JP2008084536A - Optical recording medium and optical recording and reproducing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a high density optical recording medium performing recording and reproduction by a blue laser having a short wavelength while maintaining compatibility with a DVD and to provide an optical recording and reproducing device. <P>SOLUTION: In the optical recording medium wherein a light transmission layer 2 having 0.6 mm thickness is formed on an information recording surface 1 and at least either of recording or reproduction is performed from the light transmission layer side by using a laser beam having wavelength λ of 390 nm≤λ≤440 nm through a lens system having a N.A. (numerical aperture) of 0.6≤N.A.≤0.72, thickness unevenness of the light transmission layer 2 is specified to be within the range of ±5.98λ/(N.A.)<SP>4</SP>. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an optical recording medium and an optical recording / reproducing apparatus, for example, an optical recording medium such as an optical disk or an optical card, and an optical recording / reproducing apparatus having a function of performing either or both of optical recording and reproduction.

  With the rapid development of the information society, digital signals are being promoted especially in the fields of information, communication, video, and audio. Along with this, there is an increasing demand for such software supply or higher density for optical disks as information recording media. As a means for realizing it, a short wavelength laser beam, that is, a blue laser is used as a laser beam for optical recording and reproduction, and / or a high N.D. A. (Numerical aperture) is the most reliable and effective.

On the other hand, in recent years, a DVD (Digital Versatile Disc) has been standardized and commercialized as a high-density optical disk, and is gradually spreading. In addition, for example, many technical developments for increasing the capacity on the extended line of a DVD have been reported (see, for example, Non-Patent Document 1).
Nikkei Electronics 1997.55.5 (no.688), page 13, table 1

  It is an object of the present invention to provide a high-density optical recording medium and an optical recording / reproducing apparatus that can perform recording and reproduction by a short wavelength blue laser while maintaining compatibility with a DVD.

The optical recording medium according to the present invention has a light transmissive layer having a thickness of 0.6 mm. From the light transmissive layer side, a laser beam having a wavelength λ of 390 nm ≦ λ ≦ 440 nm is used. A. (Numerical aperture) is 0.6 ≦ N. A. An optical recording medium on which at least one of recording and reproduction is performed through a lens system of ≦ 0.72, and the thickness unevenness of the light transmission layer is within a range of ± 5.98λ / (NA) ⁴ Select.

The recording / reproducing apparatus according to the present invention has a light transmission layer having a thickness of 0.6 mm, and the thickness unevenness of the light transmission layer is selected within a range of ± 5.98λ / (NA) ⁴ . An optical recording medium is used. Then, from the light transmission layer side, the laser beam having a wavelength λ of 390 nm ≦ λ ≦ 440 nm is used for N.D. A. (Numerical aperture) is 0.6 ≦ N. A. At least one of optical recording and reproduction is performed through an objective lens of ≦ 0.72.

  The present invention makes it possible to perform recording / reproduction with a compatibility with a conventional DVD even with a short wavelength laser having a wavelength of 390 nm ≦ λ ≦ 440 nm by the above-described configuration.

  As described above, according to the optical recording medium of the present invention, the recording density can be increased and the recording capacity can be increased while maintaining compatibility with the conventional DVD and its recording / reproducing apparatus.

  Further, according to the optical recording / reproducing apparatus that performs at least one of optical recording and reproduction according to the present invention, since skew correction is performed, the recording and reproduction can be performed with excellent recording and reproduction characteristics.

1 to 5, the optical recording medium 10 according to the present invention has a thickness t of 0.6 mm on the information recording surface 1 and an uneven thickness Δt of ± 5.98λ. / (NA) ⁴ is formed, and the light transmission layer 2 is formed from the side of the light transmission layer 2 by laser light having a wavelength λ of 390 nm ≦ λ ≦ 440 nm. A. (Numerical aperture) is 0.6 ≦ N. A. At least one of recording and reproduction is performed through a lens system of ≦ 0.72.

  Then, at least the thickness tc of the mounting portion to the drive portion, that is, the clamp portion 3 is set to a thickness corresponding to the DVD in order to correspond to the mounting portion to the drive portion of the optical recording / reproducing apparatus for a normal DVD. 2 mm.

  1 to 5 illustrate an optical recording medium 10 according to the present invention, but the optical recording medium according to the present invention is not limited to these examples.

In the example shown in FIGS. 1 and 2, an optical recording medium is constituted by a light-transmitting disk substrate made of injection molding such as polycarbonate (PC), for example, and at least a clamp part 3 to the disk rotation driving part of the optical recording / reproducing apparatus is provided. The thickness tc to be configured is 1.2 mm, and the thickness t of the light transmission layer 2 in the peripheral portion including the formation portion of the information recording surface 1 is the specific thickness described above, that is, 0.6 mm ± 5.98λ / (N. A.) This is the case of ⁴ .

For example, the information recording surface 1 may be an information recording surface having a ROM (Read Only Memory) type structure, such as an information recording pit formed by a recording track, and an Al deposited film formed on the surface thereof, or A structure in which a recordable area is formed in part or all may be used. On the information recording surface, for example, a guide groove is formed along the recording track, for example, on the above-described light-transmitting disk substrate, and further, for example, in the case of having a ROM configuration at least partially, a recording pit row is formed.
Then, on the information recording surface on which the recordable area is formed, the recordable area is formed within the groove, between the grooves, or both. Such an information recording surface may be configured such that, for example, a magneto-optical recording layer is applied to the above-described groove or pit formation surface and information is read by the Kerr effect, or phase change or pits are formed by irradiation of a recording laser. By formation, information can be read by optical characteristics, interference, or the like. Also, for example, a reflective layer is formed on these recording layers. Furthermore, a protective layer is formed on the surface of the information recording surface 2 as necessary.

  In the example shown in FIG. 1, the information recording surface 1 is formed on a surface that becomes a recess that is recessed from one main surface of the thick clamp portion 3. In the example shown in FIG. 2, the information recording surface 1 Is formed on a surface that forms the same surface as one main surface of the clamp portion 3.

  The optical recording and / or reproduction of information on the information recording surface 1 of these optical recording media is performed by focusing the laser light L from the side having the light transmission layer 2 by the objective lens 4 as shown in FIGS. Do by irradiation.

  In the example shown in FIGS. 3 and 4, the first and second substrates 21 and 22 are bonded to each other by, for example, an ultraviolet curable resin, and the total thickness tc including the clamp portion 3 is 1.2 mm. This is the case. These first and second substrates 21 and 22 are both made of the same material such as PC and have substantially the same thickness in order to avoid the occurrence of warpage. The substrate 22 can be formed of an opaque substrate.

  In the example of FIG. 3, the information recording surface 1 is formed on the surface of the first substrate 21 facing the second substrate 22. In the example of FIG. 4, When the information recording surface 1 is formed on the surface facing the substrate 21, the light transmitting layer 2 is formed on the information recording surface 1 of the first substrate 21 in any case. 3 and 4, the configuration of the information recording surface 1 can be the same as that described with reference to FIGS. 1 and 2.

  Then, optical recording and / or reproduction of information with respect to the information recording surface 1 of these optical recording media is performed by irradiation with laser light L from the side having the light transmission layer 2 as shown in FIGS.

  Also in the example of FIG. 5, the first and second substrates 21 and 22 are bonded to each other by, for example, an ultraviolet curable resin having optical transparency, and the total thickness tc including the above-described clamp portion 3 is 1.2 mm. This is the case. Also in this case, it is advantageous in avoiding the occurrence of warping that both the first and second substrates 21 and 22 are made of the same material such as PC and have the same thickness. However, the second substrate 22 can be constituted by an opaque substrate. In this example, one information recording surface, that is, the first and second information recording surfaces 11 and 12 are formed on the opposing surfaces of the first and second substrates 21 and 22, respectively.

  Also in this example, the light transmission layer 2 is constituted by the portion of the first substrate 21 on the first information recording surface 1 with respect to the first information recording surface 1. On the other hand, the light transmission layer 2 is configured to include, for example, an ultraviolet curable resin having light transmittance between the substrates 21 and 22.

The optical recording and / or reproduction of information on the information recording surfaces 11 and 12 of these optical recording media can be performed from the side having the light transmission layer 2, that is, the same substrate 21 side. In this case, the focus positions of the laser beams L ₁ and L ₂ of the same laser beam or different wavelengths are selected for the first and second information recording surfaces 11 and 12 for the information recording surfaces 11 and 12, respectively. Do.

Also in FIG. 5, the information recording surfaces 11 and 12 can be configured to correspond to the configurations described in FIGS. 1 and 2, but in this example, information for the second information recording surface 12 is used. recording, reproduction, from doing by transmitting the first information recording surface 11, the reflecting surface of the first information recording surface 11, the reflecting surface of the semi-transparent to the laser beam L _2, for example, the film thin It is constituted by a metal reflection film such as Al or a dielectric reflection film set to be translucent.

In the optical recording / reproducing apparatus according to the present invention, as described above, the light transmission layer having a thickness of 0.6 mm is formed on the information recording surface, and the thickness unevenness of the light transmission layer is ± 5.98λ / (N A.) An optical recording medium selected within the range of ⁴ is used, and from the light transmission layer side, a laser beam having a wavelength λ of 390 nm ≦ λ ≦ 440 nm is used. A. (Numerical aperture) is 0.6 ≦ N. A. At least one of optical recording and reproduction is performed through an objective lens of ≦ 0.72.

  On the other hand, the optical recording / reproducing apparatus according to the present invention comprises an optical device 31 that performs optical recording and / or reproduction as shown in FIG. A correction means 30 is provided for performing mechanical or electrical correction to improve the signal characteristics according to the skew of the optical recording medium.

  In this case, the optical device 31 has, for example, a drive mechanism 32 that changes and adjusts the entire inclination of the optical device 31, for example, an electromagnetic unit or a mechanism that rotates the entire optical device 31 by motor driving and adjusts the inclination. .

  The information recording medium 10 includes a skew detection unit, an amplifier 34 that amplifies a detection signal therefrom, and a drive device 35 that drives and controls the drive mechanism 32 based on the output thereof.

The skew in the optical recording medium is generally due to saddle-like deformation, and the skew detection means 33 is configured to detect the inclination in each part. The detection means 33 is, for example, a detection light L ₀ having a wavelength or power that does not affect recording or reproduction on the optical recording medium 10, for example, a semiconductor laser 36 that generates laser light, and the detection light L ₀ . comprising a detecting element for example a photodiode 37 detects reflected light L _R from the optical recording medium 10. The detection light L ₀ from the detection means 33 is irradiated in the vicinity of the irradiation position of the laser light from the optical device 31.

Then, the reflected light L _R from the optical recording medium 10 of the detection light L ₀ is, since the incident position on the photodiode 37 varies depending on the inclination of the irradiation part of the detection light L _0, for example, a photodiode 37 By constituting with the divided photodiodes, it is possible to detect the inclination of the optical recording medium 10 in the vicinity of the irradiation position of the detection light L ₀ , that is, the irradiation position of the laser light from the optical device 31, based on the change in the light quantity of each of the divided portions. . Therefore, the detection signal is amplified by the amplifier 34, and the output is input to the drive device 35, whereby the drive mechanism 32 is driven and controlled, and the tilt of the optical device 31 is adjusted. In this way, the optical characteristics of the optical device 31 are always good, for example, the generation of the distortion of the irradiation spot shape, and the reliable return light, that is, the reproduction light can be detected.

  The configuration of the optical device 31 main body can be based on various conventionally known configurations. For example, in the case of an optical device that performs optical reproduction, for example, as shown in a schematic configuration of FIG. 7, for example, a semiconductor laser or a laser light source 41 having a configuration including a laser and its wavelength conversion element, a grating 42, It has a beam splitter 43, an objective lens 4, and a detection element 44 such as a photodiode for reading out information by detecting the return light from the optical recording medium 10, that is, the reproduction light whose light intensity is modulated in accordance with the recorded information. It can be set as the structure which consists of.

As described above, the laser light, that is, the lasers L, L _1, and L ₂ shown in FIGS. 1 to 5 are obtained by converting the wavelength of the laser having a wavelength of 860 nm by the wavelength conversion element SHG (second harmonic generation) element. Is 430 nm laser light, or semiconductor laser light in the vicinity of 400 nm, and can be varied by about ± 10 nm. Therefore, the wavelength λ of the target laser light used in the present invention is 390 nm ≦ λ ≦ 440 nm. .

By the way, the permissible thickness unevenness of the light transmission layer 2 is described in FIG. M.M. And allowable skew S.E. M.M. Respectively
T.A. M.M. ∝λ / (NA) ⁴
S. M.M. ∝λ / (NA) ³ / t
The wavelength λ = 0.65 μm in the DVD, T. M.M. = ± 30 μm, S.I. M.M. = ± 0.4 ° based on the format, when the thickness t of the light transmission layer in the present invention is 0.6 mm,
T.A. M.M. = ± 30 × (0.6 / NA) ⁴ × (λ / 0.65)
= ± 5.98λ / (NA) ⁴
S. M.M. = ± 0.4 × (0.6 / NA) ³ × (λ / 0.65)
= ± 0.133λ / (NA) ³
It becomes.

By the way, when a substrate having a diameter of 120 mm and a thickness of 0.6 mm is manufactured by the current injection molding technique, ± 10 μm is the thickness accuracy, that is, the limit value of the thickness unevenness at the mass production level.
Considering this,
T.A. M.M. = ± 30 × (0.6 / NA) ⁴ × (λ / 0.65) ≧ 10 (1)
It becomes.

N. A. The upper limit of λ is when λ is the largest, and as described above, the largest value of λ is 440 nm (0.44 μm). A. Is
N. A. ≦ 0.72
It becomes.

That is, in the configuration of the present invention, when the thickness t of the light transmission layer is 0.6 mm, the thickness unevenness Δt is set to the allowable thickness T.sub. M.M. Of ± 5.98λ / (NA) ⁴ . Further, in the case of 0.39 μm ≦ λ ≦ 0.44 μm, the N.D. A. = 0.6 or more and 0.72 or less. That is, 0.6 ≦ N. A. ≦ 0.72.

  Also, the configuration when the diameter φ = 120 mm according to the present invention and the information recording surface is a single layer with reference to a signal recording area equivalent to that of a DVD will be described.

[In the case of ROM disk]
In the case of the lowest capacity, λ = 0.44 μm, N.D. A. = 0.6, the recording capacity of the DVD is 4.7 GB, and the track pitch T.I. P. = 0.74 μm, linear density L.P. D. = 0.27 μm / bit, the shortest pit length P _min = 0.4 μm, and as described above, λ = 0.65, S.I. M.M. = ± 0.4 °
For recording capacity,
4.7 × (0.65 / 0.44) ² GB
= 10.3 GB
It becomes.
And at this time
T.A. M.M. = ± 5.98λ / (NA) ⁴ [μm]
= ± 20 [μm]
S. M.M. = ± 0.133λ / (NA) ³ [°]
= ± 0.27 °
T.A. P. = 0.74 x 0.44 / 0.65 [μm]
= 0.5μm
L. D. = 0.27 × 0.44 / 0.65 [μm / bit]
= 0.18 μm / bit
P _min = 0.4 × 0.44 / 0.65 [μm]
= 0.27 μm.

On the other hand, in the case of the highest capacity, λ = 0.39 μm, N.P. A. = 0.72, so the recording capacity is
4.7 × (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 18.8 GB
It becomes.
At this time
T.A. M.M. = ± 5.98λ / (NA) ⁴ [μm]
= ± 9μm
S. M.M. = ± 0.133λ / (NA) ³ [°]
= ± 0.14 °
T.A. P. = 0.74 x 0.39 / 0.65 x 0.6 / 0.72 [μm]
= 0.37 μm
L. D. = 0.27 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.13 μm / bit
P _min = 0.4 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.20 μm.

  That is, in the optical recording medium in which the pit string data is recorded at least in part, in the present invention, the track pitch is 0.37 [μm] to 0.5 [μm], and the shortest pit length However, pit string data of 0.20 [μm] to 0.27 [μm] and recording linear density of 0.13 [μm / bit] to 0.18 [μm / bit] is used as at least a part of the information area. Recorded configuration.

Although these are of a reduced scale with respect to the DVD, the pit width is reduced by about 30% when the technique for reducing the pit width disclosed in JP-A-1-31748 is used.
And from this, it is reduced to 70% of the above P _min ,
P _min = 0.37 × 0.7 = 0.26 μm.
Furthermore, the capacity increases to 18.8 / 0.7 = 26.8 GB.

[For rewritable discs]
First, DVD + R / W (manufactured by Sony) is used as a standard. P. = 0.80 μm single spiral groove recording structure, linear density L.P. D. = 0.35 μm / bit and the recording capacity is 3.0 GB. In this case, when the capacity is the lowest, λ = 0.44 μm, N.I. A. = 0.6, so
Recording capacity is
3.0 × (0.65 / 0.44) ² GB
= 6.5GB
And
T.A. P. = 0.8 × 0.44 / 0.65 [μm]
= 0.54 μm
L. D. = 0.35 × 0.44 / 0.65 [μm / bit]
= 0.24 μm / bit.

When the capacity is highest, λ = 0.39, N.D. A. = 0.72, so
Recording capacity is
3.60 (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 12GB
T.A. P. = 0.8 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.4μm
L. D. = 0.35 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.18 μm / bit.

  Therefore, in the present invention, the track pitch T.P. P. Is an optical recording having a single spiral recordable area of 0.4 [μm] to 0.54 [μm] and a recording linear density of 0.18 [μm / bit] to 0.24 [μm / bit]. Configure the medium.

Next, DVD-RAM's T.I. P. = 0.74 μm L / G (Land and Groove) recording structure as a reference, the linear density L.G. D. = 0.41 μm / bit and the recording capacity is 2.6 GB. In this case, when the capacity is the lowest, λ = 0.44 μm, N.I. A. = 0.6, so
Recording capacity is
2.6 × (0.65 / 0.44) ² GB
= 5.7 GB
It becomes.
And T. P. As for the above-mentioned ROM disk,
T.A. P. = 0.74 x 0.44 / 0.65 [μm]
= 0.5μm
And
L. D. = 0.41 × 0.44 / 0.65 [μm / bit]
= 0.28 μm / bit
It is.

When the capacity is highest, λ = 0.39, N.D. A. = 0.72, so
Recording capacity is
2.6 × (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 10.4 GB
And
T.A. P. = 0.74 × 0.39 / 0.65 × 0.6 / 0.72 μm
= 0.37 μm
L. D. = 0.41 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.21 μm / bit

  Therefore, in the present invention, the land pitch having a track pitch of 0.37 [μm] to 0.50 [μm] and a recording linear density of 0.21 [μm / bit] to 0.28 [μm / bit]. An optical recording medium having a recordable area having an and groove structure is formed.

Further, in the format of the red laser described in the above-mentioned Nikkei Electronics, 1997.55.5 (no.688), page 13, Table 1, the wavelength is shortened and the high N.D. A. In the magneto-optical recording system, the ASOM (Advanced Storage Magneto Optical) format is used. P. = 0.6 μm, L. D. = 0.2 μm / bit, and the capacity is 7 GB.
The lowest recording capacity is
5 x (0.65 / 0.44) ² GB
= 10GB
In the L / G recording structure,
T.A. P. = 0.64 x 0.44 / 0.65 [μm]
= 0.43 μm
L. D. = 0.23 × 0.44 / 0.65 [μm / bit]
= 0.16 μm / bit
The highest recording capacity is
7 x (0.65 / 0.39 x 0.72 / 0.6) ² GB
= 28GB
T.A. P. = 0.6 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.30 μm
L. D. = 0.2 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.10 μm / bit
It is.

In the phase change method, T.M. P. = 0.56 μm, L.P. D. = 0.285 μm / bit, and the capacity is 5.2 GB.
The lowest recording capacity is
5.2 × (0.65 / 0.44) ² GB
= 11.3 GB
In the L / G recording structure,
T.A. P. = 0.56 x 0.44 / 0.65 [μm]
= 0.38 μm
L. D. = 0.285 × 0.44 / 0.65 [μm / bit]
= 0.19 μm / bit
The highest recording capacity is
5.2 × (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 21 GB
T.A. P. = 0.56 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.28 μm
L. D. = 0.285 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.10 μm / bit
It is.

  8 to 10 exemplify patterns on the information recording surface of the optical recording medium according to the present invention. FIG. 8 shows an example of the arrangement of the pit string data. For example, the pits P are formed on a single spiral line as shown in FIG. 8A, or are formed on two spiral lines in the illustrated example as shown in FIG. 8B. Can do.

Further, the example shown in FIG. 9 illustrates a configuration in which a recordable area 40 indicated by hatching is provided in an area other than the pit P forming portion.
This recordable area 40 can be a single or a plurality of spirals as in the above-described pit row.

  Further, when a plurality of structures such as a double spiral (two parallel spirals) are formed, a spiral groove is formed, and a recordable area is formed in each of the so-called lands in the groove and between the grooves, For example, the pits P that constitute the ROM portion may be formed on the land.

  Further, as shown in the schematic pattern diagram of FIG. 10A, a spiral groove Grv indicated by hatching is formed, and pit row data P is formed on each extension of the groove Grv and the land Lnd therebetween. As shown in FIGS. 10B and 10C, the groove Grv and the land Lnd can be formed continuously, and a row of pits P can be formed on the extension. For example, various arrangement configurations can be adopted.

  As described above, according to the respective formats of the optical recording medium according to the present invention, it is possible to increase the recording capacity and increase the recording capacity while maintaining compatibility with the conventional DVD and its recording / reproducing apparatus. .

  According to the optical recording / reproducing apparatus that performs at least one of optical recording and reproduction according to the present invention, the inclination of the optical apparatus that performs at least one of the optical recording and reproduction is adjusted according to the skew of the optical recording medium. The skew of the optical recording medium can be substantially corrected, and the recording and reproduction can be performed with excellent recording and reproduction characteristics.

It is a schematic block diagram of the optical recording / reproducing apparatus by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic block diagram of an example of the skew correction means of an example of the optical recording / reproducing apparatus by this invention. It is a schematic block diagram of an example of the optical pick-up part of the optical recording / reproducing apparatus by this invention. A and B are diagrams each showing an example of a recording pattern on the information recording surface of the optical recording medium according to the present invention. It is a figure which shows another example of the recording pattern of the information recording surface of the optical recording medium by this invention. A, B, and C are diagrams each showing another example of the recording pattern on the information recording surface of the optical recording medium according to the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Information recording surface, 2 ... Light transmission layer, 3 ... Clamp part, 4 ... Objective lens, 10 ... Optical recording medium, 11 ... 1st information recording surface, 12 ... 2nd information recording surface, 21 ... 1st board | substrate, 22 ... 2nd board | substrate, 30 ... correction | amendment means, 31 ... optical apparatus, 32 ... drive mechanism, 33 ... Skew detection means, 34 ... Amplifier, 35 ... Drive device, 36 ... Semiconductor laser, 37 ... Photodiode, 40 ... Recordable area, 41 ... Laser light source , 42... Grating, 43... Beam splitter, 44... Photodetecting element, P... Pit, L, L ₁ , L ₂ ... Laser beam, Lnd.・ Groove

  The present invention relates to an optical recording medium and an optical recording / reproducing apparatus, for example, an optical recording medium such as an optical disk or an optical card, and an optical recording / reproducing apparatus having a function of performing either or both of optical recording and reproduction.

  With the rapid development of the information society, digital signals are being promoted especially in the fields of information, communication, video, and audio. Along with this, there is an increasing demand for such software supply or higher density for optical disks as information recording media. As a means for realizing it, a short wavelength laser beam, that is, a blue laser is used as a laser beam for optical recording and reproduction, and / or a high N.D. A. (Numerical aperture) is the most reliable and effective.

On the other hand, in recent years, a DVD (Digital Versatile Disc) has been standardized and commercialized as a high-density optical disk, and is gradually spreading. In addition, for example, many technical developments for increasing the capacity on the extended line of a DVD have been reported (see, for example, Non-Patent Document 1).
Nikkei Electronics 1997.55.5 (no.688), page 13, table 1

  It is an object of the present invention to provide a high-density optical recording medium and an optical recording / reproducing apparatus that can perform recording and reproduction by a short wavelength blue laser while maintaining compatibility with a DVD.

Optical recording medium according to the present invention is an optical recording medium having a thickness to have a light transmission layer of 0.6 mm, the thickness unevenness of the light-transmitting layer is ^{± 5.98λ / (N.A.) 4} ≦ From the light transmission layer side, a wavelength λ of N.sub..ltoreq.440 nm is applied from the light transmitting layer side so that the N.D. A. Either recording or reproduction is performed through a lens system in which ≦ 0.72.

The recording reproducing apparatus according to the present invention, the thickness has a light transmission layer of 0.6 mm, the thickness unevenness of the light transmission layer of ^{± 5.98λ / (N.A.) 4} ≦ ± 10μm range The optical recording medium selected in the above is used. Then, the wavelength lambda of the light-transmitting layer side, the lambda ≦ 440 nm of the laser beam, N. A. An optical device that performs either optical recording or reproduction through an objective lens of ≦ 0.72 .

The present invention makes it possible to perform recording / reproduction with a compatibility with a conventional DVD even with a short wavelength laser whose wavelength is λ ≦ 440 nm by the above-described configuration.

  As described above, according to the optical recording medium of the present invention, the recording density can be increased and the recording capacity can be increased while maintaining compatibility with the conventional DVD and its recording / reproducing apparatus.

In addition, according to the optical recording / reproducing apparatus that performs either optical recording or reproduction according to the present invention, since skew correction is performed, the recording and reproduction can be performed with excellent recording and reproduction characteristics.

1 to 5, the optical recording medium 10 according to the present invention has a thickness t of 0.6 mm on the information recording surface 1 and an uneven thickness Δt of ± 5.98λ. / (NA) ⁴ ≦ ± 10 μm is formed, and from this light transmissive layer 2 side, a wavelength λ of λ ≦ 440 nm is applied by laser light having a wavelength λ ≦ 440 nm . A. (Numerical aperture) is N. A. Either recording or reproduction is performed through a lens system of ≦ 0.72 .

  Then, at least the thickness tc of the mounting portion to the drive portion, that is, the clamp portion 3 is set to a thickness corresponding to the DVD in order to correspond to the mounting portion to the drive portion of the optical recording / reproducing apparatus for a normal DVD. 2 mm.

  1 to 5 illustrate an optical recording medium 10 according to the present invention, but the optical recording medium according to the present invention is not limited to these examples.

In the example shown in FIGS. 1 and 2, an optical recording medium is constituted by a light-transmitting disk substrate made of injection molding such as polycarbonate (PC), for example, and at least a clamp part 3 to the disk rotation driving part of the optical recording / reproducing apparatus is provided. The thickness tc to be configured is 1.2 mm, and the thickness t of the light transmission layer 2 in the peripheral portion including the formation portion of the information recording surface 1 is the specific thickness described above, that is, 0.6 mm ± 5.98λ / (N. A.) This is the case of ⁴ .

The information recording surface 1 has an information recording surface of, for example, a ROM (Read Only Memory) type structure, for example, an information recording pit formed by a recording track, and an Al deposited film is formed on the surface thereof, or A structure in which a recordable area is formed in part or all may be used. On the information recording surface, for example, a guide groove is formed along the recording track, for example, on the above-described light-transmitting disk substrate, and further, for example, in the case of having a ROM configuration at least partially, a recording pit row is formed.
Then, on the information recording surface on which the recordable area is formed, the recordable area is formed within the groove, between the grooves, or both. Such an information recording surface may be configured such that, for example, a magneto-optical recording layer is applied to the above-described groove or pit formation surface and information is read by the Kerr effect, or phase change or pits are formed by irradiation of a recording laser. By formation, information can be read by optical characteristics, interference, or the like. Also, for example, a reflective layer is formed on these recording layers. Furthermore, a protective layer is formed on the surface of the information recording surface 2 as necessary.

  In the example shown in FIG. 1, the information recording surface 1 is formed on a surface that becomes a recess that is recessed from one main surface of the thick clamp portion 3. In the example shown in FIG. 2, the information recording surface 1 Is formed on a surface that forms the same surface as one main surface of the clamp portion 3.

  The optical recording and / or reproduction of information on the information recording surface 1 of these optical recording media is performed by focusing the laser light L from the side having the light transmission layer 2 by the objective lens 4 as shown in FIGS. Do by irradiation.

  In the example shown in FIGS. 3 and 4, the first and second substrates 21 and 22 are bonded to each other by, for example, an ultraviolet curable resin, and the total thickness tc including the clamp portion 3 is 1.2 mm. This is the case. These first and second substrates 21 and 22 are both made of the same material such as PC and have substantially the same thickness in order to avoid the occurrence of warpage. The substrate 22 can be formed of an opaque substrate.

  In the example of FIG. 3, the information recording surface 1 is formed on the surface of the first substrate 21 facing the second substrate 22. In the example of FIG. 4, When the information recording surface 1 is formed on the surface facing the substrate 21, the light transmitting layer 2 is formed on the information recording surface 1 of the first substrate 21 in any case. 3 and 4, the configuration of the information recording surface 1 can be the same as that described with reference to FIGS. 1 and 2.

  Then, optical recording and / or reproduction of information with respect to the information recording surface 1 of these optical recording media is performed by irradiation with laser light L from the side having the light transmission layer 2 as shown in FIGS.

  Also in the example of FIG. 5, the first and second substrates 21 and 22 are bonded to each other by, for example, an ultraviolet curable resin having optical transparency, and the total thickness tc including the above-described clamp portion 3 is 1.2 mm. This is the case. Also in this case, it is advantageous in avoiding the occurrence of warping that both the first and second substrates 21 and 22 are made of the same material such as PC and have the same thickness. However, the second substrate 22 can be constituted by an opaque substrate. In this example, one information recording surface, that is, the first and second information recording surfaces 11 and 12 are formed on the opposing surfaces of the first and second substrates 21 and 22, respectively.

  Also in this example, the light transmission layer 2 is constituted by the portion of the first substrate 21 on the first information recording surface 1 with respect to the first information recording surface 1. On the other hand, the light transmission layer 2 is configured to include, for example, an ultraviolet curable resin having light transmittance between the substrates 21 and 22.

The optical recording and / or reproduction of information on the information recording surfaces 11 and 12 of these optical recording media can be performed from the side having the light transmission layer 2, that is, the same substrate 21 side. In this case, the focus positions of the laser beams L ₁ and L ₂ of the same laser beam or different wavelengths are selected for the first and second information recording surfaces 11 and 12 for the information recording surfaces 11 and 12, respectively. Do.

Also in FIG. 5, the information recording surfaces 11 and 12 can be configured to correspond to the configurations described in FIGS. 1 and 2, but in this example, information for the second information recording surface 12 is used. recording, reproduction, from doing by transmitting the first information recording surface 11, the reflecting surface of the first information recording surface 11, the reflecting surface of the semi-transparent to the laser beam L _2, for example, the film thin It is constituted by a metal reflection film such as Al or a dielectric reflection film set to be translucent.

In the optical recording / reproducing apparatus according to the present invention, as described above, the light transmission layer having a thickness of 0.6 mm is formed on the information recording surface, and the thickness unevenness of the light transmission layer is ± 5.98λ / (N A.) An optical recording medium selected within the range of ⁴ ≦ ± 10 μm is used, and from the light transmission layer side, a laser beam having a wavelength λ of λ ≦ 440 nm is used. A. (Numerical aperture) is N. A. An optical device that performs either optical recording or reproduction through an objective lens of ≦ 0.72 .

  On the other hand, the optical recording / reproducing apparatus according to the present invention comprises an optical device 31 that performs optical recording and / or reproduction as shown in FIG. A correction means 30 is provided for performing mechanical or electrical correction to improve the signal characteristics according to the skew of the optical recording medium.

  In this case, the optical device 31 has, for example, a drive mechanism 32 that changes and adjusts the entire inclination of the optical device 31, for example, an electromagnetic unit or a mechanism that rotates the entire optical device 31 by motor driving and adjusts the inclination. .

  The information recording medium 10 includes a skew detection unit, an amplifier 34 that amplifies a detection signal therefrom, and a drive device 35 that drives and controls the drive mechanism 32 based on the output thereof.

The skew in the optical recording medium is generally due to saddle-like deformation, and the skew detection means 33 is configured to detect the inclination in each part. The detection means 33 is, for example, a detection light L ₀ having a wavelength or power that does not affect recording or reproduction on the optical recording medium 10, for example, a semiconductor laser 36 that generates laser light, and the detection light L ₀ . comprising a detecting element for example a photodiode 37 detects reflected light L _R from the optical recording medium 10. The detection light L ₀ from the detection means 33 is irradiated in the vicinity of the irradiation position of the laser light from the optical device 31.

Then, the reflected light L _R from the optical recording medium 10 of the detection light L ₀ is, since the incident position on the photodiode 37 varies depending on the inclination of the irradiation part of the detection light L _0, for example, a photodiode 37 By configuring with the divided photodiodes, it is possible to detect the inclination of the optical recording medium 10 near the irradiation position of the detection light L ₀ , that is, the irradiation position of the laser light from the optical device 31, based on the change in the light amount of each of the divided portions. . Therefore, the detection signal is amplified by the amplifier 34, and the output is input to the drive device 35, whereby the drive mechanism 32 is driven and controlled, and the tilt of the optical device 31 is adjusted. In this way, the optical characteristics of the optical device 31 are always good, for example, the generation of the distortion of the irradiation spot shape, and the reliable return light, that is, the reproduction light can be detected.

  The configuration of the optical device 31 main body can be based on various conventionally known configurations. For example, in the case of an optical device that performs optical reproduction, for example, as shown in a schematic configuration of FIG. 7, for example, a semiconductor laser or a laser light source 41 having a configuration including a laser and its wavelength conversion element, a grating 42, It has a beam splitter 43, an objective lens 4, and a detection element 44 such as a photodiode for reading out information by detecting the return light from the optical recording medium 10, that is, the reproduction light whose light intensity is modulated in accordance with the recorded information. It can be set as the structure which consists of.

As described above, the laser light, that is, the lasers L, L _1, and L ₂ shown in FIGS. 1 to 5 are obtained by converting the wavelength of the laser having a wavelength of 860 nm by the wavelength conversion element SHG (second harmonic generation) element. Is 430 nm laser light, or semiconductor laser light in the vicinity of 400 nm, and can be varied by about ± 10 nm. Therefore, the wavelength λ of the target laser light used in the present invention is 390 nm ≦ λ ≦ 440 nm. .

By the way, the permissible thickness unevenness of the light transmission layer 2 is described in FIG. M.M. And allowable skew S.E. M.M. Respectively
T.A. M.M. ∝λ / (NA) ⁴
S. M.M. ∝λ / (NA) ³ / t
The wavelength λ = 0.65 μm in the DVD, T. M.M. = ± 30 μm, S.I. M.M. = ± 0.4 ° based on the format, when the thickness t of the light transmission layer in the present invention is 0.6 mm,
T.A. M.M. = ± 30 × (0.6 / NA) ⁴ × (λ / 0.65)
= ± 5.98λ / (NA) ⁴
S. M.M. = ± 0.4 × (0.6 / NA) ³ × (λ / 0.65)
= ± 0.133λ / (NA) ³
It becomes.

By the way, when a substrate having a diameter of 120 mm and a thickness of 0.6 mm is manufactured by the current injection molding technique, ± 10 μm is the thickness accuracy, that is, the limit value of the thickness unevenness at the mass production level.
Considering this,
T.A. M.M. = ± 30 × (0.6 / NA) ⁴ × (λ / 0.65) ≧ 10 (1)
It becomes.

N. A. The upper limit of λ is when λ is the largest, and as described above, the largest value of λ is 440 nm (0.44 μm). A. Is
N. A. ≦ 0.72
It becomes.

That is, in the configuration of the present invention, when the thickness t of the light transmission layer is 0.6 mm, the thickness unevenness Δt is set to the allowable thickness T.sub. M.M. ± 5.98λ / (NA) ^{4 in} the range. Further, in the case of 0.39 μm ≦ λ ≦ 0.44 μm, the N.D. A. = 0.6 or more and 0.72 or less. That is, 0.6 ≦ N. A. ≦ 0.72.

  Also, the configuration when the diameter φ = 120 mm according to the present invention and the information recording surface is a single layer with reference to a signal recording area equivalent to that of a DVD will be described.

[In the case of ROM disk]
In the case of the lowest capacity, λ = 0.44 μm, N.D. A. = 0.6, the recording capacity of the DVD is 4.7 GB, and the track pitch T.I. P. = 0.74 μm, linear density L.P. D. = 0.27 μm / bit, the shortest pit length P _min = 0.4 μm, and as described above, λ = 0.65, S.I. M.M. = ± 0.4 °
For recording capacity,
4.7 × (0.65 / 0.44) ² GB
= 10.3 GB
It becomes.
And at this time
T.A. M.M. = ± 5.98λ / (NA) ⁴ [μm]
= ± 20 [μm]
S. M.M. = ± 0.133λ / (NA) ³ [°]
= ± 0.27 °
T.A. P. = 0.74 x 0.44 / 0.65 [μm]
= 0.5μm
L. D. = 0.27 × 0.44 / 0.65 [μm / bit]
= 0.18 μm / bit
P _min = 0.4 × 0.44 / 0.65 [μm]
= 0.27 μm.

On the other hand, in the case of the highest capacity, λ = 0.39 μm, N.P. A. = 0.72, so the recording capacity is
4.7 × (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 18.8 GB
It becomes.
At this time
T.A. M.M. = ± 5.98λ / (NA) ⁴ [μm]
= ± 9μm
S. M.M. = ± 0.133λ / (NA) ³ [°]
= ± 0.14 °
T.A. P. = 0.74 x 0.39 / 0.65 x 0.6 / 0.72 [μm]
= 0.37 μm
L. D. = 0.27 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.13 μm / bit
P _min = 0.4 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.20 μm.

  That is, in the optical recording medium in which the pit string data is recorded at least in part, in the present invention, the track pitch is 0.37 [μm] to 0.5 [μm], and the shortest pit length However, pit string data of 0.20 [μm] to 0.27 [μm] and recording linear density of 0.13 [μm / bit] to 0.18 [μm / bit] is used as at least a part of the information area. Recorded configuration.

Although these are of a reduced scale with respect to the DVD, the pit width is reduced by about 30% when the technique for reducing the pit width disclosed in JP-A-1-31748 is used.
And from this, it is reduced to 70% of the above _Pmin ,
P _min = 0.37 × 0.7 = 0.26 μm.
Furthermore, the capacity increases to 18.8 / 0.7 = 26.8 GB.

[For rewritable discs]
First, DVD + R / W (manufactured by Sony) is used as a standard. P. = 0.80 μm single spiral groove recording structure, linear density L.P. D. = 0.35 μm / bit and the recording capacity is 3.0 GB. In this case, when the capacity is the lowest, λ = 0.44 μm, N.I. A. = 0.6, so
Recording capacity is
3.0 × (0.65 / 0.44) ² GB
= 6.5GB
And
T.A. P. = 0.8 × 0.44 / 0.65 [μm]
= 0.54 μm
L. D. = 0.35 × 0.44 / 0.65 [μm / bit]
= 0.24 μm / bit.

When the capacity is highest, λ = 0.39, N.D. A. = 0.72, so
Recording capacity is
3.60 (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 12GB
T.A. P. = 0.8 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.4μm
L. D. = 0.35 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.18 μm / bit.

  Therefore, in the present invention, the track pitch T.P. P. Is an optical recording having a single spiral recordable area of 0.4 [μm] to 0.54 [μm] and a recording linear density of 0.18 [μm / bit] to 0.24 [μm / bit]. Configure the medium.

Next, DVD-RAM's T.I. P. = 0.74 μm L / G (Land and Groove) recording structure as a reference, the linear density L.G. D. = 0.41 μm / bit and the recording capacity is 2.6 GB. In this case, when the capacity is the lowest, λ = 0.44 μm, N.I. A. = 0.6, so
Recording capacity is
2.6 × (0.65 / 0.44) ² GB
= 5.7 GB
It becomes.
And T. P. As for the above-mentioned ROM disk,
T.A. P. = 0.74 x 0.44 / 0.65 [μm]
= 0.5μm
And
L. D. = 0.41 × 0.44 / 0.65 [μm / bit]
= 0.28 μm / bit
It is.

When the capacity is highest, λ = 0.39, N.D. A. = 0.72, so
Recording capacity is
2.6 × (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 10.4 GB
And
T.A. P. = 0.74 × 0.39 / 0.65 × 0.6 / 0.72 μm
= 0.37 μm
L. D. = 0.41 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.21 μm / bit

  Therefore, in the present invention, the land pitch having a track pitch of 0.37 [μm] to 0.50 [μm] and a recording linear density of 0.21 [μm / bit] to 0.28 [μm / bit]. An optical recording medium having a recordable area having an and groove structure is formed.

Further, in the format of the red laser described in the above-mentioned Nikkei Electronics, 1997.55.5 (no.688), page 13, Table 1, the wavelength is shortened and the high N.D. A. In the magneto-optical recording system, the ASOM (Advanced Storage Magneto Optical) format is used. P. = 0.6 μm, L. D. = 0.2 μm / bit, and the capacity is 7 GB.
The lowest recording capacity is
5 x (0.65 / 0.44) ² GB
= 10GB
In the L / G recording structure,
T.A. P. = 0.64 x 0.44 / 0.65 [μm]
= 0.43 μm
L. D. = 0.23 × 0.44 / 0.65 [μm / bit]
= 0.16 μm / bit
The highest recording capacity is
7 × (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 28GB
T.A. P. = 0.6 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.30 μm
L. D. = 0.2 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.10 μm / bit
It is.

In the phase change method, T.M. P. = 0.56 μm, L.P. D. = 0.285 μm / bit, and the capacity is 5.2 GB.
The lowest recording capacity is
5.2 × (0.65 / 0.44) ² GB
= 11.3 GB
In the L / G recording structure,
T.A. P. = 0.56 x 0.44 / 0.65 [μm]
= 0.38 μm
L. D. = 0.285 × 0.44 / 0.65 [μm / bit]
= 0.19 μm / bit
The highest recording capacity is
5.2 × (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 21 GB
T.A. P. = 0.56 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.28 μm
L. D. = 0.285 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.10 μm / bit
It is.

  8 to 10 exemplify patterns on the information recording surface of the optical recording medium according to the present invention. FIG. 8 shows an example of the arrangement of the pit string data. For example, the pits P are formed on a single spiral line as shown in FIG. 8A, or are formed on two spiral lines in the illustrated example as shown in FIG. 8B. Can do.

Further, the example shown in FIG. 9 illustrates a configuration in which a recordable area 40 indicated by hatching is provided in an area other than the pit P forming portion.
This recordable area 40 can be a single or a plurality of spirals as in the above-described pit row.

  Further, when a plurality of structures such as a double spiral (two parallel spirals) are formed, a spiral groove is formed, and a recordable area is formed in each of the so-called lands in the groove and between the grooves, For example, the pits P that constitute the ROM portion may be formed on the land.

  Further, as shown in the schematic pattern diagram of FIG. 10A, a spiral groove Grv indicated by hatching is formed, and pit row data P is formed on each extension of the groove Grv and the land Lnd therebetween. As shown in FIGS. 10B and 10C, the groove Grv and the land Lnd can be formed continuously, and a row of pits P can be formed on the extension. For example, various arrangement configurations can be adopted.

  As described above, according to the respective formats of the optical recording medium according to the present invention, it is possible to increase the recording capacity and increase the recording capacity while maintaining compatibility with the conventional DVD and its recording / reproducing apparatus. .

  According to the optical recording / reproducing apparatus that performs at least one of optical recording and reproduction according to the present invention, the inclination of the optical apparatus that performs at least one of the optical recording and reproduction is adjusted according to the skew of the optical recording medium. The skew of the optical recording medium can be substantially corrected, and the recording and reproduction can be performed with excellent recording and reproduction characteristics.

It is a schematic block diagram of the optical recording / reproducing apparatus by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic block diagram of an example of the skew correction means of an example of the optical recording / reproducing apparatus by this invention. It is a schematic block diagram of an example of the optical pick-up part of the optical recording / reproducing apparatus by this invention. A and B are diagrams each showing an example of a recording pattern on the information recording surface of the optical recording medium according to the present invention. It is a figure which shows another example of the recording pattern of the information recording surface of the optical recording medium by this invention. A, B, and C are diagrams each showing another example of the recording pattern on the information recording surface of the optical recording medium according to the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Information recording surface, 2 ... Light transmission layer, 3 ... Clamp part, 4 ... Objective lens, 10 ... Optical recording medium, 11 ... 1st information recording surface, 12 ... 2nd information recording surface, 21 ... 1st board | substrate, 22 ... 2nd board | substrate, 30 ... correction | amendment means, 31 ... optical apparatus, 32 ... drive mechanism, 33 ... Skew detection means, 34 ... Amplifier, 35 ... Drive device, 36 ... Semiconductor laser, 37 ... Photodiode, 40 ... Recordable area, 41 ... Laser light source , 42... Grating, 43... Beam splitter, 44... Photodetecting element, P... Pit, L, L ₁ , L ₂ ... Laser beam, Lnd.・ Groove

  The present invention relates to an optical recording medium and an optical recording / reproducing apparatus, for example, an optical recording medium such as an optical disk or an optical card, and an optical recording / reproducing apparatus having a function of performing either or both of optical recording and reproduction.

  With the rapid development of the information society, digital signals are being promoted especially in the fields of information, communication, video, and audio. Along with this, there is an increasing demand for such software supply or higher density for optical disks as information recording media. As a means for realizing it, a short wavelength laser beam, that is, a blue laser is used as a laser beam for optical recording and reproduction, and / or a high N.D. A. (Numerical aperture) is the most reliable and effective.

On the other hand, in recent years, a DVD (Digital Versatile Disc) has been standardized and commercialized as a high-density optical disk, and is gradually spreading. In addition, for example, many technical developments for increasing the capacity on the extended line of a DVD have been reported (see, for example, Non-Patent Document 1).
Nikkei Electronics 1997.55.5 (no.688), page 13, table 1

  It is an object of the present invention to provide a high-density optical recording medium and an optical recording / reproducing apparatus that can perform recording and reproduction by a short wavelength blue laser while maintaining compatibility with a DVD.

Optical recording medium according to the present invention is an optical recording medium having a thickness to have a light transmission layer of 0.6 mm, the thickness unevenness of the light-transmitting layer is ^{± 5.98λ / (N.A.) 4} ≧ From the light transmission layer side, a wavelength λ of N.sub..ltoreq.440 nm is applied from the light transmitting layer side so that the N.D. A. Either recording or reproduction is performed through a lens system in which ≦ 0.72.

The recording reproducing apparatus according to the present invention, the thickness has a light transmission layer of 0.6 mm, the thickness unevenness of the light transmission layer of ^{± 5.98λ / (N.A.) 4} ≧ ± 10μm range The optical recording medium selected in the above is used. Then, the wavelength lambda of the light-transmitting layer side, the lambda ≦ 440 nm of the laser beam, N. A. An optical device that performs either optical recording or reproduction through an objective lens of ≦ 0.72 .

The present invention makes it possible to perform recording / reproduction with a compatibility with a conventional DVD even with a short wavelength laser whose wavelength is λ ≦ 440 nm by the above-described configuration.

  As described above, according to the optical recording medium of the present invention, the recording density can be increased and the recording capacity can be increased while maintaining compatibility with the conventional DVD and its recording / reproducing apparatus.

In addition, according to the optical recording / reproducing apparatus that performs either optical recording or reproduction according to the present invention, since skew correction is performed, the recording and reproduction can be performed with excellent recording and reproduction characteristics.

1 to 5, the optical recording medium 10 according to the present invention has a thickness t of 0.6 mm on the information recording surface 1 and an uneven thickness Δt of ± 5.98λ. / (NA) ^{4 4} ≧ ± 10 μm is formed, and from this light transmitting layer 2 side, the wavelength λ is λ ≦ 440 nm by a laser beam. A. (Numerical aperture) is N. A. Either recording or reproduction is performed through a lens system of ≦ 0.72 .

  Then, at least the thickness tc of the mounting portion to the drive portion, that is, the clamp portion 3 is set to a thickness corresponding to the DVD in order to correspond to the mounting portion to the drive portion of the optical recording / reproducing apparatus for a normal DVD. 2 mm.

  1 to 5 illustrate an optical recording medium 10 according to the present invention, but the optical recording medium according to the present invention is not limited to these examples.

In the example shown in FIGS. 1 and 2, an optical recording medium is constituted by a light-transmitting disk substrate made of injection molding such as polycarbonate (PC), for example, and at least a clamp part 3 to the disk rotation driving part of the optical recording / reproducing apparatus is provided. The thickness tc to be configured is 1.2 mm, and the thickness t of the light transmission layer 2 in the peripheral portion including the formation portion of the information recording surface 1 is the specific thickness described above, that is, 0.6 mm ± 5.98λ / (N. A.) This is the case of ⁴ .

The information recording surface 1 has an information recording surface of, for example, a ROM (Read Only Memory) type structure, for example, an information recording pit formed by a recording track, and an Al deposited film is formed on the surface thereof, or A structure in which a recordable area is formed in part or all may be used. On the information recording surface, for example, a guide groove is formed along the recording track, for example, on the above-described light-transmitting disk substrate, and further, for example, in the case of having a ROM configuration at least partially, a recording pit row is formed.
Then, on the information recording surface on which the recordable area is formed, the recordable area is formed within the groove, between the grooves, or both. Such an information recording surface may be configured such that, for example, a magneto-optical recording layer is applied to the above-described groove or pit formation surface and information is read by the Kerr effect, or phase change or pits are formed by irradiation of a recording laser. By formation, information can be read by optical characteristics, interference, or the like. Also, for example, a reflective layer is formed on these recording layers. Furthermore, a protective layer is formed on the surface of the information recording surface 2 as necessary.

  In the example shown in FIG. 1, the information recording surface 1 is formed on a surface that becomes a recess that is recessed from one main surface of the thick clamp portion 3. In the example shown in FIG. 2, the information recording surface 1 Is formed on a surface that forms the same surface as one main surface of the clamp portion 3.

  The optical recording and / or reproduction of information on the information recording surface 1 of these optical recording media is performed by focusing the laser light L from the side having the light transmission layer 2 by the objective lens 4 as shown in FIGS. Do by irradiation.

  In the example shown in FIGS. 3 and 4, the first and second substrates 21 and 22 are bonded to each other by, for example, an ultraviolet curable resin, and the total thickness tc including the clamp portion 3 is 1.2 mm. This is the case. These first and second substrates 21 and 22 are both made of the same material such as PC and have substantially the same thickness in order to avoid the occurrence of warpage. The substrate 22 can be formed of an opaque substrate.

  In the example of FIG. 3, the information recording surface 1 is formed on the surface of the first substrate 21 facing the second substrate 22. In the example of FIG. 4, When the information recording surface 1 is formed on the surface facing the substrate 21, the light transmitting layer 2 is formed on the information recording surface 1 of the first substrate 21 in any case. 3 and 4, the configuration of the information recording surface 1 can be the same as that described with reference to FIGS. 1 and 2.

  Then, optical recording and / or reproduction of information with respect to the information recording surface 1 of these optical recording media is performed by irradiation with laser light L from the side having the light transmission layer 2 as shown in FIGS.

  Also in the example of FIG. 5, the first and second substrates 21 and 22 are bonded to each other by, for example, an ultraviolet curable resin having optical transparency, and the total thickness tc including the above-described clamp portion 3 is 1.2 mm. This is the case. Also in this case, it is advantageous in avoiding the occurrence of warping that both the first and second substrates 21 and 22 are made of the same material such as PC and have the same thickness. However, the second substrate 22 can be constituted by an opaque substrate. In this example, one information recording surface, that is, the first and second information recording surfaces 11 and 12 are formed on the opposing surfaces of the first and second substrates 21 and 22, respectively.

  Also in this example, the light transmission layer 2 is constituted by the portion of the first substrate 21 on the first information recording surface 1 with respect to the first information recording surface 1. On the other hand, the light transmission layer 2 is configured to include, for example, an ultraviolet curable resin having light transmittance between the substrates 21 and 22.

The optical recording and / or reproduction of information on the information recording surfaces 11 and 12 of these optical recording media can be performed from the side having the light transmission layer 2, that is, the same substrate 21 side. In this case, the focus positions of the laser beams L ₁ and L ₂ of the same laser beam or different wavelengths are selected for the first and second information recording surfaces 11 and 12 for the information recording surfaces 11 and 12, respectively. Do.

Also in FIG. 5, the information recording surfaces 11 and 12 can be configured to correspond to the configurations described in FIGS. 1 and 2, but in this example, information for the second information recording surface 12 is used. recording, reproduction, from doing by transmitting the first information recording surface 11, the reflecting surface of the first information recording surface 11, the reflecting surface of the semi-transparent to the laser beam L _2, for example, the film thin It is constituted by a metal reflection film such as Al or a dielectric reflection film set to be translucent.

In the optical recording / reproducing apparatus according to the present invention, as described above, the light transmission layer having a thickness of 0.6 mm is formed on the information recording surface, and the thickness unevenness of the light transmission layer is ± 5.98λ / (N A.) An optical recording medium selected within the range of ⁴ ≧ ± 10 μm is used, and from the light transmission layer side, a laser beam having a wavelength λ of λ ≦ 440 nm is used. A. (Numerical aperture) is N. A. An optical device that performs either optical recording or reproduction through an objective lens of ≦ 0.72 .

  On the other hand, the optical recording / reproducing apparatus according to the present invention comprises an optical device 31 that performs optical recording and / or reproduction as shown in FIG. A correction means 30 is provided for performing mechanical or electrical correction to improve the signal characteristics according to the skew of the optical recording medium.

  In this case, the optical device 31 has, for example, a drive mechanism 32 that changes and adjusts the entire inclination of the optical device 31, for example, an electromagnetic unit or a mechanism that rotates the entire optical device 31 by motor driving and adjusts the inclination. .

  The information recording medium 10 includes a skew detection unit, an amplifier 34 that amplifies a detection signal therefrom, and a drive device 35 that drives and controls the drive mechanism 32 based on the output thereof.

The skew in the optical recording medium is generally due to saddle-like deformation, and the skew detection means 33 is configured to detect the inclination in each part. The detection means 33 is, for example, a detection light L ₀ having a wavelength or power that does not affect recording or reproduction on the optical recording medium 10, for example, a semiconductor laser 36 that generates laser light, and the detection light L ₀ . comprising a detecting element for example a photodiode 37 detects reflected light L _R from the optical recording medium 10. The detection light L ₀ from the detection means 33 is irradiated in the vicinity of the irradiation position of the laser light from the optical device 31.

Then, the reflected light L _R from the optical recording medium 10 of the detection light L ₀ is, since the incident position on the photodiode 37 varies depending on the inclination of the irradiation part of the detection light L _0, for example, a photodiode 37 By configuring with the divided photodiodes, it is possible to detect the inclination of the optical recording medium 10 near the irradiation position of the detection light L ₀ , that is, the irradiation position of the laser light from the optical device 31, based on the change in the light amount of each of the divided portions. . Therefore, the detection signal is amplified by the amplifier 34, and the output is input to the drive device 35, whereby the drive mechanism 32 is driven and controlled, and the tilt of the optical device 31 is adjusted. In this way, the optical characteristics of the optical device 31 are always good, for example, the generation of the distortion of the irradiation spot shape, and the reliable return light, that is, the reproduction light can be detected.

  The configuration of the optical device 31 main body can be based on various conventionally known configurations. For example, in the case of an optical device that performs optical reproduction, for example, as shown in a schematic configuration of FIG. 7, for example, a semiconductor laser or a laser light source 41 having a configuration including a laser and a wavelength conversion element thereof, a grating 42, It has a beam splitter 43, an objective lens 4, and a detection element 44 such as a photodiode for reading out information by detecting the return light from the optical recording medium 10, that is, the reproduction light whose light intensity is modulated in accordance with the recorded information. It can be set as the structure which consists of.

As described above, the laser light, that is, the lasers L, L _1, and L ₂ shown in FIGS. 1 to 5 are obtained by converting the wavelength of the laser having a wavelength of 860 nm by the wavelength conversion element SHG (second harmonic generation) element. Is 430 nm laser light, or semiconductor laser light in the vicinity of 400 nm, and can be varied by about ± 10 nm. Therefore, the wavelength λ of the target laser light used in the present invention is 390 nm ≦ λ ≦ 440 nm. .

By the way, the permissible thickness unevenness of the light transmission layer 2 is described in FIG. M.M. And allowable skew S.E. M.M. Respectively
T.A. M.M. ∝λ / (NA) ⁴
S. M.M. ∝λ / (NA) ³ / t
The wavelength λ = 0.65 μm in the DVD, T. M.M. = ± 30 μm, S.I. M.M. = ± 0.4 ° based on the format, when the thickness t of the light transmission layer in the present invention is 0.6 mm,
T.A. M.M. = ± 30 × (0.6 / NA) ⁴ × (λ / 0.65)
= ± 5.98λ / (NA) ⁴
S. M.M. = ± 0.4 × (0.6 / NA) ³ × (λ / 0.65)
= ± 0.133λ / (NA) ³
It becomes.

By the way, when a substrate having a diameter of 120 mm and a thickness of 0.6 mm is manufactured by the current injection molding technique, ± 10 μm is the thickness accuracy, that is, the limit value of the thickness unevenness at the mass production level.
Considering this,
T.A. M.M. = ± 30 × (0.6 / NA) ⁴ × (λ / 0.65) ≧ 10 (1)
It becomes.

N. A. The upper limit of λ is when λ is the largest, and as described above, the largest value of λ is 440 nm (0.44 μm). A. Is
N. A. ≦ 0.72
It becomes.

That is, in the configuration of the present invention, when the thickness t of the light transmission layer is 0.6 mm, the thickness unevenness Δt is set to the allowable thickness T.sub. M.M. ± 5.98λ / (NA) ^{4 in} the range. Further, in the case of 0.39 μm ≦ λ ≦ 0.44 μm, the N.D. A. = 0.6 or more and 0.72 or less. That is, 0.6 ≦ N. A. ≦ 0.72.

  Also, the configuration when the diameter φ = 120 mm according to the present invention and the information recording surface is a single layer with reference to a signal recording area equivalent to that of a DVD will be described.

[In the case of ROM disk]
In the case of the lowest capacity, λ = 0.44 μm, N.D. A. = 0.6, the recording capacity of the DVD is 4.7 GB, and the track pitch T.I. P. = 0.74 μm, linear density L.P. D. = 0.27 μm / bit, the shortest pit length P _min = 0.4 μm, and as described above, λ = 0.65, S.I. M.M. = ± 0.4 °
For recording capacity,
4.7 × (0.65 / 0.44) ² GB
= 10.3 GB
It becomes.
And at this time
T.A. M.M. = ± 5.98λ / (NA) ⁴ [μm]
= ± 20 [μm]
S. M.M. = ± 0.133λ / (NA) ³ [°]
= ± 0.27 °
T.A. P. = 0.74 x 0.44 / 0.65 [μm]
= 0.5μm
L. D. = 0.27 × 0.44 / 0.65 [μm / bit]
= 0.18 μm / bit
P _min = 0.4 × 0.44 / 0.65 [μm]
= 0.27 μm.

On the other hand, in the case of the highest capacity, λ = 0.39 μm, N.P. A. = 0.72, so the recording capacity is
4.7 × (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 18.8 GB
It becomes.
At this time
T.A. M.M. = ± 5.98λ / (NA) ⁴ [μm]
= ± 9μm
S. M.M. = ± 0.133λ / (NA) ³ [°]
= ± 0.14 °
T.A. P. = 0.74 x 0.39 / 0.65 x 0.6 / 0.72 [μm]
= 0.37 μm
L. D. = 0.27 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.13 μm / bit
P _min = 0.4 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.20 μm.

  That is, in the optical recording medium in which the pit string data is recorded at least in part, in the present invention, the track pitch is 0.37 [μm] to 0.5 [μm], and the shortest pit length However, pit string data of 0.20 [μm] to 0.27 [μm] and a recording linear density of 0.13 [μm / bit] to 0.18 [μm / bit] are used as at least a part of the information area. Recorded configuration.

Although these are of a reduced scale with respect to the DVD, the pit width is reduced by about 30% when the technique for reducing the pit width disclosed in JP-A-1-31748 is used.
And from this, it is reduced to 70% of the above _Pmin ,
P _min = 0.37 × 0.7 = 0.26 μm.
Furthermore, the capacity increases to 18.8 / 0.7 = 26.8 GB.

[For rewritable discs]
First, DVD + R / W (manufactured by Sony) is used as a standard. P. = 0.80 μm single spiral groove recording structure, linear density L.P. D. = 0.35 μm / bit and the recording capacity is 3.0 GB. In this case, when the capacity is the lowest, λ = 0.44 μm, N.I. A. = 0.6, so
Recording capacity is
3.0 × (0.65 / 0.44) ² GB
= 6.5GB
And
T.A. P. = 0.8 × 0.44 / 0.65 [μm]
= 0.54 μm
L. D. = 0.35 × 0.44 / 0.65 [μm / bit]
= 0.24 μm / bit.

When the capacity is highest, λ = 0.39, N.D. A. = 0.72, so
Recording capacity is
3.60 (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 12GB
T.A. P. = 0.8 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.4μm
L. D. = 0.35 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.18 μm / bit.

  Therefore, in the present invention, the track pitch T.P. P. Is an optical recording having a single spiral recordable area of 0.4 [μm] to 0.54 [μm] and a recording linear density of 0.18 [μm / bit] to 0.24 [μm / bit]. Configure the medium.

Next, DVD-RAM's T.I. P. = 0.74 μm L / G (Land and Groove) recording structure as a reference, the linear density L.G. D. = 0.41 μm / bit and the recording capacity is 2.6 GB. In this case, when the capacity is the lowest, λ = 0.44 μm, N.I. A. = 0.6, so
Recording capacity is
2.6 × (0.65 / 0.44) ² GB
= 5.7 GB
It becomes.
And T. P. As for the above-mentioned ROM disk,
T.A. P. = 0.74 x 0.44 / 0.65 [μm]
= 0.5μm
And
L. D. = 0.41 × 0.44 / 0.65 [μm / bit]
= 0.28 μm / bit
It is.

When the capacity is highest, λ = 0.39, N.D. A. = 0.72, so
Recording capacity is
2.6 × (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 10.4 GB
And
T.A. P. = 0.74 × 0.39 / 0.65 × 0.6 / 0.72 μm
= 0.37 μm
L. D. = 0.41 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.21 μm / bit

  Therefore, in the present invention, the land pitch having a track pitch of 0.37 [μm] to 0.50 [μm] and a recording linear density of 0.21 [μm / bit] to 0.28 [μm / bit]. An optical recording medium having a recordable area having an and groove structure is formed.

Further, in the format of the red laser described in the above-mentioned Nikkei Electronics, 1997.55.5 (no.688), page 13, Table 1, the wavelength is shortened and the high N.D. A. In the magneto-optical recording system, the ASOM (Advanced Storage Magneto Optical) format is used. P. = 0.6 μm, L. D. = 0.2 μm / bit, and the capacity is 7 GB.
The lowest recording capacity is
5 x (0.65 / 0.44) ² GB
= 10GB
In the L / G recording structure,
T.A. P. = 0.64 x 0.44 / 0.65 [μm]
= 0.43 μm
L. D. = 0.23 × 0.44 / 0.65 [μm / bit]
= 0.16 μm / bit
The highest recording capacity is
7 × (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 28GB
T.A. P. = 0.6 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.30 μm
L. D. = 0.2 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.10 μm / bit
It is.

In the phase change method, T.M. P. = 0.56 μm, L.P. D. = 0.285 μm / bit, and the capacity is 5.2 GB.
The lowest recording capacity is
5.2 × (0.65 / 0.44) ² GB
= 11.3 GB
In the L / G recording structure,
T.A. P. = 0.56 x 0.44 / 0.65 [μm]
= 0.38 μm
L. D. = 0.285 × 0.44 / 0.65 [μm / bit]
= 0.19 μm / bit
The highest recording capacity is
5.2 × (0.65 / 0.39 × 0.72 / 0.6) ² GB
= 21 GB
T.A. P. = 0.56 × 0.39 / 0.65 × 0.6 / 0.72 [μm]
= 0.28 μm
L. D. = 0.285 × 0.39 / 0.65 × 0.6 / 0.72 [μm / bit]
= 0.10 μm / bit
It is.

  8 to 10 exemplify patterns on the information recording surface of the optical recording medium according to the present invention. FIG. 8 shows an example of the arrangement of the pit string data. For example, the pits P are formed on a single spiral line as shown in FIG. 8A, or are formed on two spiral lines in the illustrated example, as shown in FIG. 8B. Can do.

Further, the example shown in FIG. 9 illustrates a configuration in which a recordable area 40 indicated by hatching is provided in an area other than the pit P forming portion.
This recordable area 40 can be a single or a plurality of spirals as in the above-described pit row.

  Further, when a plurality of structures such as a double spiral (two parallel spirals) are formed, a spiral groove is formed, and a recordable area is formed in each of the so-called lands in the groove and between the grooves, For example, the pits P that constitute the ROM portion may be formed on the land.

  Further, as shown in the schematic pattern diagram of FIG. 10A, a spiral groove Grv indicated by hatching is formed, and pit row data P is formed on each extension of the groove Grv and the land Lnd therebetween. As shown in FIGS. 10B and 10C, the groove Grv and the land Lnd can be formed continuously, and a row of pits P can be formed on the extension. For example, various arrangement configurations can be adopted.

  As described above, according to the respective formats of the optical recording medium according to the present invention, it is possible to increase the recording capacity and increase the recording capacity while maintaining compatibility with the conventional DVD and its recording / reproducing apparatus. .

  According to the optical recording / reproducing apparatus that performs at least one of optical recording and reproduction according to the present invention, the inclination of the optical apparatus that performs at least one of the optical recording and reproduction is adjusted according to the skew of the optical recording medium. The skew of the optical recording medium can be substantially corrected, and the recording and reproduction can be performed with excellent recording and reproduction characteristics.

It is a schematic block diagram of the optical recording / reproducing apparatus by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic sectional drawing of another example of the optical recording medium by this invention. It is a schematic block diagram of an example of the skew correction means of an example of the optical recording / reproducing apparatus by this invention. It is a schematic block diagram of an example of the optical pick-up part of the optical recording / reproducing apparatus by this invention. A and B are diagrams each showing an example of a recording pattern on the information recording surface of the optical recording medium according to the present invention. It is a figure which shows another example of the recording pattern of the information recording surface of the optical recording medium by this invention. A, B, and C are diagrams each showing another example of the recording pattern on the information recording surface of the optical recording medium according to the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Information recording surface, 2 ... Light transmission layer, 3 ... Clamp part, 4 ... Objective lens, 10 ... Optical recording medium, 11 ... 1st information recording surface, 12 ... 2nd information recording surface, 21 ... 1st board | substrate, 22 ... 2nd board | substrate, 30 ... correction | amendment means, 31 ... optical apparatus, 32 ... drive mechanism, 33 ... Skew detection means, 34 ... Amplifier, 35 ... Drive device, 36 ... Semiconductor laser, 37 ... Photodiode, 40 ... Recordable area, 41 ... Laser light source , 42... Grating, 43... Beam splitter, 44... Photodetecting element, P... Pit, L, L ₁ , L ₂ ... Laser beam, Lnd.・ Groove

Claims (11)

A light transmission layer having a thickness of 0.6 mm is provided, and from the light transmission layer side, a laser beam having a wavelength λ of 390 nm ≦ λ ≦ 440 nm is used. A. (Numerical aperture) is 0.6 ≦ N. A. An optical recording medium on which at least one of recording and reproduction is performed through a lens system of ≦ 0.72.
An optical recording medium, wherein the thickness unevenness of the light transmission layer is selected within a range of ± 5.98λ / (NA) ⁴ .  2. The optical recording medium according to claim 1, wherein at least a clamp portion has a thickness of 1.2 mm. 2. The optical recording medium according to claim 1, wherein the skew is within a range of ± 0.133λ [μm] / (NA) ³ [°].  Pit string data having a track pitch of 0.37 [μm] to 0.50 [μm], a shortest pit length of 0.27 μm or less, and a recording linear density of 0.18 [μm / bit] or less is an information area. The optical recording medium according to claim 1, wherein the optical recording medium is recorded on at least a part of the optical recording medium.  The track pitch is 0.37 [μm] to 0.50 [μm], the shortest pit length is 0.20 μm to 0.27 μm, and the recording linear density is 0.13 [μm / bit] to 0.18 [ 2. The optical recording medium according to claim 1, wherein pit row data of μm / bit] is recorded in at least a part of the information area.  2. The recordable area having a track pitch of 0.54 [μm] or less and a recording linear density of 0.24 [μm / bit] or less in at least a part of the information recording area. Optical recording media.  A recordable area having a track pitch of 0.4 [μm] to 0.54 [μm] and a recording linear density of 0.18 [μm / bit] to 0.24 [μm / bit] is at least an information recording area. The optical recording medium according to claim 1, wherein the optical recording medium is partially included.  At least a part of the information recording area has a recordable area having a land-and-groove recording structure with a track pitch of 0.50 [μm] or less and a recording linear density of 0.28 [μm / bit] or less. The optical recording medium according to claim 1.  Land-and-groove recording structure with a track pitch of 0.37 [μm] to 0.50 [μm] and a recording linear density of 0.21 [μm / bit] to 0.28 [μm / bit]. The optical recording medium according to claim 1, further comprising a recordable area in at least a part of the information recording area. An optical recording medium having a light-transmitting layer having a thickness of 0.6 mm, the thickness unevenness of the light-transmitting layer being selected within a range of ± 5.98λ / (NA) ⁴ is used. From the light transmission layer side, the laser beam having a wavelength λ of 390 nm ≦ λ ≦ 440 nm is used for N. A. (Numerical aperture) is 0.6 ≦ N. A. An optical recording / reproducing apparatus comprising an optical device that performs at least one of optical recording and reproduction through an objective lens satisfying ≦ 0.72.  The optical recording / reproducing apparatus according to claim 10, wherein the optical apparatus includes a mechanical or electrical correction unit that corrects a signal characteristic according to a skew of the optical recording medium.

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