected. There is known a magneto-optical disk device that reproduces information by using, for example, TOGAMI etal "Amo.
rpho us thim film disk for magnetro-optical memon
y "SPIE Vol.329Optical Disk Technology (1982) pp20
See 8-214). In order to reverse the magnetization direction in this type of apparatus, there are a Curie point recording method and a compensation temperature recording method. In both cases, changes in coercive force and magnetization depending on the temperature of the recording medium are used. Here, the operating principle of storing and erasing information will be described with reference to FIGS. 1 and 2 taking the Curie point recording method as an example. FIG. 1 shows the principle of a recording operation. First (a)
Indicates the magnetization Ms in one direction before storage in the magnetic thin film.
In this way, a state in which magnetization is performed in one direction is defined as an initial magnetization state. In (b), when a laser is irradiated as a spot on the surface of the magnetic thin film, a minute portion thereof is heated to a temperature equal to or higher than the Curie point temperature and the coercive force and magnetization become zero. (C) shows the state of (d) in the recording magnetic field Hb (about 1) in the direction opposite to the magnetization Ms.
00 Oe) is applied. When the temperature drops, the inverted magnetization is generated by the sum of the recording magnetic field Hb and the demagnetizing field Hd due to the magnetization Ms (actual recording magnetic field = Hb + Hd).
(D) shows a reversed magnetization state (recording domain) which is stable in a state where the minute part is cooled (room temperature). Information is recorded in such an order. Next, FIG. 2 shows the principle of the erase operation. (A) is the state of (d) described in FIG. (B) shows a state in which a laser beam is irradiated as a spot on a recorded minute portion and heated to a temperature equal to or higher than the Curie point temperature. (The same state as FIG. 1B). (C) shows an erasing magnetic field Hb ₁ (about 200 O) in the same direction as the magnetization Ms in the state of (b).
e) is applied. At this time, the erasing magnetic field Hb ₁
(The actual erasing magnetic field = H)
b ₁ −Hd), the orientation becomes the same as the surrounding magnetization Ms. (D) shows a stable magnetization Ms state in a state where the minute part is cooled (room temperature). Erasure is performed as described above. In this manner, information is recorded and erased by reversing the magnetization of the magnetic thin film surface of the recording medium. In order to accurately record and erase information on a predetermined portion of the magnetic thin film surface, the recording medium is required. A so-called auto-focus operation is required in which a constant laser beam spot is irradiated on the magnetic thin film surface of the recording medium following the movement of the recording medium. For this reason, an actuator for finely adjusting the lens is usually used. However, the conventional magneto-optical storage device has a drawback that information recording / reproduction and erasure cannot be performed accurately due to a change in a recording domain diameter or an incomplete erasure state. SUMMARY OF THE INVENTION An object of the present invention is to provide a magnetic storage device which can solve the above-mentioned drawbacks of a conventional magnetic storage device and can record and erase information accurately. Become. According to the present invention, in order to achieve the above object, the above-mentioned drawbacks are caused by the actuator, that is, the magnitude of the leakage magnetic field of the actuator and its direction depend on the recording medium. It is determined that the recording and erasing states of the information on the magnetic thin film are affected, and the influence of the leakage magnetic field of the actuator is taken into consideration. Is used as a magnetic field for forming According to one feature of the invention, the actuator is arranged such that the magnetic field exerted by the permanent magnet in the actuator assists the erasing magnetic field applied from the magnetic field applying means. According to the present invention, the stray magnetic field of the actuator acts so as to cancel out the effect of the demagnetizing field caused by the magnetization around the portion irradiated with the light beam, and the stray magnetic field of the actuator changes the stray magnetic field of the light beam. It is used to assist the erasing magnetic field applied from the magnetic field applying means to form the erasing state magnetization in the irradiation area. An embodiment of the present invention will be described below with reference to the drawings. FIG. 3 is a schematic configuration diagram showing one embodiment of the magneto-optical storage device according to the present invention. Light emitted from the laser 11 is converted into parallel light by the condenser lens 12. The light passing through the half mirror 13 and reflected by the galvanometer mirror 14 is irradiated as a spot on the recording medium 17 by the aperture lens 15. The recording medium 17 is a transparent substrate 17a (for example, a glass substrate) and a magnetic thin film 17b (for example, an amorphous alloy thin film of a rare earth such as Gd or Tb and a transition metal such as Fe or Co).
The laser beam is applied to the transparent substrate pass 1
The light is condensed as a minute spot on the magnetic thin film 17b through the thin film 7a. The lens 15 is incorporated in the actuator 16 so that the converging spot follows the movement of the recording medium 17. FIG. 4 shows an example of the structure of this actuator. 4, the first and second fixed yokes 102 and 102 'are connected to the permanent magnet 101 to form a magnetic circuit forming a closed magnetic path as shown by an arrow A. These first,
The lens 1 is inserted into the gap between the second fixed yokes 102 and 102 '.
A movable holder 104 for holding 5 has a sleeve 104 'inserted therein. Coil 1 is placed in 104 'of the movable holders.
The movable holder is moved in the direction of arrow B by passing a current through the coil 103. The drive holder 104 is fixed to the fixed yokes 102, 10 by a leaf spring 105.
2 '. In the above configuration, the coil 1
The position of the lens 15 can be adjusted by controlling the current flowing through the laser beam 03, so that the recording medium that fluctuates up and down can be irradiated with a laser beam in a fixed spot shape. The mounting direction of the permanent magnet can be arbitrarily determined. In such an actuator, since the permanent magnet 101 is arranged in the same direction as the optical axis direction of the lens 15 as shown in FIG. 4, a leakage magnetic field Ha of the permanent magnet 101 is generated in parallel with the optical axis. The distance between the actuator and the recording medium is about 2 m
m, and the value of the leakage magnetic field Ha linked to the recording medium is about 100 Oe on the recording medium. Therefore, the leakage magnetic field of the actuator affects an external magnetic field applied when recording and erasing information. Therefore, in the present invention, the minute portion of the magnetic thin film 17b is heated to the Curie point temperature by the spot, and when the magnetization is reversed by the electromagnetic coil 18, this leakage magnetic field is applied in the same direction as the erasing magnetic field during erasing. By using the leakage magnetic field as an auxiliary magnetic field of the erasing magnetic field, the above-described conventional disadvantages are solved. The actuator of the recording by the leakage magnetic field Ha and the electromagnetic coil 18, erasing magnetic field Hb, the relationship between Hb ₁ to be described later, will be described playback. In the reproduction, the same optical system as in the recording is used, and the laser beam of the laser 11 (the power is smaller in the reproduction than in the recording and erasing) is focused on the magnetic thin film 17b. The light reflected by the magnetic thin film 17b has a slight rotation of the polarization plane with respect to the polarization plane of the light emitted by the laser 11. This rotation direction (clockwise or counterclockwise) is
7b is determined by the direction of magnetization. This reflected light passes through the aperture lens 15 again, is reflected by the galvanometer mirror 14 and the heave mirror 13, and enters the half mirror 19. The light transmitted here passes through the convex lens 20 and the cylindrical lens 21 and enters the four-divided light receiver 22. A focus shift signal and tracking can be obtained from the output signal from the light receiver 22 (refer to, for example, Japanese Patent Publication No. 54-41883 for a method of extracting the focus shift signal and the tracking signal). These control signals are fed back to a driving device (not shown) of the actuator 16 and the galvanomirror 14. Here, the leakage magnetic field H of the actuator 16
a recording, erasing magnetic field Hb, the relationship between Hb ₁ will be described. FIG. 5 is a diagram for explaining the recording operation of the magneto-optical recording device according to the present invention. FIG. 5A shows the magnetization M of the magnetic thin film 17b.
s and the leakage magnetic field Ha of the actuator are shown. Where H
It is set so that the directions of a and Ms are the same.
(B) irradiating a laser beam as a spot on the film surface,
The minute part is heated above the Curie point temperature. (C)
This is a state in which the recording magnetic field Hb is applied to the state of FIG. The effective magnetic field Hf used for actual recording is Hf = Hb + H
d-Ha. Therefore, at the time of recording, Hf becomes smaller due to the presence of Ha. However, at the time of recording, Hd is added, so that the value of Hb can be smaller than that at the time of erasing.
(D) shows a stable reversal magnetization state (recording domain) in a state where the minute part is cooled (room temperature). FIG. 6 is a diagram for explaining an erase operation according to the present invention. FIG. 6A shows the state described with reference to FIG. Initially, the direction of Ms before recording is the same as the direction of Ha. (B) shows a state in which a laser beam is irradiated as a spot on a recorded minute portion and heated to a temperature equal to or higher than the Curie point temperature. (C) shows the erasing magnetic field Hb ₁
Is applied. The actual effective erasing magnetic field Hf ₁ is
Hf ₁ = Hb ₁ −Hd + Ha. (D) shows a stable magnetization Ms state in a state where the minute part is cooled (room temperature). By utilizing the leakage magnetic field Ha in this manner, a large erasing magnetic field Hf can be obtained. As described above, in the case of erasing information, a magnetic field several times as large as that in the case of storing is required, so the magnitude of the magnetic field generated by the electromagnetic coil must be considered based on the time of erasing. According to the present invention, since a leakage magnetic field is applied at the time of erasing, the magnetic field generated by the electromagnetic coil can be small, and as a result, the electromagnetic coil can be reduced in size and weight. Next, the initial setting for matching the direction of the above-described leakage magnetic field Ha of the actuator with the magnetization Ms of the magnetic thin film of the recording medium will be described with reference to FIG. FIG. 7 shows an electromagnet capable of generating a magnetic field of about 10 kOe. The electromagnet is composed of coils 201, 201 'and iron cores 202, 202'.
The direction of the magnetic field can be arbitrarily determined by controlling the direction of the current flowing through the magnetic field. The direction of the magnetic field is set to a fixed direction as shown in FIG.
The initial magnetization is set so that the direction of the magnetization Ms of the magnetic thin film 17b is perpendicular to the substrate surface by inserting a recording medium into which the recording medium b is integrated. By arranging a recording medium in which the direction of the magnetization Ms of the magnetic thin film 17b is set in advance in such a manner that the direction of the magnetization coincides with the direction of the leakage magnetic field Ha of the actuator, the recording and erasing of information can be performed. The leakage magnetic field Ha can be effectively used as described above. Although the tracking is performed by the galvanometer mirror in the embodiment, it goes without saying that another method may be used. According to the present invention, in a magneto-optical storage device, accurate storage and erasure of information can be performed, and the storage domain can be reduced, so that the storage density can be increased.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram showing a conventional recording and erasing principle. FIG. 2 is a schematic diagram showing a conventional recording and erasing principle. FIG. 3 is a configuration diagram showing one embodiment of the present invention. FIG. 4 is a sectional view showing an example of an actuator. FIG. 5 is a diagram for explaining recording and erasing operations according to the present invention. FIG. 6 is a diagram for explaining recording and erasing operations according to the present invention. FIG. 7 is a diagram for explaining initial setting of magnetization of a recording medium. [Description of Signs] Ms: magnetization of magnetic thin film, Hd: demagnetizing field due to Ms, Ha
... Leakage magnetic field by actuator Hb ... Recording magnetic field, H
b ₁ : Erasing magnetic field, Hf, Hf ₁ : Actual magnetic field on the magnetic thin film surface, 15: aperture lens, 16: actuator,
Reference numeral 17: recording medium, 17a: transparent substrate, 17b: magnetic thin film, 18: electromagnetic coil, 101: Nagaishi magnet, 102, 1
02 ': fixed coke, 103: coil, 104: movable holder, 105: plate panel.

Claims (1)

(57) [Claims] A recording medium on which information is stored by being magnetized in a direction perpendicular to the plane, an optical system for irradiating the recording medium with a light beam, and a magnetic field in a direction corresponding to the recording or erasing of information at the light beam irradiation position A magnetic field applying means for applying a magnetic field, and an actuator for moving at least a part of the optical system, wherein the information is recorded or erased on a recording medium by the action of the light beam and the magnetic field. Wherein the direction of the initial magnetization, the direction of the magnetic field when the information is erased by the magnetic field applying means, and the direction of the magnetic field leaking from the actuator coincide with each other. 2. Information by magnetizing in a first direction perpendicular to the plane is stored, and a recording medium in which information is erased by magnetization in a second direction perpendicular to the plane, for heating the predetermined portion of the recording medium Heating means having the following optical system; first magnetic field applying means for selectively applying the magnetic field in the first or second direction to the heated predetermined site; and second heating means for applying the second magnetic field to the heated predetermined site. Actuator having second magnetic field applying means for applying a magnetic field in the direction of
Is also configured as the second magnetic field applying means, and records or erases information on a recording medium. 3. A laser light source, a storage medium having a recording surface formed of a magnetic thin film in which information is stored by being magnetized in a predetermined direction, and an optical system for condensing a light beam emitted from the laser light source and irradiating the recording surface with the light beam A driving unit comprising a permanent magnet and a coil winding for driving at least a part of the optical system; and a magnetic field applying unit for applying a magnetic field to the recording medium, and a first perpendicular to the recording surface. A magneto-optical storage method for recording information by magnetizing the magnetic thin film in a direction and erasing information by magnetizing the magnetic thin film in a second direction opposite to the first direction; Is used together with an erasing magnetic field applied for erasing from the magnetic field applying means as a magnetic field for magnetizing a portion of the magnetic thin film irradiated with the light beam in the second direction. Magneto-optical storage wherein a and.