JP3898381B2 - Information recording medium, information recording medium manufacturing apparatus, and information recording apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention belongs to the technical fields of an information recording medium, an information recording medium manufacturing apparatus, and an information recording apparatus that can effectively prevent unauthorized copying of recorded information recorded on an information recording medium such as a DVD.
[0002]
[Prior art]
In recent years, a large-capacity optical disk represented by a DVD is rapidly spreading as an information recording medium for recording various contents such as video and audio. Since these contents recorded as digital data on an information recording medium such as a DVD are generally protected by copyright, it is necessary to prevent unauthorized copying to other information recording media. For example, in order to indicate that copying of content recorded on an information recording medium is prohibited, copy prohibition information may be written on an optical disc along with the content.
[0003]
Recently, DVD recordable (DVD-R) that can be recorded only once and DVD rewritable (DVD-RW) that can be repeatedly recorded have been realized. On the other hand, various control information such as identification information indicating the disc type is pre-recorded in a predetermined area on these information recording media. Therefore, the information reproducing apparatus can read the identification information included in the predetermined control information pre-recorded during the reproducing operation, and determine the disc type based on this. When the above-mentioned copy prohibition information is written in the content even though it is determined that the information reproducing apparatus can record the DVD-R or DVD-RW, an illegal copy is made on these optical discs. It is possible to recognize that it was done. In such a case, the reproduction of the illegally copied content is prevented by stopping the reproduction operation on the information reproducing apparatus side.
[0004]
[Problems to be solved by the invention]
However, the contents recorded on another DVD-ROM or the like are illegally copied to a DVD-R or DVD-RW, and the area where the above-described identification information is written is overwritten, thereby various control information. There is a concern to destroy. In such a case, the playback device cannot recognize that the copy is illegal, and it is difficult to protect the content whose copy is prohibited.
[0005]
Therefore, the present invention has been made in view of the above-described problems, and prevents overwriting of prerecorded data on a recordable information recording medium even when data is illegally copied to the information recording medium. An object of the present invention is to provide a writable information recording medium capable of effectively preventing unauthorized copying, an information recording medium manufacturing apparatus for manufacturing the information recording medium, and an information recording apparatus for recording on the information recording medium And
[0006]
[Means for Solving the Problems]
  In order to solve the above problem, an information recording medium according to claim 1 is a recording track having a first height on an information recording surface, and a guide track having a second height different from the first height. Are formed adjacent to each other, and record information can be repeatedly recorded on the recording track, in which pre-record data including predetermined control information is recorded and overwriting of other record information is prohibited. The first recording area and the pre-recording area provided at a predetermined position on the information recording surface and the predetermined height of the recording track and the adjacent guide track adjacent to the pre-recording area in the vicinity of the first height. A transition region arranged so as to transition the tracking locus of the light beam by the push-pull method to a path different from the pre-recording region,A recording track having the first height recordable by the light beam after passing through the transition region;It is characterized by providing.
  In order to solve the above problem, the information recording medium according to claim 2 is the information recording medium according to claim 1, wherein the recording track provided subsequent to the transition area continues from the pre-recording area. It is provided.
[0007]
According to the present invention, when copying content data to an information recording medium that can be repeatedly recorded, the recording track is irradiated with a light beam while performing tracking control by a push-pull method. When the light beam reaches the transition area, the guide track adjacent to the recording track is at the first height in the same manner as the recording track, so that the recording track is substantially expanded. Therefore, the traveling direction of the light beam is changed by the action of the push-pull method according to the arrangement of the transition region. Therefore, if the trajectory of the transition of the light beam and the pre-recording area are set to follow different paths, the pre-recording area is not traced, and overwriting of the pre-recorded data is prevented during illegal copying. On the other hand, in the reproduction operation, for example, if tracking control is performed by the phase difference method, the pre-recording area is traced and the pre-recorded data can be read out appropriately.
[0008]
Claim3The information recording medium described in claim 1Or 2The information recording medium according to claim 1, wherein the recording track and the guide track are formed in a spiral shape from an inner periphery toward an outer periphery, and the pre-recording area is a straight line on the same recording track. It is characterized by being provided in a shape.
[0009]
According to the present invention, when copying the content data by causing the light beam to travel on the spiral recording track from the inner periphery to the outer periphery of the disc, the light beam transits and proceeds from the straight direction of the recording track by the transition region. To do. On the other hand, during the reproducing operation, the light beam travels on the same recording track in the straight direction while reading the pre-recorded data. Therefore, it is possible to effectively prevent overwriting of the pre-recording area due to unauthorized copying without wasting the recording track of the disk.
[0010]
  Claim4The information recording medium described in claim3In the information recording medium described in the above, the transition region has the adjacent guide on the inner circumference side of the disc so that the tracking locus of the light beam by the push-pull method changes the path toward the recording track on the inner circumference side of the disc. A track is partially formed at the first height, and a subsequent recording track is partially formed at the second height.
[0011]
According to the present invention, when the content data is copied to the information recording medium, the traveling direction of the light beam reaches the transition area, and then the path changes to the recording track on the inner circumference side. to continue. Therefore, it is possible to effectively prevent overwriting of the pre-recording area due to illegal copying and to limit the recordable area on the disc.
[0012]
  Claim5The information recording medium described in claim3In the information recording medium described in the above, one of the adjacent guide tracks is partially at the first height so that the tracking region of the light beam by the push-pull method is curved in the disc radial direction. It is formed.
[0013]
According to the present invention, when the content data is copied to the information recording medium, the traveling direction of the light beam reaches the transition region, and then proceeds to bend in an oblique direction away from the recording track, and thereafter the original recording track. Return to. Therefore, it is possible to effectively prevent overwriting of the pre-recording area due to illegal copying with a simple disk structure.
[0014]
    Claim6The information recording medium described in claim 1Or 2The information recording medium according to claim 1, wherein the information recording medium is a disk-shaped recording medium in which the recording track and the guide track are spirally formed from an inner periphery toward an outer periphery, and the pre-recording area is an outer periphery of the disk. It is provided in a curved shape so as to be connected to the recording track on the side.
[0015]
According to the present invention, when copying the content data by advancing the light beam on the spiral recording track from the inner circumference to the outer circumference of the disc, the light is emitted in a direction different from the pre-record area which is curved according to the transition area. The beam transitions and proceeds. On the other hand, during the reproducing operation, the pre-recorded data is read and the light beam moves to the recording track on the outer circumference side of the disk in a curved shape. Therefore, it is possible to effectively prevent overwriting of the pre-recording area due to unauthorized copying while increasing the degree of freedom of arrangement of the pre-recording area.
[0016]
  Claim7The information recording medium described in claim6In the information recording medium described in the above, the transition region has the adjacent guide tracks on both sides symmetrically in the disk radial direction so that the tracking trajectory of the light beam by the push-pull method advances straight along the recording track. It is characterized by being formed at a second height.
[0017]
According to the present invention, when the content data is copied to the information recording medium, the traveling direction of the light beam reaches the transition region and then proceeds straight on the recording track. Advances to the outer recording track. Therefore, when illegal copying is performed, it can be reliably separated from the path during reproduction, and overwriting of the pre-recording area can be effectively prevented.
[0018]
  Claim8The information recording medium according to claim 6 is the information recording medium according to claim 6, wherein the transition region is configured such that a tracking locus of a light beam by a push-pull method changes a path toward the recording track on the inner periphery side of the disc. Further, the adjacent guide tracks on both sides are formed at the second height asymmetrically in the disk radial direction.
[0019]
According to the present invention, when copying the content data to the information recording medium, after the traveling direction of the light beam reaches the transition region, the path is changed to the recording track on the inner circumference side. The light beam travels to the outer recording track. Therefore, when illegal copying is performed, the reproduction path can be separated from the path at a certain distance, and overwriting of the pre-recording area can be effectively prevented.
[0020]
  Claim9The information recording medium described in claim7Or claim8In the information recording medium described above, predetermined dummy data is formed as an embossed pit row on the recording track that follows in the transition area.
[0021]
According to the present invention, when copying the content data to the information recording medium, the traveling direction of the light beam passes through the transition region, and then the embossed pit row on the subsequent recording track is traced to overwrite the dummy data. Therefore, the data overwritten on the embossed pit row cannot be read, and the overwrite on the pre-recording area can be effectively prevented, and the utility value of the illegally copied disc is reduced.
[0022]
  Claim10In the information recording medium manufacturing apparatus described in (2), a recording track having a first height on the information recording surface and a guide track having a second height different from the first height are formed adjacent to each other, An information recording medium manufacturing apparatus for manufacturing an information recording medium capable of repeatedly recording recording information on the recording track using a stamper, a track forming means for forming the recording track and the guide track, and predetermined control information The recording track and the adjacent guide track in the vicinity of a pre-recording area to be provided at a predetermined position on the information recording surface as an area in which pre-recording data including the same is recorded and overwriting of other recording information is prohibited A predetermined portion of the light beam tracking locus of the light beam by the push-pull method. A transition region forming means for forming a transition region which is arranged to transition to a different path and recording area,Recording track forming means for forming a recording track having the first height recordable by the light beam after passing through the transition region;It is characterized by providing.
In the information recording medium manufacturing apparatus according to claim 11, the recording track provided subsequent to the transition area formed by the recording track forming means is provided subsequent to the pre-recording area. Features.
[0023]
According to the present invention, when cutting a stamper used for manufacturing a reproducible information recording medium, the track forming means normally has a first height recording track and a second height guide track. Form. When forming the transition region, the transition region forming means forms the predetermined portion of the guide track adjacent to the recording track at the first height. Therefore, it is possible to manufacture a large number of information recording media that do not interfere with regular recording and are effective in preventing unauthorized copying by using such a stamper.
[0024]
  Claim12The information recording medium manufacturing apparatus described in claim10 or 11In the information recording medium manufacturing apparatus according to claim 1, the transition area forming means forms the guide track at the first height in a guide track section set in advance corresponding to the transition area, and the transition area The recording track is formed at the second height in a recording track section set in advance corresponding to.
[0025]
According to the present invention, the guide track section and the recording track section are determined in advance corresponding to the transition area, and when the stamper is cut, if these sections are entered, unlike the normal time, the first guide track section is set. The recording track is formed as a second height, respectively. Therefore, the cutting process can be performed on the stamper with simple control, and a large amount of information recording media effective for preventing unauthorized copying can be manufactured.
[0026]
  Claim13The information recording medium manufacturing apparatus described in claimAny one of claims 10 to 12The information recording medium manufacturing apparatus according to claim 1, further comprising pre-recording area forming means for forming the pre-recorded data as an embossed pit row in the pre-recording area.
[0027]
According to the present invention, when cutting the stamper, not only the track and transition area are formed, but also the pre-recording area forming means forms an emboss pit row corresponding to the pre-recording data in the pre-recording area. Therefore, by using such a stamper, it is possible to manufacture a large number of information recording media that are effective in preventing unauthorized copying and that can simplify the processing in the recording apparatus.
[0028]
  Claim14The information recording medium manufacturing apparatus described in claim10Claims from13In the information recording medium manufacturing apparatus according to any one of the above, an embossed pit string forming unit that forms predetermined dummy data as an embossed pit string on the subsequent recording track to which the pre-recorded area is not connected in the transition area, It is further provided with the feature.
[0029]
According to the present invention, when the stamper is cut, after forming the transition area, the emboss pit string forming means forms the emboss pit string corresponding to the dummy data for the subsequent recording track not connected to the pre-recording area. To do. Therefore, by using such a stamper, it is possible to reduce the utility value of the illegally copied disk as described above, and to manufacture a large number of information recording media that are more effective for preventing unauthorized copying.
[0030]
  Claim15The information recording apparatus according to claim 1 to claim 1.9An information recording apparatus for recording recording information on the information recording medium according to any one of the above, wherein when the recording information is written by irradiating a light beam along the recording track, When the head portion is reached, writing of the recording information is stopped, the light beam is moved toward the end portion of the pre-recording area, and then writing of the recording information is resumed.
[0031]
According to the present invention, when the normal recording operation is performed on the information recording medium manufactured as described above, when the light beam traced on the recording track reaches the head of the pre-recording area, for example, the laser power is reduced. Reduce the recording information so that it is not written. Thereafter, the tracing of the light beam is continued, and, for example, the track is moved to the end of the pre-recording area by a track jump or the like. Thereafter, the laser power is returned and writing of the recording information is resumed. Therefore, the recording information can be normally recorded on the other recording tracks without overwriting the pre-recording area.
[0032]
  Claim16The information recording device according to claim 115In the information recording apparatus according to claim 1,Any one of claims 10 to 12Prerecorded data writing means for writing the prerecorded data in the prerecorded area by laser recording with respect to the information recording medium manufactured by the information recording medium manufacturing apparatus described in 1. and a tracking error during writing of the prerecorded data. Tracking correction means that corrects and advances the light beam along the pre-recording area is further provided.
[0033]
According to the present invention, the prerecorded data writing means writes the prerecorded data in the prerecorded area by laser recording on the information recording medium on which the prerecorded data has not yet been recorded. Is corrected so that the light beam is traced along the pre-recording area. Therefore, even when tracking control by the standard push-pull method is performed on the recording apparatus, the pre-record data can be written reliably by tracing along the pre-record area.
[0034]
DETAILED DESCRIPTION OF THE INVENTION
DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the drawings. In the following embodiments, an information recording medium manufacturing apparatus that cuts a stamper disk for manufacturing a DVD-RW, and an information recording / reproducing apparatus that records and reproduces recording information on the DVD-RW, A case where the present invention is applied will be described.
[0035]
FIG. 1 is a diagram showing a configuration of an information recording surface of a DVD-RW as an information recording medium according to the present embodiment. As shown in FIG. 1, the information recording surface of the DVD-RW 10 is provided with a clamp hole 12 at the center for fixing when the DVD-RW 10 rotates, and a lead-in area in the peripheral part in order from the center. 13, a data area 14 and a lead-out area 15 are provided.
[0036]
The lead-in area 13 is an area that is first accessed during recording and playback of the DVD-RW 10, and records information related to the DVD-RW 10, various information related to recording data corresponding to the content, and the like. The data area 14 is an area for recording data corresponding to content to be recorded. For example, the content to be recorded includes image data, audio data, or computer-readable data or programs. The lead-out area 15 is an area that follows the data area 14, and information indicating that it is the lead-out area 15 is recorded.
[0037]
The DVD-RW 10 shown in FIG. 1 has a cross-sectional structure in which a phase change recording layer is laminated on a substrate with a protective layer interposed therebetween. A groove track as a recording track and a land track as a guide track are spirally formed from the inner periphery to the outer periphery of the disc. Usually, on the information recording surface, the groove track is formed at a first height, and the land track is formed at a second height different from the first height.
[0038]
As shown in FIG. 1, in the present embodiment, a pre-recording area 16 for preventing unauthorized copying is provided on a predetermined groove track in the lead-in area 13 of the DVD-RW 10. In this pre-recording area 16, pre-record data that is a bit string corresponding to predetermined control information is recorded. Only one or a plurality of pre-recording areas 16 can be provided in the lead-in area 13. The pre-recording data to be recorded in the pre-recording area 16 can be formed as an embossed pit row or can be recorded by laser recording. The specific method will be described later. The content of the pre-record data is not particularly limited, but for example, identification information indicating whether or not the disc is recordable may be included.
[0039]
Next, regarding the DVD-RW 10 according to the present invention, a specific disk structure near the pre-recording area 16 in which pre-recorded data is recorded will be described with reference to FIGS. Here, four specific examples will be described as the disk structure according to the present embodiment. 2 and 3 are first disk structure examples, FIGS. 4 and 5 are second disk structure examples, FIGS. 6 and 7 are third disk structure examples, and FIGS. 8 and 9 are fourth disk structure examples. It is a figure explaining an example, respectively.
[0040]
2 to 9, in the DVD-RW 10 in which tracks are sequentially formed in a spiral manner from the inner circumference side to the outer circumference side of the disk, the track N and the groove tracks corresponding to the tracks N-1 and N + 1 before and after the track N ( G) and an adjacent land track (L). In FIG. 2 to FIG. 9, it means that the shaded portion has the same first height as the groove track, and the other portion has the same second height as the land track. That is, in the normal area of the DVD-RW 10, the groove track and the land track are regularly formed while maintaining different heights, whereas in the case of FIGS. 2 to 9, the land track is the groove track. There is a portion formed at the height, and conversely a portion where the groove track is formed at the height of the land track. As described above, FIGS. 1 to 9 correspond to the transition area according to the present invention and have a structure in which the height of the groove track and the land track is changed in accordance with a predetermined pattern in the vicinity of the pre-recording area 16. Note that a pre-pit (not shown) is formed on the land track, and various control information such as address information is preformatted in advance.
[0041]
FIG. 2 is a diagram showing a first disc structure in the vicinity of the pre-recording area 16. As shown in FIG. 2, in the first disc structure, a pre-recording area 16 is provided in the track N and predetermined pre-recorded data is recorded. The land track on the inner peripheral side of the track N is at the height of the groove track from the position P1 to the position P2. Further, the groove track of the track N is at the height of the land track from the position P2 to the position P3. Such a structure can be formed when the stamper disk is subjected to a cutting process by a cutting device, which will be described in detail later.
[0042]
FIG. 3 is a diagram for explaining the recording / reproducing operation for the DVD-RW 10 having the first disk structure. In the present embodiment, writing to the pre-recording area 16 of the DVD-RW 10 is prohibited. Therefore, in the case of a normal recording operation, when it is determined that the area is within the pre-recording area 16, for example, the data is not written by changing the recording power of the laser to the reproducing power. However, in the case of an unauthorized recording operation, overwriting of unauthorized data should be attempted in the pre-recording area 16, and the first disk structure is effective as a countermeasure.
[0043]
FIG. 3A is a diagram illustrating a case where a normal recording operation is performed on the DVD-RW 10 corresponding to FIG. The recording light beam applied to the track N sequentially writes pit rows by phase change recording while tracing on the groove track from the left to the right in FIG. When the light beam reaches the head portion PS of the pre-recording area 16, the laser power is controlled to stop writing the pit row, and tracing is continued in this state.
[0044]
At this time, the light beam traces on a path as indicated by a dotted line in FIG. 3A, moves obliquely from the track N toward the track N-1 closer to the inner periphery, and reaches the position P2. The reason why such a path is taken is that tracking control by the push-pull method is performed during the recording operation. In other words, the push-pull method adopted as the standard tracking method for recording devices uses a detector that is divided symmetrically around the track center, and generates a tracking error signal based on the difference signal of the output obtained from each area. Is done. For this reason, when the light beam traces the groove track, the light intensity in each divided region does not match unless the land tracks on both sides are symmetrically arranged, so tracking control is performed in the direction in which the difference signal becomes zero. It is done.
[0045]
In FIG. 3A, since the groove track substantially extends in the inner circumferential direction in the track N ahead of the position P1, the light beam is in a state where the tracking center is shifted to the inner circumferential side. Are traced, resulting in an oblique trajectory. When the light beam reaches the position P2, the light beam transits to the track N-1, and after that, the land track returns to the original shape, so that the tracking control is again performed in the same manner as the normal groove track.
[0046]
In FIG. 3A, when the track N-1 is advanced in the right direction, the track N-1 comes out to the left side of the track N, and the same processing is continued repeatedly as it is, so that the track N-1 does not proceed further. Therefore, control is performed so as to perform a track jump from the track N-1 to the track N in the vicinity of the position P3. Then, since the transition is made again to the vicinity of the end portion PE of the pre-recording area 16, the process proceeds from the right side of the track N to the left side of the track N + 1, and after that, a normal track transition becomes possible.
[0047]
Then, after the end portion PE of the pre-recording area 16, writing of the stopped pit string is resumed. Thereafter, the light beam traces on the groove track in the right direction of the track N, and the pit row is written again.
[0048]
As shown in FIG. 3A, when a normal recording operation is performed on the DVD-RW 10 having the first disk structure and then a reproducing operation is performed on the DVD-RW 10, the pre-recorded data recorded in the pre-recording area 16 is recorded. Can be read normally. This is because tracking control by the phase difference method is performed during the reproduction operation. In other words, the phase difference method adopted as the standard tracking method for DVD playback devices uses a four-division detector, calculates the sum of the outputs in the diagonal area, and generates a tracking error signal based on the phase difference. The Therefore, when the light beam is traced and deviated from the pit row on the groove track, a phase difference occurs and the track becomes off-track, and Torres is always performed along the pit row. That is, the pit row on the groove track can be traced without being affected by the arrangement of the groove track and land track as in the push-pull method.
[0049]
Therefore, in FIG. 3A, the pit train recorded until the light beam traces the track N during the reproducing operation and reaches the head portion PS of the pre-recording area 16 is read out, and thereafter, the inner circumference The tracing on the pre-recording area 16 is continued without making a transition to the side. Then, the pre-record data recorded in the pre-record area 16 is read up to the end portion PE. After that, the recorded pit row is read again, the track N is shifted to the track N + 1, the same reading is performed, and the reading of the pit row is continued while repeating the track shift one after another.
[0050]
On the other hand, FIG. 3B is a diagram for explaining a case where an illegal recording operation is performed on the DVD-RW 10 corresponding to FIG. In FIG. 3B, as in FIG. 3A, the light beam traces the track N, and the pit rows are sequentially written. In FIG. 3B, even when the light beam reaches the leading portion PS of the pre-recording area 16, the case where illegal data is written without stopping the writing of the pit row is considered.
[0051]
Then, since tracking control by the push-pull method is performed during the recording operation as described above, the light beam transits to the track N-1 while writing data along the dotted path in FIG. become. Therefore, as shown in FIG. 3B, pit rows are formed along the oblique trajectory until the position P2 is reached. Next, the transition to the track N-1 is continued to form a pit row, and the track N-1 is traced to the right. At this stage, data already written in the track N-1 is destroyed by overwriting. Then, it reaches the left side of the track N again, and thereafter, the recording operation is repeated by following the same path without moving to the track N + 1.
[0052]
In addition, when the reproducing operation is performed on the DVD-RW 10 on which illegal data is recorded as shown in FIG. 3B, the data reading from the track N is not normally performed. That is, when the light beam is located in the vicinity of the head portion PS of the pre-recording area 16, the pits in the pre-recording area 16 and the pits corresponding to illegal data are close to each other, so that it becomes difficult to discriminate data due to mutual influences. At the same time, in tracking control by the phase difference method, it is uncertain which of both pit rows is to be traced. Therefore, in this case, proper reproduction operation is not guaranteed.
[0053]
Next, FIG. 4 is a diagram showing a second disk structure in the vicinity of the pre-recording area 16. As shown in FIG. 4, in the second disc structure, the arrangement of the pre-recording areas 16 is the same as in the first disc structure. The land track closer to the inner periphery of the track N is at the height of the groove track from the position P4 to the position P5. The range from the position P4 to the position P5 is set slightly shorter than the pre-recording area 16.
[0054]
FIG. 5 is a diagram for explaining the recording / reproducing operation for the DVD-RW 10 having the second disk structure. As described above, writing to the pre-recording area 16 of the DVD-RW 10 is prohibited. In the case of the second disk structure, a difference as described below occurs between a normal recording operation and an illegal recording operation.
[0055]
FIG. 5A is a diagram for explaining a case where a normal recording operation is performed on the DVD-RW 10 corresponding to FIG. In the track N, the light beam traces the groove track and the pit row is written until the light beam reaches the head portion PS of the pre-recording area 16. Then, the laser power is controlled to stop the writing of the pit row at the leading portion PS of the pre-recording area 16, and tracing is continued in this state.
[0056]
Then, after the position P4, the groove track has a shape that substantially extends to the land track on the inner peripheral side in the track N. Therefore, as shown in FIG. Based on the action of tracking control, tracing is performed by drawing an oblique trajectory from the track N toward the inner periphery of the disk. Then, after the light beam slowly proceeds in a curved line shape, the shape of the groove track returns to the original shape at the position P5, so that tracing is performed so as to return to the track N again in the vicinity thereof. Thereafter, when the light beam reaches the end portion PE of the pre-recording area 16, the writing of the stopped pit row is resumed. In the case of FIG. 5A, since the track N does not change to the track on the inner circumference side, it is not necessary to perform a track jump as shown in FIG.
[0057]
As shown in FIG. 5A, when a normal recording operation is performed on the DVD-RW 10 having the second disk structure and then a reproducing operation is performed on the DVD-RW 10, the tracking control operation by the phase difference method described above is performed. Based on this, the pre-recorded data recorded in the pre-recording area 16 can be read normally.
[0058]
On the other hand, FIG. 5B is a diagram illustrating a case where an illegal recording operation is performed on the DVD-RW 10 corresponding to FIG. In FIG. 5B, until the light beam reaches the head portion PS of the pre-recording area 16, it is the same as that in FIG. Then, the light beam proceeds while forming a pit row along the dotted line path of FIG. From the end PE of the pre-recording area 16, tracing similar to that shown in FIG.
[0059]
Further, when performing a reproducing operation on the DVD-RW 10 on which illegal data is recorded as shown in FIG. 5B, as described above, it is difficult to discriminate data partially and the trace direction is uncertain. Therefore, proper reproduction operation is not guaranteed.
[0060]
Next, FIG. 6 is a diagram showing a third disk structure in the vicinity of the pre-recording area 16. As shown in FIG. 6, in the third disc structure, the shape of the pre-recording area 16 is changed from the track N to the track N + 1 in a curved shape unlike the first and second disc structures. The land track closer to the inner periphery of the track N and the land track from the inner periphery of the track N + 1 are at the height of the groove track from the position P6 to the position P7, respectively. The groove track of track N has a land track height from position P6 to position P7, and an emboss pit row corresponding to predetermined dummy data is placed on the groove track ahead of position P7 in track N. D is formed in an uneven shape.
[0061]
In the third disc structure shown in FIG. 6, since the pre-recording area 16 has a special shape, an embossed pit row corresponding to the pre-recorded data is not formed at the time of the cutting process by the cutting device, and later by laser recording Write pre-record data. On the other hand, the predetermined dummy data is formed as an embossed pit row D by a cutting device. Details of these processes will be described later.
[0062]
FIG. 7 is a diagram for explaining the recording / reproducing operation for the DVD-RW 10 having the third disk structure. As described above, writing to the pre-recording area 16 of the DVD-RW 10 is prohibited. In the case of the third disk structure, a difference as described below occurs between a normal recording operation and an illegal recording operation.
[0063]
FIG. 7A is a diagram illustrating a case where a normal recording operation is performed on the DVD-RW 10 corresponding to FIG. In the track N, the light beam traces the groove track and the pit row is written until the light beam reaches the head portion PS of the pre-recording area 16. Then, the laser power is controlled to stop the writing of the pit row at the leading portion PS of the pre-recording area 16, and tracing is continued in this state.
[0064]
At this time, the light beam travels straight on the groove track from the position P6 to the position P7 of the track N. This is because, in this range, the groove track substantially spreads symmetrically in both directions of the track N + 1 and the track N-1, so that the track deviation due to the tracking control by the push-pull method does not occur. Then, when the light beam reaches the vicinity of the position P7, control is performed to perform a track jump from the track N to the track N + 1. Then, the transition to the track N + 1 is made in the vicinity of the end portion PE of the pre-recording area 16, and the uneven embossed pit row D of the dummy data can be avoided. Then, the writing of the stopped pit string is resumed from the end PE of the pre-recording area 16. In the case of FIG. 7A, recording is not performed for a range of one track from the position where the embossed pit row D of the dummy data exists.
[0065]
As shown in FIG. 7A, when a normal recording operation is performed on the DVD-RW 10 having the third disk structure and then a reproducing operation is performed on the DVD-RW 10, the tracking control operation by the phase difference method described above is performed. Based on this, the pre-recorded data recorded in the pre-recording area 16 can be read normally. That is, according to the principle of the phase difference method described above, even if the pre-recording area 16 is curved, it can be accurately traced.
[0066]
On the other hand, FIG. 7B is a diagram illustrating a case where an illegal recording operation is performed on the DVD-RW 10 corresponding to FIG. In FIG. 7B, until the light beam reaches the head part PS of the pre-recording area 16, it is the same as in FIG. 7A, but the writing of illegal data is continued after that. Then, the vehicle goes straight along a pit row along the dotted path in FIG. Then, the embossed pit row D of the dummy data is reached after the position P7 and tracing is performed while overwriting the data, so that proper recording cannot be performed and the data is destroyed.
[0067]
Further, when performing a reproducing operation on the DVD-RW 10 on which illegal data is recorded as shown in FIG. 7B, it is difficult to discriminate data partially and the trace direction is uncertain as described above. Therefore, proper reproduction operation is not guaranteed.
[0068]
Next, FIG. 8 is a diagram showing a fourth disk structure in the vicinity of the pre-recording area 16. The fourth disk structure shown in FIG. 8 is a modification of the third disk structure. The fourth disk structure is different from the third disk structure in that the land track near the inner periphery of the track N becomes the height of the groove track from the position P8, while the land track near the inner periphery of the track N + 1. Is the height of the groove track from the position P9 slightly ahead of the position P8. Both tracks return to their original height at position P10. Further, the fourth disk structure is different in that the uneven embossed pit row D of dummy data is not formed after the position P10, but the uneven shape of dummy data is the same as in the third disk structure. The embossed pit row D may be formed.
[0069]
FIG. 9 is a diagram for explaining the recording / reproducing operation for the DVD-RW 10 having the fourth disk structure. As described above, writing to the pre-recording area 16 of the DVD-RW 10 is prohibited. In the case of the fourth disk structure, a difference as described below occurs between a normal recording operation and an illegal recording operation.
[0070]
FIG. 9A is a diagram illustrating a case where a normal recording operation is performed on the DVD-RW 10 corresponding to FIG. In the track N, the light beam traces the groove track and the pit row is written until the light beam reaches the head portion PS of the pre-recording area 16. Then, the laser power is controlled to stop the writing of the pit row at the leading portion PS of the pre-recording area 16, and tracing is continued in this state.
[0071]
At this time, in the range from the position P8 to the position P9 of the track N, the light beam travels obliquely on the groove track to the track N-1. This is because, in this range, the groove track has a shape that substantially expands to the inner peripheral side, so that the trajectory shifts based on the action of the tracking control by the push-pull method described above. Then, when the light beam reaches the vicinity of the position P10, control is performed so as to perform a track jump for two tracks from the track N-1 to the track N + 1. Then, a transition is made to the track N + 1 at the end portion PE of the pre-recording area 16. Then, after the transition to the track N + 1, the writing of the stopped pit string is resumed from the end PE of the pre-recording area 16.
[0072]
As shown in FIG. 9A, when a normal recording operation is performed on the DVD-RW 10 having the fourth disk structure and then a reproduction operation is performed on the DVD-RW 10, as in the case of the third disk structure, The pre-record data recorded in the pre-record area 16 can be read normally.
[0073]
On the other hand, FIG. 9B is a diagram illustrating a case where an illegal recording operation is performed on the DVD-RW 10 corresponding to FIG. In FIG. 9B, until the light beam reaches the head portion PS of the pre-recording area 16, it is the same as in FIG. 9A, but the writing of illegal data is continued after that. Then, it progresses diagonally toward the track N-1 while forming a pit row along the dotted path in FIG. Then, the track N-1 is traced in the right direction, reaches the left side of the track N again, and thereafter, the recording operation is repeated along the same path without moving to the track N + 1.
[0074]
In addition, when performing a reproducing operation on the DVD-RW 10 on which illegal data is recorded as shown in FIG. 9B, it is difficult to discriminate data partially and the trace direction is uncertain as described above. Therefore, proper reproduction operation is not guaranteed.
[0075]
Next, a cutting apparatus as an information recording medium manufacturing apparatus for manufacturing a DVD-RW according to the present embodiment will be described with reference to FIGS. This cutting apparatus is an apparatus for producing a stamper disk for mass production of the DVD-RW 10 having the above-described disk structure.
[0076]
FIG. 10 is a block diagram illustrating a schematic configuration of the cutting apparatus according to the present embodiment. 10 includes a land data generator 20, a parallel / serial converter 21, a preformat encoder 22, a clock signal generator 23, a laser generator 24, an optical modulator 25, an objective, and the like. Lens 26, spindle motor 29, rotation detector 30, rotation servo circuit 31, feed unit 32, position detector 33, feed servo circuit 34, CPU 40, first switch 41, and groove data generation It comprises a device 50, an emboss data generator 51, and a second switch 52.
[0077]
The stamper disk is constituted by a glass substrate 27 and a resist 28 coated on the glass substrate 27. The resist 28 is sensitized by irradiation with a light beam B described later, and a pattern corresponding to a change in the intensity of the light beam B is formed.
[0078]
In FIG. 10, a land data generator 20 outputs parallel data corresponding to a land track and a land pre-pit formed in advance for recording various control signals under the control of the CPU 40. The output parallel data is output to the parallel / serial converter 21.
[0079]
At this time, the first switch 41 is controlled by the CPU 40 to switch the path sent to the parallel / serial converter 21 to either the land data generator 20 side or the predetermined DC voltage side. it can. That is, when the land track portion is set to the groove track height corresponding to the disk structure, the first switch 41 is controlled to be switched to the predetermined DC voltage side.
[0080]
The parallel / serial converter 21 converts the input parallel data into serial data. The serial data is input to the preformat encoder 22 and a land data signal SL as a pattern signal corresponding to the land track or prepit is generated based on the preformatting clock signal supplied from the clock signal generator 23. Is done. The land data signal SL is output to the optical modulator 25.
[0081]
The groove data generator 50 generates a pattern signal corresponding to the groove track and outputs the pattern signal to the second switch 52. Further, the emboss data generator 51 generates a pattern signal for forming an emboss data string corresponding to pre-record data or dummy data under the control of the CPU 40 and outputs the pattern signal to the second switch 52. Both the groove data generator 50 and the emboss data generator 51 are controlled by the CPU 40.
[0082]
The second switch 52 switches the path from the groove data generator 50 and the emboss data generator 51 to either one under the control of the CPU 40 and outputs the path to the optical modulator 25 as the groove data signal SG. That is, when prerecorded data or dummy data is formed as an embossed pit row for the groove track, the second switch 52 is controlled to be switched to the embossed data generator 51 side. Otherwise, the groove data generator 50 Kept on the side.
[0083]
The laser generator 24 emits a light beam B for forming a land track and a groove track with respect to the stamper disk. Actually, the laser generator 24 includes a land track laser 24L and a groove track laser 24G, and irradiates the light beam B simultaneously to the groove track and one land track adjacent to the inner peripheral side. The land track laser 24L is modulated by the land data signal SL by the optical modulator 25, and the groove track laser 24G is modulated by the groove data signal SG, and is respectively formed on the stamper disk via the objective lens 26. Focused.
[0084]
At this time, the spindle motor 29 rotates the stamper disk, and the rotation detector 30 detects the rotation of the stamper disk. Thus, the rotation servo circuit 31 controls the rotation of the stamper disk and outputs a rotation pulse synchronized with the rotation.
[0085]
The position detector 33 detects the position of the feed unit 32 and outputs the detection signal to the feed servo circuit 34. The feed servo circuit 34 acquires the position information of the feed unit 32 based on the detection signal from the position detector 33, and thereby servo-controls the movement of the feed unit 32.
[0086]
By performing the operation as described above, the spiral land track and groove track having the above-described disk structure are formed on the stamper disk, and the stamper disk as a die for manufacturing the optical disk is completed. . Thereafter, a replication process using a stamper disk is executed, and the DVD-RW 10 as a replica disk according to the present invention is mass-produced.
[0087]
Next, stamper disk cutting processing performed in the cutting apparatus according to the present embodiment will be described with reference to the flowcharts shown in FIGS. Here, a stamper disk cutting process corresponding to the second disk structure and the third disk structure will be described. This process is mainly performed by the CPU 40 in accordance with a control program stored in a memory means (not shown).
[0088]
As shown in FIG. 11, when the processing in the cutting apparatus is started, initialization is performed for each setting data such as the land data generator 20 and the groove data generator 50 (step S1). Next, based on the detection signal output from the position detector 33, the irradiation position of the light beam in the disc radial direction is detected (step S2).
[0089]
At this time, based on the irradiation position detected in step S2, it is determined whether or not the recording end position on the stamper disk has been reached (step S3). That is, it is determined whether the irradiated light beam is located at the outermost peripheral portion of the lead-out area 15 of the stamper disk.
[0090]
As a result, if it is determined that the recording end position has been reached (step S3; YES), the rotation pulse output from the rotation servo circuit 31 is detected (step S4). That is, it is determined whether or not one round of pre-pits corresponding to the recording end position of information has been formed at the determined recording end position.
[0091]
The process in step S4 is continued until the rotation pulse is detected (step S4; NO). When the rotation pulse is detected (step S4; YES), the CPU 40 sends the land data generator 20 and the groove data generator 50. In response to this, a control signal for instructing the end of writing is sent (step S5). Thereby, the cutting process for the stamper disk is completed.
[0092]
On the other hand, if the result of determination in step S3 is that the recording end position has not been reached (step S3; NO), it is determined whether or not the recording start position on the stamper disk has been reached (step S6). That is, it is determined whether or not the irradiated light beam is located at the innermost periphery of the lead-in area 13 of the stamper disk.
[0093]
As a result, if it is determined that the recording start position has been reached (step S6; YES), the rotation pulse output from the rotation servo circuit 31 is detected (step S7). That is, it is determined whether or not the determined recording start position has reached the circumferential recording reference position set at one place per rotation of the stamper disk.
[0094]
The process in step S7 is continued until a rotation pulse is detected (step S7; NO). When a rotation pulse is detected (step S7; YES), the CPU 40 sends a land data generator 20 and a groove data generator 50. In response to this, a control signal for instructing the start of writing is sent (step S8). Thereby, the preparation for the cutting process for the stamper disk is completed, the process returns to step S2, and the subsequent processes are repeated.
[0095]
On the other hand, if the result of determination in step S6 is that the recording start position has not been reached (step S6; NO), the cutting process corresponding to the disk structure described above is performed on the stamper disk. Here, the stamper disk cutting process corresponding to the second disk structure will be described with reference to FIG. 12, and the stamper disk cutting process corresponding to the third disk structure will be described with reference to FIGS. 13 and 14. .
[0096]
First, when cutting a stamper disk corresponding to the second disk structure, when the determination result of step S6 is “NO”, the process proceeds to step S11 (FIG. 12). As shown in FIG. 12, in step S11, based on the irradiation position detected in step S2, it is determined whether or not it is positioned on the track N on the stamper disk. That is, this is for forming the second disk structure shown in FIG.
[0097]
As a result, when it is not located on the track N (step S11; NO), the process returns to step S2 and the same processing is repeated. On the other hand, when it is located on the track N (step S11; YES), a rotation pulse is detected (step S12). As a result, a timing reference for determining the position where the second disk structure is formed in the track N is used. The process of step S12 is continued until a rotation pulse is detected (step S12; NO).
[0098]
When a rotation pulse is detected in step S12 (step S12; YES), time measurement is started using the time measuring means controlled by the CPU 40 (step S13). That is, the time measurement for determining the timing to reach the pre-recording area 16, positions P4, P5, etc. in the second disk structure according to the present embodiment is started with the detection position of the rotation pulse as a reference. Here, a case will be described in which the timing start timing coincides with the leading portion PS of the pre-recording area 16.
[0099]
Next, the second switch 52 that has been set on the groove data generator 50 side until this stage is switched to the emboss data generator 51 side (step S14). It is assumed that pre-recorded data is set in the emboss data generator 51 corresponding to the second disk structure. As a result, in the groove track of track N, embossed pit rows corresponding to prerecorded data to be recorded in the prerecorded area 16 begin to be formed.
[0100]
Further, the first switch 41 set on the land data generator 20 side until this stage is switched to the predetermined DC voltage side (step S15). Accordingly, the height from the position P4 on the land track near the inner periphery of the track N is controlled to be the same as that of the groove track. In addition, you may delay only appropriate timing between step S14 and step S15.
[0101]
Then, as a result of the time measurement, it is determined whether or not a predetermined time set in advance has elapsed (step S16). This predetermined time can be grasped in advance from the distance from the position P4 to the position P5. If the predetermined time has not yet elapsed as a result of the determination in step S16 (step S16; NO), the process continues to wait until it elapses.
[0102]
On the other hand, if the predetermined time has passed as a result of the determination in step S16 (step S16; YES), the first switch 41 is set to return to the land data generator 20 side (step S17). That is, since the position P6 of the land track has been reached, the original land track height is restored.
[0103]
Next, it is determined whether or not the pre-record data output from the emboss data generator 51 has been completed (step S18). As a result of the determination, if the pre-record data is not yet finished (step S18; NO), the output of the pre-record data is continued. On the other hand, when the pre-record data has been completed (step S18; YES), the second switch 52 is set to return to the groove data generator 50 side (step S19), and the process ends. In addition, you may delay only appropriate timing, before performing step S19.
[0104]
As a result of the above processing, the stamper disk is cut corresponding to the second disk structure shown in FIG.
[0105]
Next, when cutting a stamper disk corresponding to the third disk structure, when the determination result of step S6 is “NO”, the process proceeds to step S21 (FIG. 13). As shown in FIG. 13, in step S21, based on the irradiation position detected in step S2, it is determined whether or not the track N is positioned on the stamper disk. That is, this is for forming the third disk structure shown in FIG.
[0106]
As a result of the determination in step S21, when the position is not located on the track N (step S21; NO), the process proceeds to step S31. On the other hand, if it is located on track N (step S21; YES), rotation pulses are detected (step S22) in order to use the timing as described above. The process of step S22 is continued until a rotation pulse is detected (step S22; NO).
[0107]
When a rotation pulse is detected in step S22 (step S22; YES), time measurement is started using the above-described time measuring means (step S23). That is, the time measurement for determining the timing to reach the pre-recording area 16, the position P6, the position P7, etc. in the third disk structure according to the present embodiment is started on the basis of the detection position of the rotation pulse.
[0108]
In the processing shown in FIGS. 13 and 14, it is assumed that time T1 is required until the position P6 is reached from the detection position of the rotation pulse, and time T2 is required until the position P7 is reached.
[0109]
Therefore, it is determined whether or not the time T1 corresponding to the position P6 has passed (step S24). As a result of the determination, if the time T1 has not yet elapsed (step S24; NO), the process continues to wait until it elapses.
[0110]
On the other hand, when the time T1 has elapsed as a result of the determination in step S24 (step S24; YES), the first switch 41 set on the land data generator 20 side up to this stage is moved to the predetermined DC voltage side. Switching is set (step S25). Thereby, the height from the position P6 on the land track closer to the inner periphery of the track N is controlled to be the same as that of the groove track.
[0111]
Then, it is determined whether or not a time T2 corresponding to the position P7 has passed (step S26). As a result of the determination, when the time T2 has not yet elapsed (step S26; NO), the process continues to wait until it elapses.
[0112]
On the other hand, if the time T2 has elapsed as a result of the determination in step S26 (step S26; YES), the first switch 41 is set to return to the land data generator 20 side (step S27), and from the land track position P7. Control so that the tip becomes the original height.
[0113]
Further, the second switch 52 set on the groove data generator 50 side until this stage is switched to the emboss data generator 51 side (step S28). It is assumed that dummy data corresponding to the uneven shape to be formed first from the position P7 is set in the emboss data generator 51 in correspondence with the third disk structure. Therefore, the embossed pit row D corresponding to the dummy data starts to be formed in the groove track of the track N. Thereafter, the data length of the dummy data is set appropriately, and the process of step S28 may be continued for a predetermined time.
[0114]
Next, as shown in FIG. 14, when the process proceeds from step S21 to step S31, it is determined whether or not it is located on the track N + 1 on the stamper disk. That is, in order to form the third disk structure shown in FIG. 6, processing for two tracks is required.
[0115]
As a result of the determination in step S31, when the position is not located on the track N + 1 (step S31; NO), the process returns to step S2. On the other hand, when it is located on the track N (step S31; YES), the rotation pulse is detected (step S32) and used as a timing reference, and this process is continued until the rotation pulse is detected (step S32). NO).
[0116]
Thereafter, the processing shown in steps S33 to S37 is performed in the same manner as the processing shown in steps S23 to S27, and thus the description thereof is omitted.
[0117]
On the other hand, in the process shown in FIG. 14, unlike FIG. 13, the process corresponding to step S28 is not performed, and the process ends in step S37. That is, as shown in FIG. 6, in the third disk structure, the groove track of track N + 1 is formed as usual.
[0118]
As a result of the above processing, the stamper disk is cut corresponding to the third disk structure shown in FIG. Therefore, the DVD-RW 10 manufactured using this stamper disk has a similar structure. At this time, since pre-recording data has not yet been formed in the pre-recording area 16 on the stamper disk, it is necessary to write the pre-recording data to the DVD-RW 10 later by laser recording in the recording device.
[0119]
Next, an information recording / reproducing apparatus that performs recording and reproduction on the DVD-RW 10 according to the present embodiment will be described with reference to FIGS.
[0120]
FIG. 15 is a block diagram showing a schematic configuration of the information recording / reproducing apparatus according to the present embodiment. The information recording / reproducing apparatus shown in FIG. 15 includes a pickup 60, a reproduction amplifier 61, a decoder 62, a prepit signal decoder 63, a spindle motor 64, a servo circuit 65, a CPU 66, an encoder 67, and a power control circuit 68. A laser drive circuit 69, an interface 70, a pre-record data generator 73, and a switch 74. Further, an external host computer 71 is connected via an interface 70, and digital data to be recorded is input to the information recording / reproducing apparatus.
[0121]
In FIG. 15, a pickup 60 includes a laser diode (not shown), a polarizing beam splitter, an objective lens, a detector, etc., and records data to be recorded by irradiating the information recording surface of the DVD-RW 10 with a light beam B. A detection signal based on the reflected light of the beam B is output.
[0122]
The reproduction amplifier 61 amplifies the detection signal output from the pickup 60, outputs a differential signal used for generating a tracking error signal, and further outputs a prepit signal corresponding to the prepit.
[0123]
The decoder 62 performs 8-16 demodulation and deinterleaving on the amplified detection signal, and outputs a demodulated signal. The prepit signal decoder 13 decodes the prepit signal and outputs digital data corresponding to the prepit pattern.
[0124]
The servo circuit 65 performs focusing control and tracking control in the pickup 60 based on the demodulated signal from the decoder 62. In the present embodiment, the servo circuit 65 performs tracking control by outputting a tracking error signal by a push-pull method according to the operation described later, and outputs a control signal for the spindle motor 64 to perform rotation control.
[0125]
The CPU 66 generally controls the entire information recording / reproducing apparatus, obtains output signals from the decoder 62 and the pre-pit signal decoder 63, and controls writing and reproducing operations on the DVD-RW 10.
[0126]
The encoder 67 includes an ECC generator, an 8-16 modulator, a scrambler, etc. (not shown), constitutes an ECC block that is an error correction unit at the time of reproduction, and performs interleaving, 8-16 modulation, and scramble processing on the ECC block. To generate a modulated signal.
[0127]
The power control circuit 68 performs power control of the laser diode in the pickup 60 based on the modulation signal output from the encoder 67.
[0128]
The laser drive circuit 69 drives the laser diode of the pickup 60 under the control of the power control circuit 68 in order to emit the light beam B.
[0129]
The interface 70 performs an interface operation for taking digital data transmitted from the host computer 71 into the information recording / reproducing apparatus.
[0130]
The pre-record data generator 73 generates digital data corresponding to the pre-record data to be written in the pre-record area 16 of the DVD-RW 10 according to this embodiment, and outputs it to the encoder 67 via the switch 74.
[0131]
The switch 74 switches the path of the signal output to the encoder 67 under the control of the CPU 66 so that it is on the host computer 71 side during normal recording and on the pre-record data generator 73 side during pre-recording.
[0132]
Next, with reference to FIG. 16 and FIG. 17, the recording operation performed by the information recording / reproducing apparatus when prerecorded data is written to the DVD-RW 10 by laser recording corresponding to the first or second disk structure. explain.
[0133]
FIG. 16 is a block diagram showing a configuration of a circuit portion necessary for tracking control in the pre-recording area 16 corresponding to the first or second disk structure.
[0134]
In FIG. 16, tracking control is performed under the control of the CPU 66 by the circuit portion including the two-divided detector 80 in the pickup 60, the tracking amplifier 81 included in the reproduction amplifier 69, and the servo circuit 65. The servo circuit 65 includes a tracking equalizer 82 and a sample hold circuit 83.
[0135]
As already described, since tracking control by the push-pull method is performed during the recording operation, as shown in FIG. 16, tracking is performed on the difference signal with respect to the output of each area of the two-divided detector 80 divided symmetrically about the track center. It is generated by the amplifier 81 for use. This difference signal is input to the servo circuit 65, and the phase is adjusted by weighting the band component by the tracking equalizer 82.
[0136]
The output of the tracking equalizer 82 is input to the sample hold circuit 83, sampled and held at a predetermined timing, and output as a tracking error signal. At this time, a hold signal is applied from the CPU 66 to the sample hold circuit 83.
[0137]
That is, in the range from the position P1 to the position P3 of the track N in the first disk structure shown in FIG. 2 or in the range from the position P4 to the position P5 of the track N in the second disk structure shown in FIG. Due to the action of the push-pull method, the light beam cannot be traced in the straight direction along the groove track. Therefore, when this range is reached, a hold signal is applied to the sample hold circuit 83 to stop the transition of the light beam caused by the push-pull method, and the light beam is forcibly moved straight along the groove track. It is something to be made.
[0138]
FIG. 17 is a flowchart showing recording processing by laser recording of pre-recorded data in the pre-recording area 16 corresponding to the first or second disk structure. Here, in the information recording / reproducing apparatus, the pre-recorded data is written to the pre-recording area 16 with the DVD-RW 10 on which the groove track and land track corresponding to the first or second disk structure are set. An explanation will be given for the case of performing. Accordingly, consider the situation after the start of writing of data to be recorded prior to the pre-record data.
[0139]
As shown in FIG. 17, when the process is started, it is determined whether or not a predetermined address to be used as a reference on the DVD-RW 10 has been reached based on the irradiation position of the light beam (step S41). This predetermined address is recorded in advance in, for example, a pre-pit in the DVD-RW 10. Therefore, by reading the recorded address, it is possible to determine a position where pre-record data to be described later should be written.
[0140]
As a result, if the predetermined address has not been reached (step S41; NO), the process returns to step S41 and the same processing is repeated. On the other hand, when the predetermined address has been reached (step S41; YES), the timing is started using the timing means controlled by the CPU 66 (step S42). That is, it is a time measurement process for determining the arrival timing at an address at a predetermined set position, for example, using the predetermined address as a reference position.
[0141]
Then, as a result of timing, it is determined whether or not a predetermined time set in advance has elapsed (step S43). This predetermined time can be grasped in advance from the relative relationship between the reference address and the set position. If the predetermined time has not yet elapsed as a result of the determination in step S43 (step S43; NO), the process continues to wait until it elapses.
[0142]
On the other hand, if the result of determination in step S43 is that a predetermined time has elapsed (step S43; YES), a hold signal is applied to the sample hold circuit 83 (step S44). Accordingly, the tracking error signal is fixed from this point, and the writing of the light beam does not fluctuate regardless of the track shape of the second disk structure when writing to the pre-recording area 16 thereafter.
[0143]
Further, the switch 74 is controlled so as to output pre-record data (step S45). That is, the connection is switched from the digital data output from the host computer 71 to the pre-record data output from the pre-record data generator 73. The switching timing may be matched with the head part PS in the pre-recording area 16.
[0144]
Next, it is determined whether or not the recording of the pre-record data has been completed (step S46). This end timing coincides with the end portion PE in the pre-recording area 16. As a result, if the recording of the pre-record data has not been completed (step S46; NO), it continues to wait for the completion.
[0145]
On the other hand, when the pre-record data has been completed (step S46; YES), the hold signal applied to the sample hold circuit 83 is canceled (step S47). Since the track shape has returned to normal at this time, the light beam is normally tracked and traced thereafter. Thereafter, a general recording operation may be continued, but the description is omitted.
[0146]
Next, with reference to FIG. 18 and FIG. 19, the recording operation performed by the information recording / reproducing apparatus when writing pre-recorded data on the DVD-RW 10 by laser recording corresponding to the third or fourth disk structure will be described. explain.
[0147]
FIG. 18 is a block diagram showing a configuration of a circuit portion necessary for tracking control in the pre-recording area 16 corresponding to the third or fourth disk structure.
[0148]
In FIG. 18, the two-divided detector 80, the tracking amplifier 81, and the servo circuit 65 are configured similarly to the case of FIG. However, the servo circuit 65 is different from the case of FIG. 16 in that it includes a tracking equalizer 82, an offset data generator 84, and an adder 85.
[0149]
In the above configuration, the operations of the two-divided detector 80, the tracking amplifier 81, and the tracking equalizer 82 are the same as those in FIG.
[0150]
In FIG. 18, the output of the tracking equalizer 82 is input to the adder 85, added with the offset data output from the offset data generator 84, and the added output is output as a tracking error signal. At this time, the CPU 66 supplies a control signal to the offset data generation unit 84 to control the generation timing of the offset data. The offset data generation unit 84 may hold the offset data in the memory means or calculate the offset data by calculation.
[0151]
Corresponding to the third and fourth disk structures, offset data based on the offset amount of the disk radial position in the pre-recording area 16 may be set. As shown in FIGS. 6 and 8, this offset amount is an amount that changes in a curved line corresponding to the shape of the pre-recording area 16 that transitions from the track N to the track N + 1. As a result, the offset data is added to the tracking error signal as described above, so that the light beam is traced along the curved trajectory of the pre-recording area 16. In the fourth disk structure, since the track shape is asymmetric in the range from position P8 to position P9 in FIG. 8, it is necessary to add an appropriate compensation amount to the offset data.
[0152]
FIG. 19 is a flowchart showing recording processing by laser recording of pre-recorded data in the pre-recording area 16 corresponding to the third or fourth disk structure. Here, in the information recording / reproducing apparatus, the pre-recording is performed with the DVD-RW 10 in which the groove track, the land track, the embossed pit row D of dummy data, etc. corresponding to the third or fourth disc structure are set. A description will be given of the case where pre-record data is written to the area 16. Accordingly, consider the situation after the start of writing of data to be recorded prior to the pre-record data.
[0153]
Here, in the process shown in FIG. 19, the processes shown in steps S51 to S53, S55, and S56 are the same as the processes shown in steps S41 to S43, S45, and S46 of the process shown in FIG. . In FIG. 19, the processes shown in step S54 and step S57 are different from those in FIG.
[0154]
In step S54, the timing data is controlled so that the offset data generation unit 84 starts generating offset data at the timing when it reaches the leading portion PS of the pre-recording area 16. Therefore, after this, the pre-record data is written in steps S55 and S56 while the light beam transitions in a curved shape in the disc radial direction.
[0155]
In step S57, since the writing of the pre-record data to the pre-record area 16 has been completed as described above, the offset data generator 84 is controlled to cancel the generation of the offset data. Since the track shape has returned to normal at this time, the light beam is normally tracked and traced after that, and the general recording operation thereafter may be continued.
[0156]
As described above, according to the information recording medium of the present embodiment, the pre-recording area 16 is overwritten using the disk structure in which the height of each of the groove track and the land track is appropriately changed according to a predetermined pattern. And pre-recorded data can be protected. On the other hand, when reproducing this information recording medium, the pre-recording data can be easily read by tracing the pre-recording area 16 by performing tracking control by the phase difference method.
[0157]
Further, according to the information recording medium manufacturing apparatus according to the present embodiment, the above disk structure can be realized by a simple process by performing a cutting process on the stamper disk for manufacturing the above information recording medium. it can. In addition, pre-recording data to be recorded in the pre-recording area 16 can be formed as an embossed pit row during the cutting process.
[0158]
Further, according to the information recording / reproducing apparatus of the present embodiment, the DVD-RW 10 in which pre-recorded data has already been recorded in the pre-recording area 16 is avoided from being overwritten on the pre-recording area 16 and pushed. Regardless of the action of tracking control by the pull method, the recording operation can be performed while changing to an appropriate path.
[0159]
Further, according to the information recording / reproducing apparatus of the present embodiment, the prerecorded data can be written later by laser recording on the DVD-RW 10 in which the prerecorded data is not recorded in the initial prerecorded area 16. At this time, while performing tracking control by the push-pull method, the tracking error can be appropriately corrected and the trajectory of the pre-recording area 16 can be accurately traced.
[0160]
In the above-described embodiment, the case where the present invention is applied to a DVD-RW that can repeatedly record recording information has been described. However, in addition to this, a DVD-R that can record recording information only once. It is possible to apply the present invention to the above.
[0161]
【The invention's effect】
As described above, according to the present invention, by devising the disc structure of recordable information recording media, when recording content prohibited from being copied to these information recording media, identification information, etc. Overwriting pre-recorded data including is reliably prevented. Therefore, the reproduction device side can grasp that the copy is illegal, and has an advantage of effectively preventing illegal copy and reducing the possibility of copyright infringement.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of an information recording surface of a DVD-RW according to the present embodiment.
FIG. 2 shows a first disk structure according to the present embodiment.
FIG. 3 is a diagram for explaining a recording / reproducing operation with respect to a DVD-RW having the first disk structure according to the embodiment.
FIG. 4 shows a second disk structure according to the present embodiment.
FIG. 5 is a diagram for explaining a recording / reproducing operation with respect to a DVD-RW having a second disk structure according to the embodiment.
FIG. 6 shows a third disk structure according to the present embodiment.
FIG. 7 is a diagram illustrating a recording / reproducing operation for a DVD-RW having a third disk structure according to the present embodiment.
FIG. 8 shows a fourth disk structure according to the present embodiment.
FIG. 9 is a diagram illustrating a recording / reproducing operation for a DVD-RW having a fourth disk structure according to the present embodiment.
FIG. 10 is a block diagram showing a schematic configuration of a cutting apparatus according to the present embodiment.
FIG. 11 is a flowchart for explaining stamper disk cutting processing in the present embodiment;
FIG. 12 is a flowchart illustrating a process corresponding to the second disk structure in the stamper disk cutting process in the present embodiment.
FIG. 13 is a flowchart illustrating a process corresponding to a track N having a third disk structure in the stamper disk cutting process in the present embodiment.
FIG. 14 is a flowchart illustrating a process corresponding to the track N + 1 of the third disk structure in the stamper disk cutting process in the present embodiment.
FIG. 15 is a block diagram showing a schematic configuration of an information recording / reproducing apparatus according to the embodiment.
FIG. 16 is a block diagram showing a configuration of a circuit portion necessary for tracking control in a pre-recording area, corresponding to the first or second disk structure, in the information recording / reproducing apparatus according to the present embodiment.
FIG. 17 is a flowchart showing processing by laser recording of pre-record data corresponding to the first or second disk structure in the information recording / reproducing apparatus according to the present embodiment.
FIG. 18 is a block diagram showing a configuration of a circuit portion necessary for tracking control in a pre-recording area corresponding to the third or fourth disk structure in the information recording / reproducing apparatus according to the present embodiment.
FIG. 19 is a flowchart showing processing by laser recording of prerecorded data corresponding to the third or fourth disk structure in the information recording / reproducing apparatus in the embodiment.
[Explanation of symbols]
10 ... DVD-RW
12 ... Clamp hole
13 ... Lead-in area
14: Data area
15 ... Lead out area
16: Pre-recording area
20 ... Land data generator
21 ... Parallel / serial generator
22 ... Preformat encoder
23: Clock signal generator
24 ... Laser generator
25. Optical modulator
26 ... Objective lens
27 ... Glass substrate
28 ... resist
29 ... Spindle motor
30 ... Rotation detector
31 ... Rotary servo circuit
32 ... Feeding unit
33 ... Position detector
34 ... Feed servo circuit
40 ... CPU
41 ... 1st switch
50 ... Groove data generator
51 ... Emboss data generator
52 ... Second switch
61 ... Regenerative amplifier
62. Decoder
63 ... Pre-pit signal decoder
64 ... Spindle motor
65. Servo circuit
66 ... CPU
67 ... Encoder
68 ... Power control circuit
69 ... Laser drive circuit
70 ... Interface
71: Host computer
73 ... Pre-record data generator
74 ... Switch
80 ... 2 split detector
81. Tracking amplifier
82 ... Equalizer for tracking
83. Sample hold circuit
84: Offset data generator
85 ... Adder

Claims (16)

A recording track having a first height on the information recording surface and a guide track having a second height different from the first height are formed adjacent to each other, and recording information can be repeatedly recorded on the recording track. Information recording medium,
A pre-recording area provided at a predetermined position on the information recording surface as an area where pre-recording data including predetermined control information is recorded and overwriting of other recording information is prohibited;
In the vicinity of the pre-recording area, a predetermined part of the recording track and the adjacent guide track is continuously formed at the first height, and the tracking locus of the light beam by the push-pull method is A transition area arranged to transition to a different path from the pre-recording area;
A recording track having the first height recordable by the light beam after passing through the transition region;
An information recording medium comprising: The information recording medium according to claim 1, wherein the recording track provided subsequent to the transition area is provided subsequent to the pre-recording area. The information recording medium is a disk-shaped recording medium in which the recording track and the guide track are spirally formed from an inner periphery toward an outer periphery, and the pre-recording area is linearly formed on the same recording track. the information recording medium according to claim 1 or 2, characterized in that it is provided. In the transition region, the adjacent guide tracks on the inner circumference side of the disk are partially changed so that the tracking locus of the light beam by the push-pull method changes the path toward the recording track on the inner circumference side of the disk. The information recording medium according to claim 3 , wherein the information recording medium is formed at a height of 2 mm and a subsequent recording track is partially formed at the second height. The transition region is characterized in that one of the adjacent guide tracks is partially formed at the first height so that a tracking trajectory of the light beam by the push-pull method is curved in the disk radial direction. The information recording medium according to claim 3 . The information recording medium is a disk-shaped recording medium in which the recording track and the guide track are spirally formed from an inner periphery toward an outer periphery, and the pre-recording area is connected to the recording track on the outer periphery side of the disk. the information recording medium according to claim 1 or 2, characterized in that provided so that curved. In the transition region, the adjacent guide tracks on both sides are formed symmetrically in the disk radial direction at the second height so that the tracking locus of the light beam by the push-pull method goes straight along the recording track. The information recording medium according to claim 6 . In the transition region, the adjacent guide tracks on both sides are asymmetrically in the disk radial direction so that the tracking locus of the light beam by the push-pull method changes the path toward the recording track on the inner circumference side of the disk. The information recording medium according to claim 6 , wherein the information recording medium is formed at a height of two. Wherein the subsequent said recording track in the transition area, an information recording medium according to claim 7 or claim 8, characterized in that the predetermined dummy data is formed as embossed pit array. A recording track having a first height on the information recording surface and a guide track having a second height different from the first height are formed adjacent to each other, and recording information can be repeatedly recorded on the recording track. An information recording medium manufacturing apparatus for manufacturing a simple information recording medium using a stamper,
Track forming means for forming the recording track and the guide track;
As an area in which pre-record data including predetermined control information is recorded and overwriting of other record information is prohibited, the recording track and the adjacent area in the vicinity of the pre-record area to be provided at a predetermined position on the information recording surface An area in which a predetermined portion of the guide track is continuously formed at the first height, and is arranged so as to shift the tracking locus of the light beam by the push-pull method to a path different from the pre-recording area. Transition region forming means for forming a transition region;
Recording track forming means for forming a recording track having the first height recordable by the light beam after passing through the transition region;
An information recording medium manufacturing apparatus comprising: 11. The information recording medium manufacturing apparatus according to claim 10, wherein the recording track provided subsequent to the transition area formed by the recording track forming means is provided subsequent to the pre-recording area. The transition area forming means forms the guide track at the first height in a guide track section preset corresponding to the transition area, and a recording track preset corresponding to the transition area. 12. The information recording medium manufacturing apparatus according to claim 10 , wherein the recording track is formed at the second height in a section. 13. The information recording medium manufacturing apparatus according to claim 10 , further comprising pre-recording area forming means for forming the pre-recording data as an embossed pit string in the pre-recording area. Claim from claim 10, wherein in the transition region to the pre-record area is not connected subsequent said recording track, the embossed pit array forming means for forming a predetermined dummy data as embossed pit array, and further comprising 14. The information recording medium manufacturing apparatus according to any one of items 13 . An information recording apparatus for recording recorded information on the information recording medium according to any one of claims 1 to 9 ,
When recording information is written by irradiating a light beam along the recording track, when the head of the pre-recording area is reached, writing of the recording information is stopped and the recording information is directed toward the end of the pre-recording area. Then, after the light beam is moved, writing of the record information is resumed. Pre-record data writing means for writing the pre-record data in the pre-record area by laser recording on the information recording medium manufactured by the information recording medium manufacturing apparatus according to claim 10 ;
Tracking correction means for correcting a tracking error during writing of the pre-record data and advancing a light beam along the pre-record area;
The information recording apparatus according to claim 15 , further comprising:

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