Guided servo writing for data storage media

Information

  • Patent Grant
  • 6795267
  • Patent Number
    6,795,267
  • Date Filed
    Tuesday, December 11, 2001
    23 years ago
  • Date Issued
    Tuesday, September 21, 2004
    20 years ago
Abstract
The invention presents techniques for marking data storage media and responding to disturbances in the marking process. In one embodiment, the invention presents a system that uses a laser to emit a beam to ablate physical marks in a data storage medium. The system includes a sensor such as an optical sensor, configured to detect the position of the data storage medium and to generate a position signal as a function of the position of the data storage medium. An optical device, controlled by an actuator, directs the beam from the laser to an ablation site on the data storage medium as a function of the position signal.
Description




TECHNICAL FIELD




The invention relates to data storage media and, more particularly, to techniques for marking data storage media.




BACKGROUND




Magnetic media are a popular form of data storage media, and are used for storage and retrieval of data. Magnetic media come in many forms, such as magnetic tape and magnetic disks. A write/read head assembly, which includes one or more write/read transducer heads, writes data to and reads data from the magnetic medium. The data stored on the medium are usually organized into “data tracks,” and the transducer heads write data to and read data from the data tracks.




Data tracks on magnetic tape are generally parallel to each other, and often are oriented substantially longitudinally on the tape. The head assembly is usually oriented transverse to the path of the magnetic tape so that the transducer heads move transversely across the width of the tape to access the tracks. On a magnetic disk, the data tracks are generally arranged as concentric circles or a spiral pattern on the disk, and the head assembly typically moves along a radius of the disk to access the tracks.




For efficient reading and writing, a transducer head must be accurately positioned to read from or write to a particular data track. A servo control loop typically is provided to control the positioning of the head relative to the data tracks. The medium often includes specialized tracks, called “servo tracks,” to serve as references or landmarks for the servo. Data tracks can be located on the magnetic medium according to the displacement of the data tracks from one or more servo tracks.




Servo tracks may include magnetic markers, in which case the surface of the medium is homogeneous but the servo track can be detected magnetically. Another type of servo track is a physical mark on the medium, such as a groove. With this type of servo track, the medium surface is not homogeneous but is physically altered at the site of the servo track. Servo tracks of the latter type can be detected optically. The groove may be discontinuous, allowing an optical sensor to detect a groove signal when a groove is sensed and a reference signal when the groove is absent.




Because servo tracks serve as markers, it is important that the servo tracks be placed on the medium with precision and accuracy. For example, servo tracks on magnetic tape are typically straight and servo tracks on a magnetic disk are nearly perfect circles. A deviation from the ideal shape of a servo track may compromise the effectiveness of the servo track as a marker.




SUMMARY




The invention is directed to techniques for creating tracks, such as physical or magnetic marks, on a data storage medium such as magnetic tape. The physical marks can be used, for example, as servo tracks, and can be detected optically.




The invention will be described in reference to magnetic tape, but the invention is not limited to that particular data storage medium. The invention may be applied for use with other magnetic and optical data storage media.




In one embodiment, the invention presents a system that includes one or more sensors, such as edge detectors, that detect the position of a data storage medium. The system also includes a marking device that marks a track on the data storage medium, such as a laser that ablates a physical track. The system further includes an actuator that causes the marking device to mark the track as a function of the position detected by the sensor. The data storage medium may be a magnetic storage medium, but the invention encompasses other data storage media as well.




In another embodiment, the system presents a method, which includes moving a data storage medium past a marking device, sensing the position of the data storage medium and marking a track in the data storage medium as a function of the sensed position. Sensing the position of the data storage medium may include, for example, sensing an edge of the data storage medium. Marking a track in the data storage medium may include, for example, ablating a track in the data storage medium with a laser.




In a further embodiment, the system presents a method, which comprises receiving a position signal indicative of the position of a data storage medium and generating a control signal as a function of the position signal. A marking device marks a track in the data storage medium as a function of the control signal. This method may also employ feedback and/or feed-forward techniques to direct the marking, which may be performed by ablating with a laser beam.




The details of one or more embodiments of the present invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the present invention will be apparent from the description and drawings, and from the claims.











DESCRIPTION OF THE DRAWINGS





FIG. 1

is a diagram of an ablative laser servo writer.





FIG. 2

is a diagram of a feedback system that may be employed by the servo writer.





FIG. 3

is a diagram of a feedback/feed-forward system that may be employed by the servo writer.











DETAILED DESCRIPTION





FIG. 1

is a diagram of an ablative laser servo writer


10


for creating physical marks on a data storage medium such as magnetic medium


12


. The embodiment shown in

FIG. 1

is for exemplary purposes, and the invention is not limited to the creation of physical marks with a laser. The techniques of the invention may be adapted to marking of magnetic media with marking devices other than a laser-based device. Although the embodiment shown in

FIG. 1

makes physical grooves in magnetic medium


12


, the invention is not limited to the making of physical marks such as grooves.




The physical marks may be used as servo tracking. Magnetic medium


12


, shown in

FIG. 1

as a segment of magnetic tape, moves longitudinally through servo writer


10


, guided by guides


14


and


16


. Guides


14


and


16


may have flanges


18


and


20


, respectively. In addition, guides


14


and


16


may be tapered to urge magnetic medium


12


against a flange.




Reference numeral


22


shows the direction of longitudinal motion of magnetic medium


12


. The position of magnetic medium


12


is sensed with detectors


24


,


26


,


28


,


30


,


32


and


34


. Detectors


26


,


30


and


34


sense the position of far edge


36


, and detectors


24


,


28


and


32


sense the position of near edge


38


.




Detectors


24


,


26


,


28


,


30


,


32


and


34


send position signals to processor


40


. Position signals from detectors


24


,


26


,


28


,


30


,


32


and


34


allow processor


40


to compute the location of magnetic medium


12


with respect to servo writer


10


. In addition, monitoring changes in the position signals with respect to time may allow processor


40


to compute the velocity and/or acceleration of magnetic medium


12


with respect to servo writer


10


. In addition, the velocity and/or acceleration of magnetic medium


12


may be computed in terms of the longitudinal and transverse components of velocity and/or acceleration. Velocity may be determined by taking the derivative of position with respect to time, and acceleration may be determined by taking the derivative of velocity with respect to time.




Alternatively, one or more dedicated velocity sensors (not shown in

FIG. 1

) may transmit velocity signals to processor


40


, providing processor


40


with signals indicative of the longitudinal and transverse velocity of magnetic medium


12


. Position and acceleration may be determined as a function of velocity. As used herein, the term “position signals” encompasses all of these quantities, including signals reflecting any of the position, velocity or acceleration of magnetic medium


12


.




Processor


40


regulates ablative laser


42


by controlling, for example, the power pulse width, the dwell time and/or the duty cycle of a beam emitted by ablative laser


42


. Laser


42


may be any of a number of lasers, such as a double Yd:YAG delivering 400 milliwatts of power at an approximate wavelength of 532 nm. In addition, processor


40


may position ablative laser


42


with respect to magnetic medium


12


. Processor


40


also generates a signal that controls actuator


44


, which in turn controls optical device


46


. Optical device


46


directs the laser beam to a particular site upon the surface of magnetic medium


12


and the laser beam performs the ablation. As will be described below, actuator


44


may generate a signal received by processor


40


.




The surface of magnetic medium


12


receiving the ablation may be the recording surface or the non-recording surface. The width, depth and number of servo tracks may depend upon the recording format of magnetic medium


12


. In 0.25 inch (6.35 mm) magnetic tape, for example, typical servo tracks may be about two micrometers wide by about forty micrometers long by about one-quarter micrometer deep, and spaced on a longitudinal pitch of about 130 micrometers and a transverse (lateral) pitch of about twenty micrometers, providing a data track pitch of about five micrometers.




Servo writer


10


may include dedicated optical detector


48


that senses, for example, the shape and intensity of the laser beam. Optical detector


48


may be used to calibrate actuator


44


and optical device


46


. In addition, servo writer


10


may include actuator position sensor


50


, which senses the position of the beam during the marking process. A beam position signal may be provided to processor


40


to correct for errors in the position of the beam. Actuator position sensor


50


may be embodied, for example, in a glass scale or an interferometer. Servo writer


10


may further include a detector


52


that monitors the position and quality of the ablated servo tracks, after the tracks are formed. Detector


52


may provide a quality-position signal to processor


40


.




Optical device


46


may comprise a focusing apparatus, such as a focusing lens modulated by a signal from a transducer included in actuator


44


, such as a piezoelectric transducer, a microelectromechanical systems (MEMS) transducer or a voice coil. Optical device


46


may also include movable flat or curved mirrors that direct the laser beam.




Using position signals from detectors


24


,


26


,


28


,


30


,


32


and


34


, processor


40


may bring the laser beam to bear with precision upon almost any site upon the surface of magnetic medium


12


. Processor


40


may direct the laser beam by performing coarse positioning of ablative laser


42


and/or by performing fine adjustments with actuator


44


and optical device


46


.




Although

FIG. 1

shows six detectors


24


,


26


,


28


,


30


,


32


and


34


, more or fewer detectors may be used. The use of six detectors, however, provides more accuracy than using fewer detectors. Detectors


24


,


26


,


28


and


30


, placed before and after guide


14


, monitor the position of magnetic medium


12


as magnetic medium


12


engages guide


14


. In addition, detectors


24


and


26


may detect anomalies on edges


36


and


38


before those anomalies come in contact with guide


14


, providing data to processor


40


that allows processor


40


to anticipate transverse motion as well. Detectors


28


,


30


,


32


and


34


, placed before and after the ablation operation, are useful in bi-directional ablation, in which magnetic medium


12


moves not only in longitudinal direction


22


but in the opposite direction as well.




Detectors


24


,


26


,


28


,


30


,


32


and


34


sense the transverse motion and rotation of magnetic medium


12


. Position signals from detectors


24


,


26


,


28


,


30


,


32


and


34


, with beam position signal from actuator position sensor


50


, are used by processor


40


and actuator


44


to determine the actual position of magnetic medium


12


relative to the beam. Position signals from detectors


24


,


26


,


28


,


30


,


32


and


34


, in conjunction with beam position signal from actuator position sensor


50


, are further used to correct for errors in the position of the servo marks that may be caused by transverse motion and/or rotation of magnetic medium


12


. By placing detectors on both sides of ablative laser


26


, the position of magnetic medium


12


may be measured before magnetic medium


12


reaches laser


26


, regardless of the direction in which magnetic medium


12


is moving.




Detectors


24


,


26


,


28


,


30


,


32


and


34


may detect positions of edges


36


and


38


optically. Optical detectors may include a source of light, such as a light emitting diode or laser, and a detector, such as a photodiode. The photodiodes detect the light and to generate a signal based upon the detected light. Magnetic medium


12


may block a portion of the light causing the signal from the photodiodes to vary according to the amount of blockage. The signal from the detectors may therefore be a function of the position of an edge of magnetic medium


12


.




Another form of optical detection may be employed when pilot marks have been placed upon magnetic medium


12


. Pilot marks serve as guides for placement of further marks and may, for example, be created by laser ablation. In such a case, detectors


24


,


26


,


28


,


30


,


32


and


34


may detect the marks by shining light on magnetic media


12


and detecting light transmitted through the pilot mark or reflected by the pilot mark. Pilot marks may be created by laser ablation, and in the finished product may function as servo tracks. Techniques described herein may be used to create the pilot marks. When creating pilot marks, other techniques for sensing the position of magnetic medium


12


, such as optical edge detection, may be employed.




Detectors


24


,


26


,


28


,


30


,


32


and


34


may sense the position of magnetic medium


12


in non-optical ways as well. For example, detectors


24


,


26


,


28


,


30


,


32


and


34


may be magnetic detectors that sense an edge of magnetic medium


12


or the presence and location of one or more magnetic pilot tracks placed upon magnetic medium


12


.




Calculating the position, velocity and/or acceleration of magnetic medium


12


is performed continually as magnetic medium


12


moves with respect to servo writer


10


. The path of magnetic medium


12


may be regulated in several ways. The path of magnetic medium


12


in the form of tape, for example, can be controlled by precise positioning of reels that dispense or take up the tape, or by steering magnetic medium


12


with flanges


18


and


20


on guides


14


and


16


.




Although the path of magnetic medium


12


may be regulated, in practice disturbance of magnetic medium


12


is likely to occur in spite of these measures. The disturbance may displace magnetic medium


12


from its ideal intended path. Typically, the displacement is transverse, i.e., perpendicular to direction of longitudinal motion


22


.




Disturbances may be caused by countless factors, such as debris on magnetic medium


12


, debris on guide


14


or


16


, slippage of magnetic medium


12


on guide


14


or


16


, or defects in a reel that dispenses or takes up magnetic medium


12


. A defect in an edge of magnetic medium


12


, for example, may cause a transverse disturbance when the defect engages flanges


18


.




A disturbance may disrupt accurate and precise placement of the ablative marks. For ablative marks that function as servo tracks, the disruption of accurate and precise placement is highly undesirable. In many cases, servo tracks are simply assumed to be straight marks at known locations, allowing data tracks to be located by reference to the servo tracks. If a disturbance has caused a deviation in the straightness of a servo track, the usefulness of the servo track may be compromised. During usage of the magnetic media


12


, deviations in a servo track may cause mistracking errors to occur.




The invention presents techniques for dynamically compensating for disturbances. Processor


40


receives media position signals from detectors


24


,


26


,


28


,


30


,


32


and


34


. Processor


40


also receives a beam position signal actuator position sensor


50


. With the media and beam position signals, processor


40


compensates for disturbances by regulating optical device


46


. By regulating optical device


46


, processor


40


redirects the laser beam relative to magnetic medium


12


to compensate for transverse motions of magnetic medium


12


.




Generally speaking, a disturbance may be a low-frequency disturbance or a high-frequency disturbance. A low-frequency disturbance is one that causes a slower and more gradual change, and a high-frequency disturbance is one that causes a more rapid change. By selecting optical device


46


for rapid adjustability, servo writer


10


can respond quickly to detected transverse motions and can dynamically compensate for both low- and high-frequency disturbances.




Processor


40


may also dynamically compensate for disturbances by, for example, adjusting the position of ablative laser


42


with respect to magnetic medium


12


. Because of the size and mass of laser


42


, the technique of dynamic compensation of optical device


46


may be a more practical technique for responding to high-frequency disturbances. Optical device


46


tends to be less massive and easier to move than laser


42


.




Similarly, processor


40


may also dynamically compensate for disturbances by adjusting the position of magnetic media


12


by, for example, adjusting the position of guides


14


and


16


. Dynamically compensating for disturbance with optical device


46


, however, may be more practical, especially for responding to high-frequency disturbances.




Dynamic compensation with optical device


46


may also be employed when ablative laser


42


is used to form multiple tracks on magnetic medium


12


simultaneously. One or more beam splitters (not shown in

FIG. 1

) may be used to generate a plurality of laser beams. Each laser beam may be individually directed by a dedicated actuator and/or optical device, allowing for several marks in magnetic medium


12


to be created simultaneously.





FIG. 2

shows a block diagram illustrating compensation performed by servo writer


10


using a negative feedback system


60


. Processor


40


may be programmed to create a mark at a specific site on magnetic medium


12


. In other words, the ideal position of magnetic medium


12


with respect to the beam (


62


) may be a programmed parameter, embodied as an ideal position signal. The specific site for a mark may be specified, for example, with respect to an edge of magnetic medium


12


.




The actual position of magnetic medium


12


with respect to the beam (


68


) is sensed by detectors


24


,


26


,


28


,


30


,


32


,


34


,


48


and


50


. Processor


40


determines the actual position of magnetic medium


12


with respect to the beam (


68


) from the medium position signals and the beam position signal. Processor


40


may take the difference (


64


) between the ideal position of magnetic medium


12


with respect to the beam (


62


) and actual position of magnetic medium


12


with respect to the beam (


68


), as determined from medium and beam position sensing.




Taking the difference results in the generation of a correction signal (


66


). Correction signal (


66


) drives actuator


44


, which in turn controls optical device


46


(not shown in FIG.


2


). Actuator


44


adjusts optical device


46


to bring the actual position (


68


) in line with the ideal position of the beam (


62


), thereby driving correction signal (


64


) to zero.




Response to some high-frequency disturbances may be improved by use of a feedback/feed-forward system


80


shown in FIG.


3


. Feedback/feed-forward system


80


uses many of the same components as feedback system


60


, but the systems are shown in separate figures for clarity. As in feedback system


60


, the ideal position of magnetic medium


12


with respect to the beam (


82


) is a programmed parameter. The actual position of magnetic medium


12


with respect to the beam (


88


) is sensed by detectors


24


,


26


,


28


,


30


,


32


,


34


,


48


and


50


.




Unlike feedback system


60


, feedback/feed-forward system


80


includes adaptive estimator


90


, which may be a component of processor


40


. Adaptive estimator


90


receives media position signals and beam position signals. Adaptive estimator


90


may also receive signals from actuator


44


, indicating, for example, the current operation of actuator


44


, such as the state of actuator


44


. The signal from actuator


44


may be used by adaptive estimator


90


to estimate, for example, the expected response time of actuator


44


.




When a disturbance occurs, adaptive estimator


90


estimates impending motion of magnetic media


12


, and what actuator


44


may do to compensate for the disturbance. Adaptive estimator


90


generates a signal that is added or subtracted (


84


) from the ideal position (


82


) by processor


40


to generate a correction signal (


86


) that drives actuator


44


.




Adaptive estimator


90


may, for example, introduce a delay, thereby preventing actuator


44


from responding to a disturbance before the disturbance reaches the point where ablation is taking place. The amount of delay may depend, for example, upon the distance from the detecting sensor to laser


42


, the longitudinal speed of magnetic medium


12


, and the response time needed by actuator


44


to compensate for errors caused by the disturbance.




In some circumstances, adaptive estimator


90


may generate a signal to counteract a negative feedback signal generated in negative feedback system


60


. In other circumstances, adaptive estimator


90


may anticipate that actuator


44


may need to begin compensating for the disturbance before the disturbance arrives at the point where ablation is taking place, and may generate a correction signal accordingly. As a result, the correction signal (


86


) drives actuator


44


to respond ahead of the disturbance.




A number of embodiments of the invention have been described. Nevertheless, various modifications may be made without departing from the scope of the invention. Although the example provided above demonstrated the applicability of the invention to magnetic media in the form of magnetic tape, the invention is not limited to magnetic tape. In particular, the invention can be adapted to provide a physical servo track on any magnetic medium, such as a disk or a drum.




Moreover, the invention is not strictly limited to techniques involving magnetic storage media. The invention may be used, for example, to generate physical marks on other forms of data storage media, such as laser optical tape. The invention is not strictly limited to techniques for forming physical marks, nor is the invention strictly limited to techniques for forming physical marks with a laser and an optical device. The techniques for responding to disturbances in the medium may be applied to any of a number of media and marking devices, such as a magnetic recording head that makes magnetic marks on a magnetic medium. The actuator need not control an optical device as described above, but may control another device that regulates placement of marks from a marking device, such as a servomechanism that moves a magnetic recording head.




The invention may be used with data storage media that have been cut to final dimensions. The invention may also be used, however, to create marks on stock media, i.e., media that has not been cut to final dimensions.




Moreover, although the invention is useful for making servo tracks, the marks made by the invention may serve other purposes as well. One such purpose is that of pilot marks, as discussed above, and another potential application is the creation of a set of marks or rulings having the property of a diffraction grating.




Furthermore, actuator position sensor


50


is depicted in

FIG. 1

as an element separate from actuator


44


and processor


40


. The invention includes embodiments in which actuator position sensor


50


is included in actuator


44


or processor


40


. These and other embodiments are within the scope of the following claims.



Claims
  • 1. A system comprising:a sensor that detects the position of a data storage medium relative to the system; a marking device that marks a track on the data storage medium; and an actuator that causes the marking device to mark the track as a function of the position detected by the sensor.
  • 2. The system of claim 1, wherein the data storage medium is a magnetic storage medium.
  • 3. The system of claim 2, wherein the magnetic storage medium is magnetic tape.
  • 4. The system of claim 1, wherein the data storage medium is an optical storage medium.
  • 5. The system of claim 1, wherein the marking device comprises a laser that emits a beam to ablate the track in the data storage medium.
  • 6. The system of claim 5, wherein the marking device further comprises an optical device that directs the beam from the laser to an ablation site on the data storage medium.
  • 7. The system of claim 6, wherein the optical device includes a lens.
  • 8. The system of claim 6, wherein the optical device includes a mirror.
  • 9. The system of claim 1, wherein the marking device comprises a magnetic recording head.
  • 10. The system of claim 1, further comprising an actuator position sensor that detects the position of the mark relative to the system.
  • 11. The system of claim 1, wherein the sensor is one of an optical sensor and magnetic sensor.
  • 12. The system of claim 1, wherein the sensor detects the position of the data storage medium by detecting an edge of the data storage medium.
  • 13. The system of claim 1, wherein the actuator includes one of a piezoelectric transducer, a microelectromechanical system, and a voice coil.
  • 14. The system of claim 1, wherein the sensor generates a position signal as a function of the position of the data storage medium relative to the system, and wherein the actuator drives the marking device as a function of the position signal.
  • 15. The system of claim 14, further comprising a processor configured to receive the position signal and to generate a control signal that controls the actuator.
  • 16. The system of claim 15, wherein the processor comprises an adaptive estimator that receives the position signal and generates an adaptive signal, and the control signal is a function of the adaptive signal.
  • 17. A method comprising:moving a data storage medium past a marking device; sensing the position of the data storage medium; and marking a track in the data storage medium as a function of the sensed position, wherein the track is one of a servo track, a pilot mark, and a diffraction ruling.
  • 18. The method of claim 17, wherein sensing the position of the data storage medium comprises sensing an edge of the data storage medium.
  • 19. The method of claim 17, wherein marking a track in the data storage medium comprises ablating a track in the data storage medium with a laser.
  • 20. The method of claim 17, further comprising:generating a position signal as a function of the position of the data storage medium; and marking the track in the data storage medium as a function of the position signal.
  • 21. The method of claim 20, further comprising:generating a correction signal as a function of the position signal and an ideal position signal; and marking the track in the data storage medium as a function of the correction signal.
  • 22. The method of claim 17, further comprising cutting the data storage media to final dimensions following marking.
  • 23. A method comprising:receiving a position signal indicative of the position of a data storage medium; and generating, as a function of the position signal, a control signal for control of a marking device that marks a track in the data storage medium.
  • 24. The method of claim 23, further comprising differentiating the position signal to generate a velocity signal.
  • 25. The method of claim 24, further comprising generating the control signal as a function of the velocity signal.
  • 26. The method of claim 23, further comprising:receiving an ideal position signal, the ideal position signal indicative of the ideal position of the data storage medium; receiving an actuator signal, the actuator signal indicative of the operation of an actuator that directs the marking device; and generating a driving signal as a function of the ideal position signal and the actuator signal.
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