JP2007164953A - Recording and reproducing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a recording and reproducing device in which high density recording can be performed without increasing a manufacturing cost. <P>SOLUTION: The device is provided with a magnetic disk 10 (magnetic recording medium) in which a groove G (recessed part 15b: non-magnetic region) is provided between adjacent data recording tracks T (projection part 15a) in a diameter direction and a reproducing head constituted so as to be able to read recorded data from the magnetic disk 10, the magnetic disk 10 is formed so that track width Tw (length along diameter direction) of a data recording track T is 40 nm and groove width Gw (length along diameter direction) of the groove G is 40 nm, the reproducing head is formed so that reproducing head width is 50 nm. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a recording / reproducing apparatus provided with a magnetic recording medium.

  As a magnetic recording medium mounted on this type of recording / reproducing apparatus, a perpendicular magnetic recording medium (hereinafter, also referred to as “magnetic recording medium”) configured to be able to record recording data by a perpendicular magnetic recording method is disclosed in Japanese Patent Laid-Open No. 2002-2002. This is disclosed in Japanese Patent No. 298336. In this magnetic recording medium, a soft magnetic backing layer, an underlayer, a perpendicular magnetic layer, and a protective layer are formed on a substrate (base material) in this order, and are configured in a disc shape as a whole. In this case, in this magnetic recording medium, the perpendicular magnetic layer is continuously formed from the center to the outer edge. In addition, this type of magnetic recording medium is disposed in a housing of a recording / reproducing apparatus together with a magnetic head, a head driving mechanism, a control device, and the like, and a data recording track (perpendicular magnetic layer) is passed through the recording head in the magnetic head. In addition to recording data, the recording data is read from the data recording track via the reproducing head in the magnetic head.

In this case, in a recording / reproducing apparatus equipped with this kind of magnetic recording medium, when recording data is written to a predetermined data recording track, the data recording track adjacent to the data recording track in the radial direction of the magnetic recording medium is recorded. In order to avoid a situation in which unintended writing (side light) occurs, the pitch of each data recording track (track pitch), the head width of the recording head, and the like are defined. In addition, when reading recorded data from a predetermined data recording track, the above-mentioned track pitch and reproduction are performed in order to avoid an unintended reading (crosstalk) from a data recording track adjacent to the data recording track. The head width and the like of the head are defined.
JP 2002-298336 A (page 4-9, FIG. 1)

  However, a conventional recording / reproducing apparatus equipped with a magnetic recording medium (hereinafter also referred to as “conventional recording / reproducing apparatus”) has the following problems. That is, the conventional recording / reproducing apparatus employs a configuration in which recording data is written to and read from a perpendicular magnetic layer (recording layer) formed continuously from the center to the outer edge of the magnetic recording medium. On the other hand, with the increase in recording data and the downsizing of electronic devices, in order to increase the recordable capacity without incurring an increase in the size of the information recording medium, the recording density is further increased. It is desired. For this reason, even in a magnetic recording medium mounted on a hard disk drive or the like, the track pitch tends to be further reduced (track density is increased).

  In this case, in a conventional recording / reproducing apparatus configured to write recording data magnetically by defining each data recording track at a predetermined track pitch in a recording layer formed continuously over the entire area of the magnetic recording medium, Since the perpendicular magnetic layer is continuous across the data recording track to be recorded, the above-described sidelight and crosstalk are more likely to occur as the track pitch is reduced. Also, in order to avoid the occurrence of sidelight, crosstalk, etc., it is necessary to accurately track the recording head and reproducing head on the desired data recording track, and very high precision tracking servo control is required. For this reason, in order to be able to execute tracking servo control with very high accuracy, it is necessary to mount a head drive mechanism capable of operating with high accuracy and a control device capable of high-speed control processing. As described above, it is difficult to achieve high density recording without causing sidelight or crosstalk in the conventional recording / reproducing apparatus. There is a problem that the manufacturing cost increases due to the increase in the cost of components such as control processing.

  The present invention has been made in view of such problems, and a main object of the present invention is to provide a recording / reproducing apparatus capable of achieving high density recording without causing an increase in manufacturing cost.

  In order to achieve the above object, the recording / reproducing apparatus according to the present invention is capable of reading a recording data from a magnetic recording medium in which a nonmagnetic region is provided between adjacent data recording tracks in the radial direction. The magnetic recording medium has a length along the radial direction of the data recording track of 40 nm, and a length along the radial direction of the nonmagnetic region of 40 nm. The reproducing head is formed so that the reproducing head width is 50 nm.

  In addition, the recording / reproducing apparatus according to the present invention includes a magnetic recording medium in which a nonmagnetic region is provided between data recording tracks adjacent in the radial direction, and a recording configured to be able to write recording data to the magnetic recording medium. The magnetic recording medium is formed so that the length along the radial direction in the data recording track is 40 nm, and the length along the radial direction in the nonmagnetic region is 40 nm, The recording head is formed so that the recording head width is 60 nm.

  According to the recording / reproducing apparatus of the present invention, the magnetic recording medium formed so that the length along the radial direction in the data recording track is 40 nm and the length along the radial direction in the nonmagnetic area is 40 nm. And a reproducing head formed so as to have a reproducing head width of 50 nm, it is possible to reduce the track pitch of the data recording track to achieve sufficiently high density recording even when reading recorded data. It is possible to provide a recording / reproducing apparatus having a sufficiently wide range (allowable off-track amount of the reproducing head) that can avoid the occurrence of crosstalk due to the off-track of the reproducing head. Therefore, compared with a high-precision head drive mechanism and a high-speed control device of specifications required for high-density recording of a conventional recording / reproducing apparatus using a magnetic recording medium having a continuously formed recording layer. A recording / reproducing apparatus that can accurately read recorded data can be configured by a head drive mechanism or control device with a simple configuration, so that recording / reproduction is realized without increasing the manufacturing cost. An apparatus can be provided.

  Also, according to the recording / reproducing apparatus of the present invention, the magnetic recording formed so that the length along the radial direction in the data recording track is 40 nm and the length along the radial direction in the nonmagnetic region is 40 nm. Even in a configuration in which a medium and a recording head formed to have a recording head width of 60 nm are provided, the recording pitch of the data recording track can be sufficiently reduced by reducing the track pitch of the data recording track. Thus, it is possible to provide a recording / reproducing apparatus having a sufficiently wide range (allowable off-track amount of the recording head) that can prevent the occurrence of sidelight due to off-track of the recording head at the time. Therefore, compared with a high-precision head drive mechanism and a high-speed control device of specifications required for high-density recording of a conventional recording / reproducing apparatus using a magnetic recording medium having a continuously formed recording layer. A recording / reproducing device capable of accurately writing recording data by a head drive mechanism or control device with a simple configuration can be configured, so that recording / reproducing can be achieved with high density recording without causing an increase in manufacturing cost. An apparatus can be provided.

  The best mode of a recording / reproducing apparatus according to the present invention will be described below with reference to the accompanying drawings.

  First, the configuration of the hard disk drive 1 as an example of the recording / reproducing apparatus according to the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the hard disk drive 1 includes a magnetic head 2, an actuator 3, a motor 4, a control unit 5, and a magnetic disk 10, and can be mounted on various electronic devices such as a personal computer. The magnetic disk 10 is a discrete track type magnetic recording medium (patterned medium) corresponding to an example of the magnetic recording medium in the present invention, and is configured to be able to record recording data by a perpendicular magnetic recording (PMR) system. Yes. As shown in FIG. 2, the magnetic disk 10 has a soft magnetic layer (SUL) 12, a nonmagnetic layer 13, and a recording layer 14 formed in this order on a substrate 11, and is configured in a disc shape as a whole. Has been. The soft magnetic layer 12 is formed into a thin film with a soft magnetic material (for example, a soft magnetic material such as an FeNi alloy) so that the thickness is 77 nm and the residual magnetic flux density (Bs) is 1.5 T, for example. Is formed. Moreover, the nonmagnetic layer 13 is formed in a thin film shape with a nonmagnetic material (for example, a nonmagnetic material such as MgO) so that the thickness thereof is 7 nm as an example. Further, the recording layer 14 is formed into a thin film with a magnetic material (for example, a magnetic material such as an FePt alloy so that its thickness is 7 nm, and its easy axis of anisotropy is relative to the surface of the recording layer 14. The recording layer 14 has a saturation magnetization (Ms) of 800 emu / cc, an anisotropic coercive force (Hk) of 18750 Oe, and an exchange constant (A) of 1. The anisotropic dispersion is 5 degrees at 0e-7 erg / cm.

  Further, in the magnetic disk 10, as shown in FIG. 2, a plurality of concentric convex portions 15a constituting the data recording track T and a groove G between the data recording tracks T and T (the nonmagnetic in the present invention). A concave / convex pattern 15 (track pattern Pt) having a plurality of concave portions 15b constituting an example of a region is formed. In this case, as shown in FIG. 3, in this type of magnetic disk, each recess 15b is formed so as to reach a depth reaching the nonmagnetic layer 13 from the surface of the recording layer. Therefore, each convex portion 15a between the concave portions 15b, 15b is formed of a nonmagnetic material that forms the nonmagnetic layer 13 on the base end side (the lower end side in the same drawing), and the protruding end side (the same drawing). Is formed of a magnetic material constituting the recording layer 14.

  Further, in this magnetic disk 10, as shown in FIG. 2, the length (track width Tw) along the radial direction of each data recording track T (convex portion 15a) is from the inner periphery to the outer periphery of the magnetic disk 10. Is formed to be 40 nm in the entire region. Further, in this magnetic disk 10, the length (groove width Gw) along the radial direction in each groove G (recess 15b) is 40 nm, which is equal to the track width Tw in the entire area from the inner periphery to the outer periphery of the magnetic disk 10. It is formed to become. Thereby, in this magnetic disk 10, the track pitch Tp (as an example, the length between both track centers Ct in two data recording tracks T adjacent in the radial direction) is 80 nm (track density 314 kTPI). It is configured. In the present specification, the position of the most protruding portion (in this example, the protruding end surface of the protruding portion 15a: the upper surface U shown in FIG. 3) of the protruding portion 15a constituting the data recording track T, and the layer of the magnetic material (In this example, the recording layer 14) and the center (1/2 in the thickness direction) of the magnetic disk between the lower layer (in this example, the nonmagnetic layer 13) and the boundary surface (the lower surface L shown in the figure). ) And the radial length of the data recording track T on the reference plane X parallel to the boundary surface is defined as a track width Tw. In this specification, the length (opening length) along the radial direction of the recess 15b in the reference plane X is defined as the groove width Gw. Further, the track center Ct is a virtual track center line (reference line) for tracking servo control, and in this specification, this virtual track center line (defined by a servo pattern (not shown)). Reference line) is the track center Ct.

  As shown in FIG. 4, the magnetic head 2 includes a reproducing head 2r and a recording head 2w, and a reproducing element 2ra constituting the reproducing head 2r and a main magnetic pole part 2wa and a return magnetic pole part 2wb constituting the recording head 2w are sliders. It is formed on the bottom of 2s. An arrow A shown in the figure indicates the direction in which the magnetic disk 10 moves relative to the magnetic head 2 during recording and reproduction. Therefore, the head running direction of the magnetic head 2 (the relative movement direction of the magnetic head 2 with respect to the magnetic disk 10) is opposite to the arrow A. In this case, as an example, the reproducing head 2r is formed such that the reproducing head width Rw (the length along the radial direction of the reproducing element 2ra) of the reproducing element 2ra is 50 nm. In the present specification, the width of the bottom surface (the surface facing the magnetic disk 10) of the reproducing element 2ra in the reproducing head 2r (the length in the radial direction in the magnetic disk 10) is defined as the reproducing head width Rw. On the other hand, in the recording head 2w, as an example, the recording head width Ww of the main magnetic pole part 2wa (the length along the radial direction in the main magnetic pole part 2wa) is 60 nm, and the residual magnetic flux density (Bs) of the main magnetic pole part 2wa is 2. It is configured to be 4T. In the present specification, the width of the bottom surface (the surface facing the magnetic disk 10) of the main magnetic pole portion 2wa in the recording head 2w (the length in the radial direction in the magnetic disk 10) is defined as the recording head width Ww. . In this case, in this type of magnetic head 2, the bottom surface shape of the main magnetic pole portion 2wa in the recording head 2w is a trapezoid. Therefore, in this specification, the longest width (in this example, both sides along the radial direction of the trapezoid) among the widths of the respective portions (the width in the direction along the radial direction of the magnetic disk 10) on the bottom surface of the main magnetic pole portion 2wa. (The length of the longer side) is defined as the recording head width Ww.

  The actuator 3 constitutes a head driving mechanism in the hard disk drive 1 and swings the arm 3a (see FIG. 1) under the control of the control unit 5, thereby causing the magnetic head 2 (reproducing head) attached to the tip of the arm 3a. 2r and the recording head 2w) are turned on track to a predetermined data recording track T on the magnetic disk 10. As an example, the motor 4 rotates the magnetic disk 10 under the condition of a constant angular velocity of 7200 rpm, under the control of the control unit 5. The control unit 5 comprehensively controls the hard disk drive 1. Specifically, the control unit 5 controls the rotation of the magnetic disk 10 by the motor 4, the tracking control of the magnetic head 2 by the actuator 3, the reading control of the recording data through the reproducing head 2r, and the recording head 2w. Execute recording control of recorded data.

  In this hard disk drive 1, when recording data is written to the magnetic disk 10, the control unit 5 controls the actuator 3 so that the magnetic head 2 is on-tracked to a desired data recording track T. In this state, the recording head 2w is turned on. The recording data (magnetic signal) is written to the data recording track T (convex portion 15a). At this time, the control unit 5 controls the actuator 3 so that the off-track amount of the recording head 2w with respect to the track center Ct of the data recording track T is within a predetermined off-track allowable range. As a result, a magnetization pattern (not shown) corresponding to the recording data is formed on the data recording track T without causing sidelight. On the other hand, when reading the recording data from the magnetic disk 10, the control unit 5 controls the actuator 3 to on-track the magnetic head 2 to the desired data recording track T, and in that state, the data is transmitted via the reproducing head 2r. Recording data (magnetic signal) is read from the recording track T (convex portion 15a). At this time, the control unit 5 controls the actuator 3 so that the off-track amount of the reproducing head 2r with respect to the track center Ct of the data recording track T falls within a predetermined off-track allowable range. As a result, the recorded data is reproduced based on the output signal output from the reproducing head 2r without causing crosstalk.

  Next, the hard disk drive 1 provided with the magnetic disk 10 and a conventional magnetic recording medium (magnetic recording medium in which the recording layer is continuously formed over the entire area: hereinafter, also referred to as “magnetic disk 10x”). Differences in recording / reproduction characteristics from the provided hard disk drive will be described with reference to the drawings. Each characteristic described below is based on a simulation result by an LLG (Landau-Lifshits-Gilbert) micromagnetic simulation method. Further, in the following description, “x” is added to the reference numerals of components corresponding to the conventional recording / reproducing apparatus. In this case, the recording head width Wwx of the recording head 2wx (main magnetic pole portion 2wax) and the reproducing head width Rwx of the reproducing head 2rx in the conventional hard disk drive 1x are also the same as those of the recording head 2w (main magnetic pole portion 2wa) in the hard disk drive 1. It is assumed that the width is equal to the recording head width Ww and the reproducing head width Rw of the reproducing head 2r.

  First, as shown in FIG. 5, a signal of 1580 kbpi was written to the above-described magnetic disk 10 in the central data recording track T of the three data recording tracks T, T, T adjacent in the radial direction. Later, a signal of 530 kbpi is written to the data recording tracks T and T on both sides. At this time, a signal is written in a state where the center of the recording head 2w coincides with each track center Ct (a state where the off-track amount of the recording head 2w is 0 nm). Further, after a data recording track Tx is formed by writing a signal of 1580 kbpi on the conventional magnetic disk 10x, a data recording track Tx on both sides is written by writing a signal of 530 kbpi on both sides of the data recording track Tx. , Tx are formed such that the track pitch Tpx is 80 nm (a pitch equal to the track pitch Tp of the magnetic disk 10). At this time, a signal is written in a state where the center of the recording head 2wx coincides with each track center Ctx (a state where the off-track amount of the recording head 2wx is 0 nm). In this case, the magnetic spacing between the bottom surfaces of the main magnetic pole portions 2wa and 2wax in the recording heads 2w and 2wx and the surfaces of the recording layers 14 and 14x (projection end surfaces of the convex portions 15a and 15ax) in the magnetic disks 10 and 10x is performed. The thickness was 10 nm. In FIG. 7 and FIG. 7 to be referred to later, the magnetization pattern formed by signal writing is shown as a black and white stripe pattern on each data recording track T, Tx (Txo). Next, signals are read from the data recording tracks T and Tx at the center via the reproducing heads 2r and 2rx (not shown). At this time, the SNR for the output signals and noises output from the reproducing heads 2r and 2rx while moving the reproducing heads 2r and 2rx in the radial direction with respect to the track centers Ct and Ctx in the central data recording tracks T and Tx. Measure. The measurement result (off-track profile) is shown in FIG.

  As shown in FIG. 6, in the magnetic disk 10 in which the data recording track T is configured by the convex portion 15a formed with a magnetic material on the protruding end side, the center of the reproducing head 2r is made to coincide with the track center Ct. In each state from the state (on-track state) to the off-track amount of 14 nm (about 18% with respect to the track pitch Tp), the SNR for the output signal from the reproducing head 2r is almost constant at about 7 dB. ing. On the other hand, in the conventional magnetic disk 10x in which the recording layer 14x is continuously formed over the entire area, the output signal from the reproducing head 2rx increases as the off-track amount of the reproducing head 2rx with respect to the track center Ctx increases. The SNR greatly decreases. In the magnetic disk 10, for example, the SNR for the output signal when the off-track amount of the reproducing head 2r is 7 nm (about 9% with respect to the track pitch Tp) is about 7 dB, whereas in the magnetic disk 10x, the reproducing head The SNR for the output signal when the 2rx off-track amount is 7 nm is about 2.2 dB lower than the SNR of the magnetic disk 10. In this case, in the magnetic disk 10x, the SNR for the output signal when the off-track amount of the reproducing head 2rx is 0 nm (on-track state) is 5.2 dB, and the magnetic disk 10 has a characteristic higher than 5.2 dB ( The range in which (SNR) can be maintained is a range from off-track amount = 0 nm to 25 nm (about 31.2% with respect to the track pitch Tp). Based on the above measurement results, the groove G (concave portion 15b) having a groove width Gw of 40 nm is provided on both sides of the data recording track T (convex portion 15a) having a track width Tw of 40 nm, which is compared with the conventional magnetic disk 10x. Thus, it can be understood that the crosstalk at the time of reproduction (signal reading) of the recording data from the desired data recording track T is sufficiently avoided.

  Further, as shown in FIG. 7, in the state where the center of the recording head 2w is off-tracked by 7 nm in the direction of the arrow shown in FIG. After writing a 1580 kbpi signal to the central data recording track T of the three data recording tracks T, T, and T, the direction of the arrow is relative to the track center Ct in the data recording tracks T and T on both sides. As an example, in the state in which the tracks are off-tracked by 7 nm, a signal of 530 kbpi is sequentially written from the data recording track T on the left side. Further, in the state where the center of the recording head 2wx is off-tracked by 7 nm in the direction of the arrow shown in the figure with respect to the track center Ctx, a signal of 1580 kbpi is written on the magnetic disk 10x, whereby the central data recording track After forming Txo (hereinafter, the data recording track Tx formed in the off-track state will be described by adding “o” to the end of the symbol), as an example, the track center Ctx on the left side of the data recording track Txo The data recording tracks Txo and Txo on both sides are formed by writing a signal of 530 kbpi in the state of being off-tracked by 7 nm in the direction of the arrow with respect to each track center Ctx in order from the part. At this time, the magnetic gap between the bottom surfaces of the main magnetic pole portions 2wa and 2wax in the recording heads 2w and 2wx and the surfaces of the recording layers 14 and 14x (protruding end surfaces of the convex portions 15a and 15ax) in the magnetic disks 10 and 10x is obtained. The pacing was 10 nm. Next, signals are read from the data recording tracks T and Txo at the center via the reproducing heads 2r and 2rx (not shown). At this time, output signals and noises output from the reproducing heads 2r and 2rx while moving the reproducing heads 2r and 2rx in the radial direction with respect to the center track center Ct and Ctx of the three track centers Ct and Ctx. And measure the SNR for. The measurement result (off-track profile) is shown in FIG.

  As shown in FIG. 8, on the magnetic disk 10, reproduction is performed when the recording head 2w is on-tracked to the data recording track T (track center Ct) at the time of signal writing (when the off-track amount is 0 nm) as described above. The difference between the SNR of the output signal from the head 2r and the SNR of the output signal from the reproducing head 2r when the recording head 2w is off-tracked by 7 nm from the track center Ct (data recording track T) at the time of signal writing. Is as small as about 0.5 dB. In the magnetic disk 10, for example, the SNR for the output signal in the state where the off-track amount of the reproducing head 2r is 0 nm (on-track state) although the recording head 2w is off-tracked at the time of signal writing. On the other hand, in the magnetic disk 10x, the SNR for the output signal when the off-track amount of the reproducing head 2rx with respect to the track center Ctx is 0 nm is lower than the SNR in the magnetic disk 10 by about 4.1 dB. ing. As a result of this measurement, the off-track of the recording head 2wx at the time of writing the recording data becomes a serious problem (occurrence of sidelight) in the conventional magnetic disk 10x, whereas the magnetic disk 10 performs recording at the time of writing the recording data. Even if the head 2w is off-tracked, the recorded data can be read sufficiently, and it can be understood that the magnetic disk 10 has a great advantage with respect to the allowable off-track amount of the recording head 2w when writing the recorded data. Furthermore, when the off-track amount of the reproducing heads 2r and 2rx with respect to the track centers Ct and Ctx is 7 nm, the difference in SNR for the magnetic disks 10 and 10x is 4.4 dB. Based on the above measurement results, the groove G (concave portion 15b) having a groove width Gw of 40 nm is provided on both sides of the data recording track T (convex portion 15a) having a track width Tw of 40 nm, which is compared with the conventional magnetic disk 10x. Thus, it can be understood that the side write at the time of recording data recording (signal writing) on the desired data recording track T is sufficiently avoided.

  Thus, according to the hard disk drive 1, the length (track width Tw) along the radial direction in the data recording track T (convex portion 15a) is 40 nm, and the radial direction in the groove G (concave portion 15b). By providing the magnetic disk 10 having a length (groove width Gw) of 40 nm and the read head 2r formed to have a read head width Rw of 50 nm, the track pitch Tp is reduced. Even in a configuration that achieves sufficiently high density recording, the range (allowable off-track of the reproducing head 2r) that can avoid the occurrence of crosstalk due to the off-track of the reproducing head 2r at the time of reading recorded data is sufficiently large. A wide hard disk drive 1 can be provided. Therefore, since the hard disk drive 1 capable of accurately reading the recording data can be configured by the actuator 3 (head drive mechanism) or the control unit 5 having a somewhat simple configuration, the high density without causing an increase in manufacturing cost. The hard disk drive 1 in which recording is realized can be provided.

  Further, according to the hard disk drive 1, the length (track width Tw) along the radial direction of the data recording track T (convex portion 15a) is 40 nm, and the length along the radial direction of the groove G (concave portion 15b). By providing the magnetic disk 10 formed so that the (groove width Gw) is 40 nm and the recording head 2 w formed so that the recording head width Ww is 60 nm, the track pitch Tp can be sufficiently reduced. Even in a configuration that achieves high density recording, a hard disk that has a sufficiently wide range (allowable off-track amount of the recording head 2w) that can avoid the occurrence of sidelight due to off-tracking of the recording head 2w when recording data is written. A drive 1 can be provided. Accordingly, since the hard disk drive 1 capable of accurately writing the recording data can be configured by the actuator 3 (head drive mechanism) or the control unit 5 having a somewhat simple configuration, the high density without increasing the manufacturing cost. The hard disk drive 1 in which recording is realized can be provided.

In addition, this invention is not limited to said structure and method. For example, the magnetic recording medium in the present invention is not limited to the layer structure as in the magnetic disk 10 described above, and if necessary, between the layers from the soft magnetic layer 12 to the recording layer 14 on the substrate 11, In addition, a configuration in which various functional layers are provided on the recording layer 14 can be employed. Moreover, the material used for forming each said layers 11-14 is an illustration, Comprising: Each layers 11-14 can be formed with other various materials. Further, in the magnetic disk 10 described above, a configuration in which a nonmagnetic material such as SiO ₂ is embedded in the recess 15b may be employed. Further, the example in which the data recording track T is configured by the plurality of concentric convex portions 15a has been described, but the configuration in which the convex portions constituting the data recording track T are separated by concave portions (nonmagnetic regions) in the circumferential direction as well. (Patterned medium) can also be adopted.

1 is a configuration diagram showing a configuration of a hard disk drive 1. 2 is a cross-sectional view showing a layer structure of a magnetic disk 10. FIG. It is sectional drawing which shows an example of the cross-sectional shape of each convex part 15a and each recessed part 15b in a magnetic disc. FIG. 3 is a bottom view of the magnetic head 2 as viewed from the magnetic disk 10 side. The left figure is a plan view of the magnetic disk 10 on which the magnetic pattern is formed by writing a signal without off-tracking the recording head 2w, and the right figure is for writing a signal without off-tracking the recording head 2wx. It is a top view of the conventional magnetic disk 10x in which the magnetization pattern was formed in FIG. FIG. 5 is an explanatory diagram for explaining the relationship between the SNR of a reproduction signal and the off-track amount of the reproduction head when a signal is written without off-tracking the recording heads 2w and 2wx. The left figure is a plan view of the magnetic disk 10 on which the magnetization pattern is formed by writing a signal with the recording head 2w off-track, and the right figure shows the signal with the recording head 2wx off-track. It is a top view of the conventional magnetic disk 10x in which the magnetization pattern was formed by writing. FIG. 6 is an explanatory diagram for explaining a relationship between an SNR of a reproduction signal and an off-track amount of the reproduction head when a signal is written in a state where the recording heads 2w and 2wx are off-track.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Hard disk drive 2 Magnetic head 2r Reproduction head 2ra Reproduction element 2w Recording head 2wa Main magnetic pole part 5 Control part 10 Magnetic disk 14 Recording layer 15 Concave / convex pattern 15a Convex part 15b Concave part G Groove Gw Groove width Rw Reproducing head width T Data recording track Tp Track pitch Tw Track width Ww Recording head width X Reference plane

Claims (2)

A magnetic recording medium in which a nonmagnetic region is provided between data recording tracks adjacent in the radial direction, and a reproducing head configured to be able to read recorded data from the magnetic recording medium,
The magnetic recording medium is formed so that a length along the radial direction in the data recording track is 40 nm, and a length along the radial direction in the nonmagnetic region is 40 nm,
The recording / reproducing apparatus, wherein the reproducing head is formed to have a reproducing head width of 50 nm. A magnetic recording medium provided with a nonmagnetic region between adjacent data recording tracks in the radial direction, and a recording head configured to be able to write recording data to the magnetic recording medium,
The magnetic recording medium is formed so that a length along the radial direction in the data recording track is 40 nm, and a length along the radial direction in the nonmagnetic region is 40 nm,
The recording head is a recording / reproducing apparatus formed so that a recording head width is 60 nm.

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