JP3650316B2 - Data recording apparatus and control method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to detection of pre-recorded servo track positioning information. In particular, the present invention relates to tracking a track by detecting servo track positioning information from a servo track having at least two edges. Where each of the edges is between two different pre-recorded servo signals. Configure the boundary (hereinafter referred to as the interface) The servo reproduction element reproduces to enable positioning of the servo reproduction element and the corresponding data head.
[0002]
[Prior art]
U.S. Pat. No. 5,448,430 shows a servo track applied to a magnetic track following servo system. U.S. Pat. No. 5,844,814 shows an independent position detector in a head positioning system.
[0003]
In the data storage industry, increasing the data storage capacity of existing data storage media is part of the technological advancement. One means of increasing the data storage capacity of data storage media such as magnetic tape cartridges or magnetic tape cassettes is to increase the track density of the data storage media. This corresponds to reducing the width of each track.
[0004]
A typical magnetic tape records data on a plurality of parallel and long data tracks. The data head can comprise a plurality of data heads with fewer recording / playback elements than tracks. Data tracks are divided into groups and are usually interleaved. The data head is indexed laterally to the track so that each group of data tracks can be accessed. In order to properly position the data head in the data track, a pre-recorded servo track parallel to the data track is provided. A servo reproducing head located at an indexed position relative to the reproducing / recording element reproduces the servo track. The servo track has lateral positioning information. This lateral positioning information can be decoded and reproduced by the servo reproducing head to indicate whether or not the servo reproducing head is correctly positioned with respect to the servo track. Therefore, the servo head can be moved laterally to a desired position relative to the servo track so that the playback / recording element can be properly positioned relative to the desired group of data tracks. Thus, as the media and head move longitudinally relative to each other, the servo head can follow the servo track. As a result, the playback / recording element can maintain alignment with the data track.
[0005]
As an example, pre-recorded servo track positioning information consists of adjacent servo tracks with different servo patterns. One of the servo patterns consists of a single first frequency constant amplitude signal. The other servo pattern then alternates between a single second frequency constant amplitude burst signal and a zero amplitude empty signal. The interface between adjacent servo signals is called an “edge”. The resulting signal reproduced by the servo head is a maximum signal consisting of a combination of a first frequency signal and a second frequency burst signal, and a minimum consisting of a combination of a first frequency signal and a null signal. Signal. When the servo head is correctly positioned at the junction of adjacent servo tracks, the amplitude of the signal combining the first frequency signal and the second frequency signal is the first frequency signal and the null signal. Is twice the amplitude of the combined signal. U.S. Pat. No. 5,448,430 shows the servo pattern described above and describes a track following servo positioning system that uses peak detection to determine the maximum and minimum signals.
[0006]
As data capacity increases, it is also desirable to have backward compatibility to data media with conventional levels of data capacity to avoid the need to copy all the data recorded on conventional media to a new medium. It is supposed to be.
[0007]
[Problems to be solved by the invention]
It is an object of the present invention to increase the track density of a data storage medium while using conventional medium servo tracks. As a result, the servo system can be operated with conventional track positioning information for conventional media, and more with high track density tracks using the same servo track positioning information. It can be accessed in precise form.
[0008]
[Means for Solving the Problems]
Disclosed is a servo position detector and method for detecting servo positioning for an index position displaced by a certain offset relative to a servo track. The servo track has at least two edges. Each edge consists of an interface between two different recorded servo signals. The edge is located on the opposite side of the central recorded servo signal. The edges are separated by a predetermined distance.
[0009]
The detector consists of a servo regenerative element with an active detection area. The active sensing area does not exceed a predetermined distance separating the edges and is substantially equal to this entire distance. Thus, this causes the servo playback element to detect two of the different recorded servo signals on one of the edges. A logic circuit connected to the servo reproduction element compares two detected servo signals to determine a ratio between them, and determines an error between the compared ratio of the detected servo signals and a predetermined ratio. To do. The predetermined ratio is A value that is offset by a predetermined value in a predetermined direction from the amplitude ratio when the center is at the edge. Identify the index position. The index position is substantially parallel to the edge and displaced from the edge.
[0010]
The logic circuit outputs an output signal related to a predetermined error. The output signal identifies the servo position error relative to the index position.
[0011]
In a further example of the present invention, a servo track following apparatus and method for detecting and following a servo index position associated with a servo track is disclosed. A servo positioning device is connected to the logic circuit, which moves the servo reproduction element in a direction that reduces the servo position error.
[0012]
In another example of the invention, if there are a total of four index positions, i.e. one index position on each side of an edge, the displacement of the index position from one edge is a predetermined separation of the edges. Is substantially equal to ¼ of the distance. In another example, the edge is used as in the prior art, and the index position is further displaced by substantially 1/3 of the predetermined distance separating the edges for a total of six index positions. It has. The distance of the active sensing area of the servo reproduction element consists of a value between substantially 80% and substantially 100% of the predetermined distance separating the edges.
[0013]
In yet another example of the present invention, a plurality of servo playback elements are spaced apart to detect servo positioning with respect to a plurality of spaced apart servo tracks. Two different signals are detected at each edge to be detected. The logic circuit further averages the corresponding two detected different signals of each of the plurality of servo playback elements and determines an error between the compared ratio of the averaged different servo signals and a predetermined ratio.
[0014]
In yet another example of the present invention, an independent position detector is further provided to detect the coarse position of the servo reproduction element relative to the reference. The coarse position indicates which of the servo track edges are aligned and detected by the servo playback element. Furthermore, the logic circuit uses the coarse position to identify a predetermined index position and select a predetermined ratio.
[0015]
The input receives an input signal. A logic circuit is connected to the input. In response to the received input signal, the logic circuit determines the identified index position and selects a predetermined ratio indicative of the edge and the input index identified predetermined index position. The predetermined ratio is This is a value offset by a predetermined value in a predetermined direction from the amplitude ratio when the center is at the edge. A servo reproduction element with an active detection area extends in a direction substantially orthogonal to one of the edges and detects two of the recorded servo signals that differ on one of the edges. The independent position detector detects the current coarse position of the servo reproduction element relative to the reference. The current coarse position indicates the current one of the predetermined index positions of the servo track that are aligned and detected by the servo playback element. The logic circuit is connected to the independent position detector and the servo reproducing element. The logic circuit is responsive to the current coarse position to indicate the current index position detected by the servo playback element. In response to the current index position and the input identified index position, the logic circuit first moves the positioning servo from the current index position in the direction of the input identified position, and from among the predetermined index positions. Select the input identified one. Then, the logic circuit compares the two detected servo signals to determine a ratio between them, and selects one selected predetermined ratio from the ratio of the detected detected servo signals and a predetermined index position. The error between the ratio and the servo position error for that index position is determined. The logic circuit supplies a position error output to the positioning servo, operates the positioning servo in a direction in which the servo position error is reduced, and tracks the predetermined index position selected thereby.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
In the following description, the present invention will be described in a preferred embodiment with reference to the drawings. In the drawings, the same reference numerals indicate the same or similar components. While the invention will be described in terms of the best mode for achieving the objects of the invention, those skilled in the art will recognize that modifications can be made without departing from the spirit or scope of the invention in light of the teachings set forth herein. I'm getting.
[0017]
Referring to FIG. 1, a data storage device 10 such as a magnetic tape device is shown. One example of a magnetic tape device that can use the servo track positioning system of the present invention is the IBM 3590 magnetic tape device. A control device 12 is provided, and data signals and control signals are exchanged between the control device 12 and the host device 14 via the interface 16. Connected to the control device 12 is a memory device 18 such as a RAM (random access memory) for storing information such as predetermined values for changing or programming various values. As an example, the control device 12 can be configured by an IBM RS / 6000 processor. A multi-element magnetic tape head 20 known in the art includes a plurality of data reproducing / recording elements and a plurality of servo reproducing elements. The data reproduction / recording element records and reproduces data on the magnetic tape 22. The servo reproduction element reproduces a servo signal composed of servo track positioning information recorded in advance in a plurality of servo tracks on the magnetic tape 22.
[0018]
A tape reel motor system (not shown) of the tape drive moves the tape 22 in the longitudinal direction. Then, the servo positioning device 24 instructs the movement of the head 20 in the transverse direction, that is, the transverse direction with respect to the longitudinal direction that is the movement direction of the tape. The controller 12 is connected to a tape reel motor and controls the longitudinal direction, speed and acceleration of the tape 22.
[0019]
The data tracks on the tape 22 are arranged in parallel, and are arranged in parallel to the servo tracks. Thus, as the servo playback element tracks the servo track by the servo positioning device 24, the data playback / recording element tracks one of the parallel groups of data tracks. If it is desirable to track another parallel group of data tracks, the head 20 is indexed laterally so that the same servo playback element is aligned with another servo track. Alternatively, different servo playback elements are aligned to the same servo track or different servo tracks.
[0020]
When the head 20 is to be moved to the selected index position, the index controller 26 is enabled by the controller 12. As a result, the index controller 26 receives the coarse position signal from the independent position detector 460 and sends the appropriate signal to the servo logic circuit 465 to select the appropriate servo track. On the other hand, the control device 12 transmits an appropriate signal to the servo gap selector 32 to select an appropriate servo reproduction element. Independent position detector 460 is described in US Pat. No. 5,844,814, and indicates the position of head 20 relative to a fixed reference. Servo logic circuit 465 operates servo positioning device 24 in accordance with the present invention to position the servo playback element on the correct servo track, as described below. The servo logic circuit 465 can be composed of a programmable ROM (PROM), ASIC, or microprocessor. The tape device 10 can be bidirectional. That is, one of the playback / recording elements is selected for movement in one direction and the other of the playback / recording elements is selected for movement in the opposite direction. Further, the control device 12 transmits a signal to the reproduction / recording gap selection device 30 to select some appropriate ones of the reproduction / recording elements. In accordance with the present invention, servo track decoder 28 decodes servo information. Then, the servo logic circuit 465 determines positioning error information, supplies the positioning error information to the servo positioning device 24, and aligns the selected servo reproduction element with the selected servo track.
[0021]
FIG. 19 shows a conventional magnetic tape format of two adjacent servo signals 47, 48 called servo “edges”. Servo edges 47, 48 are combined with servo tracks along with servo playback elements 470, 480 with active sensing areas 471, 481. The combined pre-recorded servo track consists of two different servo signals. One servo signal present in the outer tracks 40, 42 has a single first frequency (F ₁ ) With a recorded pattern of constant amplitude. The other servo signal present in the central track 44 has a single second frequency (F ₂ ) With a recorded pattern alternating between a constant amplitude burst signal 45 and a zero amplitude (0) null signal 46.
[0022]
In FIG. 19, two servo edges 47 and 48 are shown. An “edge” consists of an interface between two different servo signals. When the servo playback element matches on servo edge 47 or servo edge 48, the resulting signal played back by the servo playback element is a combination of a first frequency signal and a second frequency signal. And a minimum signal consisting of a combination of a first frequency signal and a null signal. Servo head Heart of Of adjacent tracks Among Edge above If they match correctly, When the center is on the edge Called “centered on-edge ratio”. The amplitude of the combination of the first frequency signal and the second frequency signal is twice the amplitude of the combination of the first frequency signal and the null signal. This amplitude ratio is called a 1/2 ratio. U.S. Pat. No. 5,448,430 describes a servo track pattern as described above and a track following servo positioning system that uses peak detection to determine maximum and minimum signals.
[0023]
Typically, the combined servo tracks 40-44 are equipped with servo guard bands 500, 501 to protect the outer tracks 40, 42 from noise due to the data track areas 502, 503. Prior art servo playback elements 470, 480 have the smallest possible active sensing areas 471, 481 thereby increasing the signal-to-noise ratio (S / N ratio) for peak detection.
[0024]
The prior art servo track edges 47, 48 are separated by a predetermined distance 490 employed for magnetic tape manufacturing and servo tracks. Therefore, only two index positions are allowed. Accordingly, the index positions coincide on the edges 47 and 48. Placing an additional servo playback element at the shifted position (increasing the index position) increases the data track density. As a result, other servo reproducing elements can be indexed at the increased index position. However, its capability (a set of functions logically related to the target common resource; here the maximum number of index positions) is limited by its ability to produce precisely shifted servo playback elements.
[0025]
As mentioned above, it is desirable to add a data track. A traditional approach to accomplish this is to make the servo heads more precise by making the servo (and data) tracks narrower and positioned closer together. However, it has become difficult to achieve backward compatibility to data storage media with conventional levels of data capacity using the same servo playback element. The backward compatibility is required to avoid the need to copy all the data recorded on the conventional medium to a new medium.
[0026]
Therefore, according to the present invention, as shown in FIG. 20, the data track can be positioned in a higher density arrangement without changing the servo track.
[0027]
Specifically, the combined pre-recorded servo track consists of two outer tracks 40, 42 and a central track 44. The outer tracks 40, 42 have a single first frequency constant amplitude recorded pattern. The central track 44 realizes two servo edges 47 and 48 alternately between a recorded pattern of a constant amplitude burst signal and a recorded pattern of a zero amplitude empty signal. The edges 47, 48 are separated by a predetermined distance 490. However, this time the data tracks are aligned so that the servo reproduction element is displaced from the edges 47, 48 so that a high track density can be achieved. For example, the displaced arrangement can be arranged along dashed lines 55-58. Dashed lines 55-58 are spaced from servo edges 47, 48 in both directions by about 1/4 of the width of central track 44. As a result, four index positions are realized. In order to position the data reproducing / recording element at the index positions of “0” and “3”, the servo reproducing element needs to be arranged at the position 505 or the position 508. As a result, the servo reproducing element can reproduce the minimum signal having an amplitude of about 3/4 of the maximum signal. In order to position the data reproducing / recording element at the index positions “1” and “2”, the servo reproducing element needs to be arranged at the position 506 or the position 507. As a result, the servo reproducing element can reproduce the minimum signal having an amplitude of about 1/4 of the maximum signal.
[0028]
As above Two Rather than track the servo edges 47, 48 of the current, four index positions 55-58 can now be tracked with a single servo playback element. As a result, the data density for the current servo track can be effectively doubled. Further, similarly to the prior art, an indexed servo reproducing element can be used. According to the present invention, the data track density can be doubled.
[0029]
Another embodiment of the present invention is shown in FIG. At the index position “0” or “1”, the servo reproduction element is positioned at a position 600 on the servo edge 47 or a position 601 on the servo edge 48. The additional index position is arranged by displacing the servo reproducing element away from the servo edge 47 or 48 in both directions from the servo edge 47 or 48 along the broken lines 612 to 615 by about 1/3 of the width of the central track. Has been. As a result, the number of index positions is 6.
[0030]
In order to position the data reproducing / recording element at the index positions of “2” and “5”, the servo reproducing element needs to be arranged at the position 602 or the position 605. As a result, the servo reproducing element can reproduce the minimum signal having an amplitude of about 5/6 of the maximum signal. In order to position the data reproducing / recording element at the index positions “3” and “4”, the servo reproducing element needs to be arranged at the position 603 or the position 604. As a result, the servo reproducing element can reproduce the minimum signal having an amplitude of about 1/6 of the maximum signal.
[0031]
Although an alternative with a plurality of index positions on both sides of one edge can be envisioned, precise amplitude ratio detection is required. The specific amplitude ratio is a function such as the distance covered by the active sensing area of the servo reproducing head.
[0032]
Referring to FIG. 20, according to the present invention, the active detection area 510 of the servo reproducing element is It is a predetermined length in a direction substantially perpendicular to the edge. And it does not exceed the predetermined distance 490 and is substantially equal to the entire predetermined distance 490. Thus, the active detection area of the servo playback element extends over a distance sufficient to detect both two different recorded servo signals at one edge, and of the different recorded servo signals Two Is detected.
[0033]
Specifically, the sensing distance 510 is greater than twice the index position displacement, and from a value between substantially 80% and substantially 100% of the predetermined distance separating the edges. Become.
[0034]
The following points are clear. That is, the minimum signal at the position 506 or the position 507 is exaggerated by any noise if it is a large noise, and the maximum signal and the minimum signal are distinguished at the position 505 or the position 508 by any noise. It becomes difficult. Thus, referring to FIG. 1, servo signal decoding is illustrated in servo track decoder 28 and FIGS. US Pat. No. 6,426,846 It is done by the method.
[0035]
FIG. 4 is a diagram showing a servo track positioning system according to the present invention in which an analog servo signal is reproduced by the servo reproducing element of the head 20. The servo track positioning system includes a servo track decoder 28, and the servo track decoder 28 includes an analog front end 65 and a digital servo track decoder 66. The analog front end 65 converts the analog servo signal into an asynchronous digital sample of the same signal, and the digital servo track decoder 66 decodes the digital sample, and the minimum and maximum signals indicated by the digital sample. Determine the amplitude of the envelope. Next, the servo positioning device 24 positions the servo reproducing element of the head 20, thereby positioning the data reproducing / recording element according to the decoded positioning information. In this manner, the servo track decoder 28 decodes the servo positioning information, supplies the positioning information to the servo positioning device 24, and aligns the selected servo reproduction element with the selected index position. As a result, the data playback / recording element can be properly aligned with the desired data track.
[0036]
FIG. 5 is a diagram showing a plurality of digital servo track decoders shown in FIG. Each of the decoders comprises an envelope tracker 70 and a minimum / maximum detector 71. An envelope tracker 70 receives asynchronous digital samples of separate servo regenerative elements from the associated analog front end on each line 72-74, respectively.
[0038]
FIGS. 6A and 6B are diagrams showing waveforms of analog signals from the servo converter at positions 61 and 63 in FIG. 3, respectively. Thus, in FIG. 6A, burst 85 and burst 86 formed from the combination of the first and second frequency bursts while the servo transducer is at position “1” in FIG. The amplitude is large. However, the burst 87 formed from the combination of the first frequency and the empty signal has a small amplitude. This is because only a small portion of the servo converter is located above the first frequency. While it is easy to distinguish between these bursts, it is difficult to accurately measure the ratio of these bursts in the presence of noise. Therefore, it is difficult to accurately detect the position of the servo converter.
[0039]
In FIG. 6B, the burst 90 and the burst 91 formed from the bursts of the first frequency and the second frequency while the servo converter is at the position “3” in FIG. 20 have a large amplitude. The same applies to the burst 92 formed from the combination of the first frequency and the null signal. This is because the servo converter is mainly located above the first frequency. It is therefore difficult to distinguish these bursts in the presence of noise. Therefore, it is difficult to accurately detect the position of the servo converter.
[0040]
In short, FIG. 4 and FIG. When you refer Since the burst amplitude is supplied after each burst is digitally distinguished, the burst ratio can be determined. In the analog front end 65, a digital servo detector asynchronously samples the signal reproduced by the servo head. When the envelope follower 70 receives an asynchronous digital sample, it detects and supplies the maximum envelope output, measures the amplitude of the maximum burst envelope of the asynchronous digital sample, and outputs the minimum envelope output. Detect and supply and measure the amplitude of the smallest burst envelope of the asynchronous digital sample.
[0041]
The “DROPOUT” threshold detector receives the asynchronous digital sample, detects the received asynchronous digital sample that does not meet the “DROPOUT” threshold related to the maximum burst envelope, and “DROPOUT” A threshold detection signal is supplied. The “ACQUIRE” detector detects the minimum envelope for the envelope detector that provides the minimum envelope output in response to the “DROPOUT” threshold detection. “DROPOUT” detection distinguishes between a minimum envelope and a maximum envelope. As a result, the minimum / maximum logic circuit 71 can measure the minimum envelope. Thus, the ratio of the measured maximum envelope amplitude output to the measured minimum envelope amplitude output indicates the lateral position of the servo head. Details of the specific embodiment of FIGS. U.S. Pat. No. 6,426,846 It is stated in.
[0042]
Further, referring to FIG. 21, a plurality of servo reproduction elements 520-522 are spaced apart in the head 20, and two different signals are detected at each of the corresponding edges of the servo tracks 525-527. The corresponding two detected different signals of each servo reproduction element are then averaged to reduce the effect of noise.
[0043]
Referring to FIGS. 1, 20 and 23, a servo logic circuit 465 connected to a servo playback element, eg, servo playback element 505, via a servo track decoder 28 compares two detected servo signals. Determine the ratio between them. The servo logic circuit 465 then determines the error between the compared ratio of the detected signals and a predetermined ratio. The predetermined ratio is When the center is at the edge Amplitude ratio or When the center is at the edge Amplitude ratio Place Fixed direction Where Definite Value only offset Value And consists of a desired and expected ratio of signals detected at one of the predetermined indexing positions being detected. As described above, in FIG. 20, the predetermined index positions 505 to 508 are all displaced from the respective edges, and in FIG. 23, the index positions 602 to 605 are displaced, and 1 / of the edge. Amplitude at offset from 2 ratios. The servo logic circuit 465 supplies an output signal related to the determined error to the servo positioning device 24. The output signal identifies a servo position error for a predetermined index position. Then, the servo logic circuit 465 moves the head 20 including the servo reproduction elements 505 to 508 or the servo reproduction elements 600 to 605 in a direction in which the servo position error is reduced, and tracks the servo index position.
[0044]
Referring to FIGS. 1 and 20, the servo signals detected at index positions 505 and 508 are the same. However, the direction in which the head 20 needs to be moved in order to position the servo reproducing element with respect to the index position is reversed. Similarly, the servo signals detected at the index positions 506 and 507 are the same. However, the direction in which the head 20 needs to be moved in order to position the servo reproducing element with respect to the indexing position is also reversed in this case.
[0045]
1 and 23, the servo signals detected at the on-edge index positions 600 and 601 are the same, the servo signals detected at the index positions 602 and 605 are the same, and detected at the index positions 603 and 604. Servo signals are the same. However, in each example, the direction in which the head 20 needs to be moved in order to position the servo reproducing element with respect to the index position is reversed.
[0046]
Referring to FIG. 1, an independent position detector 460 is provided and provides coarse positioning information. The independent position detector 460, according to US Pat. No. 5,844,814, detects the current coarse position of the head 20 relative to a reference such as a fixed point near the head 20.
[0047]
According to the present invention, the coarse positioning information can take one of two alternating levels. In one embodiment, and with further reference to FIGS. 20 and 23, the coarse positioning information of the independent position detector 460 indicates the edge 47 or 48 of the servo track that is currently aligned and that the servo playback element is detecting. ing. The index position is determined by the ratio between the two servo signals. Specifically, the servo logic circuit 465 determines the ratio, and determines which of the detected servo signals is larger from the compared ratio. In response to determining the larger servo signal, the servo logic circuit 465 determines the current predetermined index of the first displacement direction or the second displacement direction from the current edge with respect to the central servo signal of the servo track. A predetermined ratio is selected as indicating the position.
[0048]
In another embodiment, the coarse positioning information of the independent position detector 460 is obtained from the index positions 505 to 508 of FIG. 20 or the index positions 600 to 600 of FIG. 23 of the servo track that is currently aligned and detected by the servo playback element. 605 is shown.
[0049]
When the head 20 is to be moved to the selected index position, the index controller 26 is enabled by the controller 12. The index controller 26 receives the coarse position signal from the independent position detector 460 and sends an appropriate signal to the servo logic circuit 465 to select the appropriate servo track. On the other hand, the control device 12 transmits an appropriate signal to the servo gap selector 32 to select an appropriate servo reproduction element.
[0050]
The servo logic circuit 465 determines the current index position display, and in response to the input index position, the servo logic circuit 465 first inputs the servo positioning device 24 from the current index position among the four predetermined index positions. Operate in a direction toward one identified index position, thereby selecting the index position identified as input. The servo logic circuit 465 selects a predetermined ratio indicating the selected index position. The servo logic 465 then determines the error between the compared ratio and the selected ratio, and subsequently operates the servo positioning device 24 in a direction that reduces the servo position error, thereby reducing the selected index position. Follow the track.
[0051]
One embodiment of the method of the present invention is shown in FIG. Referring also to FIG. 1, at step 540, the controller 12 receives input. In step 542, the servo track decoder 28 and the servo logic circuit 465 identify and select a predetermined index position. Step 545 shows an option of averaging a plurality of servo reproducing heads or using a single servo reproducing head. This option is selected based on the compatibility of the head 20 type and the medium type. Step 545 shows information related to this compatibility.
[0052]
When only one servo reproducing element is used (“1”), the servo reproducing element is selected from among recorded servo signals different at one edge in step 547. Two Is detected. The detection step detects over a distance that is less than a predetermined distance between the edges and substantially equal to the entire distance. Specifically, when the displacement of the index position from one edge is substantially 25% of the predetermined distance separating the edges, the detection distance of the servo reproduction element is substantially 80 of the predetermined distance. % And a value between substantially 97%.
[0053]
If multiple servo playback elements are used at step 545 (">1"), each servo playback element is one of the recorded servo signals that differ at corresponding edges of the servo tracks spaced apart at step 548. of Two Is detected. Each detected different signal for the servo reproduction element is averaged in step 549. Then, at step 550, the servo track decoder 28 compares either the single different servo signal from step 547 and the averaged different servo signal from step 549 to determine the difference between the servo signals. Determine the ratio.
[0054]
In the same procedure, the independent position detector 460 independently detects the current coarse position of the servo reproduction element of the head 20 relative to the reference. The current coarse position indicates the current predetermined index position detected by the servo reproducing element in step 560, or the central servo signal of the servo track detected by the servo reproducing element in step 561. When the current edge is detected in step 561, two different servo signals (S ₁ ) And (S ₂ ) In step 565, the servo logic circuit 465 compares to determine which of the two signals is greater. Signal (S ₁ ) Or (S ₂ ) Is the current predetermined value in the first direction (step 566) or the second direction (step 567) of displacement from the current edge indicated for the central servo signal of the servo track. The direction indicating the index position is shown.
[0055]
Thus, step 560, step 566, or step 567 indicates the current predetermined indexing position detected by the servo reproduction element. In step 570, using the predetermined index position selected in step 542, if any, A value that is offset by a predetermined value in a predetermined direction from the amplitude ratio when the center is at the edge Select a predetermined ratio. In the example shown in FIG. 20, the amplitude ratio indicating the offset is substantially 3/4 indicating a displacement of 1/4 of the predetermined distance 490 when moving away from the central signal 44 in the direction of reference numeral 505 or 508. And when it leaves | separates to the direction of the code | symbol 506 or 507 from an edge inside, it is substantially 1/4 which shows the displacement of 1/4 of the predetermined distance 490. FIG. In the example shown in FIG. 23, the predetermined ratio selected in step 570 is an amplitude ratio of 1/2 with respect to the on-edge index position 600 or 601, and 1/3 of the central signal 44 in one direction. With respect to indexing positions 602 and 605 that show a displacement of a distance of approximately 5/6, and with respect to indexing positions 603 and 604 that show a displacement of 1/3 of a predetermined distance 490 inward from the edge. It consists essentially of an amplitude ratio of 1/6.
[0056]
If the servo reproduction element of the head 20 is not currently located at the selected index position, the servo logic circuit 465 first operates the servo positioning device 24 at step 575 to select the servo reproduction element at the selected index position. Move to. Steps 560, 566, or 567 are repeated until the servo playback element is correctly coarsely positioned at the selected index position.
[0057]
Once the servo playback element is roughly positioned at the selected index position, track following begins. Next, at step 580, the servo logic circuit 465 compares the compared ratio of the two servo signals detected at step 550 with the selected ratio at step 570. This comparison determines the servo position error for the selected index position. Next, the servo logic circuit 465 operates the servo positioning device 24 in step 585 to move the servo reproduction element in a direction that reduces the servo position error.
[0058]
Next, in step 547 or 548, step 550, steps 580 and 585, the selected predetermined index position is tracked.
[0059]
As described above, according to the present invention, the track density of the data storage medium can be increased while using the servo track of the conventional medium. As a result, the servo system can be operated with conventional track positioning information for conventional media, and more with high track density tracks using the same servo track positioning information. It can be accessed in precise form.
[0060]
Although preferred embodiments of the present invention have been described in detail, changes and modifications to these embodiments can be readily conceived by those skilled in the art without departing from the scope of the present invention disclosed in the claims. Is clear.
[Brief description of the drawings]
FIG. 1 is a block diagram of a magnetic tape system using the present invention.
FIG. 2 is a diagram showing a magnetic tape format of two servo index positions combined with a servo track.
FIG. 3 is a diagram illustrating a magnetic tape format employed in accordance with the present invention to achieve four servo index positions on the servo track of FIG. 2;
4 is a block diagram illustrating a servo track positioning system that decodes asynchronous digital samples of prerecorded servo track positioning information from the tape of FIG. 1 and positions playback / recording elements in accordance with the parent invention. FIG.
FIG. 5 is a block diagram of an interface that provides programmable values for the plurality of servo track decoders and servo track decoders of FIG. 4;
FIG. 6 shows an example of digital envelopes of typical analog servo signals for different positions of the servo head and analog servo signals generated by the servo track decoders of FIGS. 4 and 5 respectively. It is.
FIG. 7 is a block diagram of an embodiment of a servo track decoder of the parent invention.
FIG. 8 is a block diagram of an embodiment of a servo track decoder of the parent invention.
FIG. 9 is a block diagram of an embodiment of a servo track decoder of the parent invention.
FIG. 10 is a block diagram of an embodiment of a servo track decoder of the parent invention.
FIG. 11 is a block diagram of an embodiment of a servo track decoder of the parent invention.
FIG. 12 is a block diagram of an embodiment of a servo track decoder of the parent invention.
FIG. 13 shows a flow chart illustrating an embodiment of the method of the parent invention.
FIG. 14 shows a flow chart illustrating an embodiment of the method of the parent invention.
FIG. 15 is a flowchart showing an embodiment of the method of the parent invention.
FIG. 16 is a flowchart showing an embodiment of the method of the parent invention.
FIG. 17 is a flowchart showing an embodiment of the method of the parent invention.
FIG. 18 shows a flow chart illustrating an embodiment of the method of the parent invention.
FIG. 19 illustrates a magnetic tape format of two servo positions of a servo track with two edges and a prior art servo playback element.
20 shows a magnetic tape servo track used by the servo playback element according to the present invention to realize the four servo index positions of FIG. 3; FIG.
FIG. 21 is a diagram showing a magnetic tape having three servo track areas.
FIG. 22 shows a flow chart illustrating one embodiment of the method of the present invention.
FIG. 23 shows a magnetic tape servo track used by a servo reproducing element according to the present invention to achieve six servo index positions in the servo track of FIG. 2;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Data storage device, 12 ... Control device, 14 ... Host device, 16 ... Interface, 18 ... Memory device, 20 ... Head, 22 ... Magnetic tape, 24 ... Servo positioning device, 26 ... Indexing controller, 28 ... Servo track Decoder 30 ... Playback / Recording Gap Selector 32 ... Servo Gap Selector 460 ... Independent Position Detector 465 ... Servo Logic Circuit 40 ... Outer Track 42 ... Outer Track 44 ... Center Track 45 ... Single second frequency constant amplitude burst signal, 46 ... zero amplitude null signal, 47 ... servo edge, 48 ... servo edge, 50 ... index position, 51 ... index position, 55 ... index position, 56 ... indexing position, 57 ... indexing position, 58 ... indexing position, 500 ... servo protection band, 501 ... servo protection band 502 ... Data track area, 503 ... Data track area, 520 ... Servo playback element, 521 ... Servo playback element, 522 ... Servo playback element, 525 ... Servo track, 526 ... Servo track, 527 ... Servo track, 612 ... Indexing position, 613 ... Indexing position, 614 ... Indexing position, 615 ... Indexing position, 65 ... Analog front end, 66 ... Digital servo track decoder, 70 ... Envelope tracker, 71 ... Min / max logic Circuit, 72 ... line, 73 ... line, 74 ... line, 78 ... programmable value, 80 ... microprocessor interface, 85 ... burst, 86 ... burst, 87 ... burst, 90 ... burst, 91 ... burst, 92 ... burst .

Claims (32)

(B) The servo track is provided in parallel to the data track,
  The servo track has (a) a first edge and a second edge, and a first burst pattern signal having a constant amplitude and a null signal having a zero amplitude are alternately arranged between the first edge and the second edge. A central servo track recorded repeatedly; and (b) a second burst pattern signal having a constant amplitude provided in contact with each of the first edge and the second edge of the central servo track. A recording medium having first and second outer servo tracks recorded thereon;
  (B) An element for performing data reproduction / recording on the data track, and a servo reproduction element for detecting the first outer track and the central servo track, or the central servo track and the second outer track. A head having
  (C) head positioning means for moving the head in a direction perpendicular to the first edge and the second edge of the recording medium;
  (D) the servo reproducing element may receive the second burst pattern signal of the first outer track and the first burst pattern signal of the central servo track, or the first burst of the central servo track; Detecting a first amplitude obtained from the second burst pattern signal and the first burst pattern signal when detecting the pattern signal and the second burst pattern signal of the second outer track;
  The servo reproduction element is configured to output the second burst pattern signal of the first outer track and the empty signal of the central servo track, or the empty signal of the central servo track and the empty signal of the second outer track. Means for detecting a second amplitude obtained from the empty signal and the second burst pattern signal when detecting a second burst pattern signal, and obtaining an actual measurement ratio of the second amplitude to the first amplitude And
  (E) a first predetermined position for indicating the first index position in order to set a first index position and a second index position that are separated from the first edge by a predetermined distance on both sides of the first edge; A ratio and a second predetermined ratio for representing the second index position are given in advance;
  Then, a third predetermined ratio for representing the third index position is set on both sides of the second edge to set a third index position and a fourth index position that are separated from the second edge by a predetermined distance. And a fourth predetermined ratio for representing the fourth index position are given in advance,
  (F) In response to one index position of the first to fourth index positions indicated by the input signal, the predetermined ratio given in advance for the one index position is compared with the actually measured ratio. And determining the error, and controlling the head positioning means so as to eliminate the error. The data recording apparatus according to claim 1, wherein the predetermined ratio represents a ratio of the second amplitude to the first amplitude when the servo reproduction element is at the index position. The predetermined ratio is a ratio of the second amplitude to the first amplitude matched at the on-edge of the servo reproduction element or a predetermined offset in a predetermined direction from the amplitude ratio matched at the on-edge. The data recording apparatus according to claim 1. The data recording apparatus according to claim 1, wherein a detection area of the servo reproduction element is larger than twice a predetermined distance from the edge. The data recording according to claim 1, wherein a detection area of the servo reproduction element is a value between substantially 80% and substantially 100% of a distance between the first edge and the second edge. apparatus. A plurality of sets of the servo track and the data track are provided on the recording medium. A plurality of the data reproduction / recording elements and the servo reproduction elements are provided in the head so as to correspond to the plurality of sets, and the means for obtaining the actual measurement ratio includes the plurality of servo reproduction elements. The average value of the first amplitude and the value of the second amplitude are averaged to obtain an actual ratio of the averaged second amplitude to the averaged first amplitude. The data recording device described in 1. Independent position detecting means for detecting a coarse position of a current predetermined index position of the servo reproducing element as the head is moved from a reference position;
  The head positioning means is connected to the independent position detecting means and moves the servo reproducing element from a predetermined index position currently detected by the servo reproducing element toward a predetermined index position indicated by the input signal. The data recording apparatus according to claim 1, further comprising a control unit. Independent position detection means for detecting a coarse position of the current first edge or second edge of the servo reproducing element as the head is moved from a reference position;
  Means for detecting a predetermined index position in the first direction or a predetermined index position in the second direction with respect to the first edge or the second edge by comparing the magnitudes of two different servo signals; ,
Means connected to the independent position detecting means for controlling the head positioning means so as to move the servo reproducing element from the edge currently detected by the servo reproducing element toward a predetermined index position indicated by the input signal. The data recording device according to claim 1, comprising: (B) The servo track is provided in parallel to the data track,
  The servo track has (a) a first edge and a second edge, and a first burst pattern signal having a constant amplitude and a null signal having a zero amplitude are alternately arranged between the first edge and the second edge. A central servo track recorded repeatedly; and (b) a second burst pattern signal having a constant amplitude provided so as to be in contact with the first edge or the second edge of the central servo track is recorded. A recording medium having an outer servo track,
  (B) a head having an element for performing data reproduction / recording on the data track, and a servo reproduction element for detecting the outer track and the central servo track;
  (C) head positioning means for moving the head in a direction perpendicular to the first edge and the second edge of the recording medium;
  (D) when the servo reproducing element detects the second burst pattern signal of the outer track and the first burst pattern signal of the central servo track; Detecting a first amplitude obtained from the first burst pattern signal;
  When the servo reproducing element detects the second burst pattern signal of the outer track and the empty signal of the central servo track, the first signal obtained from the empty signal and the second burst pattern signal is obtained. Means for detecting two amplitudes and obtaining an actual measurement ratio of the second amplitude to the first amplitude,
  (E) the first indexing position for setting a first indexing position and a second indexing position that are separated from the edge by a predetermined distance on both sides of the edge between the outer servo track and the central servo track; A first predetermined ratio for representing a position and a second predetermined ratio for representing the second index position are given in advance;
  (F) In response to one index position of the first and second index positions indicated by the input signal, the predetermined ratio given in advance for the one index position is compared with the actually measured ratio. And determining the error, and controlling the head positioning means so as to eliminate the error. The predetermined ratio is equal to the first amplitude when the servo reproduction element is at the index position. The data recording apparatus according to claim 9, wherein the data recording apparatus represents a ratio of the second amplitude to the second amplitude. The predetermined ratio is a ratio of the second amplitude to the first amplitude matched at the on-edge of the servo reproduction element or a predetermined offset in a predetermined direction from the amplitude ratio matched at the on-edge. The data recording apparatus according to claim 9. The data recording apparatus according to claim 9, wherein a detection area of the servo reproduction element is larger than twice a predetermined distance from the edge. The data recording according to claim 9, wherein the detection area of the servo reproducing element is a value between substantially 80% and substantially 100% of a distance between the first edge and the second edge. apparatus. A plurality of sets of the servo track and the data track are provided on the recording medium, and a plurality of the data reproduction / recording elements and the servo reproduction elements are provided in the head so as to correspond to the plurality of sets. And a means for obtaining the actual measurement ratio averages the first amplitude values and the second amplitude values for the plurality of servo reproduction elements, and averages the second amplitude values. The data recording apparatus according to claim 9, wherein an actual measurement ratio of the averaged second amplitude to one amplitude is obtained. Independent position detecting means for detecting a coarse position of a current predetermined index position of the servo reproducing element as the head is moved from a reference position;
  The head positioning means is connected to the independent position detecting means and moves the servo reproducing element from a predetermined index position currently detected by the servo reproducing element toward a predetermined index position indicated by the input signal. The data recording apparatus according to claim 9, further comprising a control unit. Independent position detection means for detecting a coarse position of the current first edge or second edge of the servo reproducing element as the head is moved from a reference position;
  Means for detecting a predetermined index position in the first direction or a predetermined index position in the second direction with respect to the first edge or the second edge by comparing the magnitudes of two different servo signals; ,
Means connected to the independent position detecting means for controlling the head positioning means so as to move the servo reproducing element from the edge currently detected by the servo reproducing element toward a predetermined index position indicated by the input signal. The data recording device according to claim 9, comprising: (B) The servo track is provided in parallel to the data track,
  The servo track has (a) a first edge and a second edge, and a first burst pattern signal having a constant amplitude and a null signal having a zero amplitude are alternately arranged between the first edge and the second edge. A central servo track recorded repeatedly; and (b) a second burst pattern signal having a constant amplitude provided in contact with each of the first edge and the second edge of the central servo track. A recording medium having first and second outer servo tracks recorded thereon;
  (B) An element for performing data reproduction / recording on the data track, and a servo reproduction element for detecting the first outer track and the central servo track, or the central servo track and the second outer track. A head having
  (C) head positioning means for moving the head in a direction perpendicular to the first edge and the second edge of the recording medium;
  (D) the servo reproducing element may receive the second burst pattern signal of the first outer track and the first burst pattern signal of the central servo track, or the first burst of the central servo track; The pattern signal and the second bar of the second outer track A first amplitude obtained from the second burst pattern signal and the first burst pattern signal when detecting a first pattern signal;
  The servo reproduction element is configured to output the second burst pattern signal of the first outer track and the empty signal of the central servo track, or the empty signal of the central servo track and the empty signal of the second outer track. Means for detecting a second amplitude obtained from the empty signal and the second burst pattern signal when detecting a second burst pattern signal, and obtaining an actual measurement ratio of the second amplitude to the first amplitude And
  (E) a first predetermined position for indicating the first index position in order to set a first index position and a second index position that are separated from the first edge by a predetermined distance on both sides of the first edge; A ratio and a second predetermined ratio for representing the second index position are given in advance;
  Then, a third predetermined ratio for representing the third index position is set on both sides of the second edge to set a third index position and a fourth index position that are separated from the second edge by a predetermined distance. And a fourth predetermined ratio for representing the fourth index position, which is given in advance,
  (A) in response to one index position of the first to fourth index positions indicated by the input signal, selecting the predetermined ratio given in advance to the one index position;
  (B) moving the head in a direction perpendicular to the first edge and the second edge of the recording medium by the head positioning means to obtain the actual measurement ratio;
  (C) comparing the predetermined ratio with the measured ratio to determine an error;
  (D) controlling the head positioning means so as to eliminate the error, and a method for controlling the data recording apparatus. The data recording apparatus control method according to claim 17, wherein the predetermined ratio represents a ratio of the second amplitude to the first amplitude when the servo reproduction element is at the index position. The predetermined ratio is a predetermined offset in a predetermined direction from a ratio of the second amplitude to the first amplitude that the servo reproduction element is matched at the on-edge or an amplitude ratio that is matched at the on-edge. The method for controlling the data recording apparatus according to claim 17. The method of controlling a data recording apparatus according to claim 17, wherein a detection area of the servo reproduction element is larger than twice a predetermined distance from the edge. 18. The data recording according to claim 17, wherein the detection area of the servo reproducing element is a value between substantially 80% and substantially 100% of the distance between the first edge and the second edge. Device control method. A plurality of sets of the servo track and the data track are provided on the recording medium, and a plurality of the data reproduction / recording elements and the servo reproduction elements are provided in the head so as to correspond to the plurality of sets. And a means for obtaining the actual measurement ratio averages the first amplitude values and the second amplitude values for the plurality of servo reproduction elements, and averages the second amplitude values. The data recording apparatus control method according to claim 17, wherein an actual measurement ratio of the averaged second amplitude to one amplitude is obtained. Independent position detecting means for detecting a coarse position of a current predetermined index position of the servo reproducing element as the head is moved from a reference position;
  The head positioning means is connected to the independent position detecting means and moves the servo reproducing element from a predetermined index position currently detected by the servo reproducing element toward a predetermined index position indicated by the input signal. 18. The method for controlling a data recording apparatus according to claim 17, further comprising: means for controlling. Independent position detecting means for detecting a coarse position where the servo reproducing element indicates a current first edge or second edge as the head is moved from a reference position;
  Means for detecting a predetermined index position in the first direction or a predetermined index position in the second direction with respect to the first edge or the second edge by comparing the magnitudes of two different servo signals; ,
Means connected to the independent position detecting means for controlling the head positioning means so as to move the servo reproducing element from the edge currently detected by the servo reproducing element toward a predetermined index position indicated by the input signal. The method for controlling a data recording apparatus according to claim 17, comprising: (B) The servo track is provided in parallel to the data track,
  The servo track has (a) a first edge and a second edge, and a first burst pattern signal having a constant amplitude and a null signal having a zero amplitude are alternately arranged between the first edge and the second edge. A central servo track recorded repeatedly; and (b) a second burst pattern signal having a constant amplitude provided so as to be in contact with the first edge or the second edge of the central servo track is recorded. A recording medium having an outer servo track,
  (B) a head having an element for performing data reproduction / recording on the data track, and a servo reproduction element for detecting the outer track and the central servo track;
  (C) head positioning means for moving the head in a direction perpendicular to the first edge and the second edge of the recording medium;
  (D) when the servo reproducing element detects the second burst pattern signal of the outer track and the first burst pattern signal of the central servo track; Detecting a first amplitude obtained from the first burst pattern signal;
  When the servo reproducing element detects the second burst pattern signal of the outer track and the empty signal of the central servo track, the first signal obtained from the empty signal and the second burst pattern signal is obtained. Means for detecting two amplitudes and obtaining an actual measurement ratio of the second amplitude to the first amplitude,
  (E) the first indexing position for setting a first indexing position and a second indexing position that are separated from the edge by a predetermined distance on both sides of the edge between the outer servo track and the central servo track; A control method for a data recording apparatus, wherein a first predetermined ratio for representing a position and a second predetermined ratio for representing the second index position are given in advance,
  (A) in response to one index position of the first and second index positions indicated by the input signal, selecting the predetermined ratio given in advance to the one index position;
  (B) moving the head in a direction perpendicular to the first edge and the second edge of the recording medium by the head positioning means to obtain the actual measurement ratio;
  (C) comparing the predetermined ratio with the measured ratio to determine an error;
  (D) controlling the head positioning means so as to eliminate the error, and a method for controlling the data recording apparatus. 26. The method of controlling the data recording apparatus according to claim 25, wherein the predetermined ratio represents a ratio of the second amplitude to the first amplitude when the servo reproduction element is at the index position. The predetermined ratio is a predetermined offset in a predetermined direction from a ratio of the second amplitude to the first amplitude that the servo reproduction element is matched at the on-edge or an amplitude ratio that is matched at the on-edge. 26. A method for controlling a data recording apparatus according to claim 25. A detection area of the servo reproduction element is larger than twice a predetermined distance from the edge; 26. A method for controlling a data recording apparatus according to claim 25. 26. A data recording according to claim 25, wherein the detection area of the servo reproduction element is a value between substantially 80% and substantially 100% of the distance between the first edge and the second edge. Device control method. A plurality of sets of the servo track and the data track are provided on the recording medium, and a plurality of the data reproduction / recording elements and the servo reproduction elements are provided in the head so as to correspond to the plurality of sets. And a means for obtaining the actual measurement ratio averages the first amplitude values and the second amplitude values for the plurality of servo reproduction elements, and averages the second amplitude values. 26. The method of controlling a data recording apparatus according to claim 25, wherein an actual measurement ratio of the averaged second amplitude to one amplitude is obtained. Independent position detecting means for detecting a coarse position of a current predetermined index position of the servo reproducing element as the head is moved from a reference position;
  The head positioning means is connected to the independent position detecting means and moves the servo reproducing element from a predetermined index position currently detected by the servo reproducing element toward a predetermined index position indicated by the input signal. 26. The method of controlling a data recording apparatus according to claim 25, further comprising a control unit. Independent position detection means for detecting a coarse position of the current first edge or second edge of the servo reproducing element as the head is moved from a reference position;
  Means for detecting a predetermined index position in the first direction or a predetermined index position in the second direction with respect to the first edge or the second edge by comparing the magnitudes of two different servo signals; ,
Means connected to the independent position detecting means for controlling the head positioning means so as to move the servo reproducing element from the edge currently detected by the servo reproducing element toward a predetermined index position indicated by the input signal. 26. A method for controlling a data recording apparatus according to claim 25, comprising:

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