Abstract: Systems and techniques relating to control of magnetic recording devices are described. Such devices can contain a recording medium including magnetic data positions, servo sync marks (SSMs), and phase tracking fields (PTFs) arranged between first and second SSMs. A described technique includes producing, based on a read head's waveform from the recoding medium, a servo detect pulse indicating a SSM detection; producing, based on the waveform, a servo detect pulse that indicates a SSM detection; producing, responsive to the servo detect pulse, calibration pulses, each of the calibration pulses corresponding to a read head's passage over one of the PTFs; and controlling, responsive to the calibration pulses, adjustments of a phase of a write clock signal to align the write clock signal with at least a portion of the data positions, the adjustments being based on groups of samples of the waveform that respectively correspond to the PTFs.

Abstract: The present disclosure includes systems and techniques relating to synchronization for writing to a recording medium. According to an aspect, an apparatus includes: circuitry configured to measure a timing difference based on a servo detect pulse and a write pulse, wherein the servo detect pulse comes from a detection of servo data from a recording medium including pre-defined data positions, and wherein the write pulse comes from a write clock signal used with the recording medium; and circuitry configured to control an adjustment to a phase of the write clock signal based on the timing difference to align the write clock signal with at least a portion of the pre-defined data positions.

Abstract: Embodiments of the present disclosure provide a method of self-servo writing, the method comprising actions of positionally tracking a selected timing track of a data storage disk, wherein the selected timing track has one or more timing segments; synchronizing an angular position signal to rotation of the data storage disk based on at least one of the one or more timing segments of the selected timing track; specifying servo sector positions relative to the synchronized angular position signal; writing servo sectors to the data storage disk at the specified servo sector positions relative to the synchronized angular position signal; detecting one or more positional errors in timing segments of a next timing track of the data storage disk based at least in part on the synchronized angular position signal; and accounting for the detected one or more positional errors in writing subsequent servo tracks. Other embodiments are also described.

Abstract: A method of writing servo data to a data storage medium includes reading a servo instruction from a memory, the servo instruction comprising a control portion and a data portion, processing the servo instruction in a controller to generate a servo data pattern from the data portion based on the control portion, and transferring the servo data pattern to the data storage medium. The processing may include transforming the data portion into the servo data pattern based on the control portion. The processing also may include following a command in the control portion to use the data portion as an index to retrieve a pre-programmed servo data pattern from a pattern store. The transferring may include storing the servo data pattern in a buffer, and writing the servo data pattern from the buffer to the data storage medium.

Abstract: Synchronization technologies for disk drives are described. A described technique includes receiving a waveform produced by a read head operated with respect to a recording medium including magnetic data positions, a first servo sync mark (SSM), a second SSM, and phase tracking fields (PTFs); producing, based on the waveform, a servo detect pulse that indicates a detection of at least one of the SSMs; controlling a first adjustment of a phase of a write clock signal, the first adjustment being responsive to the servo detect pulse; producing, based on the write clock signal, samples of the waveform that correspond to the PTFs; and controlling second adjustments of the phase based on the samples to align the write clock signal with at least a portion of the data positions, the second adjustments being responsive to the PTFs, respectively.

Abstract: Synchronization technologies for disk drives are described. A described technique includes producing signals that include processing a waveform produced by a read head operated with respect to a recording medium including magnetic data positions arranged on tracks including first and second tracks; producing, based on the waveform, a servo detect pulse that indicates a detection of servo data on the first track; measuring a timing difference that is based on the servo detect pulse and a write pulse of a write clock signal; controlling an adjustment of a phase of the write clock signal based on the timing difference to align the write clock signal with at least a portion of the data positions; and controlling a write head to write to one or more data positions of the second track based on the write clock signal while a servo clock signal is servo locked on the first track.

Abstract: The present disclosure describes systems and methods for controlling synchronization of a servo clock by tying the triggering of the gate signal of the position error signal field of the short servo wedge portion directly to the synchronization marker in the full servo wedge. The systems and methods described herein include controlling synchronization of a servo clock for reading servo information from a disk that is rotating relative to a read head. The systems and methods may include estimating a gate delay corresponding to a position error signal (PES) field in a short null servo wedge based, at least in part, on the location of the servo synchronization marker. The systems and methods include producing a servo clock timing control signal based on the estimated gate delay, and applying the servo clock timing control signal to the servo clock.

Abstract: In a disk storage system, the disk may include a full null servo position error signal (“PES”) wedge, followed by a data wedge, and then a short null servo PES wedge. To improve the accuracy with which information read from the short null servo PES wedge can be used to help keep the read head centered over the information track being read, the short null servo PES wedge may include a calibration field. Information read from the calibration field can be used to compensate the subsequently read PES information in the short wedge for possible sampling phase error that may have accumulated since the full null servo PES wedge was read. This type of short null servo PES wedge also has other possible uses.

Abstract: In one aspect, systems, apparatuses and techniques obtain, through read circuitry, timing information for a machine-readable medium to determine head position; and write, by write circuitry, a first set of spiral servo reference tracks at a first frequency on a first zone of the medium and a second set of spiral servo reference tracks at a second, different frequency on a second zone of the medium. The second zone may be different from the first zone. Further, at least one of the first and second sets of spiral servo reference tracks may be written to the medium based on at least the timing information.

Abstract: Some of the embodiments of the present disclosure provide a disk drive system comprising a disk drive system comprising a disk having a track upon a surface of the disk, the track including a first data-storing sector and a second data storing sector, and a servo sector located between the first data-storing sector and the second data-storing sector, the servo sector including a first flying height (FH) field having a predetermined pattern. Other embodiments are also described and claimed.

Abstract: The present disclosure includes systems and techniques relating to control of magnetic recording devices, such as disk drives. A described technique includes receiving a waveform produced by a read head operated with respect to a recording medium and a servo clock signal. A medium can include magnetic data bit cells, a first servo wedge, a second servo wedge, and phase tracking fields, where at least a portion of the phase tracking fields are arranged between the first servo wedge and the second servo wedge. The servo wedges can include respective servo sync marks. The technique includes producing, based on the waveform, a servo detect pulse that indicates a detection of a servo sync mark. The technique includes controlling a first adjustment of a phase of a write clock signal, the first adjustment being responsive to the servo detect pulse. The technique includes producing, based on the write clock signal, samples of the waveform that correspond to phase tracking fields.

Abstract: The present disclosure includes systems and techniques relating to control of magnetic recording devices, such as disk drives. A described technique includes producing signals that include a write clock signal and a servo clock signal, processing a waveform produced by a read head operated with respect to a recording medium, which includes magnetic bit cells arranged on tracks, and the servo clock signal. The technique includes producing, based on the waveform, a servo detect pulse that indicates a detection of servo data, measuring a timing difference that is based on the servo detect pulse and a write pulse of the write clock signal, and controlling an adjustment of a phase of the write clock signal based on the timing difference to align the write clock signal with at least a portion of the bit cells.

Abstract: In a disk storage system, the disk may include a full null servo position error signal (“PES”) wedge, followed by a data wedge, and then a short null servo PES wedge. To improve the accuracy with which information read from the short null servo PES wedge can be used to help keep the read head centered over the information track being read, the short null servo PES wedge may include a calibration field. Information read from the calibration field can be used to compensate the subsequently read PES information in the short wedge for possible sampling phase error that may have accumulated since the full null servo PES wedge was read. This type of short null servo PES wedge also has other possible uses.

Abstract: Some of the embodiments of the present disclosure provide a disk drive system comprising a disk drive system comprising a disk having a track upon a surface of the disk, the track including a first data-storing sector and a second data storing sector, and a servo sector located between the first data-storing sector and the second data-storing sector, the servo sector including a first flying height (FH) field having a predetermined pattern. Other embodiments are also described and claimed.

Abstract: In a disk storage system, the disk may include a full null servo position error signal (“PES”) wedge, followed by a data wedge, and then a short null servo PES wedge. To improve the accuracy with which information read from the short null servo PES wedge can be used to help keep the read head centered over the information track being read, the short null servo PES wedge may include a calibration field. Information read from the calibration field can be used to compensate the subsequently read PES information in the short wedge for possible sampling phase error that may have accumulated since the full null servo PES wedge was read. This type of short null servo PES wedge also has other possible uses.

Abstract: Some of the embodiments of the present disclosure provide a disk drive system comprising a disk drive system comprising a disk having a track upon a surface of the disk, the track including a first data-storing sector and a second data storing sector, and a servo sector located between the first data-storing sector and the second data-storing sector, the servo sector including a first flying height (FH) field having a predetermined pattern. Other embodiments are also described and claimed.

Abstract: Some of the embodiments of the present disclosure provide a disk drive system comprising a disk drive system comprising a disk having a track upon a surface of the disk, the track including a first data-storing sector and a second data storing sector, and a servo sector located between the first data-storing sector and the second data-storing sector, the servo sector including a first flying height (FH) field having a predetermined pattern. Other embodiments are also described and claimed.

Abstract: A hard disk control system comprises a phase adjust module, an offset adjust module, and a read/write timing module. The phase adjust module generates a phase adjust signal based on a phase difference between a first repeatable run out (RRO) field and a servo wedge field. The offset adjust module outputs a position calibration pattern to a storage medium based on the phase adjust signal; receives at least a portion of the position calibration pattern from the storage medium; and determines an offset based on a comparison between the output position calibration pattern and the received portion of the position calibration pattern. The read/write timing module determines a position to write a second RRO field on the storage medium based on the offset.

Abstract: A hard disk drive system includes a control module that generates a phase offset signal for a repeatable run out (RRO) field of a servo wedge based on an RRO phase of the RRO field and a data phase of data in at least one other servo wedge field of a previously written wedge. A read/write channel module adjusts a clock phase based on the phase offset signal.

Abstract: A hard disk drive system includes a control module that generates a phase offset signal for a repeatable run out (RRO) field of a servo wedge based on an RRO phase of the RRO field and a data phase of data in at least one other servo wedge field of a previously written wedge. A read/write channel module adjusts a clock phase based on the phase offset signal.