JP2002150611A - Multilayer optical disk, method and apparatus for recording and reproducing multilayer optical disk - Google Patents

Abstract

PROBLEM TO BE SOLVED: To confine an information signal surface to form a mask film in a multilayer optical disk in which the information signal surface having two or more layers is formed. SOLUTION: In the multilayer optical disk D1 in which a laser beam L is made incident from one surface 11a of a transparent disk substrate 11, information signal surfaces 11b and 21b having two or more layers are formed, on the side of the other surface 11b opposed to the one surface of the disk substrate 11, for performing recording and/or reproduction by using the laser beam L, a mask film 23 whose temperature is raised to increase light transmittance when the irradiated light intensity of the laser beam L is intensified is formed only on an information signal surface 21b among the information signal surfaces 11b and 21b having two or more layers most distant from the one surface 11a of the disk substrate 11 on which the laser beam L are made incident.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method in which a laser beam is incident from one surface of a transparent disk substrate and two or more information signal surfaces are formed on the other surface of the disk substrate. Among the information signal surfaces of more than one layer, a multilayer optical disk having a mask film formed on the information signal surface farthest from the laser light incident surface and having a higher temperature and a higher light transmittance when the irradiation light intensity of the laser light is increased. The present invention relates to a multilayer optical disk recording / reproducing method and apparatus for recording and / or reproducing a multilayer optical disk.

[0002]

2. Description of the Related Art Generally, an optical disk is known as a recording / reproducing medium capable of recording / reproducing a large amount of information signals and having a short access time. There is a demand for further high-density recording / reproducing with the use of a.

As a method for recording and / or reproducing information signals optically at a high density on an optical disk, for example, the following methods have been proposed.

That is, this method includes (a) shortening the wavelength of recording and / or reproducing laser light;
(B) increasing the NA (numerical aperture) of the objective lens focused on the optical disc; (c) making the information signal surface for recording and / or reproducing the information signal a multi-layer; Multiplex recording at different wavelengths,
(E) When the irradiation light intensity of the laser light is increased on the information signal surface to be recorded and / or reproduced, the temperature is increased and a mask film is formed to increase the light transmittance to substantially reduce the light spot diameter of the laser light. And other methods.

[0005] Among these methods, as an example of combining the above-mentioned items (c) and (e), an information surface for reproducing an information signal is formed in a multilayer (two layers) and a multilayer (2 layers) is formed.
A mask film is formed on the information surface of each layer, and a laser beam is irradiated from one surface of the optical disk to reproduce the information surface of each layer at a super-resolution, thereby greatly increasing the amount of information to the optical disk. The technical idea is disclosed in Japanese Patent Laid-Open No. 9-63121.
No. 6,086,045.

FIG. 9 is a sectional view showing a conventional optical information recording medium.

The conventional optical information recording medium 100 shown in FIG.
Is disclosed in the above-mentioned Japanese Patent Application Laid-Open No. 9-63121, and will be briefly described here with reference to the same.

FIG. 9 shows a conventional optical information recording medium 10.
0 is diameter 120mm, thickness 0.6mm and diameter 15mm
The first information surface 102 is formed on the first
With a diameter of 120 mm and a thickness of 0.1 mm.
The second information surface 1 has a center hole of 6 mm and a diameter of 15 mm.
12 and the second transparent substrate 111 on which the transparent layer 1 is formed.
The first information surface 102 through the second information surface 112
It is a structure that is bonded so as to face.

The above-mentioned first information surface 102 is covered with a first masking layer 103 which has a low light transmittance for reproduction light at a low temperature and transmits most of the reproduction light at a high temperature,
Further, the first masking layer 103 has a low light transmittance to reproduction light at low temperatures, reflects most of the reproduction light, and transmits most of the reproduction light at high temperatures.
04.

[0010] The surface of the second information surface 112 is covered with a second reproducing layer 113 which constantly reflects most of the reproducing light,
Further, the second reproducing layer 113 is covered with a second masking layer 114 which has a low light transmittance for reproducing light at a low temperature and transmits most of the reproducing laser light at a high temperature.

At this time, the first masking layer 103 and the second masking layer 114 are made of Sb having a relatively low phase transition temperature.
Using _X Se _1-X, the first reproducing layer 104 has a relatively high PbO _X phase transition temperature.

The conventional optical information recording medium 10 having the above configuration
When reproducing 0, a laser beam is emitted from the first transparent substrate 101 side.

Here, first, when reproducing the first information surface 102, a low-power reproducing light is irradiated. The first masking layer 103 has a low reflectance and a low light transmittance below the phase transition temperature. At this time, since the temperature of the outer peripheral portion of the reproduction light spot is low, the first masking layer 103 in the low temperature region is used.
Although the light transmittance of the first masking layer 103 is low and information cannot be read, the light transmittance of the first masking layer 103 in a region where the temperature is high is greatly increased because the temperature of the central portion of the reproduction light spot is high. In this state, the center of the reproduction light spot reaches the first reproduction layer 104, and the information on the first information surface 102 can be reproduced. Therefore, a region where the intensity distribution of the reproduction light is weak is cut off by the mask effect of the first masking layer 103, and the spot diameter of the reproduction light is substantially reduced. At this time, the reproduction light has not reached the second information surface 112.

On the other hand, in order to reproduce the second information surface 112, the first masking layer 1 in the region irradiated with the reproduction light is required.
03 and the first reproducing layer 104 are irradiated with a high-power reproducing light which has a temperature equal to or higher than the phase transition temperature. As a result, the light transmittance of the first masking layer 103 and the first reproducing layer 104 increases sharply as the reflectance decreases, and the reproducing light reaches the second masking layer 114. When the reproduction light reaches the second masking layer 114, the second masking layer 11
In No. 4, the light transmittance increases only in the region where the intensity distribution of the reproduction light is strong due to the same effect as described above. As a result, the reproduction light
, The information can be read only from the second reproducing layer 113, and the second masking layer 114 can be read.
As a result, the signal from the region where the intensity distribution of the reproduction light is weak is cut off by the mask effect, and the spot diameter of the reproduction light is substantially reduced.

[0015]

By the way, in the above-mentioned conventional optical information recording medium 100, the first and second information surfaces 1 are provided.
02, 112 respectively, the first and second masking layers 10
3, 114, the first and second information surfaces 1
02, 112 by switching the reproduction power of the laser beam, and the first and second information surfaces 102, 11 by the mask effect of the first and second masking layers 103, 114.
2 can perform high-density reproduction (super-resolution reproduction), but when reproducing the second information surface 112, the laser beam passes through the first and second masking layers 103 and 114. Since the power is greatly attenuated by the first and second masking layers 103 and 114, it is necessary to increase the reproduction power by an amount corresponding to the amount of attenuation. At this time, if the amount of light attenuation in the first masking layer 103 is reduced, the mask effect is almost eliminated.

Therefore, when reproducing the second information surface 112, the reproduction power of the laser beam is greatly increased as compared with the case where the first information surface 102 is reproduced. Problems such as a reduction in the life of the semiconductor laser element due to heat generation of the semiconductor laser element and a deterioration in the reproduction performance of the second information surface 112 due to the influence of the first masking layer 103 also occur.

In view of the above, the present invention provides a multi-layer optical disk having two or more information signal surfaces, in which the information signal surface that causes a mask effect is limited to only one location.

[0018]

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and a first invention is to apply a laser beam from one surface of a transparent disk substrate, and In a multilayer optical disc having two or more layers of information signal surfaces formed on the other surface, an information signal surface farthest from one surface of the disk substrate on which the laser beam is incident, among the two or more layers of information signal surfaces. The multi-layer optical disc is characterized in that a mask film is formed only when the irradiation light intensity of the laser beam is increased, the temperature is increased and the light transmittance is increased.

According to a second aspect of the present invention, there is provided a multi-layer optical disc recording / reproducing method for recording and / or reproducing the multi-layer optical disc according to the first aspect, wherein the mask film is formed when reproducing from the multi-layer optical disc. Wherein the reproduction power of the laser light for the information signal surface is set higher than the reproduction power of the laser light for the information signal surface on which the mask film is not formed. It is.

According to a third aspect of the present invention, there is provided the multilayer optical disk recording / reproducing method for recording and / or reproducing the multilayer optical disk according to the first aspect of the present invention, wherein the mask film is formed during recording on the multilayer optical disk. Wherein the recording power of the laser beam for the information signal surface is set higher than the recording power of the laser beam for the information signal surface on which the mask film is not formed. It is.

According to a fourth aspect of the present invention, there is provided a multi-layer optical disc recording / reproducing apparatus for recording and / or reproducing the multi-layer optical disc according to the first aspect, wherein the mask film is formed when reproducing from the multi-layer optical disc. A semiconductor for driving and controlling a semiconductor laser element so as to set the reproduction power of the laser beam for the information signal surface thus set higher than the reproduction power of the laser beam for the information signal surface on which the mask film is not formed. A multi-layer optical disc recording / reproducing apparatus comprising a laser element drive control means.

According to a fifth aspect of the present invention, there is provided a multi-layer optical disc recording / reproducing apparatus for recording and / or reproducing the multi-layer optical disc according to the first aspect, wherein the mask film is formed during recording on the multi-layer optical disc. A semiconductor for driving and controlling a semiconductor laser element so as to set the recording power of the laser beam on the information signal surface thus set higher than the recording power of the laser beam on the information signal surface on which the mask film is not formed. A multi-layer optical disc recording / reproducing apparatus comprising a laser element drive control means.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of a multi-layer optical disc, a multi-layer optical disc recording / reproducing method and apparatus according to the present invention will be described below with reference to FIGS. The multi-layer optical disc of the fourth embodiment> and the <multi-layer optical disc recording / reproducing method and apparatus> will be described in detail in this order.

In the multilayer optical discs of the first to fourth embodiments according to the present invention, a laser beam enters from one face of a transparent disc substrate and the other face opposes one face of the disc substrate. When two or more information signal surfaces for recording and / or reproduction by laser light are formed on the side, only the information signal surface farthest from one of the two or more information signal surfaces on which the laser light is incident When the intensity of the irradiation light of the laser beam increases, the temperature increases and the light transmittance increases.

<Multilayer Optical Disc of First Embodiment> FIG. 1 is a schematic enlarged cross-sectional view of a multilayer optical disc of a first embodiment according to the present invention, and FIG. 2 is a laser of a mask film shown in FIG. FIG. 3 shows light transmittance and reflectance with respect to light wavelength, FIG. 3 shows light transmittance with respect to temperature of the mask film shown in FIG. 1, and FIG. 4 shows spot diameter transmitted through the mask film shown in FIG. FIG.

The multi-layer optical disc D1 of the first embodiment shown in FIG. 1 receives a laser beam from one surface of a transparent disk substrate, and transmits a laser beam to the other surface of the transparent disk substrate. When the information signal surface of the layer is formed, both of the information signal surfaces of the two layers are formed exclusively for reproduction, and of the information signal surfaces of the two layers, the information signal surface of the second layer far from the surface on which the laser beam is incident. In which a mask film is formed.

In FIG. 1, the multilayer optical disk D1 of the first embodiment includes a first disk substrate (hereinafter, referred to as a first transparent substrate) 11 and a second disk substrate (hereinafter, referred to as a second transparent substrate) 21. One information signal surface formed on each of them is attached to each other with a transparent adhesive or the like, with the information signal surfaces facing each other.
The laser beam L enters from one side, and each information signal surface on the first and second transparent substrates 11 and 21 can be selectively reproduced by the laser light L.

First, the first transparent substrate 11 is made of a transparent resin such as polycarbonate and is formed in a disk shape by molding with a center hole having a diameter of 120 mm, a thickness of 0.6 mm and a diameter of 15 mm. . Also, the first transparent substrate 11
One surface 11a is formed flat as an incident surface of the laser beam L, and the other surface 1a facing the one surface 11a
A concave / convex pit is formed in advance in a spiral or concentric shape on 1b, and the other surface 11b is a first information signal surface exclusively for reproduction.

The other surface 11b of the first transparent substrate 11
A transflective film 12 is formed thereon, and the transflective film 12 is made of a dielectric film such as SiO ₂ or SiN, or Au.
Is formed by a sputtering method or a vapor deposition method. At this time, the reflectance of the transflective film 12 for the laser light L is about 20%, and the light transmittance is about 75%.

On the other hand, the second transparent substrate 21 is also formed of a transparent resin such as polycarbonate and has a center hole of 120 mm in diameter, 0.6 mm in thickness and 15 mm in diameter, and is formed in a disk shape by molding. . Also, the second transparent substrate 21
One surface 21a is formed flat as a label printing surface, and uneven pits are previously formed in a spiral or concentric shape on the other surface 21b facing the one surface 21a, and the other surface 21b is formed. Is a second information signal surface dedicated to reproduction.

The other surface 21b of the second transparent substrate 21
A reflective film 22 is formed thereon, and this reflective film 22
A metal film such as 1 is formed by a sputtering method or an evaporation method. At this time, the reflectance of the reflection film 22 for the laser beam L is about 90%.

On the second transparent substrate 21 side, the reflection film 2
A mask film 23 is formed on the substrate 2 to increase the temperature and increase the light transmittance when the irradiation light intensity of the laser light L is increased. The mask film 23 is formed of a thermochromic material, a photochromic material, a phase change material, or the like. The film is formed using an evaporation method or a spin coating method.

The light transmittance of the mask film 23 is about 5% when the light intensity of the laser light L is low. In the first embodiment, a thermochromic material is used as a material of the mask film 23, for example, a product name GN manufactured by Yamamoto Kasei Co., Ltd.
(2) A mixture of a color former and a developer BHPE at a weight ratio of about 1: 2. FIG. 2 shows the light transmittance and the reflectance with respect to the laser light wavelength of the mask film 23 formed of the mixed mask film material, and FIG. 3 shows the change in the light transmittance with respect to the temperature of the mask film 23.

Here, the above-mentioned mask film 23 has a small light transmittance in a portion where the light intensity of the light spot by the laser beam L is weak, while the mask film 23 is optically or in a portion where the light intensity of the light spot is strong. The light is thermally absorbed by increasing the temperature by absorbing light, and the light transmittance is increased as shown in FIG. 3, and the light spot S by the laser light L is a spot transmitted through the mask film 23 as shown in FIG. The diameter becomes substantially smaller. In FIG. 4, when the multilayer optical disc D1 is rotating in the direction of the arrow, C indicates a mask film transmitting spot that transmits through the mask film 23, and D indicates a portion of a light spot that does not transmit through the mask film 23.

In the case of the mask film 23 in which the color former GN2 and the developer BHPE are mixed at a weight ratio of about 1: 2 and deposited, the laser light L having a wavelength of about 650 nm is used. By way of example, by changing the color former and the developer, it is possible to form a thermochromic mask film that can be used with laser light L of another wavelength.

Further, on the second transparent substrate 21 side, a protective film 24 is formed on the mask film 23.
Is for protecting the mask film 23 from an adhesive described later. In the first embodiment, a film was formed by spin coating using an alicyclic hydrocarbon resin as the material of the protective film 24. The alicyclic hydrocarbon resin actually used is Quinton 1345 (trade name, manufactured by Zeon Corporation). Incidentally, as the protective film 24, a dielectric such as SiO ₂ or MgF ₂ may be formed by a sputtering method or a vapor deposition method. Also, the mask film 23
When an inorganic material such as a phase change material is used, the protective film 24 can be omitted.

Then, the first transparent substrate 11 and the second transparent substrate 21 formed as described above are arranged such that the first and second information signal surfaces 11b and 21b of the concavo-convex shape are opposed to each other. The transparent intermediate material layer 20 is formed by bonding the two information signal surfaces 11b and 21b to each other with the transparent surface of the two information signal surfaces 11b and 21b facing each other by using a transparent adhesive.

Here, a photopolymer is dropped on the transflective film 12 of the first transparent substrate 11, and the protective film 24 of the second transparent substrate 21 is brought into contact therewith, while rotating at about 1000 RPM. , A photopolymer is evenly spread over the entire surface to be bonded, and then ultraviolet light is applied to the first transparent substrate 1.
Irradiation from one side cures the photopolymer, and the first and second transparent substrates 11 and 21 are bonded together.

At this time, since a mask film is not formed on the first information signal surface 11b of the first transparent substrate 11, the information capacity of the first information signal surface 11b is about 6 GB, while the second transparent signal surface 11b has a data capacity of about 6 GB. A mask film 2 is provided on the second information signal surface 21b of the substrate 21.
3, the information capacity of the second information signal surface 21b is about 14 GB since the second information signal surface 21b can be reproduced with a super resolution by the mask effect of the mask film 23. is there.

<Multilayer Optical Disk of Second Embodiment> FIG. 5 is a cross-sectional view schematically showing an enlarged multilayer optical disk of a second embodiment according to the present invention.

In the multi-layer optical disc D2 of the second embodiment shown in FIG. 5, a laser beam is incident on one side of a transparent disk substrate, and a laser beam is incident on the other side of the transparent disk substrate. When the information signal surface of the layer is formed, the information signal surface of the first layer, which is closer to the surface on which the laser beam is incident, of the two layers of the information signal surface is formed only for reproduction, and the surface on which the laser beam is incident is formed. The remote second information signal surface is formed for recording and reproduction, and a mask film is formed on the information signal surface for recording and reproduction.

In FIG. 5, the multilayer optical disk D2 of the second embodiment includes a first disk substrate (hereinafter, referred to as a first transparent substrate) 11 and a second disk substrate (hereinafter, referred to as a second transparent substrate) 31. One information signal surface formed on each of them is attached to each other with a transparent adhesive or the like, with the information signal surfaces facing each other.
The laser beam L enters from one side, and the information signal surfaces on the first and second transparent substrates 11 and 31 can be selectively reproduced / recorded / reproduced by the laser light L.

First, the first transparent substrate 11 is formed identically to the first transparent substrate of the first embodiment described above with reference to FIG. Although the detailed description is omitted, one surface 11a of the first transparent substrate 11 is
Is an incident surface of the laser beam L, and a semi-transmissive reflective film 12 is formed on an uneven pit formed on the other surface 11b opposite to the one surface 11a, and the other surface 11b is a reproduction-only second surface. One information signal surface.

On the other hand, the second transparent substrate 31 is formed of a transparent resin such as polycarbonate and has a center hole of 120 mm in diameter, 0.6 mm in thickness and 15 mm in diameter, and is formed in a disk shape by molding. . Also, the second transparent substrate 31
One surface 31a is formed flat as a label printing surface, and a convex land and a concave groove are alternately repeated on the other surface 31b opposite to the one surface 31a in a spiral or concentric manner. Is formed. At this time, the second
A lead-in signal is preformatted in the form of pits in the form of pits and protrusions on the inner peripheral portion of the transparent substrate 31, and convex lands and / or concave grooves are formed for recording and reproduction.

The other surface 31b of the second transparent substrate 31
A reflective film 32 is formed thereon, and this reflective film 32
A metal film such as 1 is formed by a sputtering method or an evaporation method. At this time, the reflectance of the reflection film 32 with respect to the laser beam L is about 90%.

On the second transparent substrate 31 side, the reflection film 3
2, a recording film 33 is formed, and the surface of the recording film 33 becomes a second information signal surface for recording and reproduction. The above recording film 3
3 denotes a ZnS—SiO ₂ dielectric film 33 a and an Ag—In—Sb—Te phase change material film 33 from the second transparent substrate 31 side.
and b, and a ZnS-SiO ₂ dielectric film 33c is formed by laminating in this order using a sputtering method or an evaporation method. still,
Te-Ge-Sb may be used as the above-mentioned phase change material film 33b.

On the second transparent substrate 31 side, the recording film 3
A mask film 34 is formed on 3 to increase the temperature and increase the light transmittance when the irradiation light intensity of the laser light L is increased. The mask film 34 is formed of a thermochromic material, a photochromic material, a phase change material, or the like. The film is formed using an evaporation method or a spin coating method.

This mask film 34 is formed in the same manner as the first embodiment using the same thermochromic mask film material as the mask film 23 (FIG. 1) of the first embodiment described above. The detailed description in is omitted.

Further, on the second transparent substrate 31 side, a protective film 35 is formed on the mask film 34.
This is also for protecting the mask film 34 from an adhesive described later, and is formed in the same manner as in the first embodiment using the same protective film material as in the first embodiment. Omitted.

Then, the first transparent substrate 11 and the second transparent substrate 31 formed as described above are arranged such that the first and second information signal surfaces 11b and 33 of the uneven shape are opposed to each other.
The transparent intermediate material layer 30 is formed by attaching the second information signal surfaces 11b and 33 side to each other by using a transparent adhesive and a photopolymer method with the inside facing each other with the adhesive surface side.

Here, a photopolymer is dropped on the transflective film 12 of the first transparent substrate 11, and the protective film 35 of the second transparent substrate 31 is brought into contact therewith, while rotating at a rotation speed of about 1000 RPM. , A photopolymer is evenly spread over the entire surface to be bonded, and then ultraviolet light is applied to the first transparent substrate 1.
Irradiation from one side cures the photopolymer, and the first and second transparent substrates 11 and 31 are bonded together.

At this time, since a mask film is not formed on the first information signal surface 11b of the first transparent substrate 11, the information capacity of the first information signal surface 11b is about 6 GB, while the second transparent signal surface 11b has an information capacity of about 6 GB. Since the mask film 34 is formed on the incident side of the laser beam L on the recording film 33 serving as the second information signal surface of the substrate 31, the recording film 3 is formed by the mask effect of the mask film 34.
3, the information capacity is about 10 GB because the information signal can be recorded and reproduced at super-resolution.

In the second embodiment, the mask film 34 is formed on the laser beam L incident side before the recording film 33 in the recording film 33 serving as the second information signal surface of the second transparent substrate 31. When the laser light L is incident, the mask effect by the mask film 34 acts. However, the mask film 34 is not formed before the recording film 33 and the mask film 34 is used instead.
Can be formed between the reflection film 32 and the recording film 33. In this case, the laser light L having a mask effect generated by the mask film 34 is reflected by the reflection film 32 to form the recording film. A method of reproducing the information signal recorded in the recording device 33 is also possible.

<Multilayer Optical Disk of Third Embodiment> FIG. 6 is a cross-sectional view schematically showing a multilayer optical disk of a third embodiment according to the present invention in an enlarged manner.

The multilayer optical disk D3 of the third embodiment according to the present invention shown in FIG. 6 receives a laser beam from one surface of a transparent disk substrate, and transmits a laser beam to the other surface of the transparent disk substrate. When the information signal surface of the layer is formed, the information signal surface of the first layer, which is closer to the surface on which the laser light is incident, of the two information signal surfaces is formed for recording and reproduction, and the surface on which the laser light is incident The information signal surface of the second layer, which is far from the information signal surface, is formed exclusively for reproduction, and a mask film is formed on the information signal surface exclusively for reproduction.

In FIG. 6, the multilayer optical disk D3 of the third embodiment includes a first disk substrate (hereinafter, referred to as a first transparent substrate) 41 and a second disk substrate (hereinafter, referred to as a second transparent substrate) 21. One information signal surface formed on each of them is bonded to each other with a transparent adhesive or the like with the information signal surfaces facing each other.
1 and the information signal surfaces of the first and second transparent substrates 41 and 21 are selectively recorded / reproduced / reproduced by the laser light L.
It can be played.

First, the first transparent substrate 41 is formed in a disk shape by molding using a transparent resin such as polycarbonate and having a center hole having a diameter of 120 mm, a thickness of 0.6 mm and a diameter of 15 mm. . Also, the first transparent substrate 41
One surface 41a is formed flat as an incident surface of the laser beam L, and the other surface 4a opposing the one surface 41a.
In 1b, a convex land and a concave groove are alternately and repeatedly formed in a spiral or concentric shape in advance. At this time, the lead-in signal is preformatted in the form of uneven pits on the inner peripheral portion of the first transparent substrate 41, and convex lands and / or concave grooves are formed for recording and reproduction. I have.

The other surface 41b of the first transparent substrate 41
A recording film 42 is formed thereon, and the surface of the recording film 42 becomes a first information signal surface for recording and reproduction. The recording film 42
Are a ZnS—SiO ₂ dielectric film 42 a and an Ag—In—Sb—Te phase change material film 42 b from the first transparent substrate 41 side.
When a ZnS-SiO ₂ dielectric layer 42c is formed by laminating in this order using a sputtering method or an evaporation method. Note that Te-Ge-Sb may be used as the phase change material film 42b.

On the first transparent substrate 41 side, the recording film 4
A semi-transmissive reflective film 43 is formed on the substrate 2, and the semi-transmissive reflective film 43 is formed by using a metal film such as Ag by sputtering or vapor deposition. At this time, the transflective film 43
Has a light transmittance of about 50%.

On the other hand, the second transparent substrate 21 is formed identically to the second transparent substrate of the first embodiment described above with reference to FIG. Although the detailed description is omitted, one surface 21a of the second transparent substrate 21 is
Denotes a label printing surface, and a reflective film 22 is formed on the uneven pits formed on the other surface 21b opposite to the one surface 21a.
, A mask film 23 and a protective film 24 are sequentially formed, and the other surface 21b is a second information signal surface dedicated to reproduction.

Then, the first transparent substrate 41 and the second transparent substrate 21 formed as described above are arranged such that the first and second information signal surfaces 42 and 21b of the uneven shape are opposed to each other.
The transparent intermediate material layer 40 is formed by attaching the second information signal surfaces 42 and 21b to each other by using a transparent adhesive with a photopolymer method with the inside facing each other with the side of the second information signal 42 and 21b as the bonding surface side.

Here, a photopolymer is dropped on the transflective film 43 of the first transparent substrate 41, and the protective film 24 of the second transparent substrate 21 is brought into contact therewith, while rotating at a rotation speed of about 1000 RPM. , A photopolymer is evenly spread over the entire surface to be bonded, and then ultraviolet light is applied to the first transparent substrate 4.
Irradiation from one side cures the photopolymer, and the first and second transparent substrates 41 and 21 are bonded together.

At this time, since a mask film is not formed on the recording film 42 serving as the first information signal surface of the first transparent substrate 41, the information capacity of the recording film 42 for the information signal is about 5.5 GB.
On the other hand, the second information signal surface 21 of the second transparent substrate 21
Since the mask film 23 is formed on the second information signal surface 21b, it is possible to reproduce the second information signal surface 21b with super-resolution by the mask effect of the mask film 23. The capacity is about 14 GB.

<Multilayer Optical Disk of Fourth Embodiment> FIG. 7 is a cross-sectional view schematically showing an enlarged multilayer optical disk of a fourth embodiment according to the present invention.

In the multilayer optical disk D4 of the fourth embodiment shown in FIG. 7, a laser beam enters from one surface of a transparent disk substrate, and the laser beam is applied to the other surface of the transparent disk substrate. When the information signal surface of the layer is formed, both the information signal surfaces of the two layers are formed for recording and reproduction, and a mask film is formed on the information signal surface of the second layer far from the surface on which the laser beam is incident. It is.

In FIG. 7, the multilayer optical disk D4 of the fourth embodiment includes a first disk substrate (hereinafter, referred to as a first transparent substrate) 41 and a second disk substrate (hereinafter, referred to as a second transparent substrate) 31. One information signal surface formed on each of them is bonded to each other with a transparent adhesive or the like with the information signal surfaces facing each other.
The laser beam L is incident from one side, and the information signal surfaces on the first and second transparent substrates 41 and 31 can be selectively recorded and reproduced by the laser light L.

First, the first transparent substrate 41 is formed in the same manner as the first transparent substrate of the third embodiment described above with reference to FIG. Although a detailed description is omitted, one surface 41a of the first transparent substrate 41 is
Is an incident surface of the laser light L, and a recording film 42 and a semi-transmissive reflection film 43 are sequentially formed on a convex land and a concave groove formed on the other surface 41b opposite to the one surface 41a. Thus, the surface of the recording film 42 is a first information signal surface for recording and reproduction.

On the other hand, the second transparent substrate 31 is formed in the same manner as the second transparent substrate of the second embodiment described above with reference to FIG. Although the detailed description is omitted, one surface 31a of the second transparent substrate 31
Denotes a label printing surface, and a reflective film 32, a recording film 33, a mask film 34, and a protective film 35 are sequentially formed on a convex land and a concave groove formed on the other surface 31b opposite to the one surface 31a. After being formed, the surface of the recording film 33 serves as a second information signal surface for recording and reproduction.

Then, the first transparent substrate 41 and the second transparent substrate 31 formed as described above are made to face each other with the first and second information signal surfaces 42 and 33 having irregularities facing each other. The transparent intermediate material layer 50 is formed by bonding the two information signal surfaces 42 and 33 sides to each other with a transparent polymer adhesive and a photopolymer method with the insides facing each other.

Here, a photopolymer is dropped on the transflective film 43 of the first transparent substrate 41, and the protective film 35 of the second transparent substrate 31 is brought into contact therewith, while rotating at about 1000 RPM. , A photopolymer is evenly spread over the entire surface to be bonded, and then ultraviolet light is applied to the first transparent substrate 4.
Irradiation from one side cures the photopolymer, and the first and second transparent substrates 41 and 31 are bonded together.

At this time, since a mask film is not formed on the recording film 42 serving as the first information signal surface of the first transparent substrate 41, the information capacity of the recording film 42 for the information signal is about 5.5 GB.
On the other hand, since the mask film 34 is formed on the recording film 33 serving as the second information signal surface of the second transparent substrate 31 on the incident side of the laser beam L, the mask effect by the mask film 34 is used. Since an information signal can be recorded and reproduced on the recording film 33 at a super-resolution, the information capacity is about 10 GB.

In the fourth embodiment, the recording film 33 serving as the second information signal surface of the second transparent substrate 31 has the mask film 34 formed on the laser beam L incident side before the recording film 33. When the laser light L is incident, the mask effect by the mask film 34 acts. However, the mask film 34 is not formed before the recording film 33 and the mask film 34 is used instead.
Can be formed between the reflection film 32 and the recording film 33. In this case, the laser light L having a mask effect generated by the mask film 34 is reflected by the reflection film 32 to form the recording film. A method of reproducing the information signal recorded in the recording device 33 is also possible.

In the multilayer optical discs D1 to D4 of the first to fourth embodiments described in detail above, the thickness of the first and second transparent substrates is
The numerical aperture (NA) of an objective lens described later is about 0.6 to 0.5.
Both 0.6mm to be suitable for playback at about 65
However, the present invention is not limited to this. If the numerical aperture (NA) of the objective lens is about 0.4, the thickness of the first transparent substrate can be reduced to about 1.2 mm. In this case, if the total thickness of the multilayer optical discs D1 to D4 becomes too thick by bonding the first transparent substrate and the second transparent substrate, a transparent intermediate layer is provided above the first information signal surface of the first transparent substrate. What is necessary is just to form a 2nd information signal surface by 2P method etc. through a member layer.

In the multilayer optical discs D1 to D4 of the first to fourth embodiments, a laser beam is incident from one surface of a transparent disk substrate, and the other surface of the transparent substrate opposes one surface of the disk substrate. In the above description, a case was described in which a two-layer information signal surface for recording and / or reproduction by a laser beam was formed. However, the present invention is not limited to this. In this case, it is possible to increase the irradiation light intensity of the laser light only on the information signal surface farthest from one surface of the disk substrate on which the laser light is incident, of the information signal surfaces of two or more layers. Then, it is only necessary to form a mask film in which the temperature rises and the light transmittance increases, and a semi-transmissive reflective film is formed on the information signal surface where the mask film is not formed, while the mask film is formed. Deposited information signal A reflective film may be deposited in.

In the first to fourth embodiments, the laser light L is applied from one surface 11a, 41 of the first transparent substrate 11, 41.
Has been described, but the label printing surfaces 21a and 31a of the second transparent substrates 21 and 31 among the multilayer optical disks D1 to D4 of the first to fourth embodiments are further developed.
Any one of the multi-layer optical discs D1 to D4 may be stuck thereon so that recording and / or reproduction can be performed from both sides.

<Multilayer Optical Disc Recording / Reproducing Method and Apparatus>
FIG. 8 is a configuration diagram showing an optical system of a multilayer optical disk recording / reproducing apparatus applied to the multilayer optical disks of the first to fourth embodiments according to the present invention.

As shown in FIG. 8, the optical system 60 of the multi-layer optical disc recording / reproducing apparatus applied to the multi-layer optical discs D1 to D4 of the first to fourth embodiments according to the present invention comprises a semiconductor laser element drive control unit 61 A semiconductor laser element 62 that emits laser light L having a wavelength of, for example, 650 nm by the semiconductor laser element drive control unit 61; a collimator lens 63 that converts the laser light L from the semiconductor laser element 62 into parallel light; 1/4 wavelength plate 6
5, an objective lens 66 having an NA (numerical aperture) of approximately 0.65 for condensing the laser beam L on the multilayer optical disks D1 to D4, and reflection from the multilayer optical disks D1 to D4 branched from the polarizing prism 64. Condensing lens 6 for condensing light
7, a cylindrical lens 68 for obtaining focus information, tracking information, and a reproduction information signal from the reflected light, and a photodetector 69 for detecting condensed light. By detecting reflected light from the multilayer optical disks D1 to D4 by 69, each information recording surface of the multilayer optical disks D1 to D4 is recorded and / or reproduced.

In order to focus the objective lens 66 in the optical system 60 on a desired information signal surface, a multi-layer optical disk D
The focal position of the objective lens 66 is automatically set based on chapter information or the like recorded in 1 to D4.

Here, using the optical system 60 of the multi-layer optical disk recording / reproducing apparatus having the above-described configuration, the first to fifth embodiments of the present invention are described.
When recording and / or reproducing the multi-layer optical discs D1 to D4 of the fourth embodiment, the multi-layer optical disc D of the first to fourth embodiments is used.
1 to D4, as described above, the laser light L is incident from one surface 11a, 41a of the first transparent substrate 11, 41, and the other surface 11b, 41b of the first transparent substrate 11, 41.
Because the information signal surface of two layers is formed on the side and the mask film is formed on the information signal surface of the second layer far from one surface on which the laser light L is incident, the optical signal is common. System 6
The semiconductor laser element drive control section 61 within 0 indicates the reproduction power of the semiconductor laser element 62 when reproducing the information signal surface of the second layer on which the mask film is formed, and the information of the first layer on which the mask film is not formed. Control is performed so as to be set higher than the reproduction power when reproducing the signal. The reason for this is that at the time of reproduction on the multilayer optical discs D1 to D4, although the first information signal surface close to the surface on which the laser light L is incident has no mask film formed thereon, the laser light L is not attenuated.
Since the laser beam L at the time of reproduction is attenuated by the mask film on the information signal surface of the second layer far from the surface on which the laser beam L is incident, the amount of the laser beam L needs to be higher than that of the first layer. Therefore, from the above, when two or more information signal surfaces are formed on the other surfaces 11b and 41b of the first transparent substrates 11 and 41, the laser light L among the two or more information signal surfaces is formed.
Are incident on one surface 11a of the first transparent substrate 11, 41,
A mask film is formed only on the information signal surface farthest from 41a, and the reproduction power of the laser light L on the information signal surface on which the mask film is formed is increased by the laser light on the information signal surface on which the mask film is not formed. What is necessary is just to set larger than the reproduction power of L.

When the two-layer information signal surface is used for recording and reproduction as in the multilayer optical disc D4 of the fourth embodiment, the semiconductor laser element drive control section 61 in the optical system 60 is used.
Indicates that the recording power of the semiconductor laser element 62 when recording the information signal surface of the second layer on which the mask film is formed is higher than the recording power when recording the information signal of the first layer on which the mask film is not formed. It is controlled so that it is set large. Therefore, from the above, the other surface 11 of the first transparent substrates 11 and 41
When two or more layers of information signal surfaces are formed on the sides b and 41b, one of the surfaces 11a and 41a of the first transparent substrates 11 and 41 on which the laser light L is incident among the two or more layers of information signal surfaces.
A mask film is formed only on the information signal surface farthest from the laser beam, and the recording power of the laser beam L on the information signal surface on which the mask film is formed is changed to the laser beam L on the information signal surface on which the mask film is not formed. May be set to be higher than the recording power.

When recording and reproducing information signals are performed separately, the semiconductor laser element drive control section 61 in the optical system 60 irradiates the irradiation light intensity of the laser light L emitted from the semiconductor laser element 62 during recording. The light intensity and the irradiation light intensity during reproduction are switched.

More specifically, using the optical system 60 described above, the multilayer optical disc D1 of the first embodiment shown in FIG. 1 (first layer: reproduction only, second layer: super resolution reproduction only)
Is reproduced, the 1 formed on the first transparent substrate 11 is
The reproduction power of the laser light L is set to about 0.5 mW for the information signal surface 11b of the layer, and the laser light L is applied to the information signal surface 21b of the second layer formed on the second transparent substrate 21.
Was set to about 2 mW. The jitter value at this time was about 8%.

Also, the second layer of the multilayer optical disc D2 (first layer... Reproduction only, second layer... Super resolution recording and reproduction) of the second embodiment shown in FIG. In this case, the laser light L is turned on / off by the semiconductor laser element drive control section 61 in accordance with an information signal to be recorded.
The control was performed, and the recording power of the laser beam L during recording was set to about 20 mW. At the time of reproduction, the first transparent substrate 1
The reproduction power of the laser light L was set to about 0.5 mW for the first information signal surface 11b formed on the first layer 1 and recorded on the second recording film 33 formed on the second transparent substrate 31. The reproduction power of the laser beam L is about 2 m for the information signal surface.
W was set. The jitter value at this time was about 8%.

The first layer of the multilayer optical disc D3 (first layer: dedicated for recording and reproduction, second layer: dedicated to super-resolution reproduction) of the third embodiment shown in FIG. 6 is recorded by using the optical system 60 described above. In this case, the laser light L is turned on / off by the semiconductor laser element drive control section 61 in accordance with an information signal to be recorded.
The control was performed, and the recording power of the laser beam L at the time of recording was set to about 12 mW. At the time of reproduction, the first transparent substrate 1
The reproduction power of the laser beam L is set to about 0.7 mW with respect to the information signal surface recorded on the first recording film 43 formed on the first recording film 43, and the information signal of the second layer formed on the second transparent substrate 31 is formed. The reproduction power of the laser beam L for the surface 21b is about 2.2
mW. The jitter value at this time was about 8%.

Also, using the optical system 60 described above, the first or second layer of the multi-layer optical disc D4 of the fourth embodiment shown in FIG. When recording the second layer, the semiconductor laser element drive control section 61 controls the laser beam L to be turned on / off according to the information signal to be recorded, and the first layer formed on the first transparent substrate 41. The recording power of the laser light L is set to about 12 mW for the recording film 42 of the first embodiment, and the recording power of the laser light L is set to about 24 mW for the second recording film 33 formed on the second transparent substrate 31. did. During playback, the first
The reproduction power of the laser light L was set to about 0.7 mW for the information signal surface recorded on the first recording film 42 formed on the transparent substrate 11,
The reproduction power of the laser beam L for the information signal surface recorded on the recording film 33 of the layer was set to about 3.0 mW. The jitter value at this time was about 8%.

[0086]

According to the multi-layer optical disc, the multi-layer optical disc recording / reproducing method and the apparatus according to the present invention described in detail above, according to the multi-layer optical disc according to the first aspect, laser light is incident from one surface of a transparent disc substrate, When two or more information signal surfaces for recording and / or reproducing by laser light are formed on the other surface of the disk substrate opposite to one surface of the disk substrate, the laser light among the two or more information signal surfaces is used. When the intensity of the laser beam increases, the temperature rises and the light transmittance rises only on the information signal surface farthest from one side of the disk substrate where the light enters. As compared with the case where a masking layer is formed on the surface, only one information signal surface on which the mask film is formed is located farthest from one surface of the disk substrate. The laser light is not attenuated in the process until the laser light reaches the information signal surface on which the mask film is formed, so that all the information signal surfaces can be recorded and / or reproduced satisfactorily. The power to the semiconductor laser element to be emitted can be suppressed as much as possible, and the life of the semiconductor laser element can be extended.

According to the method and apparatus for recording / reproducing a multi-layer optical disc according to the second and fourth aspects, at the time of reproducing from the multi-layer optical disc according to the first aspect, the information signal surface on which the mask film is formed is used. Since the reproduction power of the laser light is set to be higher than the reproduction power of the laser light for the information signal surface on which the mask film is not formed, the information signal surface on which the mask film is formed can be reproduced satisfactorily.

According to the method and apparatus for recording / reproducing a multi-layer optical disc according to the third and fifth aspects, at the time of recording on the multi-layer optical disc according to the first aspect, the information signal surface on which the mask film is formed is used. The recording power of the laser light is set to be higher than the recording power of the laser light for the information signal surface where the mask film is not formed, so that the information signal is recorded well on the information signal surface where the mask film is formed. it can.

[Brief description of the drawings]

FIG. 1 is a schematic enlarged sectional view of a multilayer optical disc according to a first embodiment of the present invention.

FIG. 2 is a diagram showing light transmittance and reflectance with respect to laser light wavelength of a mask film material used for the mask film shown in FIG. 1;

FIG. 3 is a diagram showing a light transmittance with respect to a temperature of a mask film shown in FIG. 1;

FIG. 4 is a diagram for explaining a spot diameter transmitted through a mask film shown in FIG. 1;

FIG. 5 is a cross-sectional view schematically showing an enlarged multilayer optical disc according to a second embodiment of the present invention.

FIG. 6 is a schematic enlarged sectional view of a multilayer optical disc according to a third embodiment of the present invention.

FIG. 7 is a cross-sectional view schematically showing a multilayer optical disk according to a fourth embodiment of the present invention in an enlarged manner.

FIG. 8 is a configuration diagram showing an optical system of a multilayer optical disk recording / reproducing apparatus applied to the multilayer optical disks of the first to fourth embodiments according to the present invention.

FIG. 9 is a sectional view showing a conventional optical information recording medium.

[Explanation of symbols]

11, 41: disk substrate (first transparent substrate), 21, 31: disk substrate (second transparent substrate), 11a, 21a, 31a, 41a: one surface of the transparent substrate, 11b, 21b, 31b, 41b: transparent 20, 30, 40, 50: transparent intermediate material layer, 12, 43: semi-transmissive reflective film, 22, 32: reflective film, 33, 42: recording film, 23, 34: mask film, 24 , 35: Protective film, 60: Optical system of multilayer optical disk recording / reproducing device, 61: Semiconductor laser element drive control unit, 62: Semiconductor laser element, 66: Objective lens, D1 to D4: First to fourth embodiments Multi-layer optical disc, L: laser beam.

Continued on the front page F term (reference) 5D029 JB09 MA03 5D090 AA01 BB02 BB04 BB12 CC01 CC04 DD01 EE01 EE11 KK03 LL01 5D119 AA11 AA23 BB13 DA01 DA05 FA05 HA45 HA54

Claims (5)

[Claims] 1. A laser beam is incident on one surface of a transparent disk substrate, and recording and / or recording is performed by the laser beam on the other surface of the transparent substrate opposite to the one surface of the disk substrate.
Or, in a multilayer optical disc having two or more layers of information signal surfaces to be reproduced, only the information signal surface farthest from one surface of the disc substrate on which the laser light is incident among the two or more layers of information signal surfaces. A multi-layer optical disc, characterized in that a mask film having a higher temperature and a higher light transmittance when the irradiation light intensity of the laser light is increased is formed. 2. The multi-layer optical disc recording / reproducing method for recording and / or reproducing a multi-layer optical disc according to claim 1, wherein, when reproducing from the multi-layer optical disc, the information signal surface on which the mask film is formed is formed. A recording / reproducing method for a multi-layer optical disc, wherein a reproducing power of a laser beam is set to be higher than a reproducing power of the laser beam for the information signal surface on which the mask film is not formed. 3. The multi-layer optical disc recording / reproducing method for recording and / or reproducing a multi-layer optical disc according to claim 1, wherein, at the time of recording on the multi-layer optical disc, the information signal surface on which the mask film is formed is formed. A multi-layer optical disc recording / reproducing method, wherein a recording power of a laser beam is set to be higher than a recording power of the laser beam for the information signal surface on which the mask film is not formed. 4. A multi-layer optical disc recording / reproducing apparatus for recording and / or reproducing the multi-layer optical disc according to claim 1, wherein at the time of reproduction from the multi-layer optical disc, the information signal surface on which the mask film is formed is formed. A semiconductor laser device drive control means for controlling the drive of the semiconductor laser device so that the reproduction power of the laser beam is set higher than the reproduction power of the laser beam for the information signal surface on which the mask film is not formed. A multi-layer optical disc recording / reproducing apparatus characterized by the above-mentioned. 5. A multi-layer optical disc recording / reproducing apparatus for recording and / or reproducing a multi-layer optical disc according to claim 1, wherein at the time of recording on the multi-layer optical disc, the information signal surface on which the mask film is formed is formed. A semiconductor laser element drive control means for driving and controlling the semiconductor laser element so that the recording power of the laser light is set higher than the recording power of the laser light for the information signal surface on which the mask film is not formed. A multi-layer optical disc recording / reproducing apparatus characterized by the above-mentioned.