JP2010157273A - Magnetic disk device, tracking control method, and tracking control circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a magnetic disk device capable of highly accurately performing fast tracking control for a patterned medium, and to provide a tracking control method. <P>SOLUTION: The magnetic disk device includes: a magnetic read signal acquisition means 10 for acquiring, by reading data from a plurality of rows of recording tracks collectively by two rows via a reproducing element 2A during rotation of a magnetic disk 1, a magnetic read signal according to a plurality of magnetic dots d included in each row; a track separation signal generation means 20 for generating track separation signals of two rows according to each row of a recording track from the magnetic read signal; track absolute value signal generation means 31 and 32 for generating track absolute value signals by converting the track separation signals into absolute values; a track difference signal generation means 40 for generating a track differential signal by obtaining a difference between the track absolute value signals; and a magnetic head movement control means 60 for controlling a magnetic head moving mechanism 5 based on the track difference signal. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a magnetic disk device, a tracking control method, and a tracking control circuit excellent in tracking control of a magnetic disk called a so-called patterned medium.

  As a technique related to tracking control of patterned media, there is one disclosed in Patent Document 1. In the technique disclosed in this document, the subtracks formed by arranging a plurality of recording cells (magnetic dots) in the circumferential direction of the disk at a predetermined pitch are grouped in four rows in the disk radial direction so as to form one recording track band. A patterned medium is used that is formed so that sub-tracks adjacent to each other in the disk radial direction are shifted by a half pitch in the disk circumferential direction. As the read head, a read head that can be read across two rows of sub-tracks is used.

  In such tracking control for patterned media, since the read head reads the sub-tracks in groups of two, the read head is controlled so that it passes just between the adjacent sub-tracks. Specifically, when the read head overlaps most of one recording cell belonging to one subtrack, the read head also overlaps part of two recording cells belonging to the other subtrack. Therefore, a plurality of signal patterns corresponding to the magnetization directions of a plurality of recording cells are stored in advance, the actual measurement signal obtained at the time of actual reading is compared with the stored signal pattern, and the comparison result is obtained. By using the bit pattern information corresponding to the magnetization direction of the recording cell and the track deviation information, tracking control is performed so that the read head passes just between the adjacent subtracks.

Japanese Patent No. 3699925

  However, in the conventional tracking control technique for the patterned media, if a plurality of signal patterns stored in advance in memory are read and these signal patterns and measured signals are not compared in detail one by one, adjacent sub- Since it cannot be accurately positioned in the middle of the track and it takes a certain amount of time for the processing, tracking control cannot be performed with high accuracy and high speed.

  The present invention has been conceived under the circumstances described above, and provides a magnetic disk device, a tracking control method, and a tracking control circuit capable of performing tracking control for patterned media with high accuracy and high speed. The task is to do.

  In order to solve the above problems, the present invention takes the following technical means.

  According to the first aspect of the present invention, recording tracks formed by arranging a plurality of magnetic dots at a predetermined pitch in the circumferential direction of the disk are formed in a plurality of rows so as to form a predetermined track pitch in the disk radial direction. In addition, the magnetic recording disk formed such that the recording track columns adjacent in the disk radial direction are shifted in the circumferential direction of the disk and the plurality of recording tracks adjacent to each other in the disk radial direction can be read together. A magnetic head having a reproducing element; a magnetic head moving mechanism that reciprocates in the radial direction of the disk while the magnetic head is opposed to the magnetic disk; and the plurality of rows through the reproducing element during rotation of the magnetic disk. By reading two recording tracks at a time, the magnetic reading corresponding to the plurality of magnetic dots included in each row is performed. A magnetic read signal acquiring means for acquiring a read signal; a track separation signal generating means for generating a track separation signal for two rows corresponding to each row of the recording track from the magnetic read signal; and a track separation for the two rows A track absolute value signal generating means for generating a track absolute value signal for two columns by converting each of the signals into an absolute value, and a track difference signal is generated by obtaining a difference or average difference between the track absolute value signals for the two columns. There is provided a magnetic disk device comprising track difference signal generating means and magnetic head movement control means for controlling the magnetic head moving mechanism based on the track difference signal.

  According to the second aspect of the present invention, the recording tracks formed by arranging a plurality of magnetic dots in the circumferential direction of the disk at a predetermined pitch are formed in a plurality of rows so as to form a predetermined track pitch in the disk radial direction. In addition, the magnetic recording disk formed such that the recording track columns adjacent in the disk radial direction are shifted in the circumferential direction of the disk and the plurality of recording tracks adjacent to each other in the disk radial direction can be read together. A magnetic disk apparatus comprising: a magnetic head having a reproducing element; and a magnetic head moving mechanism that reciprocates in the disk radial direction while facing the magnetic head with respect to the magnetic disk. A tracking control method for adjusting and performing tracking control, wherein A magnetic reading signal acquisition procedure for acquiring magnetic reading signals corresponding to the plurality of magnetic dots included in each column by reading the recording tracks of the plurality of columns together in two columns through a reproducing element; A track separation signal generation procedure for generating a track separation signal for two rows corresponding to each row of the recording track from the read signal, and an absolute value of each of the track separation signals for the two rows to obtain the absolute value of the track for two rows Based on the track absolute signal generation procedure for generating the value signal, the track difference signal generation procedure for generating the track difference signal by obtaining the difference or average of the track absolute value signals for the two columns, and the track difference signal There is provided a tracking control method for executing a magnetic head movement control procedure for controlling the magnetic head movement mechanism.

  According to the third aspect of the present invention, a recording track formed by arranging a plurality of magnetic dots in a row, with respect to a magnetic recording medium in which a plurality of the magnetic dots are shifted in the track direction between adjacent rows, A tracking control circuit that performs tracking control based on a magnetic reading signal obtained from a reproducing element that collectively reads the recording tracks of the adjacent rows, wherein the plurality of recording tracks are recorded from the recording tracks of the adjacent rows based on the magnetic reading signal. A timing generation circuit for generating a timing signal serving as a reference when reading the magnetic dots, a signal separation circuit for separating the magnetic read signal based on the timing signal generated by the timing generation circuit, and the signal separation circuit A difference circuit for calculating a difference in amplitude of the separated signal and the difference circuit Based on the differential signal output, tracking control circuit is provided which includes a control circuit for generating a tracking control signal.

  According to the technique disclosed by the present invention, for example, with respect to a plurality of rows of recording tracks formed on a patterned medium, two rows of recording tracks adjacent in the disk radial direction are collected and read by the reproducing element of the magnetic head. At that time, the magnetic read signal obtained via the reproducing element is separated into two columns of track separation signals corresponding to each column of the recording track, and these track separation signals are converted into absolute values to obtain the absolute values of the tracks of two columns. A value signal is generated, and a difference between the track absolute value signals for two columns is obtained to generate a track difference signal. Based on the track difference signal, an intermediate line between two recording tracks adjacent to each other is reproduced. Tracking control can be accurately performed so as to pass. Signal separation, absolute value, and signal difference calculation can be performed in real time using, for example, a wired logic circuit, so that tracking control for patterned media can be performed with high accuracy and high speed.

  Other features and advantages of the present invention will become more apparent from the detailed description given below with reference to the accompanying drawings.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

  1 to 4 show an embodiment of a magnetic disk device according to the present invention. The magnetic disk device of this embodiment is a device for reproducing or recording magnetic information while performing tracking control of the magnetic head 2 with respect to the rotating magnetic disk 1. Components related to tracking control include the magnetic disk 1 and the magnetic head 2, as well as the spindle motor 3, swing arm 4, voice coil motor 5, head amplifier 10, timing generation circuit 11, signal separation circuit 20, and absolute value circuit. 31, 32, delay circuit 33, difference circuit 40, AD converter 41, MPU 50, DA converter 51, low-pass filter 52, and VCM drive circuit 60. The tracking control circuit includes a head amplifier 10, timing generation circuit 11, signal separation circuit 20, absolute value circuits 31, 32, delay circuit 33, difference circuit 40, AD converter 41, MPU 50, DA converter 51, low-pass filter 52, and A VCM drive circuit 60 is included.

  The magnetic disk 1 is a so-called patterned medium and is suitable for the perpendicular magnetic recording system. On the magnetic disk 1, magnetic dots d serving as magnetic recording portions are discretely formed in the nonmagnetic region. In particular, the magnetic disk 1 of the present embodiment is formed with the following pattern.

  On the magnetic disk 1, a data recording area D, a track mark M, and a servo pattern area S are formed on a sector basis in the circumferential direction of the disk. The data recording area D is an area where magnetic information is recorded and reproduced. As shown in FIG. 2, the data recording area D includes a plurality of recording tracks T1 to T6 formed by arranging a plurality of magnetic dots d at a predetermined pitch p in the disk circumferential direction. This is an area formed in a row so as to form a predetermined track pitch Tp in the disk radial direction. The rows of recording tracks T1 to T6 adjacent in the disc radial direction, for example, the rows of T1 and T2 and the rows of T2 and T3 are formed so as to be shifted by p / 2 in the circumferential direction of the disc. Note that the number of rows of recording tracks T1 to T6 and the number of magnetic dots d arranged in the circumferential direction of the disk are not limited to those shown in the figure, and there are actually a very large number of rows and the number of magnetic dots d. .

  In the magnetic dot d, a magnetization direction that is either upward or downward with respect to the surface of the magnetic disk D is recorded as magnetic information by the action of a perpendicular magnetic field by a recording element 2B described later. In FIG. 2, for example, white magnetic dots d are recorded with an upward magnetization direction (+) and black magnetic dots d are recorded with a downward magnetization direction (−) recorded. ing. For each row of recording tracks T1 to T6 in such a data recording area D, magnetic dots from the first magnetic dot that first approaches the magnetic head 2 to a predetermined midway position according to the direction of rotation of the magnetic disk 1 For example, the first magnetic dot d1 to the sixth magnetic dot d6 in the recording tracks T3 and T4 are provided as dummy patterns Dm. In such a dummy pattern Dm, predetermined magnetic information is recorded so as to form a magnetization direction pattern suitable for tracking control, and a predetermined number of magnetic dots d following the dummy pattern Dm have a user with an arbitrary magnetization direction pattern. Magnetic information as data is recorded. Note that magnetic information as user data may be recorded in the dummy pattern. The dummy pattern may be set every predetermined number of magnetic dots or may not be provided.

  As shown in FIG. 1, the track mark M is positioned between the data recording area D and the servo pattern area S before the tip position where reading of the data recording area D is started and is along the disk radial direction. A plurality are formed. Each track mark M is a triangular magnetic region, and is formed at the same position in the disk radial direction as the recording tracks T1 to T6 and at the same pitch as the track pitch Tp, as shown in FIG. Note that the shape of the track mark is not particularly limited to a triangular shape, and preferably may be a shape that can be magnetically distinguished from the magnetic dot and can be read.

  The plurality of track marks M arranged in the disk radial direction are magnetized in advance so that the magnetization directions are alternately changed every two rows of the recording tracks T1 to T6. As shown in FIG. 2 as an example, the two track marks M corresponding to the columns T1 and T2 are, for example, white and have an upward magnetization direction (+) magnetized, and the following symbols T3 and T4 The two track marks M corresponding to these columns are, for example, black and have a downward magnetization direction (-) magnetized. According to such a track mark M, the reproducing element 2A, which will be described later, reads these track marks M, and thereby the reproducing element 2A is aligned with two target recording tracks. As a result, the reproducing element 2A is approximately aligned for every two rows of the target recording tracks among the recording tracks T1 to T6. At that time, the odd-numbered recording tracks such as T1, T3, and T5 are always read first, and then the even-numbered recording tracks such as T2, T4, and T6 are read. The recording tracks T1 to T6 are sequentially read in an even order. As a modification of the track mark, a track mark may be arranged so as to correspond to every two rows of recording tracks. In the following description, when a target recording track is specified in particular, recording tracks denoted by reference signs T3 and T4 are used as “target tracks”.

  In the servo pattern area S shown in FIG. 1, a magnetic pattern for searching for two rows of target tracks to be reproduced or recorded (two rows T3 and T4 in FIG. 2) among a plurality of recording tracks T1 to T6 is formed. This is the area that has been Such a servo pattern area S includes a preamble part, an address part, and a burst pattern part, although no reference numerals are given. The preamble portion is a magnetic pattern portion for generating a timing signal that serves as a reference when recording / reproducing is performed on the data recording area D. The address portion is a magnetic pattern portion for indicating address information such as a sector number and a track number. The burst pattern portion is a magnetic pattern portion for aligning a reproducing element 2A described later with respect to, for example, two rows of target tracks T3 and T4. Since the burst pattern portion is formed at a position spaced apart from the target tracks T3 and T4 in the data recording area D to some extent in the disk circumferential direction, accurate alignment is ensured only by the burst pattern portion due to manufacturing errors and the like. is not. Therefore, tracking control described later is performed.

  As shown in FIG. 1, the magnetic head 2 records and reproduces magnetic information on the magnetic disk 1, and has a slider (not shown) at the tip of the swing arm 3 so as to face the recording surface of the magnetic disk 1. ). The magnetic head 2 has a reproducing element 2A and a recording element 2B that read and write magnetic information independently. The reproducing element 2A and the recording element 2B are arranged in the circumferential direction of the magnetic disk 1, and the recording element 2B is located on the rotation direction side of the magnetic disk 1 with respect to the reproducing element 2A.

  As shown in FIG. 2, the reproducing element 2 </ b> A has a disk radial width dimension that allows a plurality of rows of recording tracks T <b> 1 to T <b> 6 to be read together in two rows. The reproducing element 2A is positioned for every two rows of the recording tracks T1 to T6 by reading the track mark M. For example, when the reproducing element 2A is aligned with two rows of target tracks T3 and T4 separated by a broken line, the most preferable state is adjusted to a position passing through the intermediate line of the target tracks T3 and T4 as shown in FIG. It becomes a state. On the other hand, it is not possible to accurately align the target tracks T3 and T4 only by reading the track mark M. For example, as shown in FIG. 3, the reproducing element 2A has a disk radial width dimension that is not magnetically affected by the recording tracks T2 and T5 located adjacent to the target tracks T3 and T4. However, there is a case where the position of the target track T3 or T4 is biased. The reproducing element 2A reads the magnetization direction and magnetic strength of the magnetic dot d, and a signal corresponding to the magnetization direction is input to the head amplifier 10.

  Although the detailed illustration is omitted, the recording element 2B has a disk radial direction width dimension capable of recording magnetic information in two rows on a plurality of recording tracks T1 to T6 in the same manner as the reproducing element 2A. Such a recording element 2B is driven so as to apply a perpendicular magnetic field in a predetermined direction to two rows of target tracks T3 and T4 based on a drive signal corresponding to information to be recorded from a recording control circuit (not shown). The The driving frequency is a clock frequency synchronized with the timing signal. Although the reproducing element 2A and the recording element 2B are substantially at the same position in the disk radial direction, strictly speaking, they are shifted in the disk radial direction due to a manufacturing error or a so-called skew angle. Therefore, at the time of recording, head position correction is performed in addition to tracking control.

  The spindle motor 3 rotates the magnetic disk 1 at a high speed. The swing arm 4 reciprocates the magnetic head 2 substantially in the disk radial direction and is swung by a voice coil motor 5. The voice coil motor 5 is driven by the VCM drive circuit 60. Such a swing arm 4 and the voice coil motor 5 are provided as a magnetic head moving mechanism.

  The head amplifier 10 acquires an input signal from the reproducing element 2A as a magnetic read signal, amplifies the magnetic read signal, and outputs the amplified signal. For example, as shown in FIG. 2, the reproducing elements 2A are aligned so as to be evenly applied to the two target tracks T3 and T4 in the dummy pattern Dm, and in this state, the reproducing elements 2A are included in the target tracks T3 and T4. The magnetic dots d to be read are read together in two rows. In this case, the intensity of the magnetism detected by the reproducing element 2A is substantially constant for each of the magnetic dots d of the two target tracks T3 and T4, and the amplitude direction is inverted according to the magnetization direction. A magnetic read signal having a simple waveform is output from the head amplifier 10. On the other hand, as shown in FIG. 3, when the reproducing element 2A is in a position biased with respect to one target track T3 and the reproducing element 2A reads the magnetic dots d in two rows in this state, the reproducing element 2A Although the magnetization direction is detected as the amplitude direction, the magnetic strength from the magnetic dot d included in the other target track T4 is detected smaller than the one target track T3. That is, when the position of the reproducing element 2A in the disk radial direction is deviated from the target tracks T3 and T4, as shown in FIG. 3, a magnetic read signal having a waveform including a large amplitude and a small amplitude as the absolute value of the amplitude is obtained. Output from the head amplifier 10.

  The timing generation circuit 11 generates a timing signal serving as a reference at the time of recording / reproduction based on the magnetic read signal acquired by the reproduction element 2A reading the preamble portion of the servo pattern region S. This timing signal is a signal having a clock frequency corresponding to a pitch interval p / 2 in which two adjacent rows of magnetic dots d are alternately arranged in the circumferential direction of the disk, and is input to the signal separation circuit 20 and also to the AD converter 41. Entered.

  The signal separation circuit 20 separates the magnetic read signal obtained by the reproducing element 2A reading the magnetic dots d of the dummy pattern Dm into signals for two columns according to the clock frequency of the timing signal. For example, as shown in FIG. 2, when a magnetic read signal having substantially the same absolute value of amplitude is input to the signal separation circuit 20, the signal separation circuit 20 outputs a first signal corresponding to the magnetic dot d of one recording track T3. One track separation signal and a second track separation signal corresponding to the magnetic dot d of the other recording track T4 are output. On the other hand, as shown in FIG. 3, when a magnetic reading signal having two different magnitudes of the absolute value of the amplitude is input to the signal separation circuit 20, the signal separation circuit 20 outputs a magnetic signal of one recording track T3. A signal having a large amplitude is output as the first track separation signal corresponding to the dot d, and a signal having a small amplitude is output as the second track separation signal corresponding to the magnetic dot d of the other recording track T4. Such a first track separation signal always corresponds to the odd-numbered recording track T3 of the target tracks T3, T4, and the second track separation signal corresponds to the even-numbered recording track T4.

  The absolute value circuits 31 and 32 convert the first and second track separation signals into absolute values. For example, as shown in FIG. 2, when the first and second track separation signals having substantially the same amplitude level are input to the absolute value circuits 31 and 32, the amplitudes are substantially equal from the absolute value circuits 31 and 32, respectively. First and second track absolute value signals that are shifted by one cycle of the timing signal at a positive level are output. On the other hand, as shown in FIG. 3, when the first and second track separation signals having different amplitudes are input to the absolute value circuits 31 and 32, for example, the absolute value circuit 31 corresponding to the large amplitude has the same large amplitude. On the other hand, the first track absolute value signal having a positive level is output while the absolute value circuit 32 corresponding to the small amplitude outputs a second track absolute value signal having the same small amplitude and a positive level. The absolute value circuit 31 always corresponds to the odd-numbered recording track T3 of the target tracks T3 and T4, and the absolute value circuit 32 corresponds to the even-numbered recording track T4.

  Since the delay circuit 33 has a phase difference (time shift) between the first and second track absolute value signals, for example, the first track absolute value signal output from one absolute value circuit 31 is used as one cycle of the timing signal. Output by shifting by minutes. Note that the delay circuit may be arranged so that the second track absolute value signal is output by being shifted by one cycle of the timing signal.

  The difference circuit 40 calculates the difference between the first and second track absolute value signals having the same phase via the delay circuit 33, and outputs the result as a track difference signal. For example, as shown in FIG. 2, when the first and second track absolute value signals having substantially the same amplitude are input to the difference circuit 40, the track difference signal is substantially at the 0 level. On the other hand, as shown in FIG. 3, when first and second track absolute value signals having different amplitudes are input to the difference circuit 40, the track difference signal is a signal having a certain numerical level. That is, the track difference signal corresponds to the position error signal of the reproducing element 2A for the two rows of target tracks T3 and T4. For example, a track differential signal having a positive numerical level indicates that the reproducing element 2A is biased toward the odd-numbered recording track T3 and is shifted by a distance corresponding to the numerical level, and has a negative numerical level. The track difference signal indicates that the reproducing element 2A is biased toward the even-numbered recording track T4 and is shifted by a distance corresponding to the numerical level. The track difference signal output from the difference circuit 40 is a periodic signal having a frequency corresponding to the first and second track absolute value signals. FIG. 3 shows a steady signal that is digital signal processed by the MPU 50. A typical track difference signal (tracking control signal) is shown.

  The MPU 50 is a so-called microprocessor and performs digital signal processing on the track difference signal input via the AD converter 41. According to the digital signal processing of the MPU 50, a digital track difference signal is output as a tracking control signal during reproduction, and a tracking control signal including head position correction information for the recording element 2B is output during recording. As a circuit element for performing digital signal processing, for example, a digital signal processor specialized only for track difference signal processing may be applied.

  The VCM drive circuit 60 functions as a magnetic head movement control means for tracking control, receives a tracking control signal from the MPU 50 via the DA converter 51 and the low-pass filter 52, and based on the tracking control signal, a voice coil motor. 5 is controlled. As a result, tracking control is performed, and the reproducing element 2A and the recording element 2B are accurately aligned with the positions passing through the intermediate lines of the two rows of target tracks T3 and T4. After such tracking control is performed, reproduction processing and recording processing are executed, and magnetic information is reproduced and recorded accurately with respect to the magnetic dots d included in the two target tracks T3 and T4.

  Next, the processing procedure of the tracking control method for the target tracks T3 and T4 will be described with reference to FIG.

  First, as shown in FIG. 4, the MPU 50 executes a search process for the target tracks T3 and T4 in accordance with, for example, a reproduction command or a recording command from a host computer (not shown) (S1). In the search processing of the target tracks T3 and T4, the MPU 50 reads the preamble portion, the address portion, and the burst pattern portion of the servo pattern area S through the reproducing element 2A during the rotation of the magnetic disk D, thereby the target track T3. , T4, the reproducing element 2A is moved to a position in the disk radial direction where two track marks M corresponding to T4 can be read. Thereafter, the MPU 50 reads the two track marks M via the reproducing element 2A. As a result of the reading, for example, a track mark signal as shown in FIGS. 2 and 3 is obtained. When the signal level falls below a predetermined negative level, two rows of target tracks T3 as shown in FIG. 2 or FIG. , T4 overlaps the reproducing element 2A, and the target tracks T3, T4 are almost searched. However, when the signal level of the track mark signal is greater than a predetermined negative level or detected at a positive level, the reproducing element 2A is superimposed on a recording track different from the target tracks T3 and T4, in most cases. Is a state in which the reproducing element 2A overlaps the adjacent recording track T2 or recording track T5. Therefore, the MPU 50 continues the search process until the reproducing element 2A is gradually moved in the disk radial direction to detect a signal level of a desired track mark signal corresponding to the target tracks T3 and T4. For example, if the target tracks T3 and T4 cannot be searched even if the search process is continued for a predetermined time, it is processed as a tracking error.

  When the reproducing element 2A substantially overlaps the two rows of target tracks T3 and T4, the head amplifier 10 further reads the magnetic dots d of the target tracks T3 and T4 through the reproducing element 2A to obtain a magnetic read signal. (S2).

  Next, the signal separation circuit 20 separates the magnetic read signal from the head amplifier 10 based on the timing signal, thereby generating the first and second track separation signals (S3).

  Next, the absolute value circuits 31 and 32 convert the absolute values of the first and second track separation signals (S4). Thus, the absolute value circuits 31 and 32 output the first and second track absolute value signals, the first track absolute value signal is input to the difference circuit 40 via the delay circuit 33, and the second track. The absolute value signal is input to the difference circuit 40 as it is.

  Next, the difference circuit 40 calculates the difference between the first and second track absolute value signals (S5). As a result, a track difference signal is output from the difference circuit 40, and the track difference signal is converted into a digital signal by the AD converter 41 and then input to the MPU 50. The MPU 50 outputs the track difference signal as a tracking control signal without correction at the time of reproduction, but outputs a tracking control signal optimized by head position correction at the time of recording.

  Next, the MPU 50 supplies a tracking control signal to the VCM driving circuit 60 via the DA converter 51 and the low-pass filter 52, and the VCM driving circuit 60 controls the voice coil motor 5 based on the tracking control signal (S6). . Thereby, tracking control of the reproducing element 2A and the recording element 2B with respect to the target tracks T3 and T4 is performed. For example, as shown in FIG. 3, even when the reproducing element 2A is on a line slightly deviated from the intermediate lines of the target tracks T3 and T4 at the time of reproducing, The reproducing element 2A is aligned on the line. Similarly, at the time of recording, the recording element 2B is positioned just on the intermediate line of the target tracks T3 and T4 by tracking control. Such processing from S2 to S6 includes the head amplifier 10 as a wired logic circuit, the timing generation circuit 11, the signal separation circuit 20, the absolute value circuits 31, 32, the delay circuit 33, the difference circuit 40, the AD converter 41, and the MPU 50. , The DA converter 51, the low-pass filter 52, and the tracking control circuit including the VCM drive circuit 60. Therefore, when the reproducing element 2A passes through the dummy pattern Dm, the target track T3 of the reproducing element 2A or the recording element 2B is obtained. The alignment with respect to T4 is completed promptly.

  Thereafter, the MPU 50 executes a reproducing process or a recording process via the reproducing element 2A or the recording element 2B (S7). In the reproducing process, after the reproducing element 2A is finally aligned on the intermediate line of the target tracks T3 and T4, it leaves the dummy pattern Dm, and then the magnetic dots on the target tracks T3 and T4 following the dummy pattern Dm. The magnetic information is accurately read from d via the reproducing element 2A. In the recording process, after the reproducing element 2A is positioned on the intermediate line of the target tracks T3 and T4, the dummy element Dm is passed, and then the recording element 2B is immediately positioned between the target tracks T3 and T4 by the head position correction. Aligned on the line. Thereby, the magnetic information is accurately written to the magnetic dots d of the target tracks T3 and T4 following the dummy pattern Dm via the recording element 2B.

  Therefore, according to the magnetic disk apparatus of the present embodiment, when reading magnetic information with the reproducing element 2A of the magnetic head 2 or writing magnetic information with the recording element 2B with respect to the target tracks T3, T4 by two columns, wired logic is used. A track difference signal is generated in real time by signal separation, absolute value conversion, and difference calculation by the tracking control circuit of the circuit. Based on the track difference signal, the reproducing element 2A and the recording element 2B pass through the intermediate lines of the target tracks T3 and T4. Thus, tracking control can be performed accurately. Thereby, tracking control of the magnetic head 2 can be performed with high accuracy and high speed with respect to the magnetic disk 1 as a patterned medium capable of recording / reproducing two rows at a time.

  5-8 show other embodiments. In addition, the same code | symbol is attached | subjected about the component similar to the thing by embodiment mentioned above, and the description is abbreviate | omitted.

  For example, as shown in FIG. 5, the width dimension in the disk radial direction of the reproducing element 2A may be about twice the track pitch tp (2 Tp). In this case, when the reproducing element 2A is substantially aligned with the two rows of target tracks T3 and T4, the adjacent recording track T2 may be read as shown in FIG. Then, three or more different amplitudes are generated as the waveform of the magnetic read signal. In such a case, a hardware configuration as shown in FIG. 6 or 7 may be adopted.

  That is, the magnetic disk device shown in FIG. 6 integrates the first and second track absolute value signals output from the absolute value circuits 31 and 32, and outputs from these integration circuits 71 and 72. There is provided a difference averaging circuit 40 ′ that averages the integrated signals and calculates a difference between the averaged signals to generate a track difference signal.

  On the other hand, in the magnetic disk apparatus shown in FIG. 7, the first and second track absolute value signals output from the absolute value circuits 31 and 32 are directly input to the AD converter 41, and the AD converter 41 outputs the timing signals C1 and C2. The first and second track absolute value signals are AD-converted according to the clock frequency. The MPU 50 has functions equivalent to those of the integrating circuits 71 and 72 and the difference averaging circuit 40 '. The timing signal C0 input from the timing generation circuit 11 to the signal separation circuit 20 has the same clock frequency as that of the above-described embodiment, but the clock frequencies of the timing signals C1 and C2 input to the AD converter 41 are the timing signal. By dividing the clock frequency of C0, it is half that. One timing signal C1 and the other timing signal C2 are shifted from each other by one cycle. As a result, the MPU 50 receives the first and second track absolute value signals as digital signals simultaneously.

  According to the hardware configuration shown in FIG. 6 or FIG. 7, the tracking control process is performed in the procedure according to the flowchart of FIG. That is, as shown in FIG. 5, even when three or more different amplitudes are generated in the waveforms of the first and second track absolute value signals, the processing of the integrating circuits 71 and 72 and the difference averaging circuit 40 ′ (FIG. 6), or the MPU 50 after AD conversion using the timing signals C1 and C2 (see FIG. 7) obtains a track difference signal calculated by appropriately averaging the first and second track absolute value signals. (FIG. 8: S5 ′). Such a track difference signal is supplied as a tracking control signal to the VCM driving circuit 60, and the VCM driving circuit 60 controls the voice coil motor 5 based on the tracking control signal (FIG. 8: S6), thereby implementing the above-described implementation. Similar to the embodiment, tracking control of the magnetic head 2 with respect to the magnetic disk 1 can be performed with high accuracy and high speed.

  In addition, this invention is not limited to said embodiment.

  The configuration shown in the above embodiment is merely an example, and the design can be changed as appropriate according to the specification.

  For example, when the reading elements can be aligned with the two target tracks by reading the burst pattern, it is not necessary to provide a track mark, and the process of reading the track mark may be omitted. Alternatively, the magnetic dots of the burst pattern may be arranged in the same manner as the magnetic dots in the data recording area, and tracking control may be performed by reading the burst pattern in the same manner as the magnetic dots of the dummy pattern. In this case, it is no longer necessary to provide a dummy pattern.

  In the embodiment shown in FIG. 5, the first and second track absolute value signals are averaged. As another example, the lowest level of the first and second track absolute value signals is extracted and The track difference signal may be generated by taking the difference between the minimum value levels.

  The present invention can be used for tracking control in, for example, a perpendicular magnetic recording type magnetic disk apparatus.

1 is a configuration diagram showing an embodiment of a magnetic disk device according to the present invention. It is explanatory drawing for demonstrating the tracking control method by the magnetic disc device shown in FIG. It is explanatory drawing for demonstrating the tracking control method by the magnetic disc device shown in FIG. It is a flowchart for demonstrating the process sequence of a tracking control method. It is explanatory drawing for demonstrating other embodiment of the tracking control method which concerns on this invention. It is a block diagram which shows other embodiment of the magnetic disc apparatus based on this invention. It is a block diagram which shows other embodiment of the magnetic disc apparatus based on this invention. It is a flowchart for demonstrating the process sequence of the tracking control method shown in FIG.

Explanation of symbols

Dm dummy pattern d magnetic dot T1 to T6 recording track M track mark 1 magnetic disk 2 magnetic head 2A reproducing element 2B recording element 3 spindle motor 4 swing arm (magnetic head moving mechanism)
5 Voice coil motor (magnetic head moving mechanism)
10 Head amplifier (Magnetic read signal acquisition means)
20 Signal separation circuit (track separation signal generating means)
31, 32 Absolute value circuit (track absolute value signal generating means)
40 Difference circuit (track difference signal generating means)
40 'difference averaging circuit (track difference signal generating means)
60 VCM drive circuit (magnetic head movement control means)

Claims (6)

Recording tracks formed by arranging a plurality of magnetic dots in the circumferential direction of the disk at a predetermined pitch are formed in a plurality of rows so as to form a predetermined track pitch in the radial direction of the disk, and the recording tracks adjacent to each other in the radial direction of the disk A magnetic disk formed such that the rows of the disks are displaced in the circumferential direction of the disk;
A magnetic head having a reproducing element capable of collectively reading the recording tracks of the plurality of rows by two rows adjacent in the disk radial direction;
A magnetic head moving mechanism for reciprocating in the radial direction of the disk while the magnetic head is opposed to the magnetic disk;
During rotation of the magnetic disk, the plurality of rows of recording tracks are collectively read through the reproducing element to obtain a magnetic reading signal corresponding to the plurality of magnetic dots included in each row. Reading signal acquisition means;
Track separation signal generating means for generating track separation signals for two columns corresponding to each column of the recording track from the magnetic read signal;
Track absolute value signal generating means for converting each of the two columns of track separation signals into an absolute value and generating a track absolute value signal for two columns;
Track difference signal generation means for generating a track difference signal by obtaining a difference or average difference of the absolute track signals for the two columns;
Magnetic head movement control means for controlling the magnetic head movement mechanism based on the track difference signal;
A magnetic disk device comprising:   A plurality of track marks are formed on the magnetic disk so as to correspond to each row or every two rows of the recording tracks, and the plurality of track marks have a magnetization direction every two rows of the recording tracks. The magnetic disk device according to claim 1, wherein the magnetic disk device is magnetized so as to be alternately different.   3. A dummy pattern is provided for each column of the recording track from the first magnetic dot read first by the reproducing element to a magnetic dot at a predetermined halfway position in the column. The magnetic disk device described.   4. The magnetic disk device according to claim 1, wherein the magnetic head is mounted with recording elements capable of magnetic recording collectively in two rows with respect to the plurality of rows of recording tracks. 5. Recording tracks formed by arranging a plurality of magnetic dots in the circumferential direction of the disk at a predetermined pitch are formed in a plurality of rows so as to form a predetermined track pitch in the radial direction of the disk, and the recording tracks adjacent to each other in the radial direction of the disk A magnetic head formed such that the rows of the recording discs are shifted in the circumferential direction of the disc, a magnetic head having a read element that can read the plurality of rows of recording tracks in two rows adjacent to each other in the disc radial direction, and the magnetic disc In a magnetic disk device comprising a magnetic head moving mechanism that reciprocates in the disk radial direction with the magnetic head opposed to the tracking head, tracking control for performing tracking control by adjusting the disk radial position of the magnetic head A method,
During rotation of the magnetic disk, the plurality of rows of recording tracks are collectively read through the reproducing element to obtain a magnetic read signal corresponding to the plurality of magnetic dots included in each row. Read signal acquisition procedure;
A track separation signal generating procedure for generating a track separation signal for two columns corresponding to each column of the recording track from the magnetic read signal;
A track absolute value signal generating procedure for generating absolute values of the two columns of track separation signals and generating track absolute value signals of two columns;
A track difference signal generation procedure for generating a track difference signal by calculating a difference or difference average of the track absolute value signals for the two columns;
A magnetic head movement control procedure for controlling the magnetic head movement mechanism based on the track difference signal;
The tracking control method characterized by performing. The recording tracks formed by arranging a plurality of magnetic dots in a row are read together on the magnetic recording medium in which a plurality of the magnetic dots are arranged in adjacent rows and the magnetic dots are shifted in the track direction. A tracking control circuit that performs tracking control based on a magnetic read signal obtained from a reproducing element,
A timing generation circuit that generates a timing signal serving as a reference when reading the plurality of magnetic dots from the recording tracks of the adjacent rows based on the magnetic reading signal;
A signal separation circuit for separating the magnetic read signal based on the timing signal generated by the timing generation circuit;
A difference circuit for calculating a difference with respect to the amplitude of the signal separated by the signal separation circuit;
A control circuit for generating a tracking control signal based on the difference signal output from the difference circuit;
A tracking control circuit comprising:

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