JPH0495218A - Magnetic disk and magnetic disk device using the same - Google Patents

Abstract

PURPOSE:To improve the track density with simple constitution by making the use of the magnetic discontinuity caused by the fine ruggedness of a magnetic disk as the servo signals. CONSTITUTION:The fine rugged groove parts 5 and 6 are previously formed on the surface of a magnetic disk substrate 3 made of plastic, etc., to servo as the servo signals and the information for the shift control of a magnetic head 2. Then a magnetic recording layer 4 is formed on a magnetic disk substrate 3 having the parts 5 and 6. In such a case, a uniform magnetic flux is detected at the recessed part or projecting part at reproduction and no signal is regenerated. However the relative position between the head 2 and the layer 4 of a magnetic disk is changed suddenly on a boundary between the level difference parts. Thus the head 2 produces an impulsive signal in the case of passing through the boundary of the part 6. This impulsive signal is used as a servo signal. Thus it is not required to write the servo signal for the control of the head position for the production of a servo signal input magnetic disk for a high density magnetic disk device.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a magnetic disk in which recorded information is recorded by changing the shape of a ferromagnetic material adhered to the surface of a non-magnetic substrate having irregularities of the magnetic disk, and a magnetic disk using the same. The present invention relates to a magnetic disk device using.

Conventional technology In recent years, with the increase in the recording density of magnetic disks, the slider surfaces of magnetic disks and magnetic heads have become ultra-flat and ultra-mirrored.
Progress is being made to lower the flying height of magnetic heads and to increase the coercive force of magnetic disks. In addition, in order to increase the recording capacity per magnetic disk, zone pit recording is a method that increases the number of sectors on the outer circumference, increasing the recording density, instead of the conventional method where the number of sectors is the same regardless of the inner or outer circumference of the magnetic disk. Efforts are being made to increase the recording capacity of magnetic disk devices.

However, there are several problems with increasing the recording capacity of magnetic disk devices. For example, in a magnetic disk device that uses a contact start/stop method, when the device is stopped, the magnetic head may stick to the magnetic disk and the motor may stop rotating. Here, the contact start-stop method means that when the magnetic disk drive is stopped, the magnetic disk and the magnetic head are in contact with each other, and when the magnetic disk drive is in operation, the magnetic head is brought into contact with the magnetic disk by the action of air drawn in by the high-speed rotating magnetic disk. In this method, the magnetic disk floats with a certain gap between the disks, but the magnetic disk tends to stick to the magnetic head, which tends to cause problems such as difficulty in starting. Currently, magnetic head adhesion is prevented by controlling the surface roughness of the magnetic disk. Furthermore, increasing the linear recording density of magnetic disks shortens the magnetization reversal interval, resulting in increased magnetic interference, which is an obstacle to achieving higher recording densities. Prevents magnetic interference.

The magnetic disks used in these future devices have a flat magnetic recording layer and a protective layer laminated on a flat non-magnetic substrate made of aluminum or plastic material.

Next, we will discuss the configuration and operation of the magnetic disk device in the fourth section.
This will be explained with reference to the figures. In the figure, a magnetic disk 1 has continuous metal thin films such as a magnetic recording layer and a protective layer made of ferromagnetic material deposited on both sides of an aluminum nonmagnetic substrate by plating or sputtering. The magnetic head 2 is made of a soft magnetic material such as ferrite, and flies above the rotating magnetic disk 1 with a submicron gap during operation of the magnetic disk device. In addition, the magnetic disk device is equipped with an actuator that moves the magnetic head 2 in the radial direction of the magnetic disk 1, an electronic circuit system that processes recording/reproduction signals of the magnetic head 2, a motor that rotates the magnetic disk 1, and the above means. It is composed of a casing that seals the head 2 and the magnetic disk 1. During operation, the magnetic disk device records and reproduces information on the magnetic disk 1, and this operation involves moving the magnetic head 2 in the radial direction.
Information is recorded and reproduced by extremely precisely positioning the target track for recording and reproduction. However,
The relative positioning accuracy of the magnetic head 2 with respect to the magnetic disk 1 is limited due to the mechanical precision of the components of various magnetic disk drives and expansion and contraction due to temperature.

Conventionally, in order to improve the above-mentioned relative positioning accuracy, in a magnetic disk drive, position information, that is, a servo signal for controlling the position of the magnetic head by a servo mechanism, is recorded in advance on one surface of the magnetic disk. A closed-loop control servo mechanism is used in a large-capacity magnetic disk drive having a high-speed, high-precision head positioning mechanism. The magnetic head 2 on the servo signal surface reproduces reference track data and constantly sends an error signal representing the amount of positional deviation to the head positioning circuit, so that any deviation from the center of the target track is immediately corrected.

Problems to be Solved by the Invention In order to increase the recording density of magnetic disks, magnetic disks and
There is a need for magnetic heads to be made even more ultra-mirror-finished and ultra-flat, but these have the problems of attraction and increased magnetic interference. In addition, in the above conventional example, it is necessary to record servo signals with high precision on the magnetic disk in advance, and the higher the track density, the more difficult it becomes to record servo signals with high positional precision. .

Therefore, it is also difficult to increase the recording density of magnetic disks.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a magnetic disk device that enables highly accurate positioning of a magnetic head, has a high recording density magnetic disk, has a large capacity, and is highly reliable.

Means for Solving the Problems In order to achieve the above-mentioned objects, the present invention forms in advance micro uneven grooves on the surface of a magnetic disk substrate made of plastic or the like to serve as servo signals and information for controlling the movement of the magnetic head. , a magnetic recording layer is deposited on the magnetic disk substrate having the uneven portions.

Effects of the present invention With the above-described configuration, the magnetic discontinuity caused by minute irregularities on the magnetic disk can be used as a servo signal or reproduction-only information, so track density can be increased with a simple configuration. be.

Embodiment The structure of an embodiment of the present invention will be described with reference to FIG. 1 and FIG. 2. FIG. 1 is a sectional view of a concave-convex magnetic disk made of a metal thin film according to this embodiment. In the figure, 3 is a non-magnetic substrate with an uneven shape, 4 is a magnetic recording layer, 5 is a protective layer, and 6 is an uneven portion. Polyimide resin was used for the uneven substrate 3 of this example. The method of forming the non-magnetic substrate 3 is not particularly limited, but in this example, a stamper mold is created by wet selective etching, similar to the manufacturing method used in optical disk technology, and this mold is A method was used in which a polyimide resin was poured into a mold to form a nonmagnetic substrate 3 having an uneven surface. This forming method is used in the manufacture of optical disks and has a proven track record in mass production. Furthermore, if a magnetic recording layer 4, a protective layer 5, etc. are deposited on the non-magnetic substrate 3 including the uneven portions 6 by sputtering, and then DC erasing is performed over the entire magnetic disk.
A concave-convex magnetic disk with high density recording is formed.

Next, the process by which the magnetic head reproduces signals from the concavo-convex portion 6 will be explained with reference to a cross-sectional view of the main part of the magnetic disk device shown in FIG. In FIG. 2, the uneven magnetic disk is DC erased by a magnetic head 2 and magnetized in one direction. During reproduction by the magnetic head 2, the magnetic head 2 detects negative magnetic flux in the concave or convex portions, and no signal is reproduced. However, at a boundary with a stepped portion of the uneven portion 6, the relative position between the magnetic head 2, which is floating at a constant distance from the surface of the magnetic disk, and the magnetic recording layer 4 of the magnetic disk changes sharply, and the magnetic flux Since the amount changes discontinuously, the magnetic head 2 generates a pulsed signal when passing the boundary of the uneven portion 6. As described above, when the magnetic head 2 passes through the boundary of the uneven portion 6, a signal is reproduced in the magnetic head 2 in accordance with the boundary of the uneven portion 6.

An embodiment in which a signal from the uneven portion 6 is used as a servo signal will be described with reference to FIG. 3. The magnetic disk and magnetic disk device used are for 3.5 inches, and the motor rotation speed of the magnetic disk device is 360.
It was set to 0 rpm.

Figure 3(b) shows a servo pattern called a two-phase dibit used in conventional magnetic disk drives;
) is the output signal waveform when the magnetic head 2 reproduces the servo pattern of (b). Conventional servo pattern (
In b), the position bit 7 with four tracks as a layer is twice the data surface track width, the servo surface track width is 500 .mu.m, and the length of one servo pattern is 7.5 .mu.S.

The l servo pattern consists of a synchronization bit 8 and position bits 7 for A, B, C, and D. In this servo pattern (b), when the position of the magnetic head 2 is ■, the output waveform from the magnetic head 2 becomes P-■ at the 31st m (C), which is A.

Comparing the amplitudes of the output signals of B, A>B.

This means that the magnetic head 2 has shifted above the target track. Further, when the position of the magnetic head 2 is .largecircle., the output waveform from the magnetic head 2 becomes P-.circle. in FIG. 3(C), and when the amplitudes of the output signals A and B are compared, A<B. This means that the magnetic head 2 has shifted below the target track. Furthermore, when the position of the magnetic head 2 is ■, the output waveform from the magnetic head 2 is also P-■, and A
, B, A=B. In this case, it means that the magnetic head 2 is located at the center of the target track. That is, the magnetic head 2 is positioned by performing M# so that the output signals of position bits A and B are the same.

FIG. 3(a) shows an uneven two-phase tie-bit servo pattern of this embodiment corresponding to FIG. 3(b). In (a), the shaded area is a convex part, the white part is a concave part, and the level difference in the uneven part is 0.
．． It was set to 3 μm. Furthermore, in this example, two types of uneven magnetic disks were created. One is that the servo surface track width is 50 μm and the length of one servo pattern is 7.5 μS, in comparison with a conventional magnetic disk. Also, another one
First, the servo surface track width is 20 μm and the length of one servo pattern is 5.0 μs, which is about twice the linear recording density of conventional magnetic disk devices.

When these two types of magnetic disks were used in a magnetic disk device, as can be seen from the explanation of the playback process above,
An output signal was obtained in the same manner as in the conventional example, and control could be performed so that the output signals of position bits A and B were the same, and the positioning of the magnetic head 2 could be performed. Also,
When the contact start/stop test was conducted 20,000 times using the uneven magnetic disk of this example, no adhesion occurred at all.

In this embodiment, the shape and dimensions of the concavo-convex portion 6 in the present invention are arbitrary and can be set to the magnetization reversal interval and track width corresponding to the target areal recording density, and are not particularly specified. For example, it is possible to reduce the size to about the same size as an optical disk, that is, about 0.4 μm square. It is possible if the size of the step is about 0.1 μm or more. The technology of forming these minute irregularities on a flat non-magnetic substrate has been established in the current optical disc manufacturing process as a technology for mass-producing optical discs by pressing or other methods, and as a technology for manufacturing master plates for optical disc manufacturing. be. It is clear that the maximum recording density of the magnetic disk of this embodiment is equivalent to that of an optical disk, and can significantly exceed the recording density of conventional magnetic disks. Moreover, the uneven pattern is arbitrary, and various methods can be used as the servo signal information.

For example, it is possible to provide an uneven shape at a specific position in the circumferential direction on a magnetic disk and detect the reproduction signal of the magnetic head as position information. By using this, data surface servo information and zone pit information can be obtained. It can be used as Furthermore, it is also possible to use the uneven pattern as information. For example, it can also be used as a playback-only disk that is often used for playback, such as a kanji dictionary disk or an image file disk.

In addition, it is also possible to predict magnetic interference in advance and form a concavo-convex pattern to reduce the magnetic interference.

Using the magnetic disks mentioned above, large-capacity information can be recorded without problems such as sticking of magnetic disks.

It is clear from the above description that it is possible to provide a magnetic disk device that can reproduce data.

Effects of the Invention With the above-described configuration, the present invention provides the following effects.

(a) It is no longer necessary to write servo signals for controlling the magnetic head position, which conventionally required a high-precision writing device, and the servo signals are recorded on the magnetic disk substrate by means of a batch production method. , it has the advantage of being easy to produce and having excellent mass productivity.

(b) It is possible to create a servo signal magnetic disk for a high-density magnetic disk device that is higher than that of the conventional one.

(C) By changing the uneven pattern, read-only high recording density magnetic disks can be easily created. Furthermore, since magnetic interference can be eliminated, the S/N ratio of the magnetic head reproduction output is improved, and the error rate is reduced, for example.

ω) Conventional magnetic disks are mirror-polished and attracting magnetic heads is a big problem, but the magnetic disk of the present invention has an uneven shape, so it is possible to make the surface roughness larger than that of conventional magnetic disks. Even when the magnetic disk and magnetic head are in contact, the contact area becomes extremely small, and the problem of adsorption is also solved.

[Brief explanation of drawings]

FIG. 1 is a partial cross-sectional view of a magnetic disk according to an embodiment of the present invention, FIG. 2 is a cross-sectional view of essential parts showing the process in which the magnetic head reproduces signals from the uneven portions of the magnetic disk, and FIG. 3(a)
, (b) and (c) are diagrams illustrating the relationship between a servo pattern and a signal when a signal from an uneven portion is used as a servo signal, and FIG. 4 is a plan view of a conventional magnetic disk device. 3...Nonmagnetic substrate, 4...Magnetic recording layer, 5...Protective layer, 6 uneven portion. Name of agent: Patent attorney Shigetaka Awano

Claims (3)

[Claims] (1) A magnetic disk comprising a non-magnetic substrate having an uneven shape on its surface and a magnetic recording layer having an uneven shape deposited on the non-magnetic substrate. (2) The magnetic disk according to claim 1, wherein the magnetic recording layer is a recording layer for positional information on the magnetic disk, read-only information, or both. (3) A magnetic disk device using the magnetic disk according to claim 1 or 2.