JP2006286070A - Optical tape system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical tape system suitable for achieving sufficient high recording density with respect to an optical tape medium. <P>SOLUTION: The optical tape system X1 is provided with the optical tape medium 10 and a plural rows of optical heads 20 each of whose row comprises a plurality of optical heads 20 arranged in a width direction D of the optical tape medium 10 and is provided with a plural rows of optical heads 20 arranged in a spread direction of the optical tape medium 10. The optical heads 20 belonging to different rows are shifted from each other in the width direction D. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an optical tape apparatus for executing information recording and information reproduction on an optical tape medium using an optical head.

  An optical tape medium is known as one form of optical media from which information is optically read. In an optical tape medium, a recording film for magneto-optical recording and a recording film for phase change recording are formed on a tape base material, and information recording is performed using a predetermined optical head disposed opposite to the optical tape medium. And a medium on which information reproduction is executed. The technology relating to such an optical tape medium is described, for example, in Patent Documents 1 and 2 below.

JP-A-5-217197 JP-A-11-353696

  8 and 9 schematically show a part of the configuration of a conventional optical tape device X2 for performing information recording and information reproduction on an optical tape medium. 8 is a plan view of the partial configuration, and FIG. 9 is an enlarged cross-sectional view taken along line IX-IX in FIG.

  The optical tape device X2 includes an optical tape 81, which is an optical tape medium, and a single optical head 82. The optical tape 81 has a laminated structure including a tape base material 81a and a recording film 81b. The optical tape 81 can be controlled in the direction of arrow A shown in FIG. The recording film 81b includes a plurality of tracks (not shown) extending in parallel to each other in the tape extending direction. The optical head 82 includes an objective lens and the like, and is configured to emit a laser beam L from a predetermined position toward the recording film 81 b of the optical tape 81. In FIG. 9 and FIG. 11 described later, the laser beam L is schematically represented by a bold line. When the optical head 82 is configured for magneto-optical recording, the optical head 82 includes magnetic field applying means (not shown) for applying a recording magnetic field to the recording film 81b of the optical tape 81. . Further, the optical head 82 is configured to be capable of focus servo with respect to the laser beam L, to be capable of positioning control in the width direction D of the optical tape 81 (that is, in the track crossing direction), and to be capable of tracking servo.

  When recording or reproducing information on the optical tape 81, the optical head 82 is positioned and controlled at a predetermined position in the width direction, and then the optical tape 81 is controlled to be sent out in the direction of the arrow A or the arrow B in a timely manner. To the target track of the recording film 81b of the optical tape 81. By the operation of the optical head 82 with such laser beam irradiation, a predetermined signal is written on the recording film 81b using the energy of the laser beam L, or a signal already written on the recording film 81b is Reading is performed using reflected light of the laser beam L or the like. During execution of such information recording and information reproduction, the focus servo is continuously applied to the laser beam L and the tracking servo is continuously applied to the optical head 82.

  On the other hand, as a technique for increasing the recording processing speed and the reproducing processing speed in the optical tape device, information recording and information reproducing are performed in parallel on a plurality of tracks (that is, information recording is performed by receiving a recording signal transferred in parallel). Or the playback signal is transferred in parallel). 10 and 11 schematically show a part of the configuration of the optical tape device X3 configured to be able to execute information recording and information reproduction with such parallel transfer. FIG. 10 is a plan view of the partial configuration, and FIG. 11 is an enlarged cross-sectional view taken along line XI-XI in FIG.

  The optical tape device X3 includes an optical tape 81 and four optical heads 82 (82A to 82D). The configuration of the optical tape 81 and each optical head 82 is the same as that in the above-described optical tape device X2. In the optical tape device X 3, the four optical heads 82 are arranged in a row so as to be separated from each other in the width direction D of the optical tape 81. When a plurality of tracks are formed on the recording film 81 b of the optical tape 81, a plurality of tracks in a predetermined area in the width direction D are assigned to each optical head 82. For example, as shown in FIG. 11, a plurality of tracks positioned in the regions Ra to Rd are allocated to the optical heads 82A to 82D, respectively. When information recording or information reproduction is performed in the optical tape device X3, each optical head 82 operates on a target track appropriately selected from a plurality of allocated tracks. In the optical tape device X3, information recording and information reproduction are executed in parallel for a plurality of tracks in this way.

  In the optical tape device X3, the width of the optical tape 81 is, for example, about 12 mm, the width of each optical head 82 (the dimension in the width direction D of the optical tape 81) is, for example, about 3 mm, and is configured by the recording film 81b. The width of each track is, for example, about 1 μm, and the diameter of the irradiation spot formed on the surface of the optical tape 81 by the laser beam L irradiated to the recording film 81b from each optical head 82 is, for example, about 0.4 μm. In D, the four optical heads 82 are relatively densely arranged, and the width of each optical head 82 is considerably larger than the track width and the laser beam diameter. Therefore, the large structure of the optical head 82 itself becomes an obstacle, and two adjacent predetermined optical heads 82 cannot approach each other below a certain distance, and laser beam irradiation is performed by any of the optical heads 82A to 82D. A plurality of vacant areas Rv that cannot practically constitute a plurality of areas that cannot be used, that is, a track that can be used for information recording or information reproduction, are generated considerably wide in the recording film 81b. The fixed distance is the size of the two adjacent optical heads 82 adjacent to each other from the right end of the optical head 82 on the left side in FIG. 11 to the laser beam emission position, and the laser beam from the left end of the optical head 82 on the right side in FIG. It is the distance corresponding to the total dimension with the dimension to the emission point. As described above, in the optical tape device X3, a vacant area Rv in which a track that can be used for information recording and information reproduction cannot practically be formed is generated in the recording film 81b, and the vacant area Rv is considerably wide. . In such an optical tape device X3, information cannot be recorded at a sufficiently high recording density with respect to the optical tape 81. Therefore, the optical tape device X3 is not preferable for increasing the recording density of the optical tape 81.

  The present invention has been conceived under the circumstances as described above, and an object thereof is to provide an optical tape apparatus suitable for achieving a sufficiently high recording density for an optical tape medium.

  An optical tape device provided by the present invention includes an optical tape medium, and a plurality of optical heads each having a plurality of optical heads arranged in the width direction of the optical tape medium and arranged in the extending direction of the optical tape medium. And an information recording and / or reproducing information for an optical tape medium using an optical head. In this optical tape device, the optical heads belonging to different rows are displaced in the width direction of the optical tape medium. The optical tape medium has a plurality of tracks extending in the extending direction. The optical head is configured to emit a laser beam toward the optical tape medium. The position of the optical head in the width direction of the optical tape medium is the position in the width direction of the optical tape medium of the irradiation spot formed on the optical tape medium by the laser beam emitted from the optical head.

  In the optical tape device having such a configuration, since the adjacent optical heads belonging to a predetermined row cannot approach below a predetermined distance, the laser beam can be irradiated by any optical head belonging to the corresponding row. In the case where an incapable region (region assumed in the width direction of the optical tape medium) occurs in the optical tape medium, another optical head in at least one other row is connected to the region from any one of the optical heads belonging to the at least one row. It can be arranged so that it can be irradiated with a laser beam. In other words, this optical tape apparatus can be configured such that a laser beam is irradiated from any one of the optical heads over the entire area of the optical tape medium in the optical tape medium width direction. Therefore, according to the present optical tape device, a track that can be used for information recording and information reproduction can be formed in the entire area of the optical tape medium in the width direction of the optical tape medium (that is, it can be used for information recording and information reproduction). It is possible to avoid the occurrence of an empty area in the optical tape medium in which the track cannot be practically configured). When such an optical tape device is configured as a recording device, it is suitable for performing information recording at a sufficiently high recording density on the optical tape medium, and accordingly, a sufficiently high recording density for the optical tape medium. Suitable for planning.

Preferably, when the total number of optical heads is N ₀ , the number of optical heads in each column is N ₁ , the number of columns is N ₂ , the optical tape width is W ₁ , and the optical head width is W ₂ , (1) to (3) hold (the operator floor used in the expressions (1) and (2) gives a maximum integer not exceeding X when it is in the form of floorX. For example, floor [5/2] is 2). According to such a configuration, the optical head can be efficiently arranged on the optical tape medium particularly when the total number of optical heads is 2 ⁿ (n is an integer of 2 or more).

Preferably, the total number of optical heads is 2 ⁿ (n is an integer of 2 or more). Such a configuration is suitable for realizing parallel transfer when information recording or information reproduction is executed in the optical tape device.

  Preferably, the optical heads are all located within the width of the optical tape medium. According to such a configuration, when each optical head is a flying slider type head, the entire optical head positioned at both ends of each row is optical tape medium like the optical head not positioned at both ends of each row. Therefore, the optical heads positioned at both ends can be appropriately floated with respect to the optical tape medium.

  1 and 2 show an optical tape device X1 according to the present invention. FIG. 1 is a plan view schematically showing a part of the configuration of the optical tape device X1, and FIG. 2 is a partially enlarged sectional view of the optical tape device X1. The optical tape device X1 includes an optical tape 10 that is a magneto-optical recording medium and a plurality of recording / reproducing heads 20 arranged to face the optical tape 10, and performs information recording and information reproduction with parallel transfer on the optical tape 10. It is configured to be able to execute.

  As shown in FIG. 2, the optical tape 10 has a laminated structure including a tape base 11 and a recording film 12, and in this embodiment, is configured as a magneto-optical recording medium as described above. The tape substrate 11 is made of, for example, a PET film. In addition, a plurality of pregrooves (not shown) extending in the tape extending direction are formed in parallel with each other on the recording film 12 side of the tape substrate 11, and the land on the optical tape 10 is based on the pregrooves. A groove shape (not shown) is formed. The recording film 12 has a magnetic structure capable of performing two functions of thermomagnetic recording and reproduction utilizing the magneto-optical effect, and is composed of one or more magnetic films according to the reproduction method. . The magnetic film is a rare earth-transition metal amorphous alloy perpendicular magnetization film. The recording film 12 includes a plurality of tracks (not shown) extending in parallel to each other in the tape extending direction. Each track extends along a land portion (not shown) or a groove portion (not shown) in the optical tape 10. The laminated structure of the optical tape 10 may include other films as necessary. Such an optical tape 10 can be fed out in the direction of arrow A shown in FIG. 1 and can be fed out in the direction of arrow B between a pair of take-up reels (not shown).

  As shown in FIG. 2, each of the plurality of recording / reproducing heads 20 includes a slider unit 21, a lens 22, a lens actuator 23, and a head body 24, and corresponds to an optical head in the present invention.

  The slider portion 21 includes a lens 21a and a recording coil 21b, and allows a recording or reproducing laser beam L emitted from a light source (not shown) (for example, composed of a semiconductor laser diode) to pass through a predetermined path (see FIG. That is, the laser beam L can be emitted from a predetermined location. The lens 21 a is an objective lens for focusing the laser beam L on the optical tape 10. The focused laser beam L forms an irradiation spot on the surface of the optical tape 10. The recording coil 21 b is for applying a recording magnetic field of a predetermined strength to the recording film 12 of the optical tape 10 and is embedded in the slider portion 21. Such a slider portion 21 is connected to a predetermined actuator (not shown) via a leaf spring suspension 25.

  The lens 22 is for converging the laser beam L on the optical tape 10 in cooperation with the lens 21a described above, and is provided so that the position of the lens 22 can be controlled in the vertical direction in the figure by the lens actuator 23. The lens actuator 23 is configured to be able to displace the lens 22 by, for example, an electromagnetic driving force. The head body 24 supports at least the lens 22 and the lens actuator 23 inside, and is mechanically coupled to a predetermined actuator.

  Each recording / reproducing head 20 having the above configuration is configured to be capable of focus servo with respect to the laser beam L, to be capable of positioning control in the width direction D of the optical tape 10 (that is, to the track crossing direction), and to be capable of tracking servo. Yes.

In the optical tape apparatus X1, as shown in FIG. 1, N ₁ recording / reproducing heads 20 are arranged in a row spaced apart from each other in the width direction D, and the same number of recording / reproducing head rows are provided in N ₂ rows. ing. Further, the recording / reproducing heads 20 belonging to different columns are displaced in the width direction D. In FIG. 1, from the viewpoint of simplifying the drawing, the outer shape of the recording / reproducing head 20 is simplified to a rectangle. The position of the recording / reproducing head 20 in the width direction D of the optical tape 10 is the position in the width direction D of the irradiation spot formed on the optical tape 10 by the laser beam L emitted from the recording / reproducing head 20. A plurality of tracks are formed on the recording film 12 of the optical tape 10, and a plurality of tracks in a predetermined area in the width direction D are assigned to each recording / reproducing head 20. For example, the N ₁ recording / reproducing heads 20 belonging to the same column are each assigned a plurality of tracks positioned in the regions R1 to Rn as shown in FIG.

When information recording is executed in the optical tape device X1, each recording / reproducing head 20 is operated with respect to a target track appropriately selected from a plurality of allocated tracks. Specifically, at the time of information recording, each recording / reproducing head 20 is positioned and controlled at the position in the width direction of the target track selected from the plurality of allocated tracks, and then the optical tape 10 is moved in the direction of arrow A or arrow B in FIG. By irradiating a recording laser beam L emitted from each recording / reproducing head 20 through the lens 21a toward each target track of the recording film 12 while controlling the delivery in a timely manner, various portions of the recording film 12 are irradiated. Increase the temperature locally and sequentially. At the same time, a recording magnetic field is applied to these temperature rising points by the recording coil 12 b of each recording / reproducing head 20. In this way, a predetermined signal is recorded on the recording film 12 along predetermined N ₁ tracks. Specifically, a plurality of magnetic domains (recording marks) each having a predetermined length corresponding to a recording signal are formed on the recording film 12 for each track. During execution of such information recording, the focus servo is continuously applied to the laser beam L of each recording / reproducing head 20 and the tracking servo is continuously applied to each recording / reproducing head 20. In the optical tape device X1, information recording can be performed in parallel on a plurality of tracks as described above.

When information reproduction is performed in the optical tape device X1, each recording / reproducing head 20 is operated with respect to a target track appropriately selected from a plurality of allocated tracks. Specifically, at the time of information reproduction, after controlling the positioning of each recording / reproducing head 20 at the position in the width direction of the target track selected from a plurality of allocated tracks, the optical tape 10 is moved in the direction of arrow A or arrow B in FIG. The reproducing laser beam L emitted from each recording / reproducing head 20 through the lens 21 a is irradiated toward each target track of the recording film 12 and reflected by the recording film 12 while being controlled in a timely manner. Changes in the polarization angle of light are detected. In this way, the recording signal in the recording film 12 can be read along the predetermined N ₁ tracks. During execution of such information reproduction, the focus servo is continuously applied to the laser beam L of each recording / reproducing head 20 and the tracking servo is continuously applied to each recording / reproducing head 20. In the optical tape device X1, information reproduction can be executed in parallel for a plurality of tracks as described above.

  In the optical tape apparatus X1, since the adjacent recording / reproducing heads 20 belonging to a predetermined row cannot approach below a predetermined distance, any of the recording / reproducing heads 20 belonging to the same row can irradiate a laser beam. An area that cannot be recorded (an area assumed in the width direction D of the optical tape 10) exists in the optical tape 10, but the other plurality of recording / reproducing heads 20 in at least one row are connected to any one of the recording / reproducing heads 20 belonging to the at least one row. The region can be arranged so that the region can be irradiated with a laser beam. In other words, the optical tape device X1 can be configured to irradiate the entire region of the recording film 12 in the width direction D from any recording / reproducing head 20. Therefore, according to the optical tape device X1, a track that can be used for information recording and information reproduction can be formed in the entire area of the recording film 12 in the width direction D (that is, the track that can be used for information recording and information reproduction is the fact). It is possible to avoid the vacant area that cannot be configured on the optical tape 10). According to such an optical tape device X1, it is possible to perform information recording with a sufficiently high recording density on the optical tape 10, and therefore it is possible to achieve a sufficiently high recording density with respect to the optical tape 10. It is.

  FIG. 3 is a plan view schematically showing a recording / reproducing head arrangement in the case where the total number of recording / reproducing heads 20 included in the optical tape device X1 is four. 4 and 5 are plan views schematically showing one recording / reproducing head arrangement mode when the total number of recording / reproducing heads 20 included in the optical tape device X1 is eight. FIGS. 6 and 7 are plan views schematically showing one recording / reproducing head arrangement in the case where the total number of recording / reproducing heads 20 included in the optical tape device X1 is 16. FIG.

In the optical tape device X1, when the total number N ₀ of the recording / reproducing heads 20 is 2 ⁿ (n is an integer of 2 or more), N ₀ , the width W ₁ of the optical tape 10, and the width of each recording / reproducing head 20 When W ₂ is set by design (all are the same), the arrangement of all the recording / reproducing heads 20 with respect to the optical tape 10, that is, N ₁ and N ₂ is efficiently determined based on the above formulas (1) to (3) can do.

For example, if N _{0 is set} to 8, W _{1 is set} to 8.0 (mm), and W ₂ is set to 2.0 (mm), N ₁ ′ = 4 is obtained from Equation (1), and from Equation (2), N ₁ is determined to be 4 and N ₂ is determined to be 2 from equation (3).

N ₀ and 8, W ₁ to 8.0 (mm), if and sets the W ₂ 3.0 and _{(mm), N 1 '=} 2 is obtained from the equation (1), N ₁ from equation (2) Is determined to be 2 and N ₂ is determined to be 4 from equation (3).

N ₀ and 8, W ₁ to 8.0 (mm), if and sets the W ₂ 4.0 and _{(mm), N 1 '=} 2 is obtained from the equation (1), N ₁ from equation (2) Is determined to be 2 and N ₂ is determined to be 4 from equation (3).

N ₀ and 8, W ₁ to 12.6 (mm), if and sets the W ₂ 3.0 and _{(mm), N 1 '=} 4 is obtained from the equation (1), N ₁ from equation (2) Is determined to be 4 and N ₂ is determined to be 2 from equation (3).

N ₀ and 8, W ₁ to 12.6 (mm), if and sets the W ₂ 4.0 and _{(mm), N 1 '=} 3 is obtained from equation (1), N ₁ from equation (2) Is determined to be 2 and N ₂ is determined to be 4 from equation (3).

N ₀ and 8, W ₁ to 12.6 (mm), if and sets the W ₂ 5.0 and _{(mm), N 1 '=} 2 is obtained from the equation (1), N ₁ from equation (2) Is determined to be 2 and N ₂ is determined to be 4 from equation (3).

N ₀ and 8, W ₁ to 12.6 (mm), if and sets the W ₂ and _{6.0 (mm), N 1 '} = 2 is obtained from the equation (1), N ₁ from equation (2) Is determined to be 2 and N ₂ is determined to be 4 from equation (3).

When N _{0 is set} to 8, W _{1 is set} to 16.0 (mm), and W ₂ is set to 3.0 (mm), N ₁ ′ = 5 is obtained from Equation (1), and from Equation (2) to N ₁ Is determined to be 4 and N ₂ is determined to be 2 from equation (3).

When N _{0 is set} to 8, W _{1 is set} to 16.0 (mm), and W ₂ is set to 4.0 (mm), N ₁ ′ = 4 is obtained from Equation (1), and from Equation (2) to N ₁ Is determined to be 4 and N ₂ is determined to be 2 from equation (3).

N ₀ and 8, W ₁ to 16.0 (mm), if and sets the W ₂ 5.0 and _{(mm), N 1 '=} 3 is obtained from equation (1), N ₁ from equation (2) Is determined to be 2 and N ₂ is determined to be 4 from equation (3).

N ₀ and 8, W ₁ to 16.0 (mm), if and sets the W ₂ and _{6.0 (mm), N 1 '} = 2 is obtained from the equation (1), N ₁ from equation (2) Is determined to be 2 and N ₂ is determined to be 4 from equation (3).

When N _{0 is set} to 8, W _{1 is set} to 16.0 (mm), and W ₂ is set to 7.0 (mm), N ₁ ′ = 2 is obtained from Equation (1), and from Equation (2) to N ₁ Is determined to be 2 and N ₂ is determined to be 4 from equation (3).

N ₀ and 8, W ₁ to 16.0 (mm), if and sets the W ₂ 8.0 and _{(mm), N 1 '=} 2 is obtained from the equation (1), N ₁ from equation (2) Is determined to be 2 and N ₂ is determined to be 4 from equation (3).

In the optical tape device X1, for example, as described above, the arrangement of all the recording / reproducing heads 20, that is, N ₁ and N ₂ can be determined efficiently based on the above formulas (1) to (3). .

It is a top view which represents typically a part of structure of the optical tape apparatus based on this invention. It is a partial expanded sectional view extended in the optical tape width direction of the optical tape apparatus which concerns on this invention. It is a top view which represents typically the recording / reproducing head arrangement | positioning aspect in case the total number of the recording / reproducing heads which the optical tape apparatus which concerns on this invention has is four. It is a top view which represents typically the one recording / reproducing head arrangement | positioning aspect in case the total of the recording / reproducing head which the optical tape apparatus based on this invention has is eight. FIG. 12 is a plan view schematically showing another recording / reproducing head arrangement when the total number of recording / reproducing heads included in the optical tape device according to the present invention is eight. It is a top view which represents typically the one recording / reproducing head arrangement | positioning aspect in case the total of the recording / reproducing head which the optical tape apparatus which concerns on this invention has is 16. FIG. It is a top view which represents typically the one recording / reproducing head arrangement | positioning aspect in case the total of the recording / reproducing head which the optical tape apparatus which concerns on this invention has is 16. FIG. It is a top view which represents typically the structure of a part of conventional optical tape apparatus for performing information recording and information reproduction about an optical tape medium. It is an expanded sectional view along line IX-IX of FIG. It is a top view which represents typically the structure of a part of other conventional optical tape apparatus for performing information recording and information reproduction | regeneration about an optical tape medium. It is an expanded sectional view along line XI-XI of FIG.

Explanation of symbols

X1, X2, X3 Optical tape device 10, 81 Optical tape 12 Recording film 20 Recording / reproducing head 21 Slider portion 21a, 22 Lens 21b Recording coil L Laser beam

Claims (4)

An optical tape medium;
A plurality of optical heads each including a plurality of optical heads arranged in the width direction of the optical tape medium, and arranged in the extending direction of the optical tape medium,
An optical tape device in which optical heads belonging to different rows are displaced in the width direction. When the total number of optical heads is N ₀ , the number of optical heads in each column is N ₁ , the number of columns is N ₂ , the optical tape width is W ₁ , and the optical head width is W ₂ , the following formula (1 The optical tape device according to claim 1, wherein:

3. The optical tape device according to claim 1, wherein a total number of the optical heads is 2 ⁿ (n is an integer of 2 or more).   4. The optical tape device according to claim 1, wherein all of the optical heads are located within a width of the optical tape medium. 5.

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