JP2010186544A - Reproducing method for optical information recording medium, recording method for optical information recording medium, and recording/reproducing method for optical information recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical information recording medium which facilitates confirmation of a disk type in a recording/reproducing device, shares one recording/reproducing device with other types of disks, facilitates disk production, and allows old data of a ROM layer to be replaced by recording update data obtained when network connection is permitted on a RE layer. <P>SOLUTION: An optical information recording medium 1 includes, on a substrate 50, a ROM layer 20, a RE layer 40, and a cover layer 10. The RE layer 40 is an information recording layer formed at a position farthest from the cover layer 10, and a recording layer where to record disk type information and an individual identification number, a stripe having a μm width and a length of a μm to mm unit. An address of the RE layer 40 is recording by wobbling a groove. The reproducing method for the optical information recording medium 1 which is recorded in a recording format wherein the polarity of a push-pull signal obtained when information in the ROM layer 20 is reproduced, is negative, uses an address reproducing means suited to a recording format of address information of each layer. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an optical information recording medium reproducing method, an optical information recording medium recording method, and an optical information recording medium recording and reproducing method.

  Currently, there is a demand for a combination disk (a disk in which a multi-layer optical disk composed of a ROM (Read Only Memory) layer and an RE (Recording / Reproduction) layer is mixed). The reason is, for example, as follows. In car navigation software, it is not always possible to connect to the Internet, and it takes time to download all the map information. On the other hand, since map information changes every day, it is desirable to be able to update it from the net. There has been a demand for a combination disk that can replace the old data in the ROM layer that can solve both of these problems by recording the updated data obtained when the Internet connection can be made in the RE layer and replacing it.

  In order to realize the above-described combination disc, as disclosed in Patent Document 1, the return light from the information recording layer (hereinafter referred to as the L0 layer) located farthest from the reproduction light incident surface includes other information recording layers. In general, it has been considered preferable to provide a ROM layer having a higher reflectance than the RE layer.

  In addition, in one standard of optical discs, there are various types (disc types) such as ROM, R, RW, RE and the like, and two information recording layers for improving the recording capacity. For example, assuming use in a car navigation system as described above, when a car navigation system is not used with a single recording / playback device, rental movie software (ROM) or a disc (R) that records a drama recorded at home , RW, RE) can be reproduced, the recording / reproducing apparatus needs means for discriminating the type of the disk as easily as possible when the disk is loaded.

  As a means for discriminating the disc type, a method such as printing a barcode outside the information recording area may be considered, but for the reason described later, it cannot be corrected after adding information, and the disc is in a completed state. It is better to record. For this reason, the information recording layer is irradiated with a pulse laser beam by a BCA (Burst cutting area) recording (YAG laser or the like), for example, a stripe having a width of about 10 μm and a length of several hundreds of μm (barcode Recording on the inside of the disk using light irradiation such as recording information is desirable.

  Patent Document 1 discloses a combination disk including a transparent substrate, an RE layer, an intermediate layer, a ROM layer, and a protective resin film in order from the reproduction light incident surface.

  As disclosed in Patent Document 1, in order to realize a combination disk, the return light from the information recording layer (L0) located farthest from the reproduction light incident surface is caused by the presence of another information recording layer. Since loss occurs, it is generally preferable to provide a ROM layer having a higher reflectance than the RE layer.

  In addition, in non-patent literature, as a method for determining the disc type, information (BCA) is recorded with a recording mark having a size such that the value of the beam expander and the focus and tracking states can be determined even if they are not optimal. A method of recording is described.

JP-A-9-106546 (published on April 22, 1997)

(Standard ECMA-267, -382, -384)

  However, the technique described in the non-patent document (DVD standard) has a problem that the position where BCA is recorded varies depending on the type of the disk. For example, a DVD-ROM is provided on an information recording layer provided on a substrate far from the light incident surface, and two DVD-R and -RW are provided on an information recording layer provided on a substrate close to the light incident surface. Is provided. That is, the recording / reproducing apparatus cannot set in advance which layer of the disc is provided with the BCA, and when reproducing the BCA, a certain degree of focus search is performed to determine the recorded layer. It was necessary.

  Further, as disclosed in Patent Document 1, the combination disk in which the ROM layer is provided in the information recording layer (L0) that is farthest from the reproduction light incident surface is separated from the reproduction light incident surface for reasons described later. There is a problem that it is difficult to perform BCA recording on the farthest layer.

  In a BD (Blu-ray Disc: registered trademark) format multi-layer disc whose capacity can be increased more easily than the DVD type, the layer on which the above information is recorded is a single-plate optical disc in the BD type multi-layer disc. An information recording layer is always provided on the substrate.

  This is because, in a multi-plate optical disk such as a DVD that bonds two substrates together, there is no difference in cost, etc., regardless of which substrate surface has the information recording layer. In order to form two layers, it is necessary to provide a new information recording layer by providing an intermediate layer on the information recording layer provided on the substrate. For this reason, it is substantially impossible to provide the intermediate layer without providing the information recording layer on the substrate from the viewpoint of cost.

  That is, in the standard of the BD type optical disc, an information recording layer is always provided on a substrate. Therefore, a recording / reproducing apparatus for reproducing information recorded on the information recording layer has a recorded location. It is easy to assume that the BCA playback can be set in advance. Therefore, it becomes easy for one recording / reproducing apparatus to share various types of media within the same standard (including only recognizing the disc type).

  However, in order to realize the above, the combination disk described in Patent Document 1 has problems in the following points.

  First, the information recording layer is irradiated with a pulse laser beam by a YCA laser or the like to form a stripe (such as a barcode) having a width of about 10 μm and a length of several hundred μm, for example, to record information Is preferably recorded at a specific position so as to facilitate reproduction. Further, in the case of the BD format, it is desirable to record at the position L0 for the reason described later.

  Further, at the time of BCA recording, it is preferable for cost reduction that the individual identification number of the disc capable of preventing illegal dubbing to the RE layer and the like is recorded at the same time.

  Further, when recording the individual identification number, it is desirable to record the disc in a completed state from the viewpoint of manufacturing management. In other words, BCA recording needs to be performed with the disc completed.

  As will be described in detail later, in BCA recording, the laser output required for recording differs greatly between recording on the ROM layer and recording on the RE layer. The reason for the difference is that in the case of the RE layer, the state of the recording mark may be changed from a crystalline state to an amorphous state as in the case of performing normal information recording. Since only the metal reflection film is provided, the phase cannot be changed, and recording is performed by burning the metal film, so that it is necessary to use a laser with a higher output.

  On the other hand, in a dual-layer RE disc, when BCA recording is performed on L0, a phase change may occur at least in the RE layer (L1) immediately above, due to heat generated by the high-power laser transmitted to the L0 layer.

  Therefore, in a combination disc in which at least the L0 layer is a ROM layer, the L0 layer is provided at a position farthest from the light incident surface in the information recording layer. Since it passes through the layer, the beam passes through the RE layer that is necessarily present in any of the layers. Although details will be described later, in this case, the RE layer absorbs light more easily than the ROM layer, and therefore, the temperature of the RE layer rises, and the heat and the heat peel off the cover layer and the RE layer. When such a phenomenon occurs, it is impossible to focus on the L0 layer, and information recorded on the BCA on the L0 layer cannot be reproduced correctly.

  In view of the above problems, the object of the present invention is to share a recording / reproducing apparatus with various other types (R, RE, R, and media having different numbers of layers) within the same standard, and to distribute large-capacity information at low cost. In addition, an optical information recording medium and an optical information recording medium recording / reproducing apparatus that can be updated at any time with update data are provided.

  In order to solve the above problems, an optical information recording medium reproducing method of the present invention separates a plurality of information recording layers from which information can be read out by reproducing light on a substrate and each of the plurality of information recording layers. And a light-transmitting layer provided at a position farthest from the substrate, and the plurality of information recording layers include a layer that can only read information and a region that can rewrite information. An optical information recording medium comprising a rewritable layer, wherein the information recording layer provided at a position farthest from the translucent layer is a rewritable layer including an area where information can be rewritten, and disc type identification information and individual A recording layer in which stripes having a width of μm and a length of μm to mm are formed to record an identification number, and the address of the rewrite layer is a groove provided in the rewrite layer. The address of the layer that is recorded by meandering in the direction of the substrate surface and from which the information can only be read is recorded by prepits made of irregularities provided in the layer that can only read the information, and Reproduction of an optical information recording medium in which information is recorded by prepits in a recording format in which the polarity of a push-pull signal obtained when reproducing information provided in a layer that can only read the information is negative In the method, when reproducing the address of the optical information recording medium, an address reproducing means adapted to the recording format of the address information of each layer is used.

  In order to solve the above problems, an optical information recording medium reproducing method of the present invention separates a plurality of information recording layers from which information can be read out by reproducing light on a substrate and each of the plurality of information recording layers. And a light-transmitting layer provided at a position farthest from the substrate, and the plurality of information recording layers include a layer that can only read information and a region that can rewrite information. An optical information recording medium comprising a rewritable layer, wherein the information recording layer provided at a position farthest from the translucent layer is a rewritable layer including an area where information can be rewritten, and disc type identification information and individual A recording layer in which stripes having a width of μm and a length of μm to mm are formed to record an identification number, and the address of the rewrite layer is a groove provided in the rewrite layer. The address of the layer that is recorded by meandering in the direction of the substrate surface and from which the information can only be read is recorded by prepits made of irregularities provided in the layer that can only read the information, and In the reproducing method of the optical information recording medium in which the information is recorded in the in-pit format in which the prepit is formed to be concave with respect to the light incident surface in the layer that can only read the information, When reproducing the address of the information recording medium, an address reproducing means suitable for the recording format of the address information of each layer is used.

  In the optical information recording medium reproducing method according to the present invention, the address reproducing means adapted to the recording format of the address information of each layer is switched according to the type of the target layer when changing the recording / reproducing layer. Is preferred.

  In order to solve the above-described problems, an optical information recording medium recording / reproducing method of the present invention includes a plurality of information recording layers capable of reading information by a reproducing light on a substrate, and each of the plurality of information recording layers. The plurality of information recording layers include a layer that can only read information and a region that can rewrite information. An optical information recording medium comprising a rewritable layer, wherein the information recording layer provided at a position farthest from the translucent layer is a rewritable layer including an area where information can be rewritten, and disc type identification information and A recording layer in which a stripe having a width of μm and a length of μm to mm is formed in order to record an individual identification number, and the address of the rewrite layer is a group provided in the rewrite layer. The address of the layer that is recorded by meandering the probe in the substrate surface direction and from which the information can only be read is recorded by prepits made of concavities and convexities provided in the layer that can only read the information, An optical information recording medium on which information is recorded by prepits in a recording format in which the polarity of a push-pull signal obtained when reproducing information provided in a layer that can only read the information is negative In this recording / reproducing method, address information indicating a recording position is recorded by a recording mark when information is recorded on the rewrite layer.

  In order to solve the above problems, an optical information recording medium recording method of the present invention separates a plurality of information recording layers on a substrate from which information can be read by reproduction light, and the plurality of information recording layers. And a light-transmitting layer provided at a position farthest from the substrate, and the plurality of information recording layers include a layer that can only read information and a region that can rewrite information. An optical information recording medium comprising a rewritable layer, wherein the information recording layer provided at a position farthest from the translucent layer is a rewritable layer including an area where information can be rewritten, and disc type identification information and individual A recording layer in which stripes having a width of μm and a length of μm to mm are formed to record an identification number, and the address of the rewrite layer is a groove provided in the rewrite layer. The address of the layer that is recorded by meandering in the direction of the substrate surface and from which the information can only be read is recorded by prepits made of irregularities provided in the layer that can only read the information, and In the recording method of the optical information recording medium in which the information is recorded in the in-pit format in which the prepit is formed to be concave with respect to the light incident surface in the layer which can only read the information, Address information indicating a recording position is recorded with a recording mark when information is recorded on the layer.

  As described above, the optical information recording medium reproducing method of the present invention includes a plurality of information recording layers capable of reading information by reproducing light on a substrate, and an intermediate layer separating each of the plurality of information recording layers. The light-transmitting layer provided at a position farthest from the substrate, and the plurality of information recording layers include a layer capable of only reading information and a rewriting layer including a region capable of rewriting information. An optical information recording medium, the information recording layer provided farthest from the translucent layer is a rewritable layer including a rewritable area, and records disc type identification information and individual identification number In order to achieve this, a recording layer in which a stripe having a width of μm and a length of μm to mm is formed, and the address of the rewrite layer is the groove provided in the rewrite layer in the direction of the substrate surface. The address of the layer that is recorded by meandering and from which the information can only be read is recorded by prepits made of irregularities provided in the layer from which the information can only be read, and the information can be read A method for reproducing an optical information recording medium in which information is recorded by prepits in a recording format in which the polarity of a push-pull signal obtained when reproducing information provided in a layer that can only be reproduced, When reproducing the address of the optical information recording medium, an address reproducing means suitable for the address information recording format of each layer is used.

  Further, the optical information recording medium reproducing method of the present invention includes a plurality of information recording layers capable of reading information by reproducing light on a substrate, an intermediate layer separating each of the plurality of information recording layers, and the substrate. And a plurality of information recording layers, wherein the plurality of information recording layers includes a layer capable of only reading information and a rewriting layer including a region capable of rewriting information. In order to record the disc type identification information and the individual identification number, the information recording layer that is a medium and is provided at a position farthest from the translucent layer is a rewritable layer including an area where information can be rewritten. A recording layer in which a stripe having a width of μm and a length of μm to mm is formed. The address of the rewrite layer causes the groove provided in the rewrite layer to meander in the substrate surface direction. The address of the layer from which the above information can be read out is recorded by the prepits made of unevenness provided in the layer from which the information can only be read out, and the above information can only be read out. The possible layer is a reproduction method of an optical information recording medium in which information is recorded in an in-pit format in which prepits are formed to be concave with respect to the light incident surface, and the address of the optical information recording medium is When reproducing, address reproducing means adapted to the recording format of address information of each layer is used.

  In order to solve the above problems, an optical information recording medium recording / reproducing method of the present invention includes a plurality of information recording layers capable of reading information on a substrate by reproducing light, and the plurality of information recording layers. Each of the plurality of information recording layers has a layer that can only read information and can rewrite information. The intermediate layer that separates each of the layers and a light-transmitting layer that is provided farthest from the substrate. An optical information recording medium comprising a rewritable layer including a region, wherein the information recording layer provided at a position farthest from the translucent layer is a rewritable layer including a region where information can be rewritten, and disc type identification A recording layer in which stripes having a width of μm and a length of μm to mm are formed to record information and an individual identification number, and the address of the rewrite layer is provided in the rewrite layer. The address of the layer that is recorded by meandering the groove in the direction of the substrate surface and can only read the information is recorded by prepits made of unevenness provided in the layer that can only read the information, An optical information recording medium on which information is recorded by prepits in a recording format in which the polarity of a push-pull signal obtained when reproducing information provided in a layer that can only read the information is negative In this recording / reproducing method, address information indicating a recording position is recorded with a recording mark when information is recorded on the rewrite layer.

  In order to solve the above-described problem, an optical information recording medium recording method of the present invention includes a plurality of information recording layers capable of reading information on a substrate by reproducing light, and each of the plurality of information recording layers. The plurality of information recording layers include a layer that can only read information and a region that can rewrite information. An optical information recording medium comprising a rewritable layer, wherein the information recording layer provided at a position farthest from the translucent layer is a rewritable layer including an area where information can be rewritten, and disc type identification information and A recording layer in which a stripe having a width of μm and a length of μm to mm is formed in order to record an individual identification number, and the address of the rewrite layer is a group provided in the rewrite layer. The address of the layer that is recorded by meandering the probe in the substrate surface direction and from which the information can only be read is recorded by prepits made of concavities and convexities provided in the layer that can only read the information, In addition, the layer capable of only reading the information is a recording / reproducing method of an optical information recording medium in which information is recorded in an in-pit format in which prepits are formed to be concave with respect to a light incident surface. Address information indicating a recording position is recorded with a recording mark when information is recorded on the rewrite layer.

  Therefore, it is easy to confirm the disc type in the recording / reproducing apparatus, and the one recording / reproducing apparatus can be used in common with other types of optical discs, and the production of the disc is facilitated. An optical information recording medium reproducing method, an optical information recording medium recording method, and an optical information recording medium recording / reproducing, in which the old data in the ROM layer can be replaced with the updated data obtained when it can be connected to the Internet. The method can be realized.

It is the schematic showing the structure of the optical information recording medium of this invention. It is a top view showing the structure of the optical information recording medium of this invention. (A) is a schematic diagram showing the configuration of an optical information recording medium in which both the L0 layer and the L1 layer are ROM layers, and (b) is an optical information recording medium in which both the L0 layer and the L1 layer are RE layers. (C) is a schematic diagram showing the configuration of an optical information recording medium in which the L0 layer is the RE layer and the L1 layer is the ROM layer. FIG. 4 is an enlarged view of a main part showing a surface state of a portion where BCA recording is performed on the optical information recording medium shown in FIG. It is a graph showing the result of having measured the thickness of the cover layer which is the surface of the optical information recording medium shown in FIG. It is the schematic explaining the ROM layer of an in-pit recording format. It is the schematic explaining the RE layer of an on-groove recording format. It is the schematic explaining the ROM layer of an on-pit recording format. (A) (b) is explanatory drawing of an opposite track path, (a) is explanatory drawing showing the track path direction of L0 layer seen from the light-incidence surface, (b) is L1 seen from the light-incidence surface. It is explanatory drawing showing the track path direction of a layer. (A) (b) is explanatory drawing of a parallel track path, (a) is explanatory drawing showing the track path direction of L0 layer seen from the light-incidence surface, (b) is L1 seen from the light-incidence surface. It is explanatory drawing showing the track path direction of a layer. (A) is a figure explaining the mode of information recording / reproducing in the case of an opposite track path, and (b) is a figure explaining the mode of recording / reproducing information in the case of a parallel track path. It is the schematic explaining the optical information recording / reproducing apparatus which concerns on one Embodiment of this invention. It is the schematic showing an example of BCA of the optical information recording medium which concerns on one Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail.
(Schematic configuration of the optical information recording medium 1)
The configuration of the optical information recording medium 1 according to one embodiment of the present invention will be described.

  FIG. 1 is a schematic diagram showing the configuration of the optical information recording medium 1.

  As shown in FIG. 1, the optical information recording medium 1 includes a ROM layer 20 and an RE layer 40, which are a plurality of information recording layers from which information can be read by reproduction light, and a ROM layer 20 and an RE layer. The intermediate layer 30 that separates the layer 40 and the cover layer 10 provided at a position farthest from the substrate 50 are included. The side on which the cover layer 10 is disposed is the reproduction light incident side.

  The ROM layer 20 is a layer that can only read information. The RE layer 40 is a rewrite layer including an area where information can be rewritten. The RE layer 40 is an information recording layer provided at a position farthest from the cover layer 10 and can be determined more easily than an information recording format used in a layer that can only read information by light irradiation. It is a recording layer of disc type identification information and individual identification number to be recorded.

  The cover layer 10 is made of, for example, an ultraviolet curable resin having a thickness of 75 μm (refractive index of 1.50 at a reproduction light wavelength of 405 nm). The cover layer 10 may be made of a material having a high transmittance at the reproduction light wavelength. That is, the cover layer 10 may be formed of, for example, a polycarbonate film and a transparent adhesive. Further, a hard coat for surface protection may be provided on the surface of the cover layer 10. Furthermore, the thickness of the cover layer 10 may be changed according to the optical system of the reproducing apparatus (driving apparatus) for the optical information recording medium. Specifically, the cover layer 10 may be, for example, a 0.6 mm polycarbonate substrate.

  The ROM layer 20 is made of, for example, APC (AgPdCu) having a thickness of 9 nm, and is formed on the surface of the intermediate layer 30 by a sputtering method. The thickness and material of the ROM layer 20 are not limited to this, and it is sufficient that the ROM layer 20 has transmittance and reflectance at the reproduction light wavelength necessary for the ROM layer 20.

  The intermediate layer 30 is made of, for example, a transparent ultraviolet curable resin having a thickness of 25 μm (a refractive index of 1.50 at the reproduction light wavelength). The material of the intermediate layer 30 is not limited to this, and any material having a high transmittance at the wavelength of the reproduction light may be used. Further, the thickness of the intermediate layer 30 is not limited to this, and the information recording layers (in this case, the ROM layer 20 and the RE layer 40) can be separated, so that the interlayer crosstalk does not cause a problem. I just need it. Interlayer crosstalk refers to noise from information recording layers other than the information recording layer being reproduced. Further, the intermediate layer 30 may have a multilayer structure. Further, prepits made of concavities and convexities corresponding to information recorded as shapes on the ROM layer 20 are provided on the surface of the intermediate layer 30 on the ROM layer 20 side by a 2P method (photo polymerization method).

  Here, the 2P method is a method in which an ultraviolet curable resin is filled between a flat plate and a master, and ultraviolet rays are irradiated to cure the ultraviolet curable resin, and then the master is peeled off to transfer the unevenness of the master onto the flat plate. It points out the technique to do.

  The RE layer (L0 layer) 40 is formed by laminating seven thin films by, for example, sputtering. Specifically, the seven-layer thin film includes, from the reproduction light incident side, a first protective film 41 (ZnS—SiO 2 with a thickness of 35 nm), a second protective film 42 (ZrO 2 with a thickness of 5 nm), and a recording layer 43. (GeTe-Sb2Te3 with a thickness of 10 nm), third protective film 44 (ZrO2 with a thickness of 5 nm), fourth protective film 45 (ZnS-SiO2 with a thickness of 35 nm), fifth protective film 46 (ZrO2 with a thickness of 5 nm) , And a reflective film 47 (APC (AgPdCu) with a thickness of 20 nm) are sequentially stacked. Note that the material, thickness, and number of layers of the RE layer 40 are not limited thereto, and any material that functions as an RE layer may be used.

  The substrate 50 is made of, for example, a polycarbonate disk-shaped substrate having a groove having a diameter of 120 mm and a thickness of 1.1 mm. The material and thickness of the substrate 50 are not limited to this, and a groove is provided on the surface, and it is sufficient that the substrate 50 has a predetermined strength enough to be used as the substrate. Specifically, the substrate 50 may be made of, for example, a polyolefin resin or a metal. Further, the substrate 50 may have a multilayer structure.

  FIG. 2 is a plan view schematically showing the configuration of the optical information recording medium 1.

  FIG. 13 is a schematic diagram illustrating an example of the BCA arranged in the optical information recording medium 1.

  As shown in FIG. 2, the optical information recording medium 1 includes an area A (content recording area) that is an area for recording and reproducing normal information, and an area B that is an area for recording and reproducing BCA. .

  Area A is an area for recording / reproducing content information and the like for use by the user.

  The area B is a BCA recording area for recording BCA, and is provided on the inner peripheral side of the optical information recording medium 1. The BCA is provided in the L0 layer immediately above the substrate 50.

  The BCA is recorded by a method that can be easily determined from the information recording format used in the ROM layer 20. The BCA includes disc type identification information and an individual identification number. An example of BCA is shown in FIG. In FIG. 13, the arrow a represents the length and the arrow b represents the width.

  In the optical information recording medium 1, the disc type identification information and the individual identification information are recorded in the L0 layer, which is an information recording layer provided at a position farthest from the light transmitting layer.

  For this reason, of the plurality of information recording layers, the disc type identification information and the individual identification information are recorded in which layer is recorded in advance on a playback device that reproduces the disc type identification information and the individual identification information. It can be set. As a result, it is possible to shorten the time required for the playback device to specify the layer in which the disc type identification information and the individual identification information are recorded among the plurality of information recording layers. Furthermore, it becomes easy to share optical discs of various disc types with the same playback device.

  Further, according to the above configuration, the information recording layer provided at the position farthest from the cover layer 10 is the RE layer. According to the above configuration, the RE layer 40 is disposed as the L0 layer.

  For this reason, the RE layer when the BCA is recorded on the ROM layer, the intermediate layer disposed on the upper or lower layer of the RE layer, the light transmitting layer, and the like, which are generated when the ROM layer is disposed as the L0 layer, are peeled off. Can be prevented. Therefore, the disc type identification information recorded on the L0 layer, the individual identification number, and the like can be correctly reproduced by a reproduction device (details will be described later).

  As described above, the optical information recording medium 1 is a BD multi-layer disc that is easier to increase the recording capacity than the DVD type, and in the combination disc, it is easier to determine than the information recording format used by the user for the L0 layer. There are disc type identification information and individual identification numbers recorded in a possible manner, and the RE layer 40 is arranged.

  With the above structure, the disc type in the recording / reproducing apparatus of the optical information recording medium 1 can be easily confirmed, and one recording / reproducing apparatus can be used in common with other types of optical discs, and the production of the disc is facilitated. Then, it is possible to realize a combination disk in which the old data in the ROM layer can be recorded and replaced in the RE layer with the update data obtained when the network connection is possible. The optical information recording medium according to the embodiment of the present invention is not limited to the above, and may be an information recording medium having three or more layers further provided with an RE layer and a ROM layer. Or the thickness of the intermediate layer may be different from the above.

  In the BCA, a pulse laser beam is applied to the RE layer 40 that is the L0 layer, whereby a stripe having a width of μm is formed in the RE layer 40. Thereby, BCA is formed in the RE layer 40. Since BCA is a stripe having a width of μm and a length of several hundreds of μm, it is larger than a prepit formed in the ROM layer 20. For this reason, even if the focus of the playback apparatus that plays back BCA is slightly deviated, the playback apparatus can read it without performing tracking. For this reason, the BCA is recorded in the RE layer 40, which is the L0 layer, in a manner that can be easily distinguished from the pre-pits used in the ROM layer in the ROM layer.

  Further, in the optical information recording medium 1, the region B is arranged on the inner periphery from the region A. That is, the BCA is arranged near the inner periphery of the optical information recording medium 1. For this reason, compared with the case where BCA is arrange | positioned in the outer periphery vicinity of the optical information recording medium 1, the recording amount of BCA recorded on the optical information recording medium 1 can be decreased. For this reason, the time for recording BCA on the optical information recording medium 1 can be shortened.

  Further, the address of the RE layer 40 (rewrite layer) is recorded by meandering the groove provided in the RE layer 40 in the substrate surface direction, and the address of the ROM layer 20 is determined from the unevenness provided in the ROM layer 20. Is recorded by pre-pits.

  Here, the RE layer 40 is usually provided with a groove so that recording marks adjacent in the radial direction do not interfere with each other during information recording, or in order to reproduce with high accuracy. Therefore, in order to record the address information, it is easiest to record the groove provided in the rewrite layer by meandering in the substrate surface direction (hereinafter referred to as wobble). On the other hand, providing a prepit on the groove or providing a prepit in the middle of the groove complicates the operation and increases the manufacturing cost.

  Similarly, since information is generally recorded in the ROM layer 20 with prepits having unevenness, for the same reason as described above, in order to record address information, prepits are provided to prevent an increase in manufacturing cost. be able to.

(Conventional problem)
Next, with reference to FIGS. 3A to 3C, problems in recording BCA on a conventional combination disc will be described using BCA recording results on the following two types of media.

  FIG. 3A is a schematic diagram showing a configuration of an optical information recording medium in which both the L0 layer and the L1 layer are ROM layers, and FIG. 3B is an optical information in which both the L0 layer and the L1 layer are RE layers. It is the schematic showing the structure of a recording medium, (c) is the schematic showing the structure of the optical information recording medium whose L0 layer is RE layer and whose L1 layer is ROM layer. That is, FIG. 3C shows the configuration of the optical information recording medium 1.

  As shown in FIG. 3A, the optical information recording medium 110 has a structure in which a cover layer 10, a ROM layer 120, an intermediate layer 30, a ROM layer 140, and a substrate 50 are stacked in this order from the reproduction light incident surface side. It has become.

  The cover layer 10 is made of an ultraviolet curable resin (refractive index of 1.50 at a reproduction light wavelength of 405 nm) having a thickness of 75 μm.

  The ROM layer 120 is made of APC (AgPdCu) having a thickness of 9 nm. The APC that forms the ROM layer 120 is formed on the surface of the intermediate layer 30 by sputtering.

  The intermediate layer 30 is made of a transparent ultraviolet curable resin (refractive index at a reproduction light wavelength of 1.50) having a thickness of 25 μm. In addition, on the surface of the intermediate layer 30 on the ROM layer 120 side, prepits having unevenness corresponding to information recorded as a shape on the ROM layer 120 are provided by the 2P method.

  The ROM layer 140 is made of APC (AgPdCu) having a thickness of 17 nm. The APC that forms the ROM layer 140 is formed on the surface of the substrate 50 by sputtering.

  The substrate 50 was a polycarbonate disk-shaped substrate having a groove having a diameter of 120 mm and a thickness of 1.1 mm.

  As shown in FIG. 3B, the optical information recording medium 200 includes a cover layer 10, an RE layer (L1 layer) 220, an intermediate layer 30, an RE layer (L0 layer) 240, and a substrate in this order from the reproduction light incident surface side. 50 is laminated.

  The cover layer 10 is made of an ultraviolet curable resin (refractive index at a reproduction light wavelength of 1.50) having a thickness of 75 μm.

  The RE layer (L1 layer) 220 is composed of six thin films. Although not shown in the drawing, the six layers of the thin film are, from the reproduction light incident side, a first protective film (ZnS—SiO 2 with a thickness of 35 nm), a second protective film (ZrO 2 with a thickness of 5 nm), and a recording layer (with a thickness of 6 nm). GeTe-Sb2Te3), a third protective film (ZrO2 having a thickness of 5 nm), a translucent film (APC (AgPdCu) having a thickness of 10 nm), and a transmittance adjusting film (TiO2 having a thickness of 19 nm) are sequentially stacked.

  The intermediate layer 30 is made of a transparent ultraviolet curable resin (refractive index at a reproduction light wavelength of 1.50) having a thickness of 25 μm. A groove is provided on the surface of the intermediate layer 30 on the RE layer (L1 layer) 220 side by the 2P method.

  In the RE layer (L0 layer) 240, seven thin films are laminated by sputtering. Specifically, although not shown, these seven thin films are formed from the reproduction light incident side from the first protective film (ZnS—SiO 2 having a thickness of 35 nm), the second protective film (ZrO 2 having a thickness of 5 nm), and the recording layer ( GeTe-Sb2Te3) having a thickness of 10 nm, a third protective film (ZrO2 having a thickness of 5 nm), a fourth protective film (ZnS-SiO2 having a thickness of 35 nm), a fifth protective film (ZrO2 having a thickness of 5 nm), and a reflective film (APC (AgPdCu) with a thickness of 20 nm) are sequentially stacked.

  The substrate 50 was a polycarbonate disk-shaped substrate having a groove having a diameter of 120 mm and a thickness of 1.1 mm.

  Then, using the optical information recording medium 110, a laser beam having a wavelength of 808 nm is emitted as a recording / reproducing apparatus in order to measure the power required for BCA recording on the LO layer in the two-layer medium whose L0 layer is the ROM layer 140. BCA recording was performed on the ROM layer 120 of the optical information recording medium 110 while changing the laser power with a BCA recording apparatus for BD-RE (ODI-1000 manufactured by Pulse Tech Co., Ltd.) having a possible semiconductor laser.

  However, BCA recording on the ROM layer 140, which is the L0 layer of the optical information recording medium 110, is possible even at 2W (linear velocity at the time of BCA recording: 3 m / s) of the BD-RE BCA recording apparatus described above. I could not do it.

  Next, using the BD-RE BCA recording apparatus, BCA recording onto the RE layer 240, which is the L0 layer, of the optical information recording medium 200 at a maximum output of 2 W (linear velocity at the time of BCA recording: 3 m / s). The surface of the optical information recording medium 200 was visually confirmed. The result is shown in FIG.

  FIG. 4 is an explanatory diagram showing a state of an experimental result obtained by performing BCA recording on the optical information recording medium 200. FIG. 5 is a graph showing the result of measuring the thickness of the cover layer 10 which is the surface of the optical information recording medium 200 along the arrows shown at the measurement points shown in FIG.

  In the arrow indicating the measurement location in FIG. 4, the left direction toward the paper surface is the inner diameter direction of the optical information recording medium 200, and the right direction toward the paper surface is the outer peripheral direction of the optical information recording medium 200. In FIG. 5, the horizontal axis represents the measurement position on the optical information recording medium 200, and the vertical axis represents the thickness of the cover layer 10 that is the surface of the optical information recording medium 200.

  4 represents the position where the measurement position on the horizontal axis in FIG. 5 is “0”. And the internal diameter direction of the arrow showing the measurement location of FIG. 4 shows a negative direction as a measurement position of FIG. Moreover, the outer periphery direction of the arrow showing the measurement location of FIG. 3 shows a positive direction as a measurement position of FIG.

  As shown in FIG. 4, it was confirmed by visual observation that the BCA recording portion where BCA recording was performed on the optical information recording medium 200 was discolored.

  Moreover, as shown in FIG. 5, it turns out that the thickness of the cover layer 10 is thick in the measurement position near "-1". As is apparent from the results of FIGS. 4 and 5, the cover layer 10 increases at the radial position where the BCA recording is performed on the optical information recording medium 200.

  This increase is considered to be caused by the separation of the RE layer 220 and the cover layer 10 in the L1 layer.

  For confirmation, an attempt was made to focus on the L0 layer at the above radial position using ODU-1000 manufactured by Pulstec, which is a BD evaluation machine, and it was found that focusing was impossible.

  The reason why the focus cannot be obtained in this way is considered that the above-described peeling of the cover layer 10 hinders the focus on the RE layer 240 that is the L0 layer. That is, when the cover layer 10 is peeled off, it is impossible to reproduce the information in the L0 layer.

  Therefore, BCA recording cannot be performed on the two-layer optical information recording medium in which the L0 layer is the ROM layer and the L1 layer is the RE layer without peeling off the cover layer. For this reason, BCA recording is substantially impossible on the two-layer optical information recording medium in which the L0 layer is the ROM layer and the L1 layer is the RE layer.

  In addition, since the BCA recording on the ROM layer needs to be performed with a higher laser power if the optical information recording medium has a multilayer structure, the above result is that of the BD type in which the RE layer and the ROM layer are mixed. In the combination disc, when BCA recording is performed on the L0 layer in order to share with other types of media, the L0 layer should not be the ROM layer.

  The RE layer (L1 layer) 220 has a configuration generally used for the L1 layer of a two-layer BD-RE. Further, even if the configuration of the RE layer (L1 layer) 220 is changed to another configuration, the result does not change because there is not much difference in the point of absorbing light and generating heat.

  That is, in a BD type combination disc in which the RE layer and the ROM layer are mixed, the L0 layer must be the RE layer.

Further, as shown in FIG. 3C, the optical information recording medium 1 was manufactured as a BD type combination disk in which the RE layer 40 was provided in the L0 layer and the ROM layer 20 was provided in the L1 layer. When BCA recording was performed on the RE layer 40, which is the L0 layer, it was confirmed that BCA recording could be performed without any problem. That is, unlike the optical information recording medium 1, by providing the RE layer 40 in the L0 layer and the ROM layer 20 in the L1 layer, there is no problem such as peeling of the cover layer where BCA recording is performed. Was confirmed.
(Prepit recording format)
Next, the format of prepits or recording marks formed in the information recording layer (ROM layer and RE layer) will be described.

  FIG. 6 is a schematic diagram for explaining an in-pit recording format ROM layer. FIG. 7 is a schematic diagram for explaining the RE layer in the on-groove recording format. FIG. 8 is a schematic diagram for explaining the ROM layer of the on-pit recording format.

  In the present embodiment, as shown in FIG. 6, the prepit 21 is formed in the ROM layer 20 of the optical information recording medium 1 so as to be concave with respect to the light (reproducing light) incident surface of the ROM layer 20. Information is recorded in in-pit format. Thereby, the ROM layer 20 in the optical information recording medium 1 which is a combination disk can be prevented from being damaged for the following reasons.

  In order to explain the reason why the ROM layer 20 can be prevented from being damaged by forming the prepit 21 in the inpit format on the ROM layer 20, first, a structure other than the above (that is, the on-pit format in the ROM layer). (Structure of a combination disk in which prepits are formed), the damage of the ROM layer will be described.

  The ROM layer on which the prepits in the on-pit format are formed is formed such that the prepit 121 is convex with respect to the light (reproducing light) incident surface of the ROM layer 120, as in the ROM layer 120 shown in FIG. It is what.

  Usually, in one standard of optical discs, address information indicating the recording position of information is simplified in the mechanism of a recording / reproducing apparatus for recording / reproducing information on / from the optical disc regardless of the type of ROM, R, RW, RE, etc. The same information format is used to do this.

  Here, the recording / reproducing apparatus of the optical information recording medium 1 includes an apparatus that performs both recording and reproduction, an apparatus that performs only recording, and an apparatus that performs only reproduction.

  For example, in BD-RE, this increases the detection speed of address information, so that address information is also recorded by the recording mark at the same time when information is recorded by the recording mark. Therefore, in the RE layer (rewrite layer) of the combination disc, the mechanism of the recording / reproducing apparatus for the combination disc can be simplified by following the same format.

  Further, in the combination disk, it is desirable that the ROM layer stamper can be shared with a ROM disk stamper (an optical disk whose information recording layer is composed only of the ROM layer) in order to reduce costs.

  Therefore, in a desirable combination disc, the same address information exists in both the ROM layer and the RE layer when information (recording marks) is recorded in the RE layer. The same applies to the optical information recording medium 1 according to the present embodiment, and the same address information exists in both the ROM layer 20 and the RE layer 40.

  Here, in the RE layer 40, a recording mark 49 that is information is formed on the groove 48 among the plurality of grooves 48 that are convex portions and between the plurality of grooves 48 that are concave portions.

  For example, when the pitch between the grooves of the RE layer is as narrow as 0.32 μm, for example, BD-RE, the convex portion (on the groove) and the concave portion (between the grooves) are equivalent to the incident light. However, when recording marks are recorded in the recesses, incident light passes over the walls of the protrusions and the recesses and reaches the adjacent protrusions, causing cross light.

  For this reason, in the RE layer having a narrower track pitch than the above, recording / reproduction is indispensable in an on-groove which is an arrangement in which the groove is a convex portion (configuration in which a recording mark is arranged in the convex portion). .

  Therefore, it can be assumed that the same applies to the RE layer 40 in the optical information recording medium 1 that is a combination disc. That is, as shown in FIG. 7, the RE layer 40 is recorded / reproduced in an on-groove which is an arrangement in which the groove 48 is a convex portion (a configuration in which the recording mark 49 is arranged on the convex portion).

  As described above, in the reproducing apparatus of the combination disk, when the address information of the RE layer is reproduced, the information is reproduced with the setting that the on-groove recording is performed.

  Here, in the combination disc, when a layer jump is performed from the ROM layer to the RE layer on which the recording mark is recorded as described above, there is no guarantee that the RE layer is always focused.

  However, when the ROM layer is in the on-pit format, such as the ROM layer 120 shown in FIG. 8, a layer jump is performed to the RE layer in which information is recorded as described above, and the ROM layer 120 is erroneously focused. Even in such a case, it is possible to track the ROM layer 20 using DPP, which is a normal tracking method for the RE layer.

  This is because DPP, which is a tracking method for a normal RE layer, has a positive push-pull polarity, a RE layer in which a recording mark is recorded by an on-groove, and a ROM layer in which pre-pits in an on-pit format are formed. In both cases, the information can be recorded and reproduced by the tracking method in which the push-pull polarity is positive.

  Therefore, only by reproducing the address information of the combination disk such as the optical information recording medium 1 in which the same address information is recorded on the ROM layer 20 and the RE layer 40, either the ROM layer 20 or the RE layer 40 is used. It is unknown whether the address information is recorded in For this reason, in the case of a combination disc including an RE layer on which a recording mark is recorded by an on-groove and a ROM layer on which a pre-pit in an on-pit format is formed, a recording / reproducing apparatus for recording / reproducing the combination disc includes a ROM It is unclear which layer is focused on between the layer and the RE layer.

  Thus, for example, in the recording / reproducing apparatus, although the focus is actually on the ROM layer of the combination disc, it is erroneously determined that the focus is on the RE layer, and the information on the ROM layer is rewritten. There is a possibility that.

  In general, the recording power (power of laser light for recording information) in a recording / reproducing apparatus is very large compared to the reproducing power (power of laser light for reproducing information).

  For this reason, an unexpectedly high power laser beam is irradiated to the read-only ROM layer. For this reason, in the case of a combination disk in which information is recorded in the on-pit format, such as the ROM layer 120, the possibility of damage to the ROM layer increases. As described above, in the combination disk in which no information is recorded in the ROM layer in the in-pit format, it can be assumed that the ROM layer is damaged.

  Next, the reason why the ROM layer 20 can be prevented from being damaged in the optical information recording medium 1 will be described.

  In the optical information recording medium 1 according to the present embodiment, the prepits 21 of the ROM layer 20 are formed in an in-pit format. As described above, the prepit 21 formed in the in-pit format can be read by a tracking method in which the push-pull polarity is negative.

  That is, it is expressed that information is recorded in the ROM layer 20 by the prepit 21 in a recording format in which the polarity of the push-pull signal obtained when the information provided in the ROM layer 20 is reproduced is negative. can do.

  Therefore, in the recording / reproducing apparatus for recording / reproducing information on the optical information recording medium 1, when the ROM layer 20 is tracked with the push-pull polarity (positive) corresponding to the on-groove information recording of the RE layer 40, the ROM layer 20 Since the prepit recording format is in-pit, the address information of the ROM layer 20 cannot be reproduced.

  In other words, erroneous information cannot be rewritten in the ROM layer 20, and even when the ROM layer 20 is mistakenly focused, the ROM layer 20 can be prevented from being damaged by the structure of the present invention. .

  The negative polarity of the push-pull signal means that the light receiving part of the reproduction signal is divided into two parts, the inner periphery and the outer periphery, and the voltage obtained from the inner light receiving part from the voltage obtained from the outer light receiving part. In the playback device in which the push-pull signal is calculated by subtracting, the order of the push-pull signal level is 0, negative, 0, positive, 0 when jumping from the track reproducing the prepit information to the inner circumference. Means that It is a general expression for those skilled in the art.

(Track path)
Next, the track path of the optical information recording medium 1 will be described.

  9A and 9B are explanatory diagrams of the opposite track path, FIG. 9A is an explanatory diagram showing the track path direction of the L0 layer as viewed from the light incident surface, and FIG. It is explanatory drawing showing the track path direction of L1 layer seen from the entrance plane.

  FIGS. 10A and 10B are explanatory diagrams of the parallel track path, and FIG. 10A is an explanatory diagram showing the track path direction of the L0 layer viewed from the light incident surface, and FIG. These are explanatory drawings showing the track path direction of L1 layer seen from the light-incidence surface.

  FIG. 11A is an explanatory diagram for explaining how information is recorded and reproduced in the case of an opposite track path, and FIG. 11B is an explanation for explaining how information is recorded and reproduced in the case of a parallel track path. FIG.

  Generally, an opposite track path is employed in a recording type two-layer optical information recording medium. For example, when a large amount of information is continuously recorded, when recording is started from the inner periphery of the L0 layer to the outermost periphery of the same layer, recording to the L1 layer is started next. In that case, when the track path direction of the L1 layer is an opposite track path from the outer periphery to the inner periphery, the layer jump to the L1 layer can be continued with almost no movement of the pickup in the radial direction, and recording can be continued.

  On the other hand, in the case of the parallel track path, recording is started from the inner circumference of the L0 layer, and when the recording is finished up to the outermost circumference of the same layer, recording to the L1 layer is started next, but the track path direction of the L1 layer is The direction is from the inner periphery toward the outer periphery. In the case of a parallel track path, a large movement is caused in the radial direction of the pickup. For this reason, generally, the opposite track path can shorten the recording time than the parallel track path.

  Since the same can be said for a read-only two-layer optical information recording medium, generally, an opposite track path is also adopted for a read-only two-layer optical information recording medium.

  By the way, in a combination disk in which the L0 layer is the RE layer and the L1 layer is the ROM layer, the RE layer and the ROM layer are preferably parallel track paths.

  That is, in the optical information recording medium 1, the track path direction of the RE layer 40 that is the L0 layer is a direction from the inner periphery to the outer periphery, and the track path of the ROM layer 20 is a parallel track path.

  Further, in the optical information recording medium 1, it is preferable that the lead-in area of the ROM layer 20 is provided in the inner peripheral part from the area A (see FIG. 2) where contents and the like are recorded.

  This is because the optical information recording medium 1 does not record information up to the L1 layer during continuous recording, and when reproducing the information recorded on the optical information recording medium 1, the old data in the ROM layer 20 described above is used. When considering the use of recording and replacing the update data obtained when the network connection is possible in the RE layer 40, the supplementary information of the RE layer 40 is used in a timely manner when reproducing the information recorded in the ROM layer 20. . For this reason, the optical information recording medium 1 cannot originally use the method of continuously reproducing from the ROM layer 20 to the RE layer 40.

  Furthermore, in the ROM layer 20, the content capacity is unlikely to match the maximum capacity of the ROM layer 20, and the content capacity is usually smaller than the maximum capacity of the ROM layer 20.

  In this case, when the track path direction of the ROM layer 20 of the L1 layer is directed from the outer circumference to the inner circumference (in the case of an opposite track path), the content can be reproduced immediately after reproducing the information recorded in the lead-in area. Therefore, the lead-in area for obtaining information for reproducing the ROM layer 20 should be at the most upstream in the track path direction. Therefore, in the case of an opposite track path, the ROM layer 20 is provided with a lead-in area at the outer peripheral portion, and the inner peripheral side is blank.

  Here, in the lead-in area, medium information related to the optical information recording medium such as medium type information, reproduction condition information, recording condition information, and sector last number information is mainly recorded.

  The medium type information is information on the type and the number of layers such as R, RE, and ROM (in this embodiment, a combination of a ROM layer and an RE layer). The reproduction condition information is information such as recommended reproduction laser power and linear velocity. The recording condition information is information such as recommended recording power and recommended recording strategy. The sector last number information is information indicating an area in which the ROM layer is recorded.

  By the way, generally, when a recording / reproducing apparatus accesses the lead-in area of an optical information recording medium, the lead-in area of the optical information recording medium does not have a certain width in the radial direction due to the limit of the pickup movement system by the servo motor. If you can not access.

  Further, there is not a lot of disc information to be recorded in the lead-in area, and the disc information is repeatedly recorded so that the information can be quickly reproduced regardless of the position at which the reproduction starts. Therefore, when a lead-in area having the same radial width is provided, the number of repetitions of recording of disc information on the outer peripheral portion is significantly larger than that on the inner peripheral portion.

  That is, when recording information of the same capacity, it takes more time to create the stamper so that the track path direction is from the inner circumference to the outer circumference than to create the stamper from the outer circumference to the inner circumference. It will be.

  Since the size of the pits used in the current BD-ROM is very small, cutting at the DVD level cannot be applied, and cutting using EBR or the like is required, and the stamper is manufactured for a very long time. It takes.

  In general, when a stamper is manufactured by EBR (electron beam exposure), it is necessary to irradiate the resist coated on the master with a sufficient electron beam because the corresponding resist is exposed using the electron beam. . For this reason, it is necessary to make the linear speed for cutting very slow. For example, in order to manufacture a ROM stamper having a capacity of 25 GB for BD, two days of work time are required. Thus, when a stamper is manufactured by EBR, a long working time is required as compared with the conventional stamper manufacturing.

  That is, if the stamper is formed so that the track path direction is from the outer periphery to the inner periphery, it takes a lot of time, and the cost of manufacturing the ROM layer becomes very high.

  On the other hand, since the track path direction of many L0 layers is directed from the inner periphery to the outer periphery, and the BCA is provided on the inner periphery to share other media, the RE layer is accessed immediately after the BCA playback. Therefore, the track path direction of the L0 layer is preferably from the inner periphery to the outer periphery.

  Therefore, in the BD type combination disc in which the RE layer and the ROM layer are mixed, it is preferable that the RE layer and the ROM layer have parallel track paths.

  That is, like the optical information recording medium 1, the track path direction of the RE layer 40 which is the L0 layer is a direction from the inner circumference to the outer circumference, and the track path of the ROM layer 20 is a parallel track path. It is preferable.

  Furthermore, even when more RE layers and ROM layers are mixed, for the same reason, the ROM layer provided at the position farthest from the cover layer among the plurality of ROM layers is provided on the optical information recording medium. It is preferable that the information recording layer has a parallel relationship with the track path direction of the RE layer provided farthest from the cover layer.

(Information recording and playback device)
Next, the optical information recording / reproducing apparatus according to the present embodiment will be described with reference to FIG.

  As shown in FIG. 12, an optical information recording / reproducing apparatus (optical information recording medium recording / reproducing apparatus) 70 is an apparatus for recording and reproducing information with respect to the optical information recording medium 1.

  As shown in FIG. 12, the optical information recording / reproducing apparatus 70 includes a control unit 72, a switching mechanism (switching means) 73, an address determination mechanism 74, a pickup control unit 75, a data reproduction circuit 76, a pickup 71, ,including.

  As shown in FIG. 12, in the optical information recording / reproducing apparatus 70, the pickup 71 is moved to a track (not shown) of the rotating optical information recording medium 1.

  The control unit 72 sets a recording condition or a reproducing condition via a laser driving circuit (not shown), and irradiates a recording / reproducing laser beam from the pickup 71 onto the recording / reproducing part of the optical information recording medium 1. The address information of the optical information recording medium 1 is reproduced.

  The optical information recording / reproducing apparatus 70 reproduces the address information of the RE layer 40 of the optical information recording medium 1 (hereinafter referred to as RE layer address information reproducing method) and the method of reproducing the address information of the ROM layer 20. (Hereinafter, referred to as a ROM layer address information reproducing method).

  The switching mechanism 73 is contained in the control unit 72 and switches an input signal to the address determination mechanism in accordance with an instruction in the control unit.

  Since the optical information recording / reproducing apparatus 70 has the switching mechanism 73, the RE layer and the ROM layer are mixed in the same optical information recording medium as in the optical information recording medium 1, and the combination disc is reduced in cost. In contrast, the address information of the RE layer and the ROM layer can be reproduced. Therefore, the address information of the RE layer and the ROM layer can be recorded and reproduced satisfactorily.

  Further, switching between the RE layer address information reproducing method and the ROM layer reproducing method by the switching mechanism 73 changes the layer in which the optical information recording / reproducing apparatus 70 is recording or reproducing information with respect to the optical information recording medium 1. When switching, switch to the desired layer type.

  As described above, when the optical information recording / reproducing apparatus 70 changes the layer in which information is recorded or reproduced (layer jump), the optical information recording / reproducing apparatus 70 can quickly change by switching the address information reproducing method. The address information can be confirmed, and the present position can be determined. In addition, if the address information cannot be reproduced, the optical information recording / reproducing apparatus 70 can quickly determine that the layer jump to the target layer has not been possible.

  In addition, the optical information recording / reproducing apparatus 70 can also reproduce information recorded on the ROM layer 20 with a laser power that can favorably reproduce information recorded on the RE layer 40 of the optical information recording medium 1.

  In general, the RE layer has a difficulty in increasing the reflectivity due to the reason for the material composing the layer, as compared with the ROM layer. Therefore, for example, in a two-layer RE disc, reproduction is performed at a higher reproduction laser power than that of the two ROM layers in order to improve the signal characteristics of the L0 layer.

  Instead of the structure of the optical information recording medium 1 of the present embodiment, in the case of a two-layer combination disc having the ROM layer in the L0 layer, the RE layer in the L1 layer has no loss of light, so that the ROM layer is reproduced. Good reproduction characteristics can be obtained even with laser power.

  However, in the combination disk having the structure of the optical information recording medium 1 of the present embodiment, light loss always occurs. Therefore, it is preferable that the RE layer 40 is not reproduced with a laser power higher than the laser power for reproducing the ROM layer 20. Reproduction characteristics cannot be obtained.

  Therefore, the RE layer 40 provided in the L0 layer needs to be set higher than the laser power for reproducing the normal ROM layer 20. In that case, switching the laser power by a layer jump or the like places a heavy burden on the recording / reproducing apparatus, and therefore needs to be the same.

  Therefore, as described above, the information recorded in the ROM layer 20 is also reproduced with the laser power that allows the information recorded in the RE layer 40 of the optical information recording medium 1 to be reproduced satisfactorily. Produces the effect that the reproduction characteristics of the L0 layer can be improved and the burden on the device itself can be reduced.

  The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

  The present invention can also be expressed as follows.

  On the substrate, a plurality of information recording layers from which information can be read by reproduction light, an intermediate layer separating each of the plurality of information recording layers, and a light-transmitting layer provided at a position farthest from the substrate The plurality of information recording layers is an optical information recording medium comprising a layer capable of only reading information and a rewrite layer including a region where information can be rewritten, the farthest position from the light transmitting layer The information recording layer provided in is a rewritable layer including a region where information can be rewritten, and can be detected more easily than an information recording format used in a layer that can only read information by light irradiation. An optical information recording medium comprising a recording layer of disc type identification information and individual identification number recorded by a method.

  The easily discriminable method is a method of recording information by irradiating the information recording layer with a pulse laser beam to form a stripe having a width of μm and a length of μm to mm. An optical information recording medium.

  An optical information recording medium characterized in that a radius position where the disc type identification information and the individual identification number are recorded is located on an inner periphery of an information recording area that requires tracking for information reproduction.

  The track path direction of the information recording layer provided at the farthest position from the light transmitting layer is the direction from the inner periphery to the outer periphery, and is provided at the position farthest from the light transmitting layer with respect to the track path direction. An optical information recording medium, wherein a track path of a layer that can only read out the information is a parallel track path.

  An optical information recording medium characterized in that a lead-in area of a layer from which only the information can be read is provided at an inner peripheral portion from a content recording area.

  The address of the rewritable layer is recorded by meandering the groove provided in the rewritable layer in the direction of the substrate surface, and the address of the layer that can only read the information is the layer that can only read the information. An optical information recording medium recorded by prepits comprising unevenness provided.

  An optical information recording medium, wherein information is recorded in an in-pit format in which prepits are formed to be concave with respect to a light incident surface in a layer from which information can only be read.

  Light characterized in that information is recorded by prepits in a recording format in which the polarity of a push-pull signal obtained when reproducing information provided in a layer that can only read the information is negative Information recording medium.

  An optical information recording medium recording / reproducing apparatus capable of recording / reproducing information with respect to the optical information recording medium, wherein when reproducing the address of the optical information recording medium, the rewriting layer address information reproducing means An optical information recording medium recording / reproducing apparatus comprising switching means capable of switching between address information reproducing means of a layer that can only read the information.

  Switching of address information reproducing means by the switching means is performed according to the type of the target layer when the layer being recorded / reproduced is changed.

  An optical information recording medium recording / reproducing apparatus capable of recording / reproducing information with respect to the optical information recording medium, wherein information recorded on an information recording layer provided at a position farthest from the light transmitting layer is favorably recorded It is possible to reproduce the information of the layer that can only read out the information by the laser power that can reproduce the information and the laser power that reproduces the information recorded in the information recording layer provided farthest from the light transmitting layer. An optical information recording medium recording / reproducing apparatus.

  As described above, the optical information recording medium of the present invention includes, on a substrate, a plurality of information recording layers from which information can be read by reproduction light, an intermediate layer that separates each of the plurality of information recording layers, And a plurality of information recording layers, wherein the plurality of information recording layers include a layer that can only read information and a rewrite layer that includes a region where information can be rewritten. A recording medium, wherein the information recording layer provided at a position farthest from the light transmitting layer is a rewriting layer including a region where information can be rewritten, and is a layer that can only read information by light irradiation. The recording layer of the disc type identification information and the individual identification number is recorded by a method that can be easily determined from the information recording format used in the above.

  Here, the disc type identification information is information for identifying the disc type. That is, the disc type identification information indicates the number of information recording layers provided on the disc, the type of information recording layers provided (ROM, R, RE, etc.), This is information indicating the arrangement position of a layer that can only read the information (hereinafter referred to as a ROM layer) and a rewrite layer (hereinafter referred to as an RE layer) that includes an area where the information can be rewritten. This is information for identifying the type of the optical information recording medium.

  The individual identification number is a number for identifying an individual of the optical information recording medium, and is preferably recorded together with the optical information recording medium during BCA recording. By appropriately using the individual identification number, illegal dubbing to the RE layer can be prevented.

  According to the above configuration, the disc type identification information and the individual identification information are recorded in an information recording layer (hereinafter referred to as L0 layer) provided at a position farthest from the translucent layer.

  For this reason, of the plurality of information recording layers, the disc type identification information and the individual identification information are recorded in which layer is recorded in advance on a playback device that reproduces the disc type identification information and the individual identification information. It becomes possible to set. As a result, it is possible to shorten the time required for the playback device to specify the layer in which the disc type identification information and the individual identification information are recorded among the plurality of information recording layers. Furthermore, it becomes easy to share optical discs of various disc types with the same playback device.

  Further, according to the above configuration, the information recording layer provided at a position farthest from the light transmitting layer is the RE layer. That is, according to the above configuration, the RE layer is disposed as the L0 layer.

  Therefore, when the ROM layer is disposed as the L0 layer, the RE layer when the BCA is recorded on the ROM layer, the intermediate layer disposed on the upper layer or the lower layer of the RE layer, the translucent layer, and the like Can be prevented from peeling off. For this reason, the disc type identification information recorded in the L0 layer and the individual identification number can be correctly reproduced by a reproduction device or the like.

  Thus, the above configuration is a BD format multi-layer disc that is easier to increase the recording capacity than the DVD type, and in the combination disc, the user uses the information recording layer (L0) far from the light incident surface. There are disc type identification information and individual identification number (information recorded at the time of BCA recording) recorded by a method that can be easily determined by the information recording format, and an RE layer is arranged.

  With the above structure, the disc type in the recording / reproducing apparatus can be easily confirmed, and one recording / reproducing apparatus can be used in common with other types of optical discs, and the production of the disc becomes easy. Then, it is possible to realize an optical information recording medium in which the old data in the ROM layer can be replaced with the updated data obtained when the Internet connection is possible in the RE layer.

  In the optical information recording medium of the present invention, it is preferable that the discriminable method is a method of irradiating the information recording layer with a pulse laser beam to form a stripe having a width of μm to record information.

  With the above configuration, even when the radial position of the focus or reproduction light irradiation is slightly shifted during reproduction by the reproduction device for reading the disc type identification information and the individual identification number, Individual identification number can be read.

  In the optical information recording medium of the present invention, the radius position of the region B that is not essential for tracking when reproducing the information in which the disc type identification information and the individual identification number are recorded is tracked when the information is reproduced. Is preferably located on the inner periphery of the necessary information recording area A.

  According to the above configuration, the disc type identification information and the individual identification number are arranged near the inner periphery of the optical information recording medium. Therefore, the disc type identification information and the individual identification number are compared with the case where the disc type identification information and the individual identification number are arranged on the outer peripheral side of the information recording area, that is, in the vicinity of the outer periphery of the optical information recording medium. Can be shortened and the information recording capacity can be increased.

  In the optical information recording medium of the present invention, the track path direction of the information recording layer provided farthest from the light transmitting layer is the direction from the inner periphery to the outer periphery, and only the information is read out. It is preferable that a track path with a layer that can only read the information provided at a position farthest from the light transmitting layer among the possible layers is a parallel track path.

  According to the above configuration, from the vicinity of the inner periphery during the production of the stamper necessary for producing the layer that can only read out the information provided in the position farthest from the light transmitting layer among the layers that can only read out the information. Since cutting can be started, except when recording information on the entire surface of the information recording area A, cutting is easier in terms of accuracy than in the vicinity of the outer periphery, and manufacturing costs are reduced. it can.

  In addition, it is preferable that a lead-in area of a layer that can only read the information is provided in the inner peripheral part from the content recording area.

  According to the above configuration, the medium information (information such as medium type information, reproduction condition information, sector final number information, etc.) recorded in the lead-in area is arranged near the inner periphery of the optical information recording medium. Therefore, as compared with the case where the medium information is arranged on the outer peripheral side of the information recording area A, that is, in the vicinity of the outer periphery of the optical information recording medium, a stamper necessary for producing a layer that can only read the information is provided. Since the medium information can be recorded in the vicinity of the inner periphery at the time of manufacture, the time for manufacturing the stamper can be reduced, and the manufacturing cost can be reduced, and the information recording capacity can be further increased.

  This is because the medium information is necessary when reproducing the content information recorded in the information area A, and thus needs to be reproduced quickly. Therefore, it is preferable that the medium information can be reproduced without confirming the address. Information is reproduced immediately, regardless of the position of one round of playback, in an area of a certain width (determined by the accuracy of the servo motor that moves the pickup in the radial direction, for example, a width of several hundred μm). This is because the same information is recorded repeatedly so that a larger area is required if it is provided near the outer periphery, and more information needs to be recorded.

  The address of the rewrite layer of the optical information recording medium of the present invention is recorded by meandering a groove provided in the rewrite layer in the direction of the substrate surface, and the address of the layer from which only the information can be read is the information It is preferable that recording is performed by pre-pits made of unevenness provided in a layer that can only read the data.

  Here, the RE layer is usually provided with a groove so that recording marks adjacent in the radial direction do not interfere with each other during information recording, or in order to reproduce with high accuracy. Therefore, in order to record the address information, it is easiest to record the groove provided in the rewrite layer by meandering in the substrate surface direction (hereinafter referred to as wobble). On the other hand, providing a prepit on the groove or providing a prepit in the middle of the groove complicates the operation and increases the manufacturing cost.

  Similarly, since information is generally recorded in the ROM layer by prepits having unevenness, for the same reason as described above, in order to record address information, a prepit is provided on the groove or a prepit is provided in the middle of the groove. Compared with the provision, an increase in manufacturing cost can be prevented.

  Moreover, it is preferable that information is recorded in an in-pit format in which prepits are formed to be concave with respect to the light incident surface in the layer from which only the information can be read.

  Here, when the pitch of the groove of the RE layer becomes narrow, the convex and concave are not equivalent to the incident light, and when recording in the concave, the incident light gets over the wall of the convex and concave and the adjacent convex Therefore, in the RE layer having a narrow track pitch, recording / reproduction is required in the on-groove in which the grooves are arranged to be convex.

  When a layer jump is performed from the ROM layer to the RE layer, the ROM layer may be erroneously focused.

  In this case, if the ROM layer is tracked with the push-pull polarity (positive) corresponding to the on-groove information recording of the RE layer, the address of the ROM layer cannot be reproduced because the pre-pit recording format in the ROM layer is in-pit.

  That is, erroneous information rewriting in the ROM layer cannot be performed, and even when the ROM layer is mistakenly focused, the structure of the present invention can prevent damage to the ROM layer.

  As described above, in the case of the above configuration, it is possible to prevent damage to a layer that can only read information in the combination disk.

  In addition, it is preferable that information is recorded by prepits in a recording format in which the polarity of a push-pull signal obtained when information provided in a layer that can only read the information is reproduced is negative.

  Here, when recording / reproduction is performed in an on-groove in which the groove of the RE layer is arranged as a convex portion, the push-pull polarity corresponding to the information recording of the RE layer becomes positive.

  According to the above configuration, information is recorded on the ROM layer by the prepits in a recording format in which the polarity of the push-pull signal obtained when information is reproduced is negative.

  For this reason, when a layer jump is performed from the ROM layer to the RE layer, even if the ROM layer is mistakenly focused, the push-pull polarity (positive) corresponding to the information recording in the on-groove of the RE layer is positive. ) Cannot reproduce the ROM layer address.

  That is, erroneous information rewriting in the ROM layer cannot be performed, and even when the ROM layer is mistakenly focused, the structure of the present invention can prevent damage to the ROM layer.

  As described above, in the case of the above configuration, it is possible to prevent damage to a layer that can only read information in the combination disk.

  The negative polarity of the push-pull signal means that the light receiving part of the reproduction signal is divided into two parts, the inner periphery and the outer periphery, and the voltage obtained from the inner light receiving part from the voltage obtained from the outer light receiving part. In the playback device in which the push-pull signal is calculated by subtracting, the order of the push-pull signal level is 0, negative, 0, positive, 0 when jumping from the track reproducing the prepit information to the inner circumference. Means that It is a general expression for those skilled in the art.

  The optical information recording medium recording / reproducing apparatus of the present invention is an optical information recording medium recording / reproducing apparatus capable of recording / reproducing information with respect to the optical information recording medium, wherein the address of the optical information recording medium is reproduced. In addition, it is preferable to have a switching mechanism capable of switching between the address information reproducing method of the rewrite layer and the address information reproducing method of the layer that can only read the information.

  Here, the optical information recording medium recording / reproducing apparatus (recording / reproducing apparatus) includes an apparatus that performs both recording and reproduction, an apparatus that performs only recording, and an apparatus that performs only reproduction.

  By having the switching mechanism, the address information can be reproduced even for a combination disc in which the RE layer and the ROM layer are mixed in the same optical information recording medium as in the optical information recording medium and the cost is reduced. . For this reason, it becomes possible to record and reproduce each address information of the RE layer and the ROM layer satisfactorily.

  The switching of the address information reproducing method by the switching mechanism is preferably performed in accordance with the type of the target layer when the layer being recorded / reproduced is changed.

  With the above configuration, the optical information recording medium recording / reproducing apparatus switches the address reproducing method when changing the layer in which the information is recorded or reproduced (layer jump), so that the optical information recording medium recording / reproducing apparatus is switched. Has an effect that the address can be confirmed quickly and the current position can be determined. Further, the optical information recording medium recording / reproducing apparatus has an effect that, when the address cannot be reproduced, it can be quickly determined that the layer jump to the target layer cannot be performed.

  The optical information recording medium recording / reproducing apparatus has a laser power capable of satisfactorily reproducing information recorded on an information recording layer provided at a position farthest from the light transmitting layer, and is at a position farthest from the light transmitting layer. It is preferable to reproduce information of a layer that can only read information with laser power for reproducing information recorded on the information recording layer provided.

  Here, in general, it is difficult to increase the reflectance of the RE layer due to the material constituting the layer, as compared with the ROM layer. Therefore, for example, in a two-layer RE disc, reproduction is performed at a higher reproduction laser power than that of the two ROM layers in order to improve the signal characteristics of the L0 layer.

  In the two-layer combination disk having the ROM layer in the L0 layer which is not the optical information recording medium of the present invention, the RE layer in the L1 layer has no light loss, so even if the laser power is sufficient to reproduce the ROM layer. Good reproduction characteristics can be obtained. However, since the optical information recording medium of the present invention always causes a loss of light, good reproduction characteristics cannot be obtained unless reproduction is performed with a laser power higher than the minimum laser power necessary for reproducing the ROM layer. I can't.

  Therefore, the RE layer provided in the L0 layer needs to be set higher than the laser power for reproducing the normal ROM layer. In that case, switching the laser power by a layer jump or the like places a heavy burden on the apparatus, and therefore needs to be the same.

  Therefore, with the above configuration, the reproduction characteristics of the L0 layer can be improved and the burden on the apparatus can be reduced.

  As described above, the optical information recording medium of the present invention includes, on a substrate, a plurality of information recording layers from which information can be read by reproduction light, an intermediate layer that separates each of the plurality of information recording layers, And a plurality of information recording layers, wherein the plurality of information recording layers include a layer that can only read information and a rewrite layer that includes a region where information can be rewritten. A recording medium, wherein the information recording layer provided at a position farthest from the light transmitting layer is a rewriting layer including a region where information can be rewritten, and is a layer that can only read information by light irradiation. This is a recording layer of disc type identification information and individual identification numbers recorded in a manner that can be easily determined from the information recording format used in the above.

  Therefore, it is easy to confirm the disc type in the recording / reproducing apparatus, and the one recording / reproducing apparatus can be used in common with other types of optical discs, and the production of the disc is facilitated. Then, it is possible to realize an optical information recording medium in which the old data in the ROM layer can be replaced by recording the updated data obtained when the network connection is possible in the RE layer.

  The present invention can be applied to a combination disc and a recording / reproducing apparatus for information on the combination disc.

1 Optical information recording medium 10 Cover layer (translucent layer)
20 ROM layer 21 Prepit 30 Intermediate layer 40 RE layer (rewrite layer)
48 groove 49 recording mark 50 substrate 70 optical information recording / reproducing apparatus (optical information recording medium recording / reproducing apparatus)
71 Pickup 72 Control Unit 73 Switching Mechanism

Claims (5)

On the substrate, a plurality of information recording layers from which information can be read by reproduction light, an intermediate layer separating each of the plurality of information recording layers, and a light-transmitting layer provided at a position farthest from the substrate The plurality of information recording layers is an optical information recording medium comprising a layer capable of only reading information and a rewriting layer including a region capable of rewriting information,
The information recording layer provided at a position farthest from the light transmitting layer is a rewriting layer including an area where information can be rewritten, and has a width of μm in order to record the disc type identification information and the individual identification number. And a recording layer in which a stripe having a length of μm to mm is formed,
The address of the rewritable layer is recorded by meandering the groove provided in the rewritable layer in the direction of the substrate surface, and the address of the layer that can only read the information is the layer that can only read the information. It is recorded by prepits consisting of unevenness provided,
An optical information recording medium on which information is recorded by prepits in a recording format in which the polarity of a push-pull signal obtained when reproducing information provided in a layer that can only read the information is negative The playback method of
When reproducing the address of the optical information recording medium,
An optical information recording medium reproducing method comprising using address reproducing means adapted to the recording format of address information of each layer. On the substrate, a plurality of information recording layers from which information can be read by reproduction light, an intermediate layer separating each of the plurality of information recording layers, and a light-transmitting layer provided at a position farthest from the substrate The plurality of information recording layers is an optical information recording medium comprising a layer capable of only reading information and a rewriting layer including a region capable of rewriting information,
The information recording layer provided at a position farthest from the light transmitting layer is a rewriting layer including an area where information can be rewritten, and has a width of μm in order to record the disc type identification information and the individual identification number. And a recording layer in which a stripe having a length of μm to mm is formed,
The address of the rewritable layer is recorded by meandering the groove provided in the rewritable layer in the direction of the substrate surface, and the address of the layer that can only read the information is the layer that can only read the information. It is recorded by prepits consisting of unevenness provided,
And, in the layer that can only read the information, the reproducing method of the optical information recording medium in which the information is recorded in the in-pit format in which the prepit is formed to be concave with respect to the light incident surface,
When reproducing the address of the optical information recording medium,
An optical information recording medium reproducing method comprising using address reproducing means adapted to the recording format of address information of each layer.   3. The address reproducing means adapted to the recording format of the address information of each layer switches according to the type of the target layer when changing the recording / reproducing layer. Optical information recording medium reproduction method. On the substrate, a plurality of information recording layers from which information can be read by reproduction light, an intermediate layer separating each of the plurality of information recording layers, and a light-transmitting layer provided at a position farthest from the substrate The plurality of information recording layers is an optical information recording medium comprising a layer capable of only reading information and a rewriting layer including a region capable of rewriting information,
The information recording layer provided at a position farthest from the light transmitting layer is a rewriting layer including an area where information can be rewritten, and has a width of μm in order to record the disc type identification information and the individual identification number. And a recording layer in which a stripe having a length of μm to mm is formed,
The address of the rewritable layer is recorded by meandering the groove provided in the rewritable layer in the direction of the substrate surface, and the address of the layer that can only read the information is the layer that can only read the information. It is recorded by prepits consisting of unevenness provided,
An optical information recording medium on which information is recorded by prepits in a recording format in which the polarity of a push-pull signal obtained when reproducing information provided in a layer that can only read the information is negative Recording and playback method,
An optical information recording medium recording / reproducing method, wherein address information indicating a recording position is recorded with a recording mark when information is recorded on the rewrite layer. On the substrate, a plurality of information recording layers from which information can be read by reproduction light, an intermediate layer separating each of the plurality of information recording layers, and a light-transmitting layer provided at a position farthest from the substrate The plurality of information recording layers is an optical information recording medium comprising a layer capable of only reading information and a rewriting layer including a region capable of rewriting information,
The information recording layer provided at a position farthest from the light transmitting layer is a rewriting layer including an area where information can be rewritten, and has a width of μm in order to record the disc type identification information and the individual identification number. And a recording layer in which a stripe having a length of μm to mm is formed,
The address of the rewritable layer is recorded by meandering the groove provided in the rewritable layer in the direction of the substrate surface, and the address of the layer that can only read the information is the layer that can only read the information. It is recorded by prepits consisting of unevenness provided,
And, in the layer that can only read the information, the recording method of the optical information recording medium in which the information is recorded in the in-pit format in which the prepit is formed to be concave with respect to the light incident surface,
An optical information recording medium recording method, wherein address information indicating a recording position is recorded with a recording mark when information is recorded on the rewrite layer.