JP2010176739A - Storage device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a storage device for stably reading data, while suppressing fluctuations in the read output. <P>SOLUTION: A storage medium 14 defines a magnetic track 64, which extends in a circumferential direction while it is mutually separated by a non-magnetic body 65. Since a carriage 16 oscillates about a spindle 18, a read element 45 at a tip of the carriage 16 changes a skew angle θ, with respect to a radial direction position of the storage medium 14. According to the skew angle θ increase, a track width TW of the magnetic track 64 is reduced. The track width TW of the magnetic track 64 is set smaller than the effective read width RW. Thus, despite, for instance, a positioning error or influences due to the vibration of the read element 45, fluctuation in the read output is suppressed. In a storage device 11, the read element 45 stably reads data from the storage medium 14. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a patterned medium incorporated in a storage device such as a hard disk drive (HDD).

  The magnetic disk incorporated in the HDD constitutes a patterned medium such as a discrete track medium (DTM) or a bit patterned medium (BPM). In such a magnetic disk, a plurality of magnetic tracks are formed along the circumferential direction of the magnetic disk. The recording track is formed, for example, concentrically. Adjacent magnetic tracks are separated from each other by non-magnetic separation tracks extending in the circumferential direction, for example.

JP-A-3-12076 JP-A-5-54302 JP 2008-16182 A

  In the HDD, for example, a so-called skew angle is generated between the read element and the magnetic track. The skew angle increases, for example, from the intermediate position in the radial direction of the magnetic disk toward the outer peripheral side and the inner peripheral side. In that case, the effective read width of the read element defined in the radial direction of the magnetic disk decreases from the intermediate position toward the outer peripheral side and the inner peripheral side. On the other hand, the track width of the magnetic track is designed to be narrower than the effective read width because of the recording density.

 When the track width of the magnetic track is set uniformly at all radial positions, the effective read width may be wider than the track width on the outer peripheral side and the inner peripheral side. At this time, the magnetic track sometimes protrudes from the effective read width based on the positioning error, and the read output decreases. That is, the read output fluctuates when the magnetic track protrudes from the effective read width or the magnetic track falls within the effective read width.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a storage device that can stably read data while suppressing fluctuations in read output.

  In order to achieve the above object, a specific example of a storage device is disposed outside a storage medium that defines a plurality of magnetic tracks extending in the circumferential direction while being separated from each other by a nonmagnetic material. A carriage that is swingably connected to a support shaft, and a reading element that is supported on the tip of the carriage and that faces the surface of the storage medium and changes a skew angle with respect to a radial position of the storage medium. Prepare. At this time, the track width of the magnetic track is smaller than the effective read width of the read element defined in the radial direction, and decreases as the skew angle increases.

  According to such a storage device, the skew angle changes with respect to the radial position of the storage medium. As the skew angle increases, the track width of the magnetic track decreases. The track width of the magnetic track is set smaller than the effective read width. Therefore, fluctuations in the read output are suppressed regardless of the positioning error of the read element and the influence of vibration, for example. In such a storage device, the reading element can stably read data from the storage medium.

  As described above, according to the disclosed storage device, it is possible to stably read data while suppressing fluctuations in read output.

1 is a plan view schematically showing an internal structure of a specific example of a storage device according to the present invention, that is, a hard disk drive (HDD). It is an expansion perspective view which shows roughly the flying head slider which concerns on one specific example. It is a front view of the electromagnetic conversion element which shows roughly the electromagnetic conversion element observed from a medium opposing surface. FIG. 4 is a cross-sectional view taken along line 4-4 of FIG. It is a top view which shows roughly the structure of the storage medium which concerns on one specific example, ie, a magnetic disc. It is a partial enlarged plan view which shows roughly the structure of a magnetic track and a nonmagnetic material. It is a partial expanded sectional view which shows the structure of a magnetic disc roughly. 1 is a partially enlarged plan view schematically showing the structure of a magnetic disk according to a first embodiment. It is a top view which shows roughly the relationship between a magnetic disc and a carriage. FIG. 4 is a partially enlarged plan view schematically showing a relationship between a magnetic track and a read element. 4 is a graph showing changes in effective read width and track width on a magnetic disk according to a specific example of the first embodiment. It is a graph which shows the change of the effective read width and track width on the magnetic disc which concerns on the modification of 1st Embodiment. FIG. 5 is a partially enlarged plan view schematically showing the structure of a magnetic disk according to a second embodiment. It is a graph which shows the change of the effective read width on the magnetic disc concerning one specific example of 2nd Embodiment, a track width, and a track pitch. FIG. 4 is a partially enlarged plan view schematically showing a relationship between a magnetic track and a write element.

  Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

  FIG. 1 schematically shows an internal structure of a hard disk drive (HDD) 11 as a specific example of a storage device according to the present invention. The HDD 11 includes a housing, that is, a housing 12. The housing 12 includes a box-shaped base 13 and a cover (not shown). The base 13 defines, for example, a flat rectangular parallelepiped internal space, that is, an accommodation space. The cover is coupled to the opening of the base 13. The accommodation space is sealed between the cover and the base 13.

  In the accommodation space, one or more magnetic disks 14 as storage media are accommodated. The magnetic disk 14 is mounted on the drive shaft of the spindle motor 15. The spindle motor 15 can rotate the magnetic disk 14 at a high speed such as 5400 rpm, 7200 rpm, 10000 rpm, and 15000 rpm. Here, for example, the magnetic disk 14 is configured as a perpendicular magnetic recording disk.

  A carriage 16 is further accommodated in the accommodation space. The carriage 16 includes a carriage block 17. The carriage block 17 is rotatably connected to a support shaft 18 extending in the vertical direction. The support shaft 18 is disposed outside the contour of the magnetic disk 14. The support shaft 18 is defined parallel to the rotation axis of the spindle motor 15. A plurality of carriage arms 19 extending in the horizontal direction from the support shaft 18 are defined in the carriage block 17.

  A head suspension 21 is attached to the tip of each carriage arm 19. A flexure is attached to the head suspension 21. A flying head slider 22 is mounted on the flexure. The posture of the flying head slider 22 can be changed with respect to the head suspension 21 by the action of the flexure. A magnetic head, that is, an electromagnetic transducer is mounted on the flying head slider 22.

  When an air flow is generated on the surface of the magnetic disk 14 based on the rotation of the magnetic disk 14, positive pressure, that is, buoyancy and negative pressure act on the flying head slider 22 by the action of the air flow. Since the buoyancy and negative pressure balance with the pressing force of the head suspension 21, the flying head slider 22 can continue to fly with relatively high rigidity during the rotation of the magnetic disk.

  For example, a power source such as a voice coil motor (VCM) 23 is connected to the carriage block 17. The carriage block 17 can rotate around the support shaft 18 by the action of the VCM 23. Based on the rotation of the carriage block 17, the swing of the carriage arm 19 and the head suspension 21 is realized.

  When the carriage arm 19 swings around the spindle 18 while the flying head slider 22 is flying, the flying head slider 22 can move along the radial line of the magnetic disk 14. As a result, the electromagnetic transducer on the flying head slider 22 can cross the data zone between the innermost recording track and the outermost recording track. Thus, the electromagnetic transducer on the flying head slider 22 is positioned on the target recording track.

  As is clear from FIG. 1, the flexible printed circuit board unit 25 is disposed on the carriage block 17. The flexible printed circuit board unit 25 includes a head IC (integrated circuit) 27 mounted on the flexible printed circuit board 26. The head IC 27 is connected to a read element and a write element of an electromagnetic conversion element. A flexure 28 is used for connection. The flexure 28 is connected to the flexible printed circuit board unit 25.

  At the time of reading magnetic information, that is, binary information, a sense current is supplied from the head IC 27 toward the reading element of the electromagnetic transducer. Similarly, at the time of writing binary information, a write current is supplied from the head IC 27 toward the write element of the electromagnetic conversion element. The current value of the sense current is set to a specific value. A current is supplied to the head IC 27 from a small circuit board 29 arranged in the accommodation space or a printed circuit board (not shown) attached to the back side of the bottom plate of the base 13.

  FIG. 2 shows a flying head slider 22 according to one specific example. The flying head slider 22 includes a base material formed in a flat rectangular parallelepiped, that is, a slider body 31. An insulating nonmagnetic film, that is, a device built-in film 32 is laminated on the air outflow side end face of the slider body 31. The electromagnetic conversion element 33 is incorporated in the element built-in film 32. Details of the electromagnetic transducer 33 will be described later.

The slider body 31 is made of a hard nonmagnetic material such as Al ₂ O ₃ —TiC (Altic). The element built-in film 32 is made of a relatively soft insulating nonmagnetic material such as Al ₂ O ₃ (alumina). The slider body 31 faces the magnetic disk 14 at the medium facing surface, that is, the air bearing surface 34. A flat base surface 35, that is, a reference surface is defined on the air bearing surface 34. When the magnetic disk 14 rotates, an air flow 36 acts on the air bearing surface 34 from the front end to the rear end of the slider body 31.

  A single front rail 37 that rises from the base surface 35 is formed on the air bearing surface 34 on the upstream side of the air flow 36, that is, on the air inflow side. The front rail 37 extends in the slider width direction along the air inflow end of the base surface 35. Similarly, a rear center rail 38 rising from the base surface 35 is formed on the air bearing surface 34 on the downstream side of the air flow 36, that is, on the air outflow side. The rear center rail 38 is disposed at the center position in the slider width direction. The rear center rail 38 reaches the element built-in film 32. A pair of left and right rear side rails 39, 39 are further formed on the air bearing surface 34. The rear side rail 39 rises from the base surface 35 along the side end of the slider body 31 on the air outflow side. A rear center rail 38 is disposed between the rear side rails 39 and 39.

  So-called air bearing surfaces (ABS) 41, 42, 43, 43 are defined on the top surfaces of the front rail 37, the rear center rail 38 and the rear side rails 39, 39. The air inflow ends of the air bearing surfaces 41, 42 and 43 are connected to the top surfaces of the front rail 37, the rear center rail 38 and the rear side rail 39 by steps. When the air flow 36 is received by the air bearing surface 34, a relatively large positive pressure, that is, buoyancy, is generated on the air bearing surfaces 41, 42, and 43 by the action of the steps. In addition, a large negative pressure is generated behind the front rail 37, that is, behind the front rail 37. The flying posture of the flying head slider 22 is established based on the balance between these buoyancy and negative pressure.

  The electromagnetic conversion element 33 is embedded in the rear center rail 38 on the air outflow side of the air bearing surface 42. The electromagnetic conversion element 33 includes, for example, a reading element and a writing element. The electromagnetic conversion element 33 exposes the read gap of the read element and the write gap of the write element on the surface of the element built-in film 32. However, a hard protective film may be formed on the surface of the element built-in film 32 on the air outflow side of the air bearing surface 42. Such a hard protective film covers the read gap and the write gap exposed on the surface of the element built-in film 32. For example, a DLC (diamond-like carbon) film may be used as the protective film. The form of the flying head slider 22 is not limited to this form.

  As shown in FIG. 3, the electromagnetic conversion element 33 includes a read element 45. As the read element 45, for example, a tunnel junction magnetoresistive effect (TuMR) element is used. In the read element 45, a tunnel junction magnetoresistive film 48 is sandwiched between a pair of upper and lower conductive layers, that is, a lower electrode 46 and an upper electrode 47. The lower electrode 46 and the upper electrode 47 may be made of a high magnetic permeability material such as FeN (iron nitride), NiFe (nickel iron), NiFeB (nickel iron boron), or CoFeB (cobalt iron boron). Thus, the lower electrode 46 and the upper electrode 47 can function as a lower shield layer and an upper shield layer. As a result, the interval between the lower electrode 46 and the upper electrode 47 determines the magnetic recording resolution in the down-track direction of the recording track on the magnetic disk 14.

At the same time, a pair of magnetic domain control films 49 are disposed between the lower electrode 46 and the upper electrode 47. The tunnel junction magnetoresistive film 48 is disposed between the magnetic domain control films 49 along the air bearing surface 34. The magnetic domain control film 49 is made of a hard magnetic material such as CoCrPt (cobalt chromium platinum). The magnetic domain control film 49 establishes magnetization in one direction along the air bearing surface 34. An insulating film 51 is sandwiched between the magnetic domain control film 49 and the lower electrode 46 and between the magnetic domain control film 49 and the tunnel junction magnetoresistive film 48. The insulating film 51 is made of, for example, Al ₂ O ₃ . The magnetic domain control film 49 is insulated from the lower electrode 46 and the tunnel junction magnetoresistive film 48. In such a read element 45, the resistance change of the tunnel junction magnetoresistive film 48 is caused according to the direction of the magnetic field acting from the magnetic disk 14. Based on such resistance change, binary information is read from the magnetic disk 14.

  The electromagnetic conversion element 33 includes a writing element 52, that is, a single magnetic pole head disposed on the trailing side of the reading element 45. The writing element 52 includes a main magnetic pole 53 and an auxiliary magnetic pole 54 that expose the front end surface on the surface of the rear center rail 38, that is, the air bearing surface 34. A trailing shield 55 is defined at the leading end of the auxiliary magnetic pole 54 on the air bearing surface 34. The trailing shield 55 is opposed to the main magnetic pole 53. The main magnetic pole 53 and the auxiliary magnetic pole 54 are made of a magnetic material such as FeN, NiFe, NiFeB, or CoFeB. Referring also to FIG. 4, the rear end of the auxiliary magnetic pole 54 is connected to the main magnetic pole 53 by a magnetic coupling piece 56. A magnetic coil, that is, a thin film coil pattern 57 is formed around the magnetic coupling piece 56. Thus, the main magnetic pole 53, the auxiliary magnetic pole 54, and the magnetic coupling piece 56 form a magnetic core that penetrates the center position of the thin film coil pattern 57. In such a write element 52, the recording magnetic field leaks from the main magnetic pole 53 by the action of the thin film coil pattern 57. Binary information is written on the magnetic disk 14 by the action of the recording magnetic field.

  FIG. 5 schematically shows the structure of the magnetic disk 14. The magnetic disk 14 constitutes a patterned medium such as a discrete track medium (DTM). A plurality of recording tracks 61, 61,... Extend on the surface of the magnetic disk 14 along the circumferential direction of the magnetic disk 14, that is, the down track direction. A plurality of servo sector regions 62 extending along the radial direction of the magnetic disk 14, that is, the cross track direction, are defined on the surface of the magnetic disk 14. A servo pattern is established in the servo sector area 62. A data sector area 63 is secured between adjacent servo sector areas 62. Binary information is stored in the recording track 61 in the data sector area 63.

  As shown in FIG. 6, each recording track 61 includes an annular magnetic track 64 extending in the down track direction. The magnetic track 64 is made of a magnetic material. The magnetic tracks 64 are separated from each other by an annular non-magnetic material or separation track 65. The separation track 65 is formed from a nonmagnetic material. Similar to the magnetic track 64, the separation track 65 extends concentrically in the down track direction of the magnetic disk 14. A boundary line 66 of the recording track 61 is defined on the separation track 65. Thus, each recording track 61 is formed by one magnetic track 64 and a part of a pair of separation tracks 65 and 65 adjacent to the magnetic track 64.

  As shown in FIG. 7, the magnetic disk 14 includes a substrate 67. For example, a glass substrate is used as the substrate 67. A soft magnetic backing layer 68 spreads on the surface of the substrate 67. In the backing layer 68, an easy axis of magnetization is established in an in-plane direction defined parallel to the surface of the substrate 67. A composite film 69 spreads on the surface of the backing layer 68. In the composite film 69, magnetic tracks 64 and separation tracks 65 are alternately arranged in the in-plane direction of the magnetic disk 14. In the magnetic track 64, an easy axis of magnetization is established in a direction perpendicular to the surface of the substrate 67. The surface of the composite film 69 may be covered with a protective film 71 such as a diamond-like carbon (DLC) film and a lubricating film 72 such as a perfluoropolyether (PFPE) film.

  As shown in FIG. 8, in the magnetic disk 14, a predetermined track width TW is defined by the magnetic track 64 of the recording track 61 defined at an intermediate position between the innermost recording track 61 and the outermost recording track 61. The track width TW of the magnetic track 64 decreases from the recording track 61 at the intermediate position toward the inner periphery and the outer periphery in the cross track direction. Therefore, the track width TW is defined as the maximum value in the magnetic track 64 of the recording track 61 at the intermediate position. The track width TW of the magnetic track 64 of the innermost recording track 61 and the magnetic track 64 of the outermost recording track 61 is set to the minimum value.

  As shown in FIG. 9, when the carriage 16 rotates about the support shaft 18, the flying head slider 22 moves on the magnetic disk 14 along a virtual arc drawn around the support shaft 18. When the electromagnetic transducer 33 is positioned on the recording track 61 at the intermediate position, as shown in FIG. 10, the intersection of the center line of the tunnel junction magnetoresistive film 48 of the reading element 45 and the center line of the recording track 61 is obtained. The angle, that is, the skew angle θ is set to 0 (zero) degree. Here, when the skew angle θ is set to 0 degree, the effective read width RW of the tunnel junction magnetoresistive film 48 defined in the cross track direction and the tunnel junction magnetoresistive film defined in the slider width direction The case where the core width CW of 48 matches is taken as an example. The effective read width RW is specified by the width and flying height of the tunnel junction magnetoresistive film 48 defined in the cross track direction. In this magnetic disk 14, the track width TW of the magnetic track 64 is defined to be smaller than the effective read width RW at all radial positions.

  For example, when the electromagnetic transducer 33 is positioned on the innermost recording track 61, the skew angle θ is set to the maximum value. In the innermost recording track 61, the effective read width RW is defined as a minimum value based on the skew angle θ. That is, the effective read width RW decreases as the skew angle θ increases. Since the track width TW is defined to be smaller than the effective read width RW, the effective read width RW and the track width TW decrease from the intermediate position toward the inner periphery. On the other hand, when the electromagnetic transducer 33 is positioned on the outermost recording track 61, for example, the skew angle θ is set to the maximum value. In the outermost recording track 61, the effective read width RW is defined as a minimum value based on the skew angle θ. That is, the effective read width RW decreases as the skew angle θ increases. Since the track width TW is defined to be smaller than the effective read width RW, the effective read width RW and the track width TW decrease from the intermediate position toward the outer periphery.

  In this magnetic disk 14, the skew angle θ increases from the recording track 61 at the intermediate position toward the inner circumference and the outer circumference. As shown in FIG. 11, the effective read width RW decreases from the radial position “0 (zero)”, that is, from the intermediate position toward the inner circumference (minus) and the outer circumference (plus). As described above, the track width TW decreases from the intermediate position toward the inner periphery and the outer periphery. In this embodiment, the difference between the effective read width RW and the track width TW is set to be uniform at all radial positions. That is, the reduction rate of the effective read width RW that decreases as the distance from the intermediate position decreases is set to be greater than the decrease rate of the track width TW that decreases as the distance from the intermediate position increases. As a result, the width of the recording track 61 defined in the cross track direction is set to be smaller from the intermediate position toward the inner periphery and the outer periphery.

  In the HDD 11 as described above, the track width TW is set smaller than the effective read width RW. The difference between the effective read width RW and the track width TW is set uniformly at all radial positions. At the same time, the effective read width RW decreases from the intermediate position toward the inner periphery and the outer periphery. Therefore, for example, the tunnel junction magnetoresistive film 48 faces the magnetic track 64 with relatively high accuracy over the entire width of the magnetic track 64 regardless of the positioning error of the electromagnetic transducer 33 and the influence of the vibration of the flying head slider 22. be able to. Variations in the output of binary information are suppressed. The read element 45 can read binary information stably. Moreover, a position error is ensured in the tunnel junction magnetoresistive film 48 within a certain tolerance in the cross track direction on the magnetic track 64.

  On the other hand, for example, if the ratio between the effective read width RW and the track width TW is set uniformly at all radial positions, the difference between the effective read width RW and the track width TW is, for example, on the inner peripheral side and the outer peripheral side. Reduced compared to the invention. Therefore, for example, based on the positioning error of the electromagnetic transducer 33 and the influence of the vibration of the flying head slider 22, the tunnel junction magnetoresistive film 48 is difficult to face the magnetic track 64 over the entire width of the magnetic track 64. The output of binary information will fluctuate. In addition, the allowable range of the position error of the tunnel junction magnetoresistive film 48 is reduced as compared with the present invention. The tunnel junction magnetoresistive film 48 cannot read binary information with high accuracy.

  Moreover, since the skew angle θ increases from the intermediate position toward the inner periphery and the outer periphery, the effective read width RW decreases as the skew angle θ increases. As a result, the track width TW of the magnetic track 64 on the magnetic disk 14 is set to be smaller from the intermediate position toward the inner periphery and the outer periphery. Based on such a decrease in the track width TW, the width of the recording track 61 decreases from the intermediate position toward the inner periphery and the outer periphery. As a result, on the magnetic disk 14, the magnetic track 64, that is, the recording track 61 is formed with a higher density than when a uniform track width TW is defined at all radial positions. Such a magnetic disk 14, that is, the HDD 11, can greatly contribute to the improvement of the recording density.

  As shown in FIG. 12, a plurality of track groups 75 may be defined on the magnetic disk 14 in the cross track direction. Each track group 75 includes a plurality of magnetic tracks 64, that is, recording tracks 61. Within each track group 75, the track width TW of each magnetic track 64 is set equal. The track width TW decreases from the track group 75 defined at the intermediate position toward the inner track group 75 and the outer track group 75. On the other hand, the effective read width RW may be set in the same manner as described above. The number of magnetic tracks 64 for each track group 75 is arbitrarily set. According to such a magnetic disk 14, the same effect as described above is realized.

  FIG. 13 shows a magnetic disk 14a according to a second embodiment of the present invention. In this magnetic disk 14a, the track pitch TP between the recording tracks 61 adjacent to each other increases from the intermediate position toward the inner periphery and the outer periphery. The track pitch TP is specified by the pitch between the center lines of the recording tracks 61 and 61. As described above, the skew angle θ increases from the intermediate position toward the inner periphery and the outer periphery. Therefore, the track pitch TP increases as the skew angle θ increases. At the same time, the width of the recording track 61 increases from the intermediate position toward the inner periphery and the outer periphery. In the innermost recording track 61 and the outermost recording track 61, the width of the recording track 61 is defined as a maximum value.

  As shown in FIG. 14, a plurality of track groups 76 are defined in the cross track direction on the magnetic disk 14a. Each track group 76 includes a plurality of magnetic tracks 64, that is, recording tracks 61. The track pitch TP increases from the track group 76 including the recording track 61 at the intermediate position toward the inner track group 76 and the outer track group 76. In addition, similarly to the magnetic disk 14 described above, the track width TW of the magnetic track 64 decreases from the intermediate position toward the inner periphery and the outer periphery. The track width TW is set smaller than the effective read width RW. The difference between the effective read width RW and the track width TW is set uniformly at all radial positions.

  When the electromagnetic conversion element 33 is positioned on the recording track 61 at the intermediate position, as shown in FIG. 15, the crossing angle, that is, the skew angle between the center line of the main magnetic pole 53 of the writing element 52 and the center line of the magnetic track 64. θ is set to 0 (zero) degree. The contour of the main magnetic pole 53 on the air bearing surface 34 is defined as an inverted trapezoid. That is, in the main magnetic pole 53, the width of the leading end is defined to be smaller than the width of the trailing end. When the skew angle θ is set to 0 degree, the effective write width WW of the main pole 53 defined in the cross track direction matches the core width CW of the main pole 53 defined in the slider width direction. In this magnetic disk 14a, the track width TW of the magnetic track 64 is defined to be smaller than the effective write width WW at all radial positions.

  For example, when the electromagnetic transducer 33 is positioned on the innermost recording track 61, the skew angle θ is set to the maximum value. In the innermost recording track 61, the track pitch TP is defined as the maximum value. However, the track width TW is defined to be smaller than the effective write width WW. Here, the effective writing width WW is specified by the maximum width between the leading end corner and the trailing end corner defined in the cross-track direction. On the other hand, when the electromagnetic conversion element 33 is positioned on the outermost recording track 61, for example, the skew angle θ is set to the maximum value. In the outermost recording track 61, the track pitch TP is defined as a maximum value. However, the track width TW of the magnetic track 64 is defined to be smaller than the effective write width WW.

  According to the magnetic disk 14a as described above, the track pitch TP increases as the skew angle θ increases. That is, the track pitch TP increases from the intermediate position toward the inner periphery and the outer periphery. As a result, even if the effective write width WW of the write element 45 increases as the skew angle θ increases, the action of the recording magnetic field on the recording track 61 adjacent to the recording track 61 to be written is suppressed. Side erase is suppressed. On the other hand, when the track pitch TP is uniformly set at all radial positions, the recording magnetic field is applied to the adjacent recording track 61 by, for example, the inner recording track 61 or the outer recording track 61 based on the increase in the effective writing width WW. Increases the possibility of action. Side erase will occur.

  In the HDD 11 as described above, the magnetic disks 14 and 14a may be composed of patterned media such as bit patterned media (BPM). At this time, the magnetic track 64 may be formed of a plurality of magnetic bits arranged in the down track direction. Magnetic bits adjacent in the down track direction are separated from each other by a non-magnetic material. According to such magnetic disks 14 and 14a, the same effects as described above are realized.

  The applicant further discloses the following supplementary notes regarding the above embodiment.

(Supplementary Note 1) A storage medium that defines a plurality of magnetic tracks extending in the circumferential direction while being separated from each other by a non-magnetic material,
A carriage that is swingably coupled to a support shaft disposed outside the storage medium;
A reading element that is supported on the front end of the carriage and faces the surface of the storage medium and changes a skew angle with respect to a radial position of the storage medium;
The storage device according to claim 1, wherein a track width of the magnetic track is smaller than an effective read width of the read element defined in the radial direction, and decreases as the skew angle increases.

  (Supplementary note 2) The storage device according to supplementary note 1, wherein a difference between a track width of the magnetic track and an effective read width of the read element is uniformly set in all the magnetic tracks.

(Supplementary note 3) In the storage device according to supplementary note 1 or 2, the storage device includes a plurality of track groups that are defined in parallel in a radial direction of the storage medium and include a plurality of the magnetic tracks,
The storage device according to claim 1, wherein the track widths of the magnetic tracks included in each of the track groups are set to be equal.

(Additional remark 4) In the memory | storage device of Additional remark 1 or 2, The write element which is supported by the front-end | tip of the said carriage and is made to face the surface of the said storage medium, and changes a skew angle with respect to the radial direction position of the said storage medium With
The storage device according to claim 1, wherein a track pitch between the magnetic tracks adjacent to each other increases as the skew angle increases.

(Supplementary note 5) In the storage device according to supplementary note 4, the storage device includes a plurality of track groups that are defined in parallel in the radial direction on the storage medium and include a plurality of the magnetic tracks,
The storage device characterized in that the track pitches included in each of the track groups are set equal.

(Supplementary Note 6) A storage medium that defines a plurality of magnetic tracks extending in the circumferential direction while being separated from each other by a non-magnetic material,
A carriage that is swingably coupled to a support shaft disposed outside the storage medium;
A writing element that is supported on the front end of the carriage and faces the surface of the storage medium, and changes a skew angle with respect to a radial position of the storage medium;
The storage device according to claim 1, wherein a track pitch between the magnetic tracks adjacent to each other increases as the skew angle increases.

(Supplementary note 7) In the storage device according to supplementary note 6, the storage device includes a plurality of track groups defined in parallel in the radial direction on the storage medium and including a plurality of the magnetic tracks.
The storage device characterized in that the track pitches included in each of the track groups are set equal.

  11 storage device (hard disk drive), 14 storage medium (magnetic disk), 16 carriage, 18 spindle, 45 read element, 52 write element, 64 magnetic track, 65 non-magnetic material, 75 track group, 76 track group.

Claims (5)

A storage medium for defining a plurality of magnetic tracks extending in the circumferential direction while being separated from each other by a non-magnetic material;
A carriage that is swingably coupled to a support shaft disposed outside the storage medium;
A reading element that is supported on the front end of the carriage and faces the surface of the storage medium and changes a skew angle with respect to a radial position of the storage medium;
The storage device according to claim 1, wherein a track width of the magnetic track is smaller than an effective read width of the read element defined in the radial direction, and decreases as the skew angle increases.   2. The storage device according to claim 1, wherein the difference between the track width of the magnetic track and the effective read width of the read element is set uniformly in all the magnetic tracks. The storage device according to claim 1, further comprising a plurality of track groups that are defined in parallel in a radial direction of the storage medium and include a plurality of the magnetic tracks,
The storage device according to claim 1, wherein the track widths of the magnetic tracks included in each of the track groups are set to be equal. 3. The storage device according to claim 1, further comprising a writing element that is supported by a tip of the carriage and faces the surface of the storage medium, and changes a skew angle with respect to a radial position of the storage medium,
The storage device according to claim 1, wherein a track pitch between the magnetic tracks adjacent to each other increases as the skew angle increases. The storage device according to claim 4, comprising a plurality of track groups that are defined in parallel in the radial direction on the storage medium and include a plurality of the magnetic tracks,
The storage device characterized in that the track pitches included in each of the track groups are set equal.

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