JPH0773506A - Optical recording medium and its reproducing device - Google Patents

Abstract

PURPOSE:To provide the optical recording medium which is less deteriorated in spite of repetitive use at the time of providing this medium with a light transmittance variable medium to reduce an effective spot diameter and with which stable reproduced signals are obtainable, and its reproducing device. CONSTITUTION:This optical disk 1 is not provided with a mask layer 13 in a lead-in signal region 2 and is recorded with the signals to be recorded in the lead-in signal region 2 by lowering the information recording density per unit area as compared with an information signal region 4 in such a manner that these signals can be read out even if the effective spot diameter is not reduced. The information to regulate the reproducing light intensity of the laser beam for irradiation for the purpose of efficiently reducing the effective spot diameter is recorded in the lead-in signal region 2. The information signal region 4 of the optical disk 1 is reproduced by using the laser beam adjusted in the irradiation intensity in accordance with the information regulating the reproducing light intensity at the time of reproducing this region.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical recording medium in which information is recorded at a high density and a reproducing apparatus therefor, and more particularly to a mask layer made of a light transmittance variable medium whose transmittance changes according to the intensity of irradiation light. The present invention relates to an optical recording medium for reproducing information recorded at high density on an optical recording medium by reducing the effective spot diameter of an irradiation spot, and a reproducing apparatus therefor.

[0002]

2. Description of the Related Art In recent years, a large capacity optical disc has been studied,
Various proposals have been made. An optical disc can form a recording mark smaller than the light spot diameter by controlling the laser light power at the time of recording, and therefore there is no limit in principle to the improvement of the density at the time of recording. However, the diameter of the light spot when the laser light is narrowed down by a lens has a limit value that cannot be narrowed down to a certain value or less, and the densification of an optical disk depends on how to reduce the reproduction laser spot. The repetition wavelength (recording wavelength) of the recording mark at the reproduction limit is given by λ / 2NA. Here, λ is the wavelength of light and NA is the numerical aperture of the lens.

It is understood that in order to identify and reproduce a recording mark having a shorter recording wavelength, it is sufficient to reproduce with a light having a short wavelength λ or use a lens having a large numerical aperture NA. However, it is technically difficult to shorten the wavelength of a semiconductor laser used for reproduction, and it is not easy to incorporate a lens having a large numerical aperture NA into an optical disk device.

Therefore, a substance having a high light transmittance due to temperature rise due to light irradiation is provided in a layered form in the optical disk, and only the central portion of the light irradiated portion is made light transmissive when recording or reproducing information on the optical disk. Conventionally, a method of recording or reproducing information on an optical disc with high density has been known.

As one of the high-density recording techniques for such an optical disc, a variable-light-transmittance medium layer having temperature dependency is provided on the information recording layer so that the optical spot traveling direction in the optical spot on the optical disc is changed. Japanese Unexamined Patent Publication (Kokai) No. 5-12673 discloses a technique for reducing the apparent light spot diameter by utilizing the high temperature of the rear portion. Reflection from the disk in the optical head by utilizing the fact that the reflectance of the low light transmittance part of the temperature-dependent light transmittance variable medium is sufficiently lower than the reflectance of the high light transmittance part. By controlling the output laser power so that the amount of light received by the photodetector that monitors the light is always constant, the area ratio of the portion with high light transmittance in the total area of the light spot is always controlled to be constant. You can

[0006]

By the way, the reproducing system based on the above-mentioned prior art uses a temperature-dependent light transmittance variable medium whose light transmittance changes with temperature. However, such a temperature-dependent variable light transmittance medium has a problem in that its characteristics are thermally deteriorated by repeated use, and the effect of reducing the effective spot diameter is reduced. It was

Therefore, if a light-dependent variable light transmittance medium disclosed in, for example, Japanese Patent Application No. 4-331049 is used as a mask layer, the temperature of the mask layer will not be high during laser beam irradiation. Even without it, since the light transmittance changes, deterioration due to heat can be suppressed.

However, the above-described light-dependent light transmittance variable medium has the characteristics shown in FIG. 5, and the light transmittance changes most near the saturation intensity. Therefore, in order to reproduce information recorded at a high density using such a variable light transmittance medium, the irradiation intensity of the laser beam is optimized so that the light transmittance of the variable light transmittance medium changes greatly. There is a need.

Various proposals regarding the laser power control such as controlling the irradiation intensity of the laser beam are disclosed in Japanese Patent Laid-Open No. 5-12673, but there is a problem that they are relatively complicated.

Therefore, the present invention has been made by paying attention to the above points, and in providing a variable optical transmittance medium for reducing the effective spot diameter, there is little deterioration even after repeated use, and stable reproduction is achieved. An object of the present invention is to provide an optical recording medium capable of obtaining a signal and a reproducing apparatus thereof.

[0011]

As a means for achieving the above object, the present invention is a light-transmissive substrate in which reproduction information and preliminary information of this reproduction information are recorded by a row of minute pits capable of being optically read. A mask layer for reducing the effective spot diameter of the laser beam irradiated from the device side on the pit row by reversibly changing the light transmittance by absorbing light of a specific wavelength, After the information is referenced,
In an optical recording medium in which the reproduction information is reproduced using a laser beam spot having a reduced effective spot diameter, the reproduction information is recorded as a signal recording density per unit area of a preliminary information signal region in which the preliminary information is recorded. It is an object of the present invention to provide an optical recording medium characterized by having a signal recording density lower than a signal recording density per unit area of a recorded reproduction information signal region.

As a means for achieving the above-mentioned object, the present invention specifies a reproduction information and preliminary information of the reproduction information on a light-transmissive substrate on which fine readable pits are recorded. The light transmittance reversibly changes by absorbing light of a wavelength, and a mask layer is provided on the pit row to reduce the effective spot diameter of the laser beam irradiated from the device side, and the preliminary information is referred to. Then, in the optical recording medium in which the reproduction information is reproduced by using the laser beam spot whose effective spot diameter is reduced, the preliminary information defines the irradiation intensity of the laser beam irradiated when reproducing the reproduction information. The present invention is intended to provide an optical recording medium characterized by containing information for operating.

Further, according to the present invention, as means for achieving the above object, reproduction information and preliminary information including light intensity information defining the irradiation intensity of a laser beam irradiated when reproducing this reproduction information are optical. A laser beam irradiating the pit row from the device side by reversibly changing the light transmittance by absorbing light of a specific wavelength on the light-transmissive substrate recorded by the readable minute pit row. Is a reproducing apparatus for an optical recording medium having a mask layer for reducing the effective spot diameter, the light intensity information is extracted with reference to the preliminary information, and the irradiation intensity of the laser beam is set based on the light intensity information. After that, the reproduction information of the optical recording medium is reproduced by using the laser beam having the irradiation intensity set therein.

[0014]

Embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 1 is a configuration diagram of an optical disc according to an embodiment of the present invention. The optical disc 1 shown in the figure is a read-only type optical disc, in which a lead-in signal area (preliminary information signal area) 2 is provided in the innermost peripheral portion and a lead-out signal area 3 is provided in the outermost peripheral portion. Further, in the area sandwiched between the lead-in signal area 2 and the lead-out signal area 3, an information signal area 4 in which information signals (reproduction information signals) are recorded at high density is provided.

The structure of the read-only optical disc 1 is as shown in FIG. That is, the mask layer 13, the reflection layer 14, and the protective film layer 16 are provided on the light-transmissive substrate 12, and the pre-modulated signal is transferred as pits 15 on the substrate 12. Thus, the optical disc 1
Is a reflection type optical disc, and is easily compatible with the existing optical disc system.

As the light-transmitting substrate 12, various materials can be used as is well known, and any of glass, epoxy resin, polycarbonate resin, polymethacrylic acid ester resin, amorphous polyolefin resin and the like can be used. In the case of, it can be used if it has good transparency. The mask layer 13 is formed, for example, in Japanese Patent Application No. 4-
It is possible to use a light-dependent light transmittance variable medium such as a saturable absorptive substance, a substance having a nonlinear optical effect, or a phase change type substance as disclosed in Japanese Patent No. 331049. Specifically, various dyes such as xanthene dyes, organic dyes such as azo dyes and cyanine dyes, inorganic dyes, inorganic semiconductors, simple metals or alloys, and the like are included. These substances have absorption in a specific wavelength region at room temperature, and an appropriate substance may be selected according to the laser light wavelength used in the reproducing device. By irradiating the mask layer 13 made of such a light transmittance variable medium with the laser beam, the light transmittance is increased only in the irradiation spot where the light intensity is large, and the effective spot diameter can be reduced. You can do it.

In the lead-in signal area 2, a mask layer 13 for reducing the execution spot diameter is not formed, and the recorded signal is an information signal area 4 as shown in FIG. It is recorded with a lower information recording density per unit area compared to. That is, the size of the pit 15A formed in the lead-in signal area 2 is larger than the size of the pit 15B formed in the information signal area 4. In the figure, the shaded areas within spots 6 and 7 are the effective spots that are actually irradiated onto the pit 15. As a result, the information recorded in the lead-in signal area 2 can be read out without reducing the effective spot diameter of the laser beam, and the information recorded in the information signal area 4 can be read by the mask layer 13. Reading can be performed by reducing the effective spot diameter. Furthermore, by not forming the mask layer 13 in the lead-in signal area 2, it becomes easy to fabricate a device compatible with a conventionally known optical disc system such as a CD on which high density recording is not performed.

Further, in the lead-in signal area 2, the reproduction light intensity of the irradiation laser beam for efficiently reducing the effective spot diameter in addition to the address information, the content information and the like as in the conventional reproduction-only recording medium. Is recorded. If the light intensity of the irradiation laser beam is optimally set by this light intensity information, the effective spot diameter can always be kept constant by only the focus servo. Therefore, the structure of the reproducing apparatus can be simplified. In addition, by recording the light intensity information for each optical disc in this way, it is possible to correct the optimal variation of the reproduction light intensity of the mask layer 13 for each optical disc 1 due to variations in manufacturing (for example, different manufacturers). it can.

Next, a method of manufacturing the optical disc 1 will be described. First, the substrate 12 on which signals are recorded by the minute pit train is created. The method of recording signals on the lead-in signal area 2 and the information signal area 4 on the substrate 12 is not particularly limited, but a photoresist is coated on a polished glass master and the signals are recorded by a recording laser. A method of providing a conductive film after development, producing a stamper by plating, and obtaining the substrate 12 by injection molding,
Any method such as an etching method, a so-called 2P method, or an embossing method using an ultraviolet curable resin may be used. Here, the signal is recorded in the lead-in signal area 2 at a low recording density (for example, a pit width of about 1 μm and a track pitch of the current CD signal recording density) so that the signal can be read without reducing the effective spot diameter. The information signal area 4 is recorded with a high density so that high density reproduction can be performed by reducing the irradiation spot diameter.

Next, a mask layer is formed on the substrate 12. When the mask layer 13 is formed by, for example, a vacuum deposition method, after masking the lead-in signal area 2 on the innermost circumference, the mask layer 13 is formed only on the information signal area 4. If it is soluble in a solvent, it can be formed by spin coating by dissolving it in a suitable solvent. In that case, the coating liquid is brought into contact with only the outer periphery of the lead-in signal region 2. The mask layer 13 is formed only in the information signal region 4.

Here, in order to maximize the information recording area on the optical disc 1, the lead-in signal area 2 and
The distance to the information signal area 4 needs to be as narrow as possible. However, in the method of forming the mask layer 13 as described above, between the lead-in signal area 2 and the information signal area 4, that is, between the area with low signal recording density and the area with high signal recording density, It becomes difficult to accurately provide a boundary for forming the mask layer 13. However, the mask layer 13
Need only be formed in the information signal area 4 which is a high density recording area. Therefore, the area in which the mask layer 13 is formed is provided slightly from the inner peripheral side of the information signal area 4. As a result, the mask layer 13 is also formed near the outermost periphery of the lead-in signal area 2, but since the lead-in signal area 2 is recorded at a low recording density, there is no problem in signal reproduction. .

Then, the reflective layer 14 and the protective film layer 16 are formed. The reflective film 4 is provided on the substrate 12 on which the mask layer 13 is formed by means such as vacuum deposition or sputtering, and a protective film 16 made of an ultraviolet curable resin or the like is further formed thereon.

Although the optical disc 1 has the mask layer 13 formed in the area other than the lead-in signal area 2, the signal in the lead-in signal area 2 is recorded at a low recording density.
Since stable reading can be performed without reducing the effective spot diameter, the entire signal recording area (lead-in signal area 2, information signal area 4, lead-out signal area 3) of the optical disc 1 including the lead-in signal area 2 can be read. ) Mask layer 1
3 may be formed. When the mask layer 13 is formed in the lead-in signal area 2, only the lead-in signal area 2 is irradiated with a laser beam having a high irradiation intensity, and the information signal area 4 is optimally recorded in the lead-in signal area 2. Irradiate with a laser beam having an irradiation intensity. Further, although the optical disk 1 is described as the reflected light detection type, it may be of the transmitted light detection type.

Next, the reproducing apparatus for the optical disc 1 will be described. FIG. 4 is a schematic configuration diagram showing an example of a main part of the optical disc reproducing apparatus according to the embodiment of the present invention. In the figure, a reproducing device 21 includes an optical disk 1 and an optical head 2 described above.
3 and a light receiver 24 that receives the reflected light reflected by the optical disc 1 and outputs an output signal according to the detection result.
And a laser power signal 2 for adjusting the irradiation intensity of the irradiation laser beam based on the output signal from the light receiver 24.
7 and a control circuit 25 for outputting a head drive signal 28 for scanning the irradiation light spot on the track on the optical disc 1 and a lens driving signal 29 for causing the irradiation light spot to follow the surface deflection of the optical disc 1. ing.

The optical head 23 is used for the optical disc 1
A semiconductor laser 30 for generating irradiation light for servo or signal reproduction, a condenser lens 31 for condensing irradiation light emitted from the semiconductor laser 30, and a condenser lens 31 for driving the lens drive signal 29. Based on the above, the actuator 32 for driving in the direction perpendicular to the information signal recording surface of the optical disc 1 and the reflected light reflected on the optical disc 1 and incident on the condenser lens 31 are received by the light receiver 2
The polarization prism 33 is divided into four parts.

Next, the operation of the reproducing apparatus 21 will be described. When the optical disc 1 is loaded into the playback device 21,
The control circuit 25 transfers the optical head 23 to the lead-in signal area 2.
A head drive signal 28 for driving is output. Then, first, the lead-in signal area 2 is irradiated with a laser beam at an appropriate irradiation intensity to perform focus servo and toking servo, and then the lead-in signal area 2 is reproduced.
The control circuit 25 extracts the light intensity information for defining the irradiation intensity of the laser beam from the reproduced information of the lead-in signal area 2, and generates the laser power signal 27 based on this light intensity information. The laser light output of the laser 30 is set. Then, the information signal area 4 is reproduced while maintaining the set laser light output. Since the reproduction of the information signal region 4 is performed by using the laser bee whose light intensity is optimally set by the light intensity information, the effect of reducing the effective spot diameter by the mask layer 13 is excellently exhibited.
The information signal recorded at high density can be stably reproduced.

As described above, the reproducing device 21 sets the irradiation intensity of the laser beam based on the light intensity information recorded on the optical disc 1, and if the laser beam having this irradiation intensity is used, the mask is performed only by the focus servo. Since the effective spot diameter on the layer 13 can be always kept constant, it is not necessary to use a complicated detection circuit for controlling the effective spot diameter, and the structure of the device is simplified.

The above-mentioned optical disc 1 and reproducing device 21 are only examples used for explaining the present invention, and it is needless to say that they can be appropriately modified as long as they have the technical idea of the present invention. Is.

[0029]

As described above, according to the optical recording medium of the present invention, in the optical recording medium in which the reproduction information is recorded at a high density, the signal per unit area of the preliminary information signal area in which the preliminary information is recorded. Since the recording density is set lower than the signal recording density per unit area of the reproduction information signal region in which the reproduction information is recorded, it is important information that must be read out in order to reproduce the optical recording medium. The preliminary information signal area in which information is recorded can be read without the effect of reducing the spot diameter. Further, if the mask layer is not formed in the preliminary information signal area, the preliminary information signal area can be stably reproduced, and a conventionally known optical disc system such as a CD in which high density recording is not performed. It becomes easier to provide a reproducing apparatus compatible with the.

By recording the light intensity information for defining the irradiation intensity of the laser beam on the optical recording medium, the structure of the reproducing device for reproducing the optical recording medium can be simplified and the optical recording medium can be simplified. It is possible to correct the variation in the optimum irradiation intensity of the mask layer for each.

Further, according to the reproducing apparatus of the optical recording medium of the present invention, the irradiation intensity of the laser beam for irradiating the optical recording medium is set based on the light intensity information recorded on the optical recording medium. Therefore, it is possible to simplify the structure of the device and to stably reproduce the reproduction information recorded at high density on the optical recording medium while effectively reducing the effective spot diameter.

[Brief description of drawings]

FIG. 1 is a configuration diagram of an optical disc according to an embodiment of the present invention.

FIG. 2 is a diagram showing a part of a vertical cross section of the optical disc in FIG.

FIG. 3 is a diagram showing recording pits of an optical disc according to an embodiment of the present invention.

FIG. 4 is a schematic configuration diagram showing an example of a main part of an optical disc reproducing apparatus according to an embodiment of the present invention.

FIG. 5 is a diagram showing light transmittance characteristics of a variable light transmittance medium.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 optical disk (optical recording medium) 2 lead-in signal area (preliminary information signal area) 4 information signal area (reproduction information signal area) 12 substrate 13 mask layer 14 reflective layer 15 pit 21 reproducing device 23 optical head 24 light receiver 25 control circuit 27 Laser Power Signal 28 Head Drive Signal 29 Lens Drive Signal 30 Semiconductor Laser 31 Condenser Lens 32 Actuator 33 Polarizing Prism

Claims (4)

[Claims] 1. A light transmissivity is reversible by absorbing light of a specific wavelength on a light transmissive substrate on which reproduction information and preliminary information of this reproduction information are recorded by a row of minute pits capable of being optically read. To a mask layer for reducing the effective spot diameter of the laser beam irradiated from the device side on the pit row, and after the preliminary information is referred to, a laser beam spot with the reduced effective spot diameter is formed. In the optical recording medium in which the reproduction information is reproduced by using the signal recording density per unit area of the spare information signal area in which the spare information is recorded, per unit area of the reproduction information signal area in which the reproduction information is recorded. An optical recording medium characterized by having a signal recording density lower than that of the above. 2. The optical recording medium according to claim 1, wherein the mask layer is not formed in a preliminary information signal area in which the preliminary information is recorded. 3. The light transmittance is reversible by absorbing light of a specific wavelength on a light-transmissive substrate in which reproduction information and preliminary information of this reproduction information are recorded by a row of minute pits capable of being optically read. To a mask layer for reducing the effective spot diameter of the laser beam irradiated from the device side on the pit row, and after the preliminary information is referred to, a laser beam spot with the reduced effective spot diameter is formed. In the optical recording medium in which the reproduction information is reproduced by using the preliminary information, the preliminary information includes the information for defining the irradiation intensity of the laser beam irradiated when reproducing the reproduction information. recoding media. 4. A light transmissive property in which reproduction information and preliminary information including light intensity information defining the irradiation intensity of a laser beam for reproducing the reproduction information are recorded by a fine readable pit row. An optical recording medium having a mask layer on a substrate that reversibly changes the light transmittance by absorbing light of a specific wavelength and reduces the effective spot diameter of a laser beam irradiated from the device side on the pit row. In the reproducing device, the light intensity information is extracted with reference to the preliminary information, and the irradiation intensity of the laser beam is set based on the light intensity information, and then the laser beam having the irradiation intensity set is used. An apparatus for reproducing an optical recording medium, which reproduces the reproduction information.