JPH03232139A - Controller for floating magnetic head position - Google Patents

Abstract

PURPOSE:To obtain a uniform recording characteristic at all times by detecting the position of an optical beam spot stopped onto a recording film face and moving a magnetic head to an optimum position is response to the position. CONSTITUTION:When a light beam spot 26 is deviated with respect to a magnetic field modulation magnetic head 1 in the radial direction of a disk due to tracing the eccentricity of the disk 10, the positional deviation between the light beam spot 1 and the magnetic field modulation magnetic head 1 is detected by using a differential signal resulting from differentially amplifying an output signal detected by each of photodetectors 3, 4 with a differential amplifier 8. Thus, an always constant magnetic field strength is applied at a recording point and overwrite by the stable magnetic field modulation with uniform recording reproduction characteristic is attained.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a position control device for a floating magnetic head for magnetic field modulation used in a magneto-optical disk device.

[Conventional technology]

A magneto-optical disk device performs magneto-optical recording using a perpendicularly magnetized rare earth-transition metal film such as a TbFe-based thin film or a TbFeCo-based thin film on a disk-shaped substrate made of transparent resin such as polycarbonate or polystyrene, or glass. A film is formed, and a light beam spot focused by an objective lens is irradiated onto the magneto-optical recording film via an optical head through a transparent substrate, and at the same time, a bias magnetic field is applied perpendicularly to the magneto-optical recording film by a bias magnetic field generator. This is a new file device that records the direction of magnetization of the recording film as data in the area irradiated with the light spot, and has major features such as large capacity, rewritability, and disk interchangeability.

In the case of the commonly used light intensity modulation recording method, when rewriting information, a focused laser beam is irradiated while applying an erasing magnetic field of -He to raise the irradiated area to a temperature above the Curie temperature. After that, in the process of cooling the recording film, an erasing operation is performed to uniformly align the direction of magnetization in the direction of the erasing magnetic field, and then a recording magnetic field Hw in the opposite direction to the erasing magnetic field is applied, and a laser beam is emitted. By turning it on and off, information is recorded as the direction of magnetization.

Therefore, using this method, the transfer speed is effectively reduced during recording since overriding is not possible. On the other hand, if it is possible to override this,
Since both recording and playback can be performed at the same transfer speed, the data transfer speed is improved, making it applicable to a wider range of fields.

Therefore, several methods have been proposed so far to enable overriding. One of these methods is a magnetic field modulation recording method.

When rewriting information, a laser beam focused by an objective lens is irradiated onto the magneto-optical recording film, and at the same time, a magnetic field modulation head applies a modulated magnetic field according to the recorded data, so that the data is transferred to the recording film. is recorded as the direction of magnetization.

However, when recording information, the magneto-optical recording film has a
It is necessary to apply a large magnetic field of about 000e, and in order to increase the recording density, it is necessary to make the switching speed of the magnetic field extremely high.

Therefore, a magnetic field modulating magnetic head attached to a floating Radius slider, such as used in magnetic disk drives, is sometimes used.

The levitating RAD slider levitates above the disk using high-speed airflow generated by the high-speed rotation of the disk, and records by applying a modulating magnetic field while maintaining a small gap between the magnetic head for magnetic field modulation and the magneto-optical recording medium. However, the floating RAD slider can move freely in pitch, roll, and parallel directions using a gimbal spring that allows it to follow the surface runout and surface protrusions of the magneto-optical disk while always keeping the spacing constant. At the same time, it is held in
A suspension spring is added to the gimbal spring to control the flying height of the flying head slider and to support the head to move the nod to the magnetic field modulation magnet on any recording track.

FIG. 4 is a configuration diagram showing an example of a magneto-optical disk device that can be overridden by magnetic field modulation using a conventional floating magnetic head.

The slider 2 is supported by a gimbal spring 5 and a suspension spring 6, and at the same time
is fixed to the carriage 7 at one end t). Further, the slider 2 has a structure in which a slight load is applied by the leaf spring effect at the root of the suspension spring 6 in order to stably achieve an appropriate floating amount. Substrate 11. Magneto-optical recording film 12. Due to the hydrodynamic effect, the slider 2 is
floats above the magneto-optical disk 10 in micron quantities.

FIG. 5 is a diagram showing an example of the magnetic field intensity distribution generated on the magneto-optical recording film 12 from the conventional floating type magnetic field modulation head 1. As shown in FIG. The region where a nearly constant magnetic field strength is obtained is within a range of about 0.4 mmφ. Therefore, when recording data on a certain portion of the disk, it is necessary to move the floating magnetic head 1, like the magneto-optical head 20, in the direction of the recording track. Note that the magnetic head 20 is
Light source 21. Collimating lens 23. Beam splitter 24. Objective lens 25. Lens actuator 27.
Beam splitter 28. Focus tracking detection system 29. It is composed of a magneto-optical reproduction signal detection system 30.

Here, apart from the magneto-optical head positioner 31 that moves the entire magneto-optical head 20 in the track direction,
If a mechanism for moving only the magnetic head 1 for magnetic field modulation is provided, the mechanism will be complicated and it will be difficult to downsize the entire device. Therefore, the carriage 7 of the magnetic head 1 for magnetic field modulation is coupled to the magneto-optical head 20 with the coupling part 32 so as to sandwich the magneto-optical disk 10, and the carriage 7 is driven by the magneto-optical head positioner actuator 31 in the track direction of the magneto-optical disk IO. The magneto-optical head 20 is moved together with the magneto-optical head 20.

The magneto-optical recording film 12 is irradiated with a focused laser beam 22 from the magneto-optical head 20, and the magnetic head driving circuit 3 is moved from the magnetic head 1 for magnetic field modulation to the position of the light beam spot 26.
Overwriting of the magneto-optical disk is performed by recording information by applying a modulated magnetic field generated by No. 3.

[Problem to be solved by the invention]

In order to increase the recording density and increase the capacity, it is necessary to increase the switching speed of the magnetic field strength of the magnetic head for magnetic field modulation. Therefore, it is necessary to make the magnetic head extremely compact. However, this reduces the area to which the necessary magnetic field strength is applied, making it difficult to align the optical beam spont and the magnetic head. In other words, the high speed of override and the ease of positioning the magnetic head are in a contradictory relationship.

For example, in a conventional magnetic head, as shown in Figure 5, the area where the applied magnetic field strength is equal is 0.4 mm.
Since it is wide (φ), alignment with the light beam spot is easy, and even if the light beam spot moves along the eccentricity of the disk, it can be sufficiently covered. However, if the magnetic head is made smaller to increase the switching speed,
The part where the applied magnetic field strength is equal is 0.1mmφmm higher,
Positioning becomes difficult, and if the eccentricity of the disk is large, the position of the light beam spot that moves to follow the eccentricity may end up outside the area where the same magnetic field strength is applied.

For this reason, if the magnetic field modulation head is moved in conjunction with the positioner of the magneto-optical head and fixed together with the positioner during recording, as in the past, mechanical misalignment and disc Due to movement of the light beam spot along the eccentricity of the light beam, or displacement of the light beam spot due to temperature changes, the position of the light beam spot moves outside the range where an equal applied magnetic field strength can be obtained, and the light A problem arises in that the applied magnetic field strength at the position of the beam spot varies.

The purpose of the present invention is to detect the position of a light beam focused on the recording film surface and move the magnetic head to the optimum position according to the position, thereby detecting the position of the optical beam on a disk with a large eccentricity. Another object of the present invention is to provide a floating magnetic head position control device in which the applied magnetic field strength at the recording point is always the same and various recording characteristics can be obtained.

[Means to solve the problem]

In the present invention, a recording film made of a perpendicularly magnetized film formed on a disk-shaped substrate is heated by irradiating the recording film with a light beam while a magnetic field is applied in the perpendicular direction according to recorded data. A floating magnetic head position control device in a magneto-optical disk device that records the direction of magnetization of a recording film as information, the magnetic field modulating magnetic head applying a modulating magnetic field according to the recorded data; A magnetic head support device for magnetic field modulation consisting of a slider mounted on one end surface and floating above the recording film surface using fluid flow, a gimbal spring that supports the slider, and a suspension spring; a moving device for moving the magnetic head; a means for detecting the position of the light beam spot focused on the recording film surface; It is characterized in that it includes a position control device for tracking.

[Effect]

According to the floating magnetic head position control device of the present invention, by controlling the position of the magnetic head to the optimum position according to the position irradiated with the light beam spot, the recording position is always -
Various magnetic field strengths will be applied. Therefore, even if a magnetic head with a very small magnetic pole area is used to override a disk with a large eccentric cover, it is possible to obtain negative recording characteristics.

〔Example〕

FIG. 1 is a configuration diagram of a magneto-optical disk device showing an embodiment of a floating magnetic head position control device according to the present invention, FIG. 2 is a diagram showing an example of a floating magnetic head in the present invention, and FIG.
The figure is a diagram showing the principle of detecting the position of a light beam spot in the present invention.

In the embodiment shown in FIG. 1, light #21 from a semiconductor laser or the like
The light beam 22 emitted from the is converted into a parallel beam by the collimating lens 23, passes through the beam splinter 24, and is directed to the substrate 11, magneto-optical recording film 12, etc. by the objective lens 25. The light beam is focused onto the magneto-optical disk 10 made of the protective film 13 and forms a light beam spot 26 on the magneto-optical recording film 12 . The objective lens 25 is connected to the lens actuator 2
7, the light beam spot narrowed onto the recording film surface is controlled so as to be properly focused even in the face of disk wobbling or eccentricity, and not to deviate from the recording trunk.

Further, the reflected light from the magneto-optical recording film 12 is transmitted through the objective lens 2.
5 and is reflected by the beam splitter 24,
The beam splitter 28 guides the beam to a focus/tracking detection system 29 and a magneto-optical reproduction signal detection system 30 .

Here, the magnetic head 1 for magnetic field modulation includes a magneto-optical disk 1.
0 is placed between them and facing the magneto-optical head 20. The magnetic head l for magnetic field modulation is attached to the floating slider 2. The slider 2 is joined to a gimbal spring 5 on its lubricated rear surface, and the gimbal spring 5 is further joined to a suspension spring 6. The suspension spring 6 is fixed to the carriage 7 at one end thereof. This carriage 7 is connected to a floating slider actuator 9.
This allows slight movement in the radial direction with respect to the disk 10. The flying slider actuator 9 supporting the carriage 7 is connected to the magneto-optical head 2 by the coupling portion 32.
0, and is moved in the radial direction of the disk together with the magneto-optical head 20 by the magneto-optical positioner 31.

Here, the light beam transmitted through the magneto-optical recording film 12 reaches photodetectors 3.4 on both sides of the magnetic field modulation head 1 attached to the slider 2.

FIG. 2 shows a magnetic henode 1 for magnetic field modulation and a photodetector 3.
FIG.

The photodetectors 3 and 4 are arranged on both sides of the magnetic node I for magnetic field modulation in the radial direction with respect to the disk, and are attached to the slider 2 together with the magnetic head 1 for magnetic field modulation.

FIG. 3(a) shows that the light beam spot 26 is located on the disk 10.
It represents the change in the output signal detected by each of the photodetectors 3 and 4 when the disk is displaced in the radial direction with respect to the magnetic field modulation magnetic head 1 due to tracking the eccentricity of the disk. Further, FIG. 3(b) shows changes in the output signals obtained by differentially amplifying the output signals of these two photodetectors by the differential amplifier 8. With this differential signal, the amount of positional deviation between the optical beam spot 26 and the magnetic head 1 for magnetic field modulation can be detected.

Based on the amount of positional deviation detected in this way, the position of the flying slider 2 is controlled by the flying slider actuator 9 consisting of, for example, a voice coil, thereby aligning the light beam spot 26 and the magnetic head 1 for magnetic field modulation. It can be done automatically. With this method, it is possible to always apply a constant magnetic field strength at the recording point, and it is possible to achieve override by stable magnetic field modulation with similar recording/reproducing characteristics.

[Effects of the Invention] As explained above, the floating magnetic head position control device of the present invention detects the position of the light beam spot nod with the photodetectors attached to both sides of the magnetic head for magnetic field modulation, and adjusts the position of the light beam spot. By aligning the magnetic field modulation magnetic head to the optimal position according to the position, it is possible to avoid negative overrides even when recording on a disk with a large eccentricity using a magnetic field modulation magnetic head with a small magnetic pole area. It becomes possible to achieve the characteristics.

[Brief explanation of drawings]

FIG. 1 is a configuration diagram of a magneto-optical disk device showing one embodiment of a floating magnetic head position control device according to the present invention, FIG. 2 is a perspective view showing an example of a floating magnetic head in the present invention, and FIG. FIG. 4 is a diagram illustrating the principle of detecting the position of a light beam spot in the invention; FIG. 4 is a configuration diagram of a conventional magneto-optical disk device; FIG. 5 is a diagram illustrating an example of magnetic field strength distribution of a floating magnetic head for magnetic field modulation. . 1... Magnetic head for magnetic field modulation 2... Slider 3.4... Photodetector 5... Gimbal spring 6... Suspension spring 7... Carriage 8 ... Differential amplifier 9 ... Flying slider actuator 10 ...
- Magneto-optical disk 11... Substrate 12... Magneto-optical recording film 13... Protective film 20... Magneto-optical head 21... Light source 22...・Light beam 23...Collimating lens 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, ・Beam splinter, objective lens, light beam spot, lens actuator, beam splinter, focus, Tracking detection system, magneto-optical reproduction signal detection system, magneto-optical head positioner actuator, coupling unit, magnetic head drive circuit

Claims (1)

[Claims] (1) heating a recording film made of a perpendicularly magnetized film formed on a disk-shaped substrate by irradiating the recording film with a light beam while applying a magnetic field in the perpendicular direction according to recorded data;
A floating magnetic head position control device in a magneto-optical disk device that records the direction of magnetization of the recording film as information, comprising: a magnetic field modulation magnetic head that applies a modulated magnetic field according to the recorded data; A magnetic head support device for magnetic field modulation comprising a slider mounted on one end surface of the slider and floating above the recording film surface using a fluid flow, a gimbal spring that supports the slider, and a suspension spring; a moving device for moving the magnetic head; a means for detecting the position of the light beam spot focused on the recording film surface; and a means for detecting the position of the light beam spot focused on the recording film surface; What is claimed is: 1. A floating magnetic head position control device comprising: a position control device for tracking