JPH0125124B2 - - Google Patents

Description

[Detailed description of the invention] The present invention relates to a magnetic disk device.

In large capacity memory devices, the most important issue is to shorten access time while increasing storage capacity. In order to record more information on a limited magnetic disk, it is necessary to perform higher-density recording within one track and to narrower the spacing between tracks. When narrowing the track spacing and providing more tracks on one magnetic disk, relative positioning of the tracks and the magnetic head is a major problem.

Especially flexible disks that can be replaced.
In the case of devices using disks, the disks are made of synthetic resin that expands significantly due to temperature and humidity, so it is impossible to improve the track density without reading the relative position of the track and magnetic head. .

FIG. 1 schematically explains a well-known method for accurate positioning without being bothered by unstable factors such as thermal expansion.

Reference numerals 1 and 2 are magnetic disks, each of which has a recording medium coated (or plated) on both the front and back sides. Three of the magnetic heads 3 to 6 are magnetic heads for detecting servo tracks, and information representing track positions (called servo signals) is provided concentrically on the magnetic disk surface that these magnetic heads face. The position of the head 3 is obtained as an electrical output signal. 7 is a servo control circuit, and 8 is a voice coil type actuator, which compares the output signal of the magnetic head 3 with the target track number and selects the desired magnetic head 3 (and by extension, the magnetic heads 4 to 6 attached to the same arm). position exactly on the track. In this case, if the magnetic disks 1 and 2 are the same, accurate positioning can be performed regardless of changes in temperature, humidity, or changes over time. On the other hand, of the four recording surfaces in total, one surface is occupied by the servo track, so only three surfaces are used for data recording. Furthermore, a single magnetic head is used for positioning purposes. In this example, there are two magnetic disks, but if there is only one magnetic disk, the efficiency will be even worse. In order to avoid these drawbacks, the present invention records information and signals relating to track position on the same magnetic disk surface, and reads both information with the same magnetic head.

The magnetic disk device of the present invention has a first layer of a magnetic recording layer formed on a base, a second layer of a magnetic recording layer formed on the first layer of the magnetic recording layer, and The coercive force of the first layer of the magnetic recording layer is larger than the coercive force of the second layer of the magnetic recording layer, and information indicating the position of the recording track is recorded in the first layer of the magnetic recording layer. In a magnetic disk device for recording and reproducing data using a magnetic disk in which data is recorded on the second layer, a magnetic head used in the magnetic disk device includes a recording/reading head for recording and reproducing the data, and a magnetic disk for recording and reproducing the data. The recording/reading head is sandwiched between two erasing heads for forming a guard band, and the erasing head also has the function of reading information indicating the position of the recording track.

Further, by tilting the magnetic recording angle (azimuth) of information indicating the position on the magnetic disk by 5 degrees or more from the radial direction of the magnetic disk, interference with recorded data can be avoided.

Furthermore, by making the gap length of the erasing core of the erasing head at least twice the gap length of the recording/reading core of the recording/reading magnetic head, detection of high frequency signals on the data track is eliminated. can do.

Furthermore, the phase difference of the information indicating the position recorded across the data track can be detected by making the inside and outside of the data track different by a predetermined value, making detection more reliable. can.

This will be explained below using figures.

FIG. 2 is a radial cross-sectional view of a magnetic disk and a magnetic head according to the present invention. The magnetic disk 8 has magnetic layers 12 and 1 on both sides of the base 11.
3 is applied (or attached by other methods) in the form of a sandwich. The front side magnetic head 9 and the back side magnetic head 10 are used for recording and recording, respectively.
It has a read head, ie, a recording/read core 15, and an erasing head, ie, an erasing core 14 sandwiching it.

These two magnetic heads are each fixed to a carriage, and can be moved arbitrarily in the radial direction by a common movement mechanism (voice coil actuator, etc.). In FIG. 2, the details are omitted for the sake of simplification.

FIG. 3 is a BH curve showing the magnetic properties of the magnetic layers 12 and 13. The magnetic layer 12 has a curve 16
The magnetic layer 13 is shown by a curve 17. The magnetic layer 12 is characterized by a much higher coercive force than the magnetic layer 13.

It is not difficult at all to apply two magnetic layers having such different magnetic properties. for example,
This is possible by applying a metal thin film to the first layer and fine iron oxide powder to the second layer.

FIG. 4 is a sectional view and a plan view for explaining the functions of the present invention.

42 is a data track, using the recording/reading core 15 of the magnetic head 9 or 10,
Data is written to and read from the magnetic layer 13 . Since the magnetic field generated by the recording/reading core 15 is not high enough to overcome the coercive force of the magnetic layer 12, the magnetization of the magnetic layer 12 cannot be reversed.

Reference numeral 41 denotes a servo track, which is provided across the data track 42. Information regarding the track position is written to the servo track 41 using a strong magnetic field by a dedicated magnetic head during the manufacturing process of the magnetic disk 8.
The coercive force of the magnetic layer 12 can be overcome, and information regarding the track position can be recorded. However, this magnetization cannot be reversed by the weak magnetic field generated by the erasing core 14 or the recording/reading core 15. Therefore, when using a magnetic disk, the servo track signal will not be erased by mistake. When a servo signal is written to the servo track 41, the servo signal is also written to the medium layer 13 on the servo track at the same time, but this information can also be erased later by the magnetic field created by the erasing core 14. The data tracks and servo tracks are provided concentrically and repeatedly in the radial direction, but are omitted from the drawing.

Since the medium layer 12 is located below the medium layer 13, it does not originally provide a very high read frequency due to thickness loss, but it makes interference with data on the medium layer 13 more reliable and prevents interference. Therefore, it is desirable that the tracks 41 and 42 be arranged offset in a plane.

As shown in Fig. 4, the servo track 41 occupies a large width, which seems to widen the track spacing and reduce efficiency, but originally the purpose of the data track was to prevent interference between tracks. Since a non-recording band called a guard band is provided, no special space is required for the servo track. Furthermore, since the servo signal can be made low in frequency and resistant to noise, the width of the servo track can be made much narrower than the width of the data track. Furthermore, the phase of information on the servo tracks provided across the data track can be detected reliably by changing the inside and outside of the data track by a predetermined value.
The specific form of the servo signal recorded on the servo track 41, reading and processing it,
Various specific configurations for providing feedback to voice coil type actuators and the like have been proposed, and the method of the present invention does not limit the degree of freedom in selecting them, so we will not go into details here. A few ideas for further enhancing the effects of the present invention will be described below.

FIG. 5 is a diagram schematically showing a magnetic recording pattern according to an embodiment of the present invention. The arrow indicates the direction of magnetization, and the servo signal on the servo track is preferably a sinusoidal, low frequency signal so that the frequency spectrum is low. As a result, the frequency of the servo signal leaked to the reproduction core 15 and detected is read out from the information track 42.
Since the frequency is sufficiently lower than the original information frequency, it can be sufficiently separated by a filter circuit, and there is no problem of data interference.

Furthermore, if the gap width of the erasing core 14 is made twice or more larger than that of the recording/reading core 15, the erasing core 14 hardly detects the data (very high frequency) on the track 42.

FIG. 6 shows another embodiment of the present invention, in which the magnetic recording pattern of positional information on the servo track 41 is largely inclined with respect to the radial direction. In reality, it is preferable to tilt it at an angle of 5° or more, and the upper limit can be arbitrarily determined in view of the recording density. Of course, the gap of the erasing core 14 is also tilted accordingly. Therefore, even if a rectangular waveform signal is recorded on the servo track 41, the servo signal detected by the erasing core 14 will be weak and dull. Therefore, interference with data can be sufficiently avoided.

The erasing core 14 is originally intended for erasing both sides of the information recorded by the recording/reading head 15 and trimming the outer edge of the track, but in the present invention, the servo signal on the servo track 41 is It also has a reading function. As mentioned above, the gap width of the erasing magnetic head may be wider than that of the recording/reading head. However, it is desirable that the erasing core 14 has separate windings for erasing and reading.

It is generally desirable that the magnetic heads 9 and 10 be used alternately, with one being used for position detection and the other being used for data recording and reading.

As described above, according to the present invention, the first layer of the magnetic recording layer formed on the base has a coercive force smaller than that of the first layer formed on the first layer (that is, the coercive force of the first layer is smaller than that of the first layer formed on the first layer). In a magnetic disk device using a magnetic disk having a magnetic recording layer (having a magnetic force greater than that of the second layer), the magnetic head used therein is used as a magnetic head in which one erasing head is arranged on each side of the recording/reading head. (1) By using two erasing heads as a servo signal reproducing head, it is possible to create a magnetic head that has both the functions of reading servo signals and erasing to create a guard band. In addition, since the servo signal can be read by taking the ratio or difference in the magnitude of the output from the two heads, so-called differential detection can be performed, and detection sensitivity and accuracy can be dramatically improved. It is.

(2) Furthermore, since data information and servo information are recorded at separate positions when viewed two-dimensionally,
There is little interference, and sufficient separation can be achieved by simply tilting the gap between the recording/reading head and the erasing magnetic head by several degrees and further changing the gap length. For this reason, sufficient detection sensitivity can be obtained using a normal magnetic induction head, there is no need to install a special dedicated head, and there is no need to use a magnetic recording medium with perpendicular magnetization anisotropy. Therefore, for example, a coating type magnetic recording medium may be used, and it can be applied to the widespread use of floppy disks, from inexpensive ones to high-end ones, and is particularly suitable for inexpensive floppy disks.

It has the following effects.

As a modification of the present invention, it is not difficult to use a plurality of magnetic disks, or to use one magnetic disk used in the present invention and one (or more) ordinary magnetic disks arranged coaxially. . Furthermore, various methods can be used, such as providing a servo track on only one side of a double-sided magnetic disk, or providing a servo track every few tracks.

[Brief explanation of drawings]

FIG. 1 is a diagram schematically showing a conventional positioning method for a magnetic disk device. FIG. 2 is a radial cross-sectional view of a magnetic disk and a magnetic head according to the present invention. FIG. 3 is a diagram showing a BH curve showing the magnetic characteristics of a magnetic medium. FIG. 4a is a sectional view of a magnetic head and a magnetic disk according to the present invention. FIG. 4b is a diagram showing a magnetic recording pattern of a magnetic disk according to the present invention. FIG. 5 is a diagram schematically showing a magnetic recording pattern according to an embodiment of the present invention. FIG. 6 is a diagram showing another embodiment of the present invention. 8...Magnetic disk, 9...Magnetic head, 11
...Base, 12...First layer, 13...Second layer,
14... Erasing head (erasing core), 15...
Recording/reading head (recording/reading core), 41... information indicating position, 42... data track.

Claims (1)

[Scope of Claims] 1. A first layer of a magnetic recording layer formed on a base, and a second layer of a magnetic recording layer formed on the first layer of the magnetic recording layer, The coercive force of the first layer of the magnetic recording layer is larger than the coercive force of the second layer of the magnetic recording layer, information indicating the position of the recording track is recorded in the first layer of the magnetic recording layer, and the coercive force of the first layer of the magnetic recording layer is In a magnetic disk device that performs recording and reproduction using a magnetic disk in which data is recorded on two layers, a magnetic head used in the magnetic disk device includes:
It has a recording/reading head for recording and reproducing the data, and two erasing heads for creating a guard band across the recording/reading head for recording and reproducing the data. A magnetic disk device characterized in that the head also has the function of reading information indicating the position of the recording track. 2. The magnetic disk device according to claim 1, wherein the magnetic recording angle (azimuth) of information indicating a position on the magnetic disk is inclined by 5 degrees or more from the radial direction of the magnetic disk. 3. The magnetic disk device according to claim 1, wherein the gap length of the erasing core of the magnetic head is at least twice the gap length of the recording/reading core. 4. Information indicating the position of the magnetic disk is recorded across data tracks when viewed in plan, and the phase of the information indicating the position differs by a predetermined value between the inside and outside of the data track. Claim 1 characterized in that
The magnetic disk device described in Section 1.