JP2008234834A - Disk drive and data writing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a data write method preventing influence of fringe area particularly due to an azimuth angle to improve the resultant data recording and reproducing characteristics. <P>SOLUTION: The data write method is applied to the disk drive recording data on a disk medium by a head mounted on a rotary type actuator. The method executes a track pitch conversion processing in which, when the position of a data track is included in an inner circumferential area or an outer circumferential area on the disk medium, the track pitch of the data track is set to be larger than that in an intermediate circumferential area on the basis of the azimuth angle of the head. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention generally relates to a disk drive, and more particularly to a data write technique in a perpendicular magnetic recording type disk drive.

  Generally, in a disk drive represented by a hard disk drive, a rotary (rotary) actuator is used as a mechanism for positioning a head at a target position (track to be accessed) on a disk medium as a data recording medium. in use.

  When the head mounted on such a rotary actuator is positioned and controlled (servo controlled) in the radial direction on the disk medium under the control of the CPU which is the main controller of the drive, the inner peripheral area or outer periphery on the disk medium In the area, so-called azimuth angles occur.

  In a disk drive, servo control is executed by reproducing a servo pattern (servo data) recorded on a disk medium by a read head included in the head. In this case, for example, in the outer peripheral area on the disk medium, the azimuth angle becomes large, so that the detection range (detection sensitivity) by the read head is expanded. For this reason, it becomes a factor which causes the fall of head positioning accuracy.

  In order to solve such a problem, there has been proposed a disk drive that narrows the interval between servo tracks on which servo patterns are recorded, for example, in an outer peripheral area where the azimuth angle increases (see, for example, Patent Document 1). .

Further, when the azimuth angle is increased, the effective track width of the data track on which user data is recorded fluctuates, which causes an influence such as a decrease in recording density. In order to eliminate such a point, a configuration has been proposed in which the distance between tracks adjacent in the radial direction on the disk medium is changed (see, for example, Patent Document 2).
JP-A-6-60573 JP 2002-237142 A

  As a result of the azimuth angle of the head, when data is written on the disk medium by the write head, a so-called fringe area is generated in addition to an effective recording area in the data track. This fringe area is an area in which data cannot normally be read by the read head. In particular, in a perpendicular magnetic recording type disk drive, a single pole type head having a length in the circumferential direction of a track is used as a write head, and therefore, a fringe region due to an azimuth angle is generated to a degree that cannot be ignored.

  In the above-mentioned prior art documents and the like, a technique that can solve the influence of the fringe region particularly by the azimuth angle is not proposed.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a disk drive that can suppress the influence of a fringe area due to an azimuth angle and improve data recording / reproducing characteristics as a result.

  A disk drive according to an aspect of the present invention includes a head including a single magnetic pole type head for perpendicular magnetic recording as a write head for recording data, positioning control of the head, and the write head at a specified position. A controller for recording data, a data track configured in the radial direction based on the data recorded by the controller, and a disk medium on which a servo track used for positioning control of the head is recorded, On the disk medium, each data track included in the outer peripheral area is set larger in accordance with the fringe area generated based on the azimuth angle of the head with respect to the track pitch of each data track included in the intermediate peripheral area. In this configuration, recording is performed at a track pitch.

  According to the present invention, it is possible to configure a data track that can suppress the influence of the fringe area due to the azimuth angle of the head, and as a result, it is possible to improve the data recording / reproducing characteristics of the disk drive.

  Embodiments of the present invention will be described below with reference to the drawings.

(Disk drive configuration)
FIG. 1 is a block diagram showing a main part of a perpendicular magnetic recording type disk drive according to the present embodiment.

  The disk drive 10 includes a disk medium 11 that is rotated by a spindle motor 16, a head 12 that records or reproduces data, and a microprocessor (CPU) 17 that is a main controller.

  The head 12 has a structure in which a write head element and a read head element are mounted on a slider. The write head element (120) is a single pole type head capable of perpendicular magnetic recording on the disk medium 11. The read head element is a reproducing head that reads servo patterns (servo data) or user data recorded on the disk medium 11.

  The head 12 is mounted on a rotary (rotary) actuator 13. The actuator 13 is rotated in the radial direction on the disk medium 11 by a voice coil motor (VCM) 14. The VCM 14 is driven and controlled according to the servo control of the CPU 20.

  The CPU 20 executes control for recording or reproducing data with respect to a target position (access target track) on the disk medium 11 in accordance with an instruction from a host system such as a personal computer outside the drive. In the present embodiment, the CPU 20 executes servo control (head positioning control) including track pitch conversion processing as described later.

  The disk drive 10 is provided with a circuit board 15 on which circuit components such as a head amplifier connected to the write head element and the read head element of the head 12 are mounted. The CPU 20 is mounted on a circuit board (not shown) different from the circuit board 15.

(Track format)
In the disk drive, a servo pattern (servo data) 200 is recorded on the disk medium 11 as shown in FIG. An area where the servo pattern 200 is recorded may be called a servo sector. The servo sectors are arranged at equal intervals in the circumferential direction on the disk medium 11.

  The CPU 20 performs servo control (head positioning control) using the servo pattern 200, thereby configuring the data track 100 that records user data between servo sectors.

  FIG. 2 is a diagram in which the data surface on the disk medium 11 shown in FIG. 1 is developed on a plane.

  As shown in FIG. 2, a large number of data tracks 100 are concentrically arranged in the radial direction 210 on the disk medium 11. Each data track is divided and managed into a plurality of data sectors 100a to 100c. That is, in the disk drive, the data sector is an access unit. In the servo sectors 200a and 200b, a track address (cylinder code) An for identifying the data track 100 and servo burst data (A to D) described later are recorded as data included in the servo pattern.

  Here, the distance (STw) between the tracks (servo tracks) defined by the servo data 200a and 200b and the radial distance between the adjacent data tracks 100 are not necessarily the same. The data track 100 is arranged in the radial direction with a distance of 1.5 times the servo track interval, for example. The distance in the radial direction between adjacent data tracks 100 means the distance between the center line of the data track width Tw (dotted line in FIG. 2) and the center line of the adjacent track.

  FIG. 3 shows the shape of servo patterns 200 arranged radially on the disk medium 11 in the radial direction. In the disk drive, as described above, since the head 12 moves in the radial direction on the disk medium 11 by the rotary actuator 13, the servo pattern 200 shows an arc shape 300 along the rotation locus of the head 12. It is preferable.

(Servo pattern and azimuth angle)
FIG. 4 is a diagram for explaining the servo pattern and the azimuth angle of the head 12 according to this embodiment.

  The servo pattern includes servo burst data (A to D) 400 and a track address (cylinder code) 401 as shown in FIG. Here, the CPU 20 executes servo control for controlling the positioning of the head 12 by controlling the actuator 13 on the target data track (for example, track address k) included in the middle area on the disk medium 11. Normally, the CPU 20 uses the servo burst data A and B and positions the head 12 at the track center position identified by the track address k.

  In FIG. 4A, the CPU 20 positions the read head of the head 12 on the target data track. Here, in the middle circumferential area, the azimuth angle of the head 12 is substantially zero according to the state of the rotary actuator 13. On the other hand, as shown in FIG. 4B, for example, in the outer peripheral area, an azimuth angle is generated in the head 12. In this case, the servo patterns are arranged so that the data tracks are equally spaced (Tw) in the radial direction of the disk medium 11 regardless of the azimuth angle of the head 12.

  In such a servo pattern arrangement, in servo control, when the read head has an azimuth angle, a wide range of servo patterns are detected. In order to eliminate such a point, as shown in FIG. 4C, when a servo pattern is recorded on the disk medium 11, the azimuth of the head 12 is at the track position included in the outer peripheral area or the inner peripheral area. It is preferable to record the servo pattern so that the track interval (cylinder interval) is narrowed according to the angle (θ). Thus, when the read head detects a servo pattern in the outer peripheral area or the inner peripheral area, it is possible to keep the detection sensitivity of the servo pattern constant regardless of the azimuth angle. It is practical to record servo patterns at intervals corresponding to the respective azimuth angles for each zone divided in the radial direction on the disk medium 11.

(Azimuth angle and data track width)
Next, the relationship between the azimuth angle of the write head 120 of the head 12 and the data track width will be described with reference to FIG.

  First, in a perpendicular magnetic recording type disk drive, the write head 120 is a single pole type head whose main pole has a length in the circumferential direction of the track, as shown in FIG. The main magnetic pole corresponds to a magnetic gap of a write head used in a longitudinal magnetic recording type drive.

  As shown in FIG. 5A, since the azimuth angle is almost zero in the middle area, user data corresponding to the magnetic recording width (W) of the write head 120 is written and data having the recording area DT. A track is constructed. Here, the data track width Tw corresponding to the distance between adjacent tracks is determined based on the recording area DT with a margin such as an erase band width and a positioning error. A width corresponding to this margin is called a guard band region GB.

  On the other hand, in the outer peripheral area or the inner peripheral area, as shown in FIG. 5B, data writing by the write head 120 is executed with an azimuth angle. In this case, a fringe area (or sidelight area) DTf in which data reproduction becomes unstable occurs. In this case, as shown in FIG. 5C, it is preferable to secure a guard band region GB for sufficiently maintaining the distance between adjacent tracks according to the fringe region DTf.

  Here, when the adjacent distance (track width) Tw in the radial direction of the data track is W, the magnetic recording width (write head width) is L, the magnetic recording length is L, and the guard band width is G, the following formula ( It can be formulated as shown in 1).

Tw> W × cos θ + L × sin θ + G (1)
The magnetic recording length L may be an equivalent value for indicating the amount of the fringe area DTf. Further, from the above equation (1), when the value of L cannot be ignored, it is necessary to ensure a long adjacent track distance Tw according to sin θ.

  FIG. 8 shows setting values (vertical distance) of servo pattern track width (cylinder width STw) and data track width (interval Tw) with respect to the radial position (horizontal axis) of the write head 120 on the disk medium 11. It is a figure which shows an example. As shown in FIG. 8A, the track width 810 of the servo pattern is set to be narrow at the position of the inner peripheral area or the outer peripheral area where the azimuth angle occurs. On the other hand, the data track width 800 is set to be wide (the distance is large) in the inner peripheral area or the outer peripheral area where the azimuth angle is generated.

  FIG. 8B is a diagram showing the ratio of the data track width 820 based on the track width (cylinder width STw) of the servo pattern. That is, when the azimuth angle of the write head 120 is not present and the fringe area (side light area) can be ignored, the servo cylinder interval is widest and the user data adjacent distance can be narrowest. Therefore, the data track width 820 is set to the servo track interval. The ratio is set to the minimum value based on.

  Conversely, when the azimuth angle is given to the write head 120, the reverse tendency is shown. Therefore, the data track width 820 is set to be large in the ratio based on the servo track interval.

  FIG. 8C shows an example of setting values that are actually used in the process of setting the data track width (data track pitch) (track pitch conversion process) when the CPU 20 executes the write operation, as will be described later. FIG.

  That is, the ratio based on the servo track interval is set to be a constant value in a certain section in the radial direction on the disk medium 11. Specifically, a data track width (interval) 830 that sets the radial direction on the disk medium 11 for each of the middle area, the outer area, and the inner area is used as a zone setting value.

(Data write operation)
Hereinafter, the data write operation of this embodiment will be described with reference to FIGS.

  FIG. 6 is a diagram for explaining the state of the track pitch of the data track when user data is recorded in the radial direction (outer peripheral direction 60 and inner peripheral direction 61) on the disk medium 11 according to the present embodiment.

  Here, the track pitch (TP1, TP2) means an adjacent track interval based on the center line (dotted line) of the data track. The data track width (Tw) is a range including the recording area DTd, the fringe area (side light area) DTf, and the guard band area GB.

  When receiving a data write command from the host system, the CPU 20 obtains a track address (cylinder code) indicating a data track position (target position) on the disk medium 11 that executes the write operation (step S1). Here, the command from the host system also includes write data to be recorded on the disk medium 11.

  The CPU 20 determines whether or not the zone including the acquired track address is within the range of the middle area (step S2). Here, each zone includes a plurality of track addresses.

  When the target data track position to be accessed is included in the middle area on the disk medium 11, the CPU 20 executes normal servo control (YES in step S2, S3). That is, the CPU 20 uses the track address and servo burst data reproduced by the read head of the head 12 to drive and control the actuator 13 (actually the VCM 14), thereby controlling the write head 120 of the head 12 with the target data track. Position control to the position.

  Further, the CPU 20 executes a write operation for writing data to the target data track position by the positioned write head 120 (step S4). Here, since the azimuth angle of the write head 120 is substantially zero in the middle area, as shown in FIG. 6, only the data track of the recording area DTd in which the fringe area DTf does not occur is recorded (FIG. 5A). )).

  Here, since the azimuth angle of the write head 120 is substantially zero in the middle area, the interval (track pitch) between adjacent data tracks does not take the fringe area DTf into consideration, and the recording area DTd and the guard band area GB. Determined by.

  On the other hand, when the target data track position to be accessed is included in, for example, the outer peripheral area (arrow 60) instead of the middle peripheral area on the disk medium 11, the CPU 20 executes a track pitch conversion process (step S2). NO, S5). In other words, in the outer peripheral area, the write head 120 executes a write operation for writing data with an azimuth angle (see FIG. 5C).

  The track pitch conversion process is based on the track pitch (TP1, TP2) when a certain guard band region GB is secured in the data width including the fringe region DTf generated during the write operation based on the azimuth angle of the write head 120. Is a process for setting.

  Next, the CPU 20 executes servo control using the track address and servo burst data reproduced by the read head of the head 12 (step S6). In this servo control, the CPU 20 controls the center position of the write head 120 according to the track pitch (for example, TP1) calculated by the track pitch conversion process.

  In other words, the CPU 20 writes the write head 120 so that the track pitch of the servo pattern corresponding to the original target data track position (set by the cylinder code) becomes the track pitch converted based on the azimuth angle of the write head 120. Execute positioning control. Here, the track pitch conversion amount based on the azimuth angle of the write head 120 is the range of the fringe region DTf corresponding to the azimuth angle, that is, the guard band region GB secured in accordance with the increase of the fringe region DTf. Determined by.

(Specific example of track pitch conversion processing)
The CPU 20 executes the following specific processing as the track pitch conversion processing.

  That is, when the CPU 20 converts the address of the target data track into the cylinder code of the servo pattern, the CPU 20 sets the ratio of the servo cylinder interval to the data track interval as a multiple of a number k (integer multiple) as a zone setting value.

  Specifically, in the 1/3 feed servo pattern, for example, when “k = 1/4”, the following servo pattern offset amount can be set. That is, when “ratio = 6/4”, the servo pattern positions used for positioning control of the write head 120 are “1/8”, “1+ (5/8)”, “3+ (1/8)”. It becomes. When “ratio = 7/4”, the servo pattern position used for positioning control of the write head 120 is “1/8”, “1+ (7/8)”, “3+ (5/8)” . When “ratio = 8/4”, the servo pattern position used for positioning control of the write head 120 is “1/8”, “2+ (1/8)”, “4+ (1/8)” .

  Here, in practice, the CPU 20 executes a conversion process using the following track pitch conversion formula (2) to execute a data write operation as shown in the flowchart of FIG.

  That is, when the target data track address is A, the target servo cylinder code is B, the pitch conversion coefficient is p, and the correction coefficient is b, the track pitch conversion expression (2) can be expressed as a linear expression. .

B = p × A + b (2)
The CPU 20 obtains a data track address for executing the write operation in accordance with a command from the host system (step S11). Thereafter, the CPU 20 converts the servo cylinder code recorded on the disk medium 11 using the track pitch conversion formula (2) (step S12). Then, the CPU 20 executes servo control for positioning the write head 120 based on the servo cylinder code obtained by the conversion (step S13). A write operation for writing user data on the disk medium 11 is executed by the positioned write head 120 (step S14).

  As described above, according to the present embodiment, the outer circumferential area or the inner circumferential area where the influence of the azimuth angle of the write head 120 is large is set to be larger than the track pitch in the middle circumferential area where there is no influence of the azimuth angle. Thus, errors due to crosstalk between adjacent data tracks can be mitigated. That is, crosstalk between adjacent data tracks can be suppressed by sufficiently securing the guard band region GB according to the range of the fringe region (side light region) by the azimuth angle. Therefore, it is possible to provide the optimum data track width for recording / reproducing user data. In other words, the data recording / reproducing characteristics of the disk drive can be improved.

  The data write method according to the present embodiment is particularly effective for a write operation when a single magnetic pole type head is used as a write head in a perpendicular magnetic recording type disk drive. It is also effective in a longitudinal magnetic recording type disk drive.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

The block diagram which shows the principal part of the disk drive regarding embodiment of this invention. The figure which shows the data format regarding this embodiment. The figure which shows the shape of the servo pattern regarding this embodiment. The figure for demonstrating the servo pattern and azimuth angle of a head regarding this embodiment. The figure for demonstrating the relationship between the azimuth angle of the write head and data track width regarding this embodiment. The figure for demonstrating the track pitch of the data track in the data write operation regarding this embodiment. 6 is a flowchart for explaining a procedure of a data write operation according to the embodiment. FIG. 5 is a diagram illustrating an example of a set value of a track width with respect to a radial position of a write head according to the present embodiment. 6 is a flowchart for explaining a procedure of a data write operation using a track conversion formula according to the present embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Disk drive, 11 ... Disk medium, 12 ... Head, 13 ... Actuator,
14 ... voice coil motor (VCM), 15 ... circuit board, 16 ... spindle motor,
20 ... Microprocessor (CPU), 100 ... Data track,
200: Servo pattern (servo sector), 120: Write head (single pole type head).

Claims (10)

A head including a single magnetic pole type head for perpendicular magnetic recording as a write head for recording data;
A controller that performs positioning control of the head and records data with the write head at a specified position;
A data track configured in a radial direction based on data recorded by the controller, and a disk medium on which a servo track used for positioning control of the head is recorded,
On the disk medium, each data track included in the outer peripheral area is set larger in accordance with the fringe area generated based on the azimuth angle of the head with respect to the track pitch of each data track included in the intermediate peripheral area. A disc drive characterized by being recorded at a track pitch. A head including a single magnetic pole type head for perpendicular magnetic recording as a write head for recording data;
A controller that performs positioning control of the head and records data with the write head at a specified position;
A data track configured in a radial direction based on data recorded by the controller, and a disk medium on which a servo track used for positioning control of the head is recorded,
On the disk medium, each data track included in the inner area is larger than the track pitch of each data track included in the middle area according to the fringe area generated based on the azimuth angle of the head. A disc drive characterized by being recorded at a set track pitch. A head including a single magnetic pole type head for perpendicular magnetic recording as a write head for recording data;
A controller that performs positioning control of the head and records data with the write head at a specified position;
A data track configured in a radial direction based on data recorded by the controller, and a disk medium on which a servo track used for positioning control of the head is recorded,
On the disk medium, each data track included in the outer peripheral area and the inner peripheral area is in a fringe area generated based on the azimuth angle of the head with respect to the track pitch of each data track included in the intermediate peripheral area. A disk drive having a configuration in which recording is performed at a track pitch that is set to be large according to the above. The controller is
Means for determining a position of a data track on which data is to be recorded on the disk medium;
Means for determining whether or not the position of the data track is included in the middle area;
When the data track position is included in an area other than the middle area according to the determination result, a track pitch conversion process is performed to set the track pitch of the data track to be larger than the track pitch in the middle area. Conversion means to
And a servo control unit for positioning the head at the position of the data track based on the track pitch converted by the conversion unit or the track pitch in the middle area. The disk drive according to any one of claims 1 to 3. The controller is
A track address corresponding to the position of the data track is determined from the group of tracks recorded on the disk medium;
Determining whether the determined track address is a track address included in an intermediate area on the disk medium;
The disk drive according to claim 4, wherein the servo control is executed using the track address. On the disk medium, a guard band area is set between each data track,
5. The track pitch is set in an area other than the middle peripheral area so that the guard band area is secured constant based on a range of the fringe area. The disk drive according to any one of the above. Used for a head including a single magnetic pole type head suitable for a perpendicular magnetic recording system as a write head, a data track configured in a radial direction based on data recorded by the write head, and positioning control of the head A data write method applied to a disk drive having a disk medium on which servo tracks are recorded,
On the disk medium, each data track included in the outer peripheral area is set larger than the track pitch of each data track included in the middle peripheral area according to the fringe area generated based on the azimuth angle of the head. A data write method characterized by recording at a track pitch. Used for a head including a single magnetic pole type head suitable for a perpendicular magnetic recording system as a write head, a data track configured in a radial direction based on data recorded by the write head, and positioning control of the head A data write method applied to a disk drive having a disk medium on which servo tracks are recorded,
On the disk medium, each data track included in the inner peripheral area is set larger than the track pitch of each data track included in the intermediate peripheral area according to the fringe area generated based on the azimuth angle of the head. The data write method is characterized by recording at a track pitch. The disk drive includes a controller that performs positioning control of the head and records data with the write head at a designated position;
The controller is
A process for determining a position of a data track on which data is to be recorded on the disk medium;
A process of determining whether or not the position of the data track is included in the middle area;
In accordance with the determination result, when the data track position is included in an area other than the middle area, a track pitch conversion process is performed so that the track pitch of the data track is set larger than the track pitch in the middle area. Processing to
8. A process of executing servo control for positioning the head at the position of the data track based on the converted track pitch or the track pitch in the middle area. Or the data write method of any one of Claim 8. On the disk medium, a guard band area is set between each data track,
10. The track pitch is set in an area other than the middle peripheral area so that the guard band area is secured constant based on a range of the fringe area. The data write method according to any one of the above.

Images