JP2011097630A - 3d conversion unit, and information recording device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To simply convert a 2D video content to a 3D video content to be recorded and viewed without changing the specification, a communication method or the like of the 2D video content which is generally distributed. <P>SOLUTION: This 3D conversion unit includes: an information separation part 121 for separating a compressed +α moving image video 3 for converting a TV program video 2 to a 3D video from a TV program P including the TV program video 2 of a form handleable by a TV only corresponding to a 2D video obtained from the outside, and a +α moving image video 3 compressed in accordance with a maximum transfer rate; a 3D conversion supplemental information extension part 123 for extending the compressed +α moving image video 3 output by the information separation part 121; and a 3D data integration part 125 for performing the arrangement processing of arranging the TV program video 2 and the +α moving image video 3 to be reproducible as a 3D video by adjusting a temporal difference generated between a point of time the information separation part 121 outputs the TV program video 2 and the compressed +α moving image video 3, and a point of time the 3D conversion supplemental information extension part 123 completes the extension of the compressed +α moving image video 3. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a three-dimensional unit for viewing and listening to a three-dimensional (hereinafter abbreviated as “3D”) video and an information recording apparatus including the three-dimensional unit.

  In recent years, research on methods for viewing 3D video other than 2D video has become active.

  In order to view 3D video, for example, it is necessary to separately display a right-eye video and a left-eye video dedicated to 3D video, and to view two videos with only the right eye and the left eye with deflection glasses or the like. is there.

  As an example of such conventional 3D video viewing technology, there is a stereoscopic video recording method disclosed in Patent Document 1.

  In the stereoscopic video recording method disclosed in Patent Document 1, the left-eye video and the right-eye video dedicated to 3D video are arranged and recorded in a sequence so that 3D video can be output on the optical disc, It is possible to view 3D video.

  Moreover, the video tape recorder disclosed by patent document 2 can be illustrated as another example of the technique of viewing and listening to the conventional 3D video.

  In the video tape recorder disclosed in Patent Document 2, it is possible to view and listen to 3D video by selecting and playing back an odd field image dedicated to 3D video and an even field image.

  Although not related to 3D video viewing and the like, a recording medium disclosed in Patent Document 3 can be exemplified as an example of a technique for combining and reproducing information of a plurality of fields.

  In the recording medium disclosed in Patent Document 3, a main stream distributed from the Internet and a substream from a ROM (read only memory) are simultaneously output to a TV (television) to combine information of a plurality of fields. It is possible to play.

JP 2009-135686 A (released on June 18, 2009) JP 62-166669 A (published July 23, 1987) WO2006 / 109716A1 pamphlet (Internationally released on October 19, 2006)

Co-authored by Satoshi Kanehara and Hideo Fujiwara “Applied Physics Selection 3. Thin Film” 198

  However, in the conventional technology for viewing 3D video, a method for playing back 3D video using two types of video dedicated to 3D video prepared in advance has been disclosed, but generally distributed. There is no disclosure or suggestion regarding a method for easily converting a 2D video content into 3D and recording or viewing the information on an information recording medium.

  By the way, when converting 2D video into 3D, an extra information amount of at least about 30% is required as compared with 2D video.

  For example, the transfer rate of the current broadcasting format (for example, terrestrial digital broadcasting) is a maximum of 17 Mbps (Mega-bits / second), and the breakdown of the entire transfer rate is that the transfer rate of this broadcast is about 15 Mbps, The broadcast transfer rate is about 2 Mbps, and the data broadcast transfer rate is about 13% of the main broadcast.

  Therefore, unless the maximum transfer rate is increased, it is difficult to directly broadcast 3D video with the current broadcasting system. Also, if the current broadcasting system is changed and the transfer rate of the main broadcast is lowered, the image quality of the main broadcast is deteriorated, which is not realistic.

  On the other hand, in video content distributed over the Internet or the like, unlike the case of broadcasting described above, the maximum transfer rate is large, so it is considered possible to directly distribute 3D video, but current standards and communication methods, etc. Is premised on the distribution of 2D video, so in order to directly distribute 3D video, it is necessary to change the standard, the communication method, etc., which is not practical.

  Then, in order to improve the convenience for the user, the 2D video content (for example, a broadcast program) that is generally distributed can be easily recorded in 3D and viewed without changing the standard or communication method. It is necessary to devise such as.

  However, the stereoscopic video recording method and the like disclosed in the conventional patent documents 1 and 2 and the video tape recorder disclose a method for recording two types of video dedicated to 3D video prepared in advance on an information recording medium. Although there is no change in the standard of 2D video content that is generally distributed, the communication method, etc., there is no disclosure regarding a method for easily converting to 3D and recording / viewing it on an information recording medium. There is no suggestion.

  In addition, in the conventional recording medium disclosed in Patent Document 3, the viewpoint of combining and reproducing information of a plurality of fields is mentioned, but in the first place the viewpoint of viewing 3D video is completely touched. Not.

  The present invention has been made in view of the above-mentioned conventional problems, and its purpose is to easily record in three dimensions without changing the standard or communication method of the two-dimensional video content that is generally distributed. It is an object to provide a three-dimensional unit or the like that enables viewing and viewing.

  In order to solve the above problems, the three-dimensional unit of the present invention is a three-dimensional unit that converts a two-dimensional video content into a three-dimensional video, and is a television receiver that supports only a two-dimensional video acquired from the outside. The 2D video content and the compressed complementary information are separated and output from the data including the 2D video content in a format that can be supported by and the complementary information compressed in accordance with the maximum transfer rate. Information separating means, decompressing processing means for decompressing the compressed complementary information output by the information separating means, and a point in time when the information separating means outputs the 2D video content and the compressed complementary information, Adjusting the time difference generated between the time when the decompression processing means completes decompression of the compressed complementary information, and the two-dimensional video content and the complementary information Characterized in that it and a sequence processing means for performing sequence processing for arranging to play as dimensions image.

  According to the above configuration, the information separating means includes 2D video content in a format that can be handled by a television receiver that supports only 2D video acquired from the outside, complementary information compressed in accordance with the maximum transfer rate, , 2D video content and compressed complementary information are separated and output.

  Next, the decompression processing means decompresses the compressed complementary information output from the information separating means.

  Next, the array processing means generates a time difference between the time when the information separating means outputs the 2D video content and the compressed complementary information and the time when the expansion processing means completes the expansion of the compressed complementary information. Is adjusted to arrange the 2D video content and the complementary information so that they can be reproduced as a 3D video.

  As a result, it is possible to arrange the 2D video content separated from the externally acquired data and the complementary information obtained by decompressing the compressed complementary information separated from the data so as to be reproduced as a 3D video. It becomes.

  Therefore, it is possible to easily record and view three-dimensionally without changing the standard or communication method of the two-dimensional video content that is generally distributed.

  In Patent Documents 1 to 3 mentioned above, when a two-dimensional TV is occupied as in the present situation, if a three-dimensional broadcast is performed, it is impossible to view on most TVs. There is no description about a point or a method for obtaining “complementary information” of the present application, which is a solution thereof.

  Here, examples of “2D video content” include moving images (including music, audio data, text data such as subtitles), and still images such as images for frame-by-frame playback.

  The data format or data compression scheme for “2D video content” includes Flash (video animation software sold by Macromedia), JPEG (Joint Photographic Experts Group) scheme for still image compression, An example is the Moving Picture Experts Group (MPEG) system for video compression.

  The MPEG system is a standard for compressing / decompressing video and audio, which is recommended as a standard technology by ITU-T (International Telecommunication Union Telecommunication Standardization Sector) and ISO (International Standard). Currently, the MPEG system includes MPEG1 used for media such as a video CD (Compact Disk), MPEG2 used for DVD (Digital versatile disc) and broadcast media, network distribution, and MPEG4 for portable terminals.

  Furthermore, as a delivery method of “2D video content”, Bluetooth (registered trademark), Felica, PLC (power line communication), Wireless LAN (wireless LAN: WLAN), IrDA (infrared wireless), IrSS (infrared wireless), and Examples include distribution by wired or wireless communication such as WCDMA (communication network).

  Examples of “broadcast content” in “2D video content” include NTSC (national television system committee) method, PAL (phase alternation by line) method, SECAM (sequential couleur a memoire system) method, HD- TV (high definition-multiple analogue component), ATV (advanced television), TV broadcasting, dual audio multiplex broadcasting, stereophonic audio multiplex broadcasting, broadcasting satellite (BS) or communication satellite (CS) Satellite broadcasting using radio waves from TV, cable broadcasting TV (cable television: CATV), high definition television (extended definition TV: EDTV), high definition television (high definition TV: HDTV), MUSE system, 1Seg, 3 Examples include broadcasting programs such as Seg and digital terrestrial broadcasting.

  Examples of “complementary information” include pseudo 3D information for pseudo 2D video content to be converted to 3D video, and 2D video content as either right eye video or left eye video. Examples include a left-eye image or a right-eye image.

  That is, “complementary information” for realizing 3D conversion need not be actual video data, and may be differential information for 2D video content (right-eye video or left-eye video), or video data in the first place. The supplemental information for realizing the 3D visualization of the 2D video may be used.

  The three-dimensional unit of the present invention further includes memory control means for performing control to record information in a predetermined temporary recording memory, in addition to the above configuration, and the memory control means is separated by the information separation means. The 2D video content recorded is recorded in a temporary recording memory, and the array processing means adjusts a time for reading the 2D video content recorded in the temporary recording memory, thereby adjusting the time difference. You may adjust it.

  Further, the information recording apparatus is an information recording apparatus including the three-dimensional unit, and the complementary information expanded by the two-dimensional video content and the expansion processing unit subjected to the array processing by the array processing unit. May be provided with a recording control means for recording the information on a predetermined information recording medium.

  According to the above configuration, the information separating unit separates the 2D video content and the compressed complementary information from the content acquired from the outside.

  Next, the memory control unit records the 2D video content separated by the information separation unit in the temporary recording memory.

  Next, decompression processing means decompresses the compressed complementary information separated by the information separating means.

  Next, the recording control unit reads the complementary information expanded by the expansion processing unit and the 2D video content recorded in the temporary recording memory by the memory control unit, and reads the 2D video content and the expanded complementary information. It arranges so that it can reproduce | regenerate as a three-dimensional image | video and it records on a 2nd information recording area.

  As a result, the 2D video content separated from the content acquired from the outside and the complementary information obtained by decompressing the compressed complementary information separated from the content are arranged so as to be reproduced as a 3D video. It is possible to record in the information recording area.

  As described above, the three-dimensional unit of the present invention is compressed in accordance with the maximum transfer rate and two-dimensional video content in a format that can be handled by a television receiver that supports only two-dimensional video acquired from the outside. Information separating means for separating and outputting the 2D video content and the compressed complementary information from the data including the complementary information; and decompressing the compressed complementary information output by the information separating means Between the decompression processing means, the time when the information separating means outputs the 2D video content and the compressed complementary information, and the time when the decompression processing means completes decompression of the compressed complementary information. And an array processing means for performing an array process for adjusting the time difference generated in the display so that the 2D video content and the complementary information can be reproduced as a 3D video. It is those who are.

  Therefore, there is an effect that it is possible to easily record in three dimensions and view without changing the standard or communication method of the two-dimensional video content that is generally distributed.

It is a schematic diagram which shows notionally the structure of one Embodiment in the information recording medium of this invention. (A) About the said information recording medium, it is a schematic diagram which shows a mode when recording space is vacated between each division | segmentation information of broadcast content so that supplementary information can be inserted, (b) is complementary information in the said recording space. It is a schematic diagram which shows a mode when inserting. It is a schematic diagram which shows notionally the structure of other embodiment in the information recording medium of this invention. It is sectional drawing which shows an example of schematic structure of the optical information recording medium which is one Embodiment of the information recording medium of this invention. It is sectional drawing which shows another example in schematic structure of the said optical information recording medium. 6 is a cross-sectional view showing a schematic configuration of Comparative Example 1 of the optical information recording medium shown in FIGS. FIG. 9 is a schematic diagram showing S-characteristic measurement results of Example 1 shown in FIGS. 4 and 5 and Comparative Example 1 shown in FIG. 7 at a reproduction laser power of 0.7 mW, and FIG. (B) shows the S-characteristic obtained by the measurement with respect to Comparative Example 1, and (c) shows in FIG. 4 and FIG. 5 at the reproduction laser power of 1.0 mW. The sigmoid characteristic measurement result of Example 1 is shown. (A) is a figure which shows the reproduction laser power dependence of the upper limit of the reflectance which cannot focus, (b) is a figure which shows the reproduction laser power dependence of the jitter in the optical information recording medium of a 2 layer (RE) structure. is there. It is explanatory drawing which shows an example of the reproduction | regeneration system which reproduces | regenerates the conventional multilayer optical information recording medium. FIG. 11 is a cross-sectional view showing a conventional multilayer optical information recording medium and a four-layer optical information recording medium. (A) is explanatory drawing which shows the S-characteristic in the reproducing | regenerating system shown in FIG. 9, (b) and (c) are focus search to the 2nd information recording layer shown in FIG. 10 by the reproducing | regenerating system shown in FIG. It is a figure which shows the transition of an objective-lens position when a process is performed, and a focus error signal, (b) shows the transition of an objective-lens position, (c) is an objective-lens position and a focus error signal. Show the relationship. It is a flowchart which shows the flow of the process in the said reproduction | regeneration system. It is a schematic diagram which shows one Embodiment in the information recording / reproducing apparatus of this invention. It is a block diagram which shows one structural example of the principal part regarding the said information recording / reproducing apparatus. It is a block diagram which shows the other structural example of the principal part regarding the said information recording / reproducing apparatus. FIG. 3 is a block diagram showing an example of a configuration of a control unit in the main part regarding the information recording / reproducing apparatus. It is a block diagram which shows the example of 1 structure of a medium writing control part regarding the said control part. It is an example of the flowchart which shows the flow of the process in the said information recording / reproducing apparatus. It is another example of the flowchart which shows the flow of a process in the said information recording / reproducing apparatus. It is another example of the flowchart which shows the flow of a process in the said information recording / reproducing apparatus.

  One embodiment of the present invention will be described with reference to FIGS. Configurations other than those described in the following specific items may be omitted as necessary, but are the same as the configurations described in other items. For convenience of explanation, members having the same functions as those shown in each item are given the same reference numerals, and the explanation thereof is omitted as appropriate.

[1. Conceptual structure of information recording medium and recorded information (part 1)]
In the present invention, information recorded in advance in a predetermined information recording area of the information recording medium, information scheduled to be recorded in the future, and the like are important points.

  Therefore, first, based on FIG. 1, FIG. 2 (a) and FIG. 2 (b), a conceptual configuration of an information recording medium according to an embodiment of the present invention and an example of the recorded information will be described. A specific example of the information recording medium of the present invention will be described below.

The information recording medium of the present invention may be an information recording medium having a single layer or a plurality of recording layers to which at least information can be read, to which a plurality of information recording areas are allocated,
It goes without saying that the present invention is not limited to the structure described in this embodiment.

  FIG. 1 is a schematic diagram conceptually showing the structure of an optical disc (information recording medium) 200 which is an embodiment of the information recording medium of the present invention.

  The optical disc 200 described here and the optical disc (information recording medium) 201 described below are both the above-described hybrid optical information recording media.

  The hybrid optical information recording medium has a plurality of recording layers, an intermediate layer separating each of the plurality of recording layers, and a light-transmitting layer provided at a position farthest from the substrate on the substrate. .

  In addition, the plurality of recording layers can read information by reproducing light.

  Further, the structure is basically such that at least one of the plurality of recording layers is a ROM layer, and at least one of the other recording layers is a layer capable of recording information.

  Here, the “layer capable of recording information” includes a layer (R layer) capable of only additional recording and a rewritable layer (RE layer).

  Here, the fact that only additional recording is possible means that information can be read and only additional recording can be performed in recording.

  More specifically, as shown in FIG. 1, the optical disc 200 of this embodiment includes a light-transmitting layer 10 and a first information recording layer (a layer that can only read information) in order from the reproduction light incident surface side. The recording layer 20, the intermediate layer 30, the second information recording layer (layer capable of recording information, recording layer) 40, and the substrate 50 are laminated.

  The physical structure, characteristics, and the like of the optical disc 200 will be described in detail later. Here, allocation of each information recording area for each recording layer, recording information for each information recording area, and the like will be described.

  First, the first information recording layer 20 includes a first information recording area (area where information can only be read) 20A and a third information recording area (first information recording area, an area where information can only be read). 20B.

  As shown in FIG. 1, the third information recording area 20B is preferably allocated to the outer circumference side of the lead-in area and the inner circumference side of the optical disc 200. However, the third information recording area 20B is assigned to the first information recording area 20B. If it is from the inner periphery side of the layer 20 to an outer periphery side, it can allocate to arbitrary positions.

  Next, a content recording area (second information recording area) 40A and an invalidation information recording area (second information recording area) 40B are allocated to the second information recording layer 40. The content recording area 40A is a so-called user area, and the invalidation information recording area 40B is preferably allocated to the outer peripheral side of the lead-in area and the inner peripheral side of the optical disc 200, as shown in FIG. As long as it is from the inner circumference side to the outer circumference side of the two information recording layers 40, it can be assigned to an arbitrary position.

  The optical disc 200 has only two recording layers, but the information recording medium has three or more recording layers to which at least information can be read, to which a plurality of information recording areas are allocated. It may have.

  Further, the allocation of the first information recording area 20A and the third information recording area 20B, the content recording area 40A, and the invalidation information recording area 40B is all in the case of an information recording medium having a single recording layer. This information recording area is assigned to a single recording layer.

  However, the single recording layer has a ROM area and an R or RE area, the first information recording area 20A and the third information recording area 20B are allocated to the ROM area, and the R or RE area is The content recording area 40A and the invalidation information recording area 40B are preferably allocated.

  On the other hand, in the case of an information recording medium having a plurality of recording layers, the first information recording area 20A and the third information recording area 20B, the content recording area 40A, and the invalidation information recording area 40B are in different recording layers. There are various cases where two or three information recording areas are assigned to a single recording layer and the remaining information recording areas are assigned to other recording layers.

  However, even in this case, the first information recording area 20A and the third information recording area 20B are allocated to the ROM area, and the content recording area 40A and the invalidation information recording area 40B are allocated to the R or RE area. Is preferred.

  This is because the content recording area 40A needs to be allocated to the R or RE area because it is necessary to record a TV program (two-dimensional video content) P acquired from outside by broadcasting, which will be described later.

  In addition, by assigning the first information recording area 20A to a ROM area that is an area where writing is impossible, 3D-complementary information (complementary information) described later is mistakenly overwritten with other data. Incorrect operation can be prevented.

  Furthermore, since the 3D supplement information can be recorded in advance when the optical disc 200 is manufactured, the user does not need to record the 3D supplement information of the TV program P on the optical disc 200 by any means, and the 3D supplement information is also provided. Is recorded in the ROM layer, the recordable area of the content recording area 40A of the R layer or RE layer in which the TV program P is recorded is not deleted.

  As an example of the ROM area, a case where information is recorded using an embossed prepit sequence or a case where information is recorded using a laser can be listed.

  Thus, from the viewpoint of the manufacturer, there is an advantage that, when the optical disc 200 is manufactured, it is possible to inexpensively and easily change the 3D supplement information.

  Further, since information can be recorded at the time of manufacturing the stamper, it is possible to distribute a large amount at a low cost in a short time as compared with the case where information is recorded after the optical disk 200 is manufactured or information distribution via the Internet or the like.

  Next, details of various types of information recorded in each information recording area included in the optical disc 200 will be described based on the table shown in FIG.

  Note that the upper and lower columns of the item “recording area” on the left side of the table shown in FIG. 1 classify each information recording area assigned to the first information recording layer 20 and the second information recording layer 40, and are in the middle. The upper and lower columns of the item “recording information” indicate data currently recorded in each information recording area.

  Further, the upper and lower columns of “Status” in the right item indicate the respective states of the first information recording area 20A, the content recording area 40A, the invalidation information recording area 40B, and the third information recording area 20B. If any data has already been recorded, write “recorded”, and if any data is to be recorded, indicate what kind of data can be recorded. Yes. The same applies to the table of FIG. 3 described below.

  As shown in FIG. 1, in the first information recording area 20A, which is a ROM area, at least 3D-complementing information for converting a TV program P that is a 2D video to be recorded in the content recording area 40A into 3D is stored in advance. It is recorded.

  Here, as an example of “3D-complementary information”, pseudo-3D information for pseudo-converting the TV program P into 3D, or the TV program P as either a right-eye video or a left-eye video, Examples include a left-eye image or a right-eye image.

  That is, “3D supplement information” for realizing 3D conversion does not have to be actual video data such as a right-eye video or a left-eye video, but is included in the TV program P (right-eye video or left-eye video). However, the difference information may not be related to the video data in the first place, and may be complementary information for realizing 3D conversion of 2D video.

  Here, “at least” indicates that information other than the 3D complementary information may be recorded.

  Further, the content recording area 40A of the second information recording layer 40 is an area where the TV program P related to the 3D-complementary information can be recorded.

  According to the above configuration, recording of a 3D video obtained by converting a TV program P into 2D video from 3D video by simply recording the TV program P related to the (specific) 3D-complementary information in the content recording area 40A is practical. Is possible.

  Further, this makes it possible to read the 3D-complementary information and the TV program P from the optical disc 200, so that the 3D video obtained by converting the TV program P into 2D from the 2D video can be viewed.

  Furthermore, since the TV program P using 2D video can be converted into 3D, there is no need to change the broadcast format of the TV program P.

  Therefore, it is possible to easily record and view in 3D without changing the broadcast format of the TV program P actually broadcast.

  Incidentally, as described above, the transfer rate of terrestrial digital broadcasting is a maximum of 17 Mbps, and the breakdown of the entire transfer rate is that the transfer rate of the main broadcast is about 15 Mbps, and the transfer rate of the data broadcast is about 2 Mbps. The transfer rate of data broadcasting is about 13% of the main broadcasting.

  Therefore, when converting a terrestrial digital broadcast into a three-dimensional image without increasing the maximum transfer rate, assuming that the transfer rate of the data broadcast (3D supplementary information) is about 2 Mbps, the transfer rate of the main broadcast (TV program P) Is about 6.7 Mbps or less, and there is a secondary problem that the image quality of the broadcast is significantly deteriorated.

  However, according to the optical disc 200, since the TV program P that is actually broadcast is used as it is, it can be easily recorded and viewed in three dimensions without degrading the image quality. Such secondary problems do not occur.

  Here, examples of the “TV program P” include NTSC, PAL, SECAM, HD-MAC, ATV, TV broadcasting, two audio multiplex broadcasting, stereophonic audio multiplex broadcasting, and broadcasting satellite (BS). Or, broadcast programs such as satellite broadcasting using radio waves from a communication satellite (CS), cable broadcasting TV, high-definition television, high-definition television, MUSE system, one-segment, three-segment, and terrestrial digital broadcasting can be exemplified. .

  In the present embodiment, “broadcast” is described as an example of a communication mode for acquiring 2D video content from the outside. However, the communication mode is not limited to “broadcast”, and Internet distribution, cable communication, etc. Regardless of wired communication or wireless communication, any communication form is included in the scope of the present invention.

  That is, the 2D video content other than the TV program P includes moving images (including music, audio data, and text data such as subtitles), and still images such as images for frame-by-frame playback.

  Examples of the data format or data compression scheme of the 2D video content include Flash for video, JPEG scheme for still image compression, and MPEG scheme for moving image compression.

  Currently, MPEG systems include MPEG1 used for media such as video CDs, MPEG2 used for DVDs and broadcast media, network distribution, and MPEG4 for portable terminals.

  Furthermore, examples of the distribution method of 2D video content include distribution by wired or wireless communication such as Bluetooth, Felica, PLC, WirelessLAN, IrDA, IrSS, and WCDMA.

  Next, as shown in the table of FIG. 1, recording reservation information (reservation information) for recording the TV program P in the content recording area 40A is recorded in advance in the third information recording area 20B, which is a ROM area. May be.

  Thus, if recording reservation information for the TV program P corresponding to the 3D supplementary information is recorded at the time of manufacturing the optical disc 200, the user does not need to record the recording reservation information for the TV program P on the optical disc 200 by any means. .

  Further, an information recording / reproducing apparatus (information recording apparatus) 1001 or an information recording / reproducing apparatus (information recording apparatus) 1002 constituting a 3D video viewing system (information recording / reproducing apparatus, information recording apparatus) 1 corresponding to the optical disc 200 described below. Is configured to record the TV program P using the recording reservation information when the broadcast of the TV program P is started.

  Therefore, the TV program P can be recorded in the content recording area 40A without requiring any user operation by simply loading the optical disc 200 into the information recording / reproducing apparatus 1001 or the information recording / reproducing apparatus 1002. .

  Since the recording reservation information is recorded in the third information recording area 20B, which is a ROM area, an erroneous operation in which another data is mistakenly overwritten on the recording reservation information recorded in advance is prevented. be able to.

  Further, since information can be recorded at the time of manufacturing the stamper, it is possible to distribute a large amount at a low cost in a short time as compared with the case where information is recorded after the optical disk 200 is manufactured or information distribution via the Internet or the like.

  Next, as shown in the table of FIG. 1, the invalidation information recording area 40B of the second information recording layer 40 which is the R or RE area is transferred to the content recording area 40A of the TV program P corresponding to the recording reservation information described above. This is an area in which invalidation information for determining cancellation of recording can be recorded.

  Thereby, when the TV program P recorded by the recording reservation information has contents that do not meet the user's expectation, the recording reservation information is invalidated by the invalidation information, and used for recording recording reservation information. The recorded area can be used for recording other contents.

  Therefore, for example, after the broadcast of the TV program P corresponding to the recording reservation information, the optical disc 200 having a recording area in which only the recording reservation information is recorded and cannot be diverted for recording of other contents is completely unnecessary for the user. Can be prevented.

  Here, the “invalidation information” is information for determining cancellation of recording of the TV program P in the content recording area 40A corresponding to the recording reservation information. For example, when “invalidation information” exists, recording of the TV program P corresponding to the recording reservation information is not executed in the content recording area 40A, or recording reservation information is reserved. The recording area used can be diverted for recording other contents.

  Next, as shown in the table of FIG. 1, in the third information recording area 20B, which is a ROM area, the TV program P and the 3D supplementary information are arranged so as to be reproduced as 3D video, and the content recording area 3D data array information (array processing information) for recording in 40A may be recorded in advance.

  Thus, as shown in FIGS. 2A and 2B, the TV program P [right-eye video information (broadcast content, two-dimensional video) R1 to R4...] Is used using the 3D data arrangement information. And 3D-complementary information (left-eye video creation complementary information (complementary information) L1 to L4...) Are arranged so as to be reproduced as 3D video and can be recorded in the content recording area 40A. .

  Therefore, as shown in FIG. 2B, the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4. In this case, in order to reproduce the 3D video, it is not necessary to read and record the left-eye video creation complementary information L1 to L4. Thereby, it is possible to save the recording capacity of the memory attached to the 3D video viewing system 1 corresponding to the optical disc 200, the hard disk, and the like.

  Here, “array processing” refers to, for example, as shown in FIG. 2B, the TV program P is converted to the right-eye video information R1 in correspondence with the left-eye video creation complementary information L1 to L4. ˜R4... And the left-eye video creation complementary information L1 corresponding to the right-eye video information R1 is inserted between the specific right-eye video information R1 and the next right-eye video information R2. This is a process of alternately arranging the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4. By such processing, the TV program P can be recorded as it is in three-dimensional playback.

  The “3D data arrangement information” is the recording start position and recording when the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4. It may be data provided for array processing, such as an end position.

  Further, as shown in FIG. 2A, recording spaces E1 to E4... Are provided between the right-eye video information R1 to R4..., And as shown in FIG. May be an array processing program that inserts the left-eye image creation complementary information L1 to L4... Corresponding to .about.E4.

  Here, a case where the “3D data array information” is data provided for the above-described array processing will be described.

  In this case, the 3D video viewing system 1 records “3D data arrangement information”, that is, the recording start positions of the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4. According to the recording end position and the like, these may be alternately arranged and recorded in the content recording area 40A of the optical disc 200.

  Since the 3D data arrangement information is recorded in the third information recording area 20B, which is a ROM area, the 3D data arrangement information recorded in advance is overwritten with another data by mistake. It is possible to prevent erroneous operation.

  Further, since information can be recorded at the time of manufacturing the stamper, it is possible to distribute a large amount at a low cost in a short time as compared with the case where information is recorded after the optical disk 200 is manufactured or information distribution via the Internet or the like.

  Next, as shown in the table of FIG. 1, in the third information recording area 20B, which is a ROM area, a 3D conversion permission key (permission information) indicating that the 3D conversion of the TV program P is permitted. It may be recorded in advance.

  Specifically, this “3D conversion permission key” indicates that, for example, the copyright holder or the copyright neighbor of a television broadcast performs 3D conversion of the TV program P using the 3D conversion complementary information. This indicates that the user has been granted permission.

  As a result, by using the 3D conversion permission key recorded in advance on the optical disc 200, the use permission for converting the TV program P into 3D is performed, so that the TV program for the information recording medium on which the valid 3D conversion permission key is not recorded. It is possible to make 3D P impossible.

  In other words, information indicating that the 3D conversion permission key recorded in advance on the optical disc 200 is permitted to 3D the TV program P acquired from the outside, that is, 3D conversion of the TV program P to the user. Information to be guaranteed.

  Therefore, if the 3D conversion permission key converts the TV program P into 3D using the optical disc 200 recorded in the third information recording area 20B in advance, the user can The TV program P can be converted to 3D with peace of mind.

  Further, the 3D supplement information recorded in the first information recording area 20A of the optical disc 200 in which the 3D conversion permission key is recorded in the third information recording area 20B in advance is surely produced by a broadcasting station or the like. Therefore, it is possible to make the TV program P 3D that matches the user preference according to the service provided by the broadcasting station or the like.

  The “authorized 3D conversion permission key” may be included in the data broadcast accompanying the TV program P, or may be program information corresponding to the TV program P in an electronic program guide (EPG). It may be included in the data. Further, it may be included in the barcode information corresponding to the TV program P published in the TV program introduction magazine or the like.

  Furthermore, the “legitimate 3D permission key” may be an encryption key that only a legitimate purchaser can know when selling the optical disc 200.

  In this case, when an encryption key is input to the 3D video viewing system 1 by the user via the operation unit 126 described later, the TV program P using the optical disc 200 can be converted to 3D.

  That is, whether or not the “3D conversion permission key” is valid depending on whether or not the 3D conversion permission key included in these data matches the 3D conversion permission key recorded in the third information recording area 20B of the optical disc 200. You just have to judge.

  Here, “3D conversion” means that the TV program P and 3D conversion complementary information are played back as 3D video, or arranged so as to be played back as 3D video, and recorded in the content recording area 40A of the optical disc 200. It is to be.

  As examples of the “3D conversion permission key”, 3D conversion complementary information, an encryption key for permitting use of 3D conversion data array information, information on a license agreement, and the like can be listed.

  The “3D conversion permission key” is recorded in advance on the optical disc 200 under the management of the copyright holder of the TV program or the copyright owner. Therefore, the act of the user converting the TV program P into 3D using the optical disc 200 on which the 3D conversion permission key is recorded or recording the TV program P into 3D is an illegal use of the TV program P. Not applicable.

  Further, for example, by including a right usage fee that the user should pay as a consideration for the 3D license in the sales price of the optical disc 200, the user of the optical disc 200 pays the 3D license when purchasing the optical disc 200. Can pay. The permitted 3D conversion may be related to dubbing to another recording medium.

  In addition to the above-described example, the 3D information recording area 20B, which is a ROM area, pseudo-converts a 2D moving image into 3D, or pseudo-converts 2D photo data into 3D for a 3D photo frame. A pseudo 3D program may be included.

  If the 3D conversion permission key and the pseudo 3D conversion processing program are recorded in the third information recording area 20B, which is a ROM area, the 3D conversion permission key and the pseudo 3D conversion processing program are mistakenly different from those recorded in advance. It is possible to prevent an erroneous operation of overwriting the data.

  Further, since information can be recorded at the time of manufacturing the stamper, it is possible to distribute a large amount at a low cost in a short time as compared with the case where information is recorded after the optical disk 200 is manufactured or information distribution via the Internet or the like.

[2. Conceptual structure of information recording medium and recorded information (Part 2)]
Next, another example of information recorded on the optical disc 200 will be described with reference to FIGS. 1 to 3, and a specific example of the information recording medium of the present invention will be described with reference to FIG.

  In the example of the table shown in FIG. 3, firstly, at least the compressed 3D-complementing information for converting the TV program P by 2D video into 3D is expanded in the first information recording area 20A, which is a ROM area. 1 is different from the example of the table shown in FIG. 1 in that expansion processing software (expansion processing program) is recorded in advance.

  Second, the content recording area 40A is an area where the TV program P related to the compressed 3D-complementary information can be recorded, unlike the example of the table shown in FIG. Yes. Note that the decompression processing software may be recorded in the 3D video viewing system 1 in advance.

  Note that the compressed 3D-complementary information is transmitted as a data broadcast accompanying the TV program P.

  According to the above configuration, the (specific) TV program P is recorded in the content recording area 40A, and the compressed 3D-complementary information accompanying the TV program P is recorded in the third information recording area 20B. By expanding the program, it is possible to easily record 3D video obtained by converting the 2D video TV program P into 3D.

  In addition, by this, it is possible to decompress the compressed 3D-complementary information and to read the TV program P from the optical disc 200 by the decompression processing program read from the optical disc 200. It is possible to view 3D video that is converted to 3D.

  For example, according to the MPEG system, if the compression rate is suppressed to about 1/100 to 1/200, the 3D-complementary information can be compressed without degrading the image quality, and transfer of about 2 Mbps is possible. Data broadcasting at a rate is also possible.

  Therefore, according to the optical disc 200, the TV program P that is actually being broadcast can be used as it is without being deteriorated in image quality, and can be recorded and viewed in a three-dimensional manner.

  Examples of the “compression method” include a JPEG method that compresses a still image by performing DCT conversion in units of pixels or a plurality of pixel blocks to cut color change data and high-frequency components, etc. An MPEG system that compresses a moving image by performing motion compensation processing in the direction can be exemplified. Examples of MPEG systems include MPEG1 and MPEG2, as well as H.264. For example, MPEG4 adopted in standards such as 264, Windows (registered trademark), Quick Time, and DivX can be exemplified.

  In particular, in the case of 3D video using right and left parallax, such as right-eye video information R1 to R4... And left-eye video creation complementary information L1 to L4. It is preferable to perform image compression by the MPEG method using difference information between the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4. Thereby, the compression rate of 3D video can be increased.

  More specifically, each of the right-eye video information R1 to R4... And each left-eye video creation complementary information L1 to L4... Is an I picture compressed in the frame and temporally forward. Digital picture information having a P picture compressed by adding motion compensation by the I picture and a B picture compressed by adding motion compensation by the I picture or the P picture in the temporal direction. Constitute.

  In addition, for example, the left-eye video creation complementary information L1 can be reproduced in units of pixels or in units of macroblocks, which are the minimum units of compressed video, with the parallax angle information that can be reproduced by the parallax angle with respect to the right-eye video information R1, The parallax angle information and the difference information are recorded on the optical disc 200 as 3D-complementary information (left-eye video creation complementary information L1).

  According to the above, since the TV program P using 2D video can be converted into 3D, it is not necessary to change the broadcast format of the TV program P.

  Therefore, it is possible to easily record and view in 3D without changing the broadcast format of the TV program P actually broadcast.

  Note that the decompression processing software is recorded in the non-writable area, that is, the third information recording area 20B, which is the ROM area. It is possible to prevent erroneous operations such as

  Further, since information can be recorded at the time of manufacturing the stamper, it is possible to distribute a large amount at a low cost in a short time as compared with the case where information is recorded after the optical disk 200 is manufactured or information distribution via the Internet or the like.

  Next, as shown in the table of FIG. 3, in the third information recording area 20B, which is a ROM area, the TV program P and the 3D-complementary information obtained by decompressing the compressed 3D-complementary information are converted into 3D video. The information for 3D data arrangement for recording in the content recording area 40A may be recorded in advance so as to be reproducible.

  If the 3D data array information is recorded in the third information recording area 20B, which is a ROM area, the 3D data array information recorded in advance is mistakenly overwritten with other data. Incorrect operation can be prevented.

  Further, since information can be recorded at the time of manufacturing the stamper, it is possible to distribute a large amount at a low cost in a short time as compared with the case where information is recorded after the optical disk 200 is manufactured or information distribution via the Internet or the like.

  Furthermore, according to the above-described configuration, the 3D-complementary information obtained by expanding the TV program P and the compressed 3D-complementary information is arranged so as to be reproduced as 3D video using the 3D-composed data array information. It becomes possible to record in the content recording area 40A.

  Therefore, as shown in FIG. 2B, the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4. In this case, in order to reproduce the 3D video, it is not necessary to read and record the left-eye video creation complementary information L1 to L4. Thereby, it is possible to save the recording capacity of the memory attached to the 3D video viewing system 1 corresponding to the optical disc 200, the hard disk, and the like.

  Next, as shown in the table of FIG. 3, in the third information recording area 20B, which is a ROM area, recording reservation information (reservation information) for recording the TV program P in the content recording area 40A is recorded in advance. May be.

  As a result, if recording reservation information of the TV program P corresponding to the 3D-complementary information compressed at the time of manufacturing the optical disc 200 is recorded, the user records the recording reservation information of the TV program P on the optical disc 200 by some means. There is no need.

  Further, the information recording / reproducing apparatus 1001 or the information recording / reproducing apparatus 1002 constituting the 3D video viewing system 1 described later can record the TV program P using the recording reservation information when the broadcast of the TV program P is started. It is configured.

  Therefore, the TV program P can be recorded in the content recording area 40A without requiring the user's operation only by loading the optical disc 200 into the information recording / reproducing apparatus 1001 or the information recording / reproducing apparatus 1002. .

  Since the recording reservation information is recorded in the third information recording area 20B, which is a ROM area, an erroneous operation in which another data is mistakenly overwritten on the recording reservation information recorded in advance is prevented. be able to.

  Further, since information can be recorded at the time of manufacturing the stamper, it is possible to distribute a large amount at a low cost in a short time as compared with the case where information is recorded after the optical disk 200 is manufactured or information distribution via the Internet or the like.

  Next, as shown in the table of FIG. 3, the invalidation information recording area 40B of the second information recording layer 40 which is the R or RE area is transferred to the content recording area 40A of the TV program P corresponding to the recording reservation information described above. It may be an area in which invalidation information for determining the cancellation of the recording can be recorded.

  Thereby, when the TV program P recorded by the recording reservation information has contents that do not meet the user's expectation, the recording reservation information is invalidated by the invalidation information, and used for recording recording reservation information. The recorded area can be used for recording other contents.

  Therefore, for example, after the broadcast of the TV program P corresponding to the recording reservation information, the optical disc 200 having a recording area in which only the recording reservation information is recorded and cannot be diverted for recording of other contents is completely unnecessary for the user. Can be prevented.

  Next, as shown in the table of FIG. 3, in the third information recording area 20B, which is a ROM area, a 3D conversion permission key indicating that the 3D conversion of the TV program P is permitted is recorded in advance. May be.

  Specifically, the “3D conversion permission key” indicates that, for example, a copyright holder of a television broadcast or a right holder of copyright or the like performs 3D conversion of the TV program P using 3D conversion complementary information. This indicates that the user has been licensed.

  Accordingly, the TV program for the information recording medium on which the valid 3D conversion permission key is not recorded can be obtained by using the 3D conversion permission key recorded in advance on the optical disc 200 to perform the use permission for converting the TV program P into 3D. It is possible to make 3D P impossible.

  In other words, information indicating that the 3D conversion permission key recorded in advance on the optical disc 200 is permitted to 3D the TV program P acquired from the outside, that is, 3D conversion of the TV program P to the user. Information to be guaranteed.

  Therefore, if the 3D conversion permission key converts the TV program P into 3D using the optical disc 200 recorded in the third information recording area 20B in advance, the user can The TV program P can be converted to 3D with peace of mind.

  Further, the 3D supplement information recorded in the first information recording area 20A of the optical disc 200 in which the 3D conversion permission key is recorded in the third information recording area 20B in advance is surely produced by a broadcasting station or the like. Therefore, it is possible to make the TV program P 3D that matches the user preference according to the service provided by the broadcasting station or the like.

  In addition to the above-described example, the 3D information recording area 20B, which is a ROM area, pseudo-converts a 2D moving image into 3D, or pseudo-converts 2D photo data into 3D for a 3D photo frame. A pseudo 3D program may be included.

  If the 3D conversion permission key and the pseudo 3D conversion processing program are recorded in the third information recording area 20B, which is a ROM area, the 3D conversion permission key and the pseudo 3D conversion processing program are mistakenly different from those recorded in advance. It is possible to prevent an erroneous operation of overwriting the data.

  In addition, since information can be recorded at the time of manufacturing the stamper, it is possible to distribute a large amount at a low cost in a short time as compared with the case where information is recorded after the information recording medium is manufactured or information distribution via the Internet or the like.

[3. Basic matters regarding information recording medium and information recording / reproducing apparatus]
Here, based on FIGS. 4 to 12, basic items regarding the optical disc 200 and the optical disc 201, which are an embodiment of the information recording medium of the present invention, and the playback system 100 corresponding to the optical disc 200 and the optical disc 201 will be described.

  First, specific structures of these recording media, which are an embodiment of the information recording medium of the present invention, will be described.

  As shown in FIGS. 1 and 4, the optical disc 200 of this embodiment includes a light-transmitting layer 10, a first information recording layer 20, an intermediate layer 30, a second information recording layer 40, and a substrate in order from the reproduction light incident surface side. 50 is laminated.

  1 is a perspective view illustrating an example of a schematic configuration of the optical disc 200, and FIG. 4 is a cross-sectional view illustrating an example of a schematic configuration of the optical disc 200.

  The translucent layer 10 is made of, for example, an ultraviolet curable resin having a thickness of 75 μm. The material of the light transmissive layer 10 may be any material having a high transmittance at the wavelength of the reproduction light. That is, the translucent 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 light transmissive layer 10. Furthermore, the thickness of the light transmitting layer 10 may be changed according to the optical system included in the information recording / reproducing apparatus corresponding to the optical disc 200. Specifically, the translucent layer 10 may be, for example, a 0.6 mm polycarbonate substrate.

  The first information recording layer 20 is a ROM layer, and is made of, for example, aluminum nitride having a thickness of 15 nm whose refractive index is adjusted by a nitrogen flow rate during film formation. The thickness and material of the first information recording layer 20 are not limited to this. For example, the reflectance value of the first information recording layer 20 at the reproduction light wavelength is larger than 0.4% and not larger than 2.2%. If it becomes.

  In other words, the first information recording layer 20 has translucency at the reproduction light wavelength, and the reflectance value is such that focus pull-in is not possible with the second reproduction light when reproducing the second information recording layer 40. Any value can be used as long as the focus can be pulled in with the first reproduction light when reproducing the first information recording layer 20.

  Specifically, the first information recording layer 20 may be made of, for example, silicon nitride or a dielectric mainly composed of aluminum nitride or silicon nitride in addition to the aluminum nitride, and has a multilayer structure. Also good.

  Here, the second reproduction light is applied to the optical disc 200 when reproducing the RE layer such as the second information recording layer 40. For example, an information recording / reproducing apparatus corresponding to an old standard optical information recording medium But it can be irradiated. The first reproduction light is higher in intensity than the second reproduction light, and is applied to the optical disc 200 (or an optical disc 201 described later) when reproducing the first information recording layer 20. The first reproduction light is emitted by an information recording / reproducing apparatus compatible with a new standard optical information recording medium.

  The intermediate layer 30 is made of, for example, a transparent ultraviolet curable resin having a thickness of 25 μm. 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 each recording layer (here, the first information recording layer 20 and the second information recording layer 40) can be separated, and interlayer crosstalk does not become a problem. It may be an appropriate thickness.

  Interlayer crosstalk refers to noise from a recording layer other than the recording layer being reproduced. Further, the intermediate layer 30 may have a multilayer structure. Further, on the surface of the intermediate layer 30 on the first information recording layer 20 side, prepits (not shown) made of unevenness corresponding to information recorded as a shape on the first information recording layer 20 are provided.

The second information recording layer 40 is an RE layer and is composed of, for example, seven thin films as shown in FIG. The seven-layer thin film includes, from the reproduction light incident side, a first protective film 41 (for example, ZnS—SiO _{2 with} a thickness of 35 nm), a second protective film 42 (for example, ZrO with a thickness of 5 nm), and a recording layer 43 ( For example, GeTe—Sb ₂ Te _{3 with} a thickness of 10 nm, a third protective film 44 (for example, ZrO with a thickness of 5 nm), a fourth protective film 45 (for example, ZnS—SiO _{2 with} a thickness of 35 nm), a fifth protective film. A film 46 (for example, ZrO having a thickness of 5 nm) and a reflective film 47 (for example, APC (AgPdCu) having a thickness of 20 nm) are sequentially stacked.

  The material, thickness, and number of layers of the second information recording layer 40 are not limited to this, and any material that functions as an RE layer may be used.

  The substrate 50 is made of polycarbonate having a thickness of 1.1 mm, for example. The material, size, and thickness of the substrate 50 are not limited to this, and a groove is provided on the surface, and the substrate 50 may have a predetermined strength that can 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.

  In addition to the groove, the surface of the substrate 50 may be provided with prepits having unevenness corresponding to information recorded as a shape on the second information recording layer 40. In this case, the area where the pre-pits of the second information recording layer 40 are provided is an area where only information can be read. That is, the second information recording layer 40 may include a RE area and a ROM area. However, from the viewpoint of applying the present invention, it is preferable that the range of the ROM area is as narrow as possible compared with the RE area.

  Further, as shown in FIG. 5, an optical disc 201 as another example of the present embodiment has a light transmitting layer 10, a first information recording layer 20, an intermediate layer 30, and a third information recording in order from the reproduction light incident surface side. A layer (a layer capable of recording information, a recording layer) 60, an intermediate layer 30, a second information recording layer 40, and a substrate 50 are stacked. FIG. 5 is a cross-sectional view showing an example of a schematic configuration of the optical disc 201.

  The translucent layer 10 is made of, for example, an ultraviolet curable resin having a thickness of 50 μm. The material of the light transmissive layer 10 may be any material having a high transmittance at the wavelength of the reproduction light. That is, the translucent 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 light transmissive layer 10. Furthermore, the thickness of the translucent layer 10 may be changed according to the optical system included in the information recording / reproducing apparatus of the optical disc 201. Specifically, the translucent layer 10 may be, for example, a 0.6 mm polycarbonate substrate. The first information recording layer 20 is a ROM layer, and is made of, for example, aluminum nitride having a thickness of 15 nm whose refractive index is adjusted by a nitrogen flow rate during film formation.

  The thickness and material of the first information recording layer 20 are not limited to this. For example, the reflectance value of the first information recording layer 20 at the reproduction light wavelength is larger than 0.4% and not larger than 2.2%. If it becomes. That is, the first information recording layer 20 has translucency at the reproduction light wavelength, and the reflectance value is the second value when the second information recording layer 40 or the third information recording layer 60 is reproduced. The value is such that the focus cannot be pulled in with the reproduction light, and any value that allows the focus to be pulled in with the first reproduction light when reproducing the first information recording layer 20 may be used.

  Specifically, the first information recording layer 20 may be made of, for example, silicon nitride or a dielectric mainly composed of aluminum nitride or silicon nitride in addition to the aluminum nitride, and has a multilayer structure. Also good.

  The intermediate layer 30 is made of, for example, a transparent ultraviolet curable resin having a thickness of 25 μm. 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. The thickness of the intermediate layer 30 is not limited to this, and each recording layer (here, the first information recording layer 20, the second information recording layer 40, and the third information recording layer 60) can be separated. An appropriate thickness is acceptable as long as interlayer crosstalk does not become a problem. Further, the intermediate layer 30 may have a multilayer structure.

  Further, in the intermediate layer 30 stacked between the first information recording layer 20 and the third information recording layer 60, the first information recording layer 20 is provided on the surface of the intermediate layer 30 on the first information recording layer 20 side. Prepits having unevenness corresponding to information recorded as a shape on the layer 20 are provided.

  In the intermediate layer 30 laminated between the second information recording layer 40 and the third information recording layer 60, a groove is provided on the surface of the intermediate layer 30 on the third information recording layer 60 side. ing. Note that the intermediate layer 30 may be provided with grooves and prepits made of irregularities corresponding to information recorded as shapes on the third information recording layer 60. In this case, the area where the pre-pits of the third information recording layer 60 are provided is an area where only information can be read. That is, the third information recording layer 60 may include a RE area and a ROM area.

  However, from the viewpoint of applying the present invention, it is preferable that the range of the ROM area is as narrow as possible compared with the RE area.

The second information recording layer 40 is an RE layer, and is composed of, for example, seven thin films. The seven-layer thin film includes, from the reproduction light incident side, a first protective film 41 (for example, ZnS—SiO _{2 with} a thickness of 35 nm), a second protective film 42 (for example, ZrO with a thickness of 5 nm), and a recording layer 43 ( For example, GeTe—Sb ₂ Te _{3 with} a thickness of 10 nm, a third protective film 44 (for example, ZrO with a thickness of 5 nm), a fourth protective film 45 (for example, ZnS—SiO _{2 with} a thickness of 35 nm), a fifth protective film. A film 46 (for example, ZrO having a thickness of 5 nm) and a reflective film 47 (for example, APC (AgPdCu) having a thickness of 20 nm) are sequentially stacked.

  The material, thickness, and number of layers of the second information recording layer 40 are not limited to this, and any material that functions as an RE layer may be used.

The third information recording layer 60 is an RE layer, and is composed of, for example, six layers of thin films. The six-layered thin film includes, from the reproduction light incident side, a first protective film 61 (for example, ZnS—SiO _{2 with} a thickness of 35 nm), a second protective film 62 (for example, ZrO with a thickness of 5 nm), and a recording layer 63 ( For example, GeTe—Sb ₂ Te _{3 having} a thickness of 6 nm, a third protective film 64 (for example, ZrO having a thickness of 5 nm), a translucent film 65 (for example, APC having a thickness of 20 nm (AgPdCu)), and transmittance adjustment A film 66 (for example, TiO ₂ having a thickness of 19 nm) is sequentially stacked.

  The material, thickness, and number of layers of the third information recording layer 60 are not limited to this, and any material that functions as an RE layer having a transmittance of about 60% at the wavelength of the reproduction light may be used.

  The substrate 50 is made of polycarbonate having a thickness of 1.1 mm, for example. The material, size, and thickness of the substrate 50 are not limited to this, and the substrate 50 may be provided with a groove having a predetermined strength that can be used as a 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.

  In addition to the groove, the surface of the substrate 50 may be provided with prepits having unevenness corresponding to information recorded as a shape on the second information recording layer 40. In this case, the area where the pre-pits of the second information recording layer 40 are provided is an area where only information can be read. That is, the second information recording layer 40 may include a RE area and a ROM area.

  However, from the viewpoint of applying the present invention, it is preferable that the range of the ROM area is as narrow as possible compared with the RE area.

  The optical disc 201 is not limited to the configuration described above, and any of the RE layers may be an R layer.

  Further, the optical disc 200 and the optical disc 201 are not limited to a two-layer or three-layer structure, and may be an optical information recording medium to which a recording layer is further added.

The optical disc 200 (and the optical disc 201) has a reproduction light wavelength of λ, a thickness of the first information recording layer 20, d, and refractive indexes of the light transmitting layer 10, the first information recording layer 20, and the intermediate layer 30, respectively. When n ₀ , n ₁ , and n are set,

Is preferably satisfied. This is because the reproduction light wavelength is λ, the thickness of the first information recording layer 20 is d, and the refractive indexes of the light transmitting layer 10, the first information recording layer 20 and the intermediate layer 30 are n ₀ , n ₁ and n, respectively. This is because the reflectance at the reproduction light wavelength of the first information recording layer in this case can be expressed by the above equation as described in Non-Patent Document 1.

  According to the above formula, the structure for obtaining the reflectance at the reproduction light wavelength of the first information recording layer 20 can be specified.

  The first information recording layer 20 of the optical disc 200 (and the optical disc 201) is preferably made of a dielectric having a refractive index greater than 1.75 and not greater than 2.06.

  Usually, a resin having a refractive index of about 1.5 is often used for both the light transmitting layer 10 and the intermediate layer 30. Further, the film thickness of the first information recording layer 20 is preferably about 15 nm in consideration of reproduction durability and cost increase accompanying an increase in film formation time due to the increase in film thickness. Considering the two limitations that occur when considering this actual production, the refractive index of the first information recording layer 20 is larger than 1.75 and 2.06 from the equation described in Non-Patent Document 1. The following is required.

〔Example〕
An optical disc 200 shown in FIG. 4 was produced as Example 1, and an optical disc 202 shown in FIG. 6 was produced as Comparative Example 1 of Example 1. Below, each structure is demonstrated using FIG.4 and FIG.6. FIG. 6 is a cross-sectional view showing a schematic configuration of an optical disc 202 that is a first comparative example of the optical disc 200 manufactured as the first embodiment.

  As shown in FIG. 4, the optical disc 200 according to the first embodiment includes a light transmitting layer 10, a first information recording layer 20, an intermediate layer 30, a second information recording layer 40, and a substrate 50 in order from the reproduction light incident surface side. It has a laminated structure.

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

  The first information recording layer 20 is a ROM layer, and is made of aluminum nitride (refractive index 2.01 at the reproduction light wavelength) with a thickness of 15 nm, the refractive index of which is adjusted by the nitrogen flow rate during film formation. The aluminum nitride forming the first information recording layer 20 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, a pre-pit composed of unevenness corresponding to information recorded as a shape in the first information recording layer 20 by the 2P method (photo polymer method) is provided on the surface of the intermediate layer 30 on the first information recording layer 20 side. It has been. 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 second information recording layer 40 is an RE layer, and seven thin films are laminated by sputtering. Specifically, from the reproduction light incident side, the first protective film 41 (ZnS—SiO _{2 with} a thickness of 35 nm), the second protective film 42 (ZrO with a thickness of 5 nm), and the recording layer 43 (GeTe— with a thickness of 10 nm). Sb ₂ Te ₃ ), a third protective film 44 (ZrO with a thickness of 5 nm), a fourth protective film 45 (ZnS—SiO _{2 with} a thickness of 35 nm), a fifth protective film 46 (ZrO with a thickness of 5 nm), and a reflection A film 47 (APC (AgPdCu) having a thickness of 20 nm) is 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.

  As shown in FIG. 6, the optical disc 202 according to Comparative Example 1 includes a light transmitting layer 10, a first information recording layer (a layer that can only read information, a recording layer) 120, and an intermediate layer in order from the reproduction light incident surface side. The layer 30, the second information recording layer 40, and the substrate 50 are stacked. The first information recording layer 120 of the optical disk 202 is made of a conventionally used metal translucent film APC (AgPdCu) and is formed to a thickness of 5 nm. The other layers (translucent layer 10, intermediate layer 30, second information recording layer 40, and substrate 50) are fabricated in the same manner as in Example 1.

  The transmittance of the first information recording layer 20 and the first information recording layer 120 was 95% in the first information recording layer 20 of Example 1, and 80% in the first information recording layer 120 of Comparative Example 1. . Further, the reflectance at the reproduction light wavelength of the first information recording layer 20 of Example 1 was 1.8%, and the return light rate of the second information recording layer 40 was 13.5%. On the other hand, the reflectance at the reproduction light wavelength of the first information recording layer 120 of Comparative Example 1 was 8%, and the return light rate of the second information recording layer 40 was 9.6%.

  Next, a laser having a wavelength of 406 nm, which is generally used as an evaluator for BD (Blu-Ray Disc), is obtained by using the S-characteristics detected when counting the number of recording layers in the initial stage of reproduction in Example 1 and Comparative Example 1. A semiconductor laser capable of emitting light; A. (Aperture ratio) It measured with the disk evaluation machine (Pulstec company make ODU-1000) which has an optical system of 0.85. The results obtained by this measurement are shown in FIGS. 7 (a), 7 (b), and 7 (c).

  Here, FIGS. 7A and 7B show the laser intensity as the intensity for reproducing the RE layer and the maximum reproduction laser power in the current standardized BD information recording / reproducing apparatus. It is a figure which shows the S character characteristic obtained by setting to a certain 0.7 mW and irradiating to the optical disks 200 and 202, respectively.

  7A shows the S-characteristic obtained by measurement with respect to the optical disc 200 of Example 1, and FIG. 7B shows the S-characteristic obtained by measurement with respect to the optical disc 202 of Comparative Example 1. It is a figure which shows a characteristic. FIG. 7C shows the S-characteristic obtained by setting the laser intensity to 1.0 mW, which is the intensity for reproducing the ROM layer, and irradiating the optical disk 200 according to the first embodiment. FIG.

  As shown in FIG. 7A, the actual measurement value of the S-characteristic in the first information recording layer 20 of Example 1 is 186 mV, and the reference voltage + V1 (230 mV) for focusing in the disk evaluator is set. Not exceeded. Therefore, FIG. 7A shows an information recording / reproducing apparatus (first information) that counts the number of recording layers with a laser beam of 0.7 mW which is the maximum reproducing laser power in the currently standardized BD information recording / reproducing apparatus. This indicates that an old standard-compliant information recording / reproducing apparatus that does not support the recording layer 20 cannot recognize the first information recording layer 20 as a recording layer.

  For this reason, the information recording / reproducing apparatus corresponding to the old standard cannot naturally focus on the first information recording layer 20. Actually, the first information recording layer 20 was focused at the time of measurement. However, the disc evaluation has high versatility and can be applied to various optical information recording media as compared with commercially available disc information recording and reproducing devices for consumer use. Even the machine did not focus. Note that the reference voltage + V1 is a value set in the ODU-1000 as a value by which information recorded on the two-layer information recording medium can be evaluated for reproduction.

  On the other hand, as shown in FIG. 7B, the measured value of the S-characteristic in the first information recording layer 120 of Comparative Example 1 is 847 mV, which exceeds the reference voltage + V1 (230 mV). Therefore, FIG. 7B shows an information recording / reproducing apparatus (first information) that counts the number of recording layers with a laser beam of 0.7 mW which is the maximum reproducing laser power in the currently standardized BD information recording / reproducing apparatus. This shows that an old standard-compliant information recording / reproducing apparatus that does not support the recording layer 120 can recognize the first information recording layer 120 as a recording layer.

  From the above results, the first information recording layer 20 of Example 1 was compared with Comparative Example 1 with a laser beam of 0.7 mW that is the maximum reproduction laser power in the current standardized BD information recording / reproduction apparatus. When the number of recording layers is counted, the possibility of being recognized by the old standard compliant information recording / reproducing apparatus is extremely low. That is, since the first information recording layer 20 cannot be focused by a disk evaluation machine that is more versatile than a normally used information recording / reproducing apparatus, the information recording / reproducing apparatus compliant with the old standard cannot substantially recognize it. I can say that.

  On the other hand, the first information recording layer 120 of the comparative example 1 has the old recording layer count at the time of counting the number of recording layers with a laser beam of 0.7 mW which is the maximum reproduction laser power in the currently standardized BD information recording / reproducing apparatus. The possibility of being recognized by the standard-compliant information recording / reproducing apparatus is high. This is because the old standard-compliant information recording / reproducing apparatus normally used at the present time can handle up to two recording layers. However, the old standard-compliant information recording / reproducing apparatus recognizes an unknown recording layer called the first information recording layer 120, which may cause a reproduction failure.

  Further, as shown in FIG. 7C, the actual measurement value of the S-characteristic in the first information recording layer 20 of Example 1 is 274 mV, which exceeds the reference voltage + V1 (230 mV). Therefore, FIG. 7C shows an information recording / reproducing apparatus (corresponding to the first information recording layer 20) that counts the number of recording layers with a laser beam of 1.0 mW that is an intensity for reproducing the first information recording layer 20. The new standard compliant information recording / reproducing apparatus) can recognize the first information recording layer 20 as a recording layer. In other words, the new standard-compliant information recording / reproducing apparatus can naturally focus on the first information recording layer 20 and can reproduce the first information recording layer 20. Actually, the first information recording layer 20 was focused at the time of measurement, and it was confirmed that the focus was applied.

  As shown in FIGS. 7A and 7C, the actual measured values of the S-characteristics of the second information recording layer 40 of Example 1 are 1438 mV and 2105 mV, respectively, both of which are the reference voltage + V1 ( 230 mV). Therefore, the second information recording layer 40 can be focused even in an information recording / reproducing apparatus compatible with any of the old and new standards (that is, the old standard-compliant information recording / reproducing apparatus or the new standard-compliant information recording / reproducing apparatus). In addition, information can be recorded / reproduced with respect to the second information recording layer 40.

  As described above, even when the optical disc 200 is reproduced by the old standard compliant information recording / reproducing apparatus, the old standard compliant information recording / reproducing apparatus causes a defective reproduction as in Comparative Example 1. In addition, information can be recorded / reproduced on / from the second information recording layer 40. In addition, since information recorded on the first information recording layer 20 can be reproduced by the new standard-compliant information recording / reproducing apparatus, the optical disc 200 can be recorded while maintaining the recording capacity limit value in the second information recording layer 40. It can be said that the capacity could be improved. The same can be said for the optical disc 201 as with the optical disc 200.

  Incidentally, the limit that can be focused by a normally used information recording / reproducing apparatus depends on the S-characteristic as described above, and thus basically depends on the amount of reflected light. Here, using the plurality of samples, the upper limit value of the reflectance that cannot be focused at each reproduction eraser power was measured by the above-described disk evaluator. The measurement result at this time is shown in FIG.

  As shown in FIG. 8A, at a maximum reproduction laser power of 0.7 mW in the current standardized BD information recording / reproducing apparatus, a reflectance of 2.2% is a reflectance that cannot be focused (cannot be recognized). It can be seen that this is the upper limit value.

  Since the reproduction laser power is highly likely to vary depending on the BD information recording / reproduction apparatus, it may be considered that the reproduction laser power is actually about 20% higher (0.84 mW). In this case (even if the reproduction laser power is 0.84 mW), the upper limit value of the reflectance that cannot be focused (cannot be recognized) was found to be 1.8% from the result shown in FIG.

  Further, the optical disc 200 and the optical disc 201 include RE layers (second information recording layer 40 and third information recording layer 60). Therefore, when the number of recording layers is counted, there is a possibility that reproduction light with high laser power for reproducing the first information recording layer 20 is condensed and irradiated on the RE layer.

  By the way, the recording layer count is usually performed in the lead-in area. Therefore, the reflectance of the lead-in area of a single-layer BD-RE currently on the market can be increased by using a semiconductor laser capable of emitting a laser beam having a wavelength of 405 nm, which can increase the reproduction laser power from the disk evaluation machine, and N.D. A. (Aperture ratio) It measured with the disk evaluation machine (DDU-1000 by a pulse tech company) which has an optical system of 0.85.

  First, the reflectivity of the lead-in area was measured at 0.35 mW, which is the reproduction laser power of the single layer BD. Next, after irradiating a higher reproduction laser power, the reflectivity was again returned to 0.35 mW and the lead-in area was Measure the reflectance. By this measurement, the reproduction laser power at which degradation of the RE layer (decrease in reflectivity of the lead-in area) occurs was measured.

  As a result, it was found that the reflectance did not change until the reproduction laser power was 3.5 mW, but the reflectance decreased by 5% (that is, the RE layer deteriorated) at 4.0 mW. That is, when the number of recording layers is counted with a laser power higher than 3.5 mW, there is a possibility that the lead-in area of the RE layer is deteriorated. Therefore, from the result shown in FIG. 8A, the upper limit value of the reflectance that is not focused at 3.5 mW is 0.4%, so the reflectance of the first information recording layer 20 is 0.4%. It will need to be bigger.

  Further, when reproducing the optical disc 200 and the optical disc 201, the focus may be lost due to an impact. In that case, there is a possibility that the reproducing light for reproducing the first information recording layer 20 is applied to the information recording area of the information recording area of the RE layer (the second information recording layer 40 or the third information recording layer 60). Therefore, the information recording part of the currently commercially available two-layer RE-BD was irradiated with reproduction light, and the reproduction laser power at which the recorded information deteriorated was measured. This measurement was performed by the above-described disk evaluator (ODU-1000), and jitter generally used as an index of the quality of a reproduction signal was used as an index of deterioration of recorded information. The measurement result at this time is shown in FIG.

  As shown in FIG. 8B, when the reproduction laser power is higher than 1.2 mW, the jitter of the first information recording layer (RE layer) of the two-layer RE-BD is rapidly deteriorated (that is, the RE layer is deteriorated). I understand). That is, it can be seen that the upper limit of the reproduction laser power that does not deteriorate the information recorded in the RE layer is 1.2 mW.

  Therefore, from the result shown in FIG. 8A, the upper limit of the reflectance that is not focused when the reproducing laser power is 1.2 mW is 1.2%. Focusing is possible with a laser power of 1.2 mW or less.

  Therefore, the reflectance at the reproduction light wavelength of the first information recording layer 20 of the optical disc 200 and the optical disc 201 may be greater than 0.4% and less than or equal to 2.2%, and more preferably greater than 1.2% and 1 .8% or less is sufficient.

  The measurement results obtained by the two disk evaluators do not change as long as the reproduction light wavelength is in the blue laser wavelength range.

  By the way, in a normally used information recording / reproducing apparatus, the recording layer is recognized when the measured value of the S-characteristic detected from each recording layer exceeds a predetermined reference voltage. When the recording layer is recognized by the information recording / reproducing apparatus, the recognized recording layer is focused, and information can be reproduced from the recording layer. The reason why information can be reproduced by focusing on the detection result of the S-characteristic will be described below.

  First, a reproduction system (information recording / reproducing apparatus, information recording apparatus) 100 for reproducing a general multilayer optical information recording medium will be described. For example, the configuration of the reproduction system 100 that reproduces the four-layer optical disc 400 shown in FIG. 10 will be described below with reference to FIG.

  As shown in FIG. 9, the disk drive motor 101 of the reproduction system 100 rotates and drives a disk-shaped optical disk 400 (see FIG. 10 for a schematic cross-sectional structure) at a predetermined speed. The disk drive motor 101 is controlled by a motor control circuit 109. Further, reading of information from the optical disk 400 that is rotationally driven in this way is performed by the optical pickup 102.

  The optical pickup 102 is configured to move in the radial direction of the optical disc 400 by the driving force of the feed motor 111. The feed motor 111 is controlled by a feed motor control circuit 108. Further, the feed motor 111 is configured such that the rotational speed thereof is detected by the speed detector 112. Then, the speed detector 112 supplies the detected result as a speed signal to the feed motor control circuit 108.

  The optical pickup 102 includes an objective lens 102a. The objective lens 102a is supported so as to be movable in a focusing direction (optical axis direction) and a tracking direction (radial direction of the optical disc 400). The objective lens 102a is controlled in position in the focus direction by supplying the focus control signal generated by the focus control circuit 105 to the focus drive coil 102c. Similarly, the position of the objective lens 102a in the tracking direction is controlled by supplying the tracking control signal generated by the tracking control circuit 106 to the tracking drive coil 102b.

  Further, the laser control circuit 103 drives the semiconductor laser oscillator 102f in the optical pickup 102, and generates laser light in the semiconductor laser oscillator 102f. The light amount detector 102 g detects the light amount of the laser light generated by the semiconductor laser oscillator 102 f and feeds back the detection result to the laser control circuit 103. With this configuration, the laser control circuit 103 can control the amount of laser light generated by the semiconductor laser oscillator 102f to be constant.

  The laser light generated by the semiconductor laser oscillator 102f passes through the collimator lens 102e, is bent at a right angle by the half prism 102d, and then collected on any recording layer of the optical disk 400 by the objective lens 102a. Will light up. Any recording layer of the optical disc 400 refers to the first information recording layer A, the second information recording layer B, the third information recording layer C, or the fourth information recording layer D shown in FIG. The first information recording layer A, the second information recording layer B, the third information recording layer C, and the fourth information recording layer D all have APC ( This is a ROM layer that can only read information in which the shape of APC (AgPdCu) is fixed by forming (AgPdCu).

  Reflected light from the optical disk 400 travels backward through the objective lens 102a and travels straight through the half prism 102d, and then is received by the photoelectric converter 102j via the condenser lens 102h and the cylindrical lens 102i. The photoelectric converter 102j includes four photodetectors 102j1 to 102j4 that generate an electrical signal corresponding to the amount of received light. In the case of this photoelectric converter 102j, the alignment direction of the photodetectors 102j1 and 102j2 and the alignment direction of the photodetectors 102j3 and 102j4 correspond to the tracking direction of the optical disc 400. Similarly, the alignment direction of the photodetectors 102j1 and 102j4 and the alignment direction of the photodetectors 102j2 and 102j3 correspond to the tangential direction of the optical disc 400.

  The electrical signal output from the photodetector 102j1 is supplied to one end of the adder circuits 113a and 113d via the amplifier circuit 114a, and the electrical signal output from the photodetector 102j2 is added to the adder circuit 113b via the amplifier circuit 114b. -It is supplied to one end of 113c. The electrical signal output from the photodetector 102j3 is supplied to the other ends of the adder circuits 113a and 113c via the amplifier circuit 114c, and the electrical signal output from the photodetector 102j4 is added via the amplifier circuit 114d. They are supplied to the other ends of the circuits 113b and 113d, respectively.

  The output signal of the adder circuit 113 a is supplied to the inverting input terminal − of the differential amplifier circuit 104, and the output signal of the adder circuit 113 b is supplied to the non-inverting input terminal + of the differential amplifier circuit 104. The differential amplifier circuit 104 generates a focus error signal by calculating the difference between the output signals of the adder circuits 113 a and 113 b and supplies the focus error signal to the focus control circuit 105. The focus control circuit 105 generates a focus control signal to be applied to the focus drive coil 102c so that the input focus error signal becomes 0 level, and focus servo is performed on the objective lens 102a.

  Here, the focus error signal output from the differential amplifier circuit 104 is obtained by moving the focus position of the laser beam by the objective lens 102a sequentially from the initial position in the focus direction, and performing the focus search process (that is, the number of recording layers). When the counting process is performed, an S-characteristic is drawn as shown in FIG.

  Specifically, when the focus search process is performed, the focus error signal indicates that the focus position of the laser beam by the objective lens 102a is the recording layer (first information recording layer A, fourth information recording layer) shown in FIG. Each time it passes through the layer D, the third information recording layer C, and the second information recording layer B), an S-characteristic as shown in FIG. Note that the initial position is a position before focusing of the objective lens 102a, and is usually below the first information recording layer A of the optical disc 400 and farthest from the optical disc 400 in the optical axis direction in FIG. Refers to the position.

  For example, at the start of reproduction of the optical disc 400, the reproduction system 100 first generates reproduction light corresponding to the single-layer optical information recording medium by the semiconductor laser oscillator 102f in the optical pickup 102.

  Next, the condensing position of the laser beam by the objective lens 102a is moved upward from the initial position to the driving upper limit position in FIG. Then, the reproduction system 100 recognizes the number of recording layers of the optical disc 400 by counting the number of times that the focus error signal exceeds a predetermined reference voltage + V0.

  Thereafter, the reproduction system 100 changes the reproduction optical power determined based on the number of recording layers that the optical disc 400 has. Then, the reproduction system 100 moves the condensing position of the laser light by the objective lens 102a from the drive upper limit position downward to the initial position in FIG. 9 with the changed reproduction light power. At that time, the gain of the amplifier included in the focus control circuit 105 or the like is changed so that the voltage value of the focus error signal detected from the recording layer first subjected to the focus search process becomes an appropriate value.

  For example, when the focus search process is performed on the second information recording layer B, the reproduction system 100 counts the number of times that the focus error signal exceeds a predetermined reference voltage + V0, and after reaching the fourth time, the reproduction system 100 first becomes 0 level. When the value reaches (center level of focus servo operation), the focus servo is turned on. Thereby, the focus search process for the second information recording layer B in the reproduction system 100 is completed.

  FIGS. 11B and 11C are diagrams showing the transition of the objective lens position and the focus error signal when the reproduction search system 100 performs the focus search process on the second information recording layer 40 described above. FIG. 4B is a diagram showing the transition of the objective lens position, and FIG. 4C shows the focus error signal.

  Further, for example, when a layer jump is performed from the fourth information recording layer D to the second information recording layer B, the reproduction system 100 temporarily turns off the focus servo and switches the fourth information recording layer D to the second information recording layer 40. The focal position of the laser beam by the objective lens 102a is sequentially moved. Then, the reproduction system 100 counts the number of times that the focus error signal output from the differential amplifier circuit 104 exceeds a predetermined reference voltage + V0. Level), the focus servo is turned on. As a result, the layer jump process ends. The layer jump process is not shown because it is almost the same process as the focus search process.

  Further, when these focus search processes are performed, the phase difference detection circuit 107 has a phase difference between the sum of the output signals of the photodetectors 102j1 and 102j4 of the photoelectric converter 102j and the sum of the output signals of the photodetectors 102j2 and 102j3. To detect. The phase difference detection circuit 107 supplies the detection result to the tracking control circuit 106 as a tracking error signal.

  The tracking control circuit 106 generates a tracking control signal to be applied to the tracking drive coil 102b based on the input tracking error signal, and applies tracking servo to the objective lens 102a. In the reproduction system 100, the optical disc 400 is reproduced while the tracking servo is being performed. The electrical signals output from the adder circuits 113c and 113d are summed by the adder circuit 113e, and converted into a digital signal by the data reproduction circuit (data reproduction control means) 110.

  The laser control circuit 103, the focus control circuit 105, the tracking control circuit 106, the motor control circuit 109, and the data reproduction circuit 110 of the reproduction system 100 are controlled by the control unit 115. Information relating to recording / reproduction of the optical disk 400 loaded in the reproduction system 100 is stored in a memory attached to the control unit 115 (not shown in FIG. 9; corresponding to the memory 116 in FIGS. 13 and 14 described below). Has been. The control unit 115 controls each circuit according to this information.

  Further, when the reflectance from the recording layer increases, the voltage value of the focus error signal of the reproduction system 100 also increases.

  Here, the flow of processing in the reproduction system 100 for reproducing a general multilayer optical information recording medium (here, the optical disc 400) will be described. FIG. 12 is a flowchart showing a processing flow in the reproduction system 100 for reproducing the multilayer optical information recording medium.

  First, after the optical disc 400 is loaded into the reproduction system 100, the optical disc 400 is rotated at a predetermined number of revolutions by the disc drive motor 101 (S1). Next, the control unit 115 moves the optical pickup 102 to a position facing the lead-in area of the optical disc 400, and performs a focus search process on a desired layer (S2). This layer refers to any one of the first information recording layer A, the second information recording layer B, the third information recording layer C, and the fourth information recording layer D in the optical disc 400. Then, the tracking control circuit 106 performs tracking processing (S3), and information reproduction processing by the reproduction system 100 is performed (S4).

  As described above, it can be seen that in the reproduction system 100, the recognition of the recording layer and the focus on each recording layer are all performed based on the S-characteristic obtained from each recording layer. Therefore, since the reproduction system 100 of the multilayer optical information recording medium as described above is used in the information recording / reproducing apparatus, the information recording / reproducing apparatus measures the S-characteristic of each recording layer, thereby The presence or absence of recognition and the possibility of reproduction can be determined.

[4. Information recording medium as one embodiment of the present invention]
This completes the description of the basic matters of the information recording medium and information recording / reproducing apparatus to which the present invention is applied.

  Then, the case where this invention is applied to the optical disk 200 and the optical disk 201 is demonstrated based on FIGS.

  First, for the optical disc 200, as shown in FIG. 4, a transparent layer 10, a first information recording layer 20, an intermediate layer 30, a second information recording layer 40, and a substrate 50 are laminated in order from the reproducing light incident surface side. It has a structure.

  Further, as shown in FIG. 1, the first information recording layer 20 is assigned with the first information recording area 20A and the third information recording area 20B, which are ROM areas, and the second information recording layer 40 has R or A content recording area 40A and an invalidation information recording area 40B, which are RE areas, are allocated.

  Since both the first information recording layer 20 and the third information recording area 20B are ROM areas, here, the information recording area of the first information recording layer 20 (single ROM layer) which is the same recording layer. Is divided into two information recording areas.

  Next, with respect to the optical disc 201, as shown in FIG. 5, in order from the reproduction light incident surface side, the light transmitting layer 10, the first information recording layer 20, the intermediate layer 30, the third information recording layer (information can be recorded). Layer, recording layer) 60, intermediate layer 30, second information recording layer 40, and substrate 50 are laminated.

  Here, the first information recording area 20A and the third information recording area 20B are a single film or a multilayer film made of a reflective film, a recording film, or the like provided to function as a recording layer in the first information recording layer 20. It refers to the range of the provided medium surface direction (in-plane direction of the incident surface of the reproduction light).

  Further, the content recording area 40A and the invalidation information recording area 40B are a single film or a multilayer film made of a reflective film or a recording film provided to function as a recording layer in a recording layer other than the first information recording layer 20. Indicates a range in the medium surface direction in which is provided.

  The second and subsequent information recording layers are counted from the side closer to the substrate 50. That is, the third information recording layer 60 is between the first information recording layer 20 and the second information recording layer 40. Similarly, the fourth information recording layer (not shown) is between the first information recording layer 20 and the third information recording layer 60.

  The arrangement of the first information recording area 20A and the third information recording area 20B, the content recording area 40A, and the invalidation information recording area 40B may be different from the arrangement in the optical disc 200 and the optical disc 201 as described above. It goes without saying that it is good.

  However, as described above, it is preferable that the first information recording area 20A and the third information recording area 20B are arranged in the ROM area, and the content recording area 40A and the invalidation information recording area 40B are arranged in the R or RE area.

  Therefore, although not shown, the first information recording area 20A and the third information recording area 20B are allocated to the first information recording layer 20, and the content recording area 40A and the invalidation information recording area 40B are the second information recording area. Assigned to the layer 40 and / or the third information recording layer 60.

  Further, in the optical disc 201, as in the optical disc 200, the third information recording area 20 </ b> B exists on the inner peripheral side of the first information recording layer 20 with respect to the first information recording area 20 </ b> A.

  As described above, in the optical disc 200 and the optical disc 201, the first information recording area 20A and the third information recording area 20B are allocated to the ROM area, and the content recording area 40A and the invalidation information recording area 40B are the R area or Preferably, it is assigned to the RE area.

  This is because the content recording area 40A needs to record the TV program P (or 3D video in which right-eye video information R1 to R4... And left-eye video creation complementary information L1 to L4... Are alternately arranged). Therefore, it is necessary to assign to the R area or the RE area.

  Further, the invalidation information recording area 40B needs to be allocated to the R area or the RE area because invalidation information needs to be recorded.

  On the other hand, by assigning the first information recording area 20A and the third information recording area 20B to the ROM area, the 3D supplementary information, the expansion processing software, the recording reservation information, the 3D data arrangement information, and the 3D conversion permission key described above are used. On the other hand, it is possible to prevent an erroneous operation in which another data is overwritten by mistake.

  As an example of the ROM area, a case where information is recorded using an embossed prepit sequence or a case where information is recorded using a laser can be listed.

  Accordingly, when viewed from the manufacturer side, there is an advantage that the 3D supplementary information, the expansion processing software, the recording reservation information, the 3D data array information, and the like can be easily changed when the optical disc 200 and the optical disc 201 are manufactured.

[5. Information recording / reproducing apparatus as one embodiment of the present invention]
Next, the configuration of the 3D video viewing system 1 which is an embodiment of the information recording / reproducing apparatus of the present invention will be described with reference to FIGS.

  Note that the basic configuration of the information recording / reproducing apparatus 1001 and the information recording / reproducing apparatus 1002 described below is the same as that of the above-described reproducing system 100. Therefore, the description of the common parts will be omitted as appropriate. To do.

  As shown in FIG. 13, the 3D video viewing system 1 includes an information recording / reproducing apparatus 1001 (or information recording / reproducing apparatus 1002), a display unit 4, a cable 4A (or cable 4B), a liquid crystal shutter 5, and deflection glasses 7. It is.

  The information recording / reproducing apparatus 1001 (or information recording / reproducing apparatus 1002) outputs a plurality of frames of TV program video (broadcast content, two-dimensional video) 2 derived from the above-described TV program P as a right-eye video, and the above-described 3D complementation. A plurality of frames of + α moving image video (complementary information) 3 for converting the TV program video 2 derived from information into 3D is output as a left-eye video.

  The TV program video 2 and the + α moving image 3 output from the information recording / reproducing apparatus 1001 (or the information recording / reproducing apparatus 1002) are respectively input to the display unit 4 and reproduced as 3D video on the display unit 4. The display unit 4 is configured by a TV, a projector, or the like.

  The liquid crystal shutter 5 is composed of liquid crystal or the like, and can switch between two transmitted deflection lights.

  The deflecting glasses 7 see the right-eye video (broadcast content, two-dimensional video) 6R derived from the TV program video 2 and the left-eye video (complementary information) 6L derived from the + α video video 3 in a predetermined frame order via the liquid crystal shutter 5. Therefore, the left and right liquid crystal shutters (or different deflecting plates are configured on the left and right sides) are used.

  In the 3D video viewing system 1 shown in FIG. 13, video information of the left-eye video 6L and the right-eye video 6R is projected to the left and right by the deflection glasses 7 using the parallax of the human eye, and is visualized as a 3D video. .

  Next, an outline of the operation of the 3D video viewing system 1 will be described.

  First, the information recording / reproducing apparatus 1001 (or the information recording / reproducing apparatus 1002) caches (temporarily records) the TV program video 2 and the + α moving picture 3 and the TV program video 2 that is the right eye video and the + α moving picture that is the left eye video. 3 is output and input to the display unit 4.

  At this time, when the information interface between the information recording / reproducing apparatus 1001 (or the information recording / reproducing apparatus 1002) and the display unit 4 is an analog system, separate information transmission is required for each of the left and right, but HDMI (high-definition In the case of a digital interface such as a multimedia interface, the left and right information can be serially transmitted alternately.

  Alternatively, the information may be compressed and transmitted on the information recording / reproducing apparatus 1001 (or information recording / reproducing apparatus 1002) side and decompressed (expanded) on the TV side.

  Further, the right-eye video 6R and the left-eye video 6L are displayed by switching the left and right for each field in the case of a normal TV, but if a TV using double scan display is used as the display unit 4, the right-eye video 6R, When the left-eye video 6L is divided into left and right for each field, problems such as flicker can be solved, and smooth 3D video playback is possible.

  Further, as shown in FIG. 13, the liquid crystal shutter 5 capable of switching between two transmitted deflection lights composed of liquid crystal or the like is configured such that the transmitted right eye image 6R is, for example, vertical deflection and the left eye image 6L is lateral deflection. By controlling the liquid crystal shutter 5, the deflection angle of light for each field can be changed.

  In this case, the deflection glasses 7 may be affixed with different left and right deflection plates (vertical deflection and lateral deflection), and a field synchronization signal corresponding to the timing at which the display unit 4 controls the liquid crystal shutter 5 via the cable 4A. Is not required for supplying the light from the display unit 4 to the deflection glasses 7.

  On the other hand, when the liquid crystal shutter 5 is not used, it is necessary to provide a liquid crystal shutter on the deflection glasses 7, and the field synchronization signal cable 4B is required.

  As described above, when the liquid crystal shutter of the deflecting glasses 7 is used, since the deflecting light is not used, even if the angle of the glasses such as tilting the neck changes, the influence on the 3D image can be suppressed to a small extent.

  Next, an outline of main functions of the 3D video viewing system 1 will be described based on FIGS. 2A and 2B and FIGS.

  The main playback functions (playback methods) of the 3D video viewing system 1 are as follows.

  Here, it is assumed that the TV program P has already been recorded in the content recording area 40A of the optical disc 200 or the optical disc 201.

  First, as shown in FIG. 14, when the TV program P is recorded in the content recording area 40A, the information recording / reproducing apparatus 1001 includes left-eye video creation complementary information L1 to L4 related to the TV program P. Is read out from the first information recording area 20A and recorded in the memory (temporary recording unit) 116 (temporary recording step).

  Next, the right-eye video information R1 to R4... Recorded in the content recording area 40A, the left-eye video creation complementary information L1 to L4. And the read right-eye video information R1 to R4 and the left-eye video creation complementary information L1 to L4... Are arranged so as to be reproduced as 3D video according to the 3D data arrangement information. 3D video is played back (playback process).

  In the above description, the case where 3D video is reproduced and displayed has been described, but the display unit 4 of the 3D video viewing system 1 is 1 when the TV program video 2 and the + α moving image 3 for each frame are sequentially input. It has a function capable of displaying a 3D image for each frame.

  Thereby, the left-eye video creation complementary information L1 to L4... And the right-eye video information R1 to R4... Can be read from the optical disc 200 or the optical disc 201 and the 3D video can be viewed.

  Next, main recording functions (recording methods) of the 3D video viewing system 1 are as follows.

  Here, in the third information recording area 20B of the optical disc 200 or the optical disc 201, decompression processing software for decompressing (decompressing) the above-mentioned compressed left-eye image creation complementary information L1 to L4. The case where the 3D video viewing system 1 records the TV program P acquired from the outside in 3D (recording method) will be described.

  As shown in FIG. 15, the information recording / reproducing apparatus 1002 starts with a TV program P acquired from the outside, right eye video information R1 to R4... And compressed left eye video creation complementary information L1 to L4. .. and are separated (information separation step).

  Note that the right-eye video information R1 to R4... May be compressed or uncompressed, but in the present embodiment, the left-eye video creation complementary information L1 to L4. It shall be.

  Next, the separated right-eye video information R1 to R4... Adjusts the expansion time difference from the left-eye video creation complementary information (after being compressed by the broadcast data expansion unit 122 when compressed). Therefore, it is recorded in the cache memory 124 (temporary recording process).

  At the same time, the separated compressed left-eye video creation complementary information L1 to L4... Is recorded in advance in the third information recording area 20B, and is preliminarily stored in the 3D-complementary information expansion unit 123 (internal memory: not shown). Or the memory 116 may be used for decompression (decompression process).

  Next, in the 3D data integration unit 125, the right-eye video information R1 to R4... And the left-eye complementary video information L1 to L4. .. Are integrated so as to be reproduced as 3D video (integration process) and recorded in the content recording area 40A (recording process).

  Thereby, the right-eye video information R1 to R4... Separated from the TV program P acquired from the outside, and the compressed left-eye video creation complementary information L1 to L4. The left-eye video creation complementary information L1 to L4... Expanded using a decompression processing program pre-recorded in the third information recording area 20B are arranged so as to be reproduced as 3D video, and the content recording area. 40A can be recorded.

  Next, another recording function of the 3D video viewing system 1 will be described.

  First, as shown in FIG. 14, the information recording / reproducing apparatus 1001 records the TV program P received from the tuner 118 and the 3D data array information read from the third information recording area 20B in the memory 116.

  Next, the information recording / reproducing apparatus 1001 reads out the information for 3D data arrangement from the memory 116, and as shown in FIG. 2A, for each right eye constituting the TV program P so that the 3D video can be easily reproduced. The right-eye video information R1 to R4... Is recorded in the content recording area 40A while recording spaces E1 to E4.

  Next, the left-eye video creation complementary information L1 to L4... Recorded in the first information recording area 20A is read and recorded in the memory 116.

  Next, the left-eye video creation complementary information L1 to L4... And the 3D data arrangement information recorded in the memory 116 are read out, and as shown in FIG. 2B, the recording spaces E1 to E4. The left-eye video creation complementary information L1 to L4 is inserted into and recorded in the content recording area 40A.

  Each function described above may be realized by a reproduction processing program or a recording processing program for causing the control unit 115 (computer) to execute these functions. These programs may be recorded in, for example, the memory 116 or an external hard disk (in the own apparatus).

  As a result, it is possible to cause the control unit 115 to realize the functions described above by reading the reproduction processing program or the recording processing program recorded in the device itself and causing the control unit 115 to read the reproduction processing program.

  Further, the left-eye video creation complementary information recorded in the first information recording area 20A does not have to be actual video data, and may be difference information with respect to the TV program P (right-eye video information). .

  Next, in the case where recording reservation information is recorded in the optical disc 201 or the third information recording area 20B of the optical disc 201, the 3D video viewing system 1 uses the right eye video information R1 to R4 based on the recording reservation information. ... May be recorded in the content recording area 40A.

  As a result, if the reservation recording of the TV program P is troublesome, the optical disc 201 or the optical disc 201 is loaded into the information recording / reproducing apparatus 1001 or the information recording / reproducing apparatus 1002 of the 3D video viewing system 1 before the start of broadcasting of the TV program P. It is possible to automatically create the optical disc 200 or the optical disc 201 on which the TV program P is recorded.

  In addition, when invalidation information is recorded in the invalidation information recording area 40B of the optical disc 200 or the optical disc 201, the 3D video viewing system 1 determines that the recording reservation information corresponding to the invalidation information is invalid, The recording of the TV program P corresponding to the recording reservation information in the content recording area 40A may be canceled.

  Thereby, when the TV program P recorded by the recording reservation information has contents that do not meet the user's expectation, the invalidation information is recorded on the optical disc 200 or the optical disc 201, so that the contents that do not meet the user's expectation. The TV program P can be prevented from being recorded on the optical disc 200 or the optical disc 201, and the convenience for the user can be improved.

  Also, the 3D video viewing system 1 permits 3D conversion using the 3D conversion permission key only when it is confirmed that the 3D conversion permission key is recorded in the third information recording area 20B of the optical disc 200 or the optical disc 201. The recorded TV program P and 3D-complementary information related to the TV program P may be arranged so as to be reproduced as 3D video and recorded in the content recording area 40A.

  Alternatively, the right-eye video information R1 to R4... And the compressed left-eye video creation complementary information L1 to L4... The information R1 to R4... And the left-eye video creation complementary information L1 to L4... Obtained by expanding the compressed left-eye video creation complementary information L1 to L4. The content may be recorded in the content recording area 40A.

  As a result, by using the 3D conversion permission key recorded in advance on the optical disc 200 or the optical disc 201, the information recording in which the legitimate 3D conversion permission key is not recorded is performed using the 3D conversion permission key recorded in advance on the optical disc 200 or the optical disc 201. The 3D conversion of the TV program P to the medium can be made impossible.

  In other words, information indicating that the 3D conversion permission key recorded in advance on the optical disc 200 is permitted to 3D the TV program P acquired from the outside, that is, 3D conversion of the TV program P to the user. Information to be guaranteed.

  Therefore, if the 3D conversion permission key converts the TV program P into 3D using the optical disc 200 recorded in the third information recording area 20B in advance, the user can The TV program P can be converted to 3D with peace of mind.

  Further, the 3D supplement information recorded in the first information recording area 20A of the optical disc 200 in which the 3D conversion permission key is recorded in the third information recording area 20B in advance is surely produced by a broadcasting station or the like. Therefore, it is possible to make the TV program P 3D that matches the user preference according to the service provided by the broadcasting station or the like.

  Next, the configuration and operation of the information recording / reproducing apparatus 1001 and the information recording / reproducing apparatus 1002, which are the main parts of the 3D video viewing system 1, will be described in detail with reference to FIGS.

  First, as shown in FIG. 14, an information recording / reproducing apparatus 1001 includes a memory 116, a timer 117, a tuner 118, a data recording circuit 119, and an operation unit 126 in addition to the components of the reproducing system 100 described above. .

  On the other hand, as shown in FIG. 15, the information recording / reproducing apparatus 1002 is configured to further include a 3D unit (three-dimensional unit) 130 in addition to the components of the information recording / reproducing apparatus 1001. The 3D unit 130 includes an information separation unit (information separation unit) 121, a broadcast data decompression unit 122, a 3D supplementary information decompression unit (decompression processing unit) 123, a cache memory 124, and a 3D data integration unit (recording control unit, array). Processing means) 125 is provided.

  As shown in FIG. 16, the information recording / reproducing apparatus 1001 or the control unit 115 of the information recording / reproducing apparatus 1002 includes a memory control unit (memory control unit, reproduction control unit) 1151, a date / time confirmation unit 1152, and a broadcast station selection unit 1153. , A medium writing control unit (recording control means) 1154, an invalidation information recognition unit 1156, and a disc recognition unit 1157.

  In the following, since it is complicated, a case where the optical disc 200 is loaded into the information recording / reproducing apparatus 1001 or the information recording / reproducing apparatus 1002 will be described. In addition, since the other configuration of the reproduction system 100 is the same as that already described, description thereof is omitted.

  First, the information separation unit 121 shown in FIG. 15 includes (compressed) right-eye video information R1 to R4... From the TV program P transmitted from the tuner 118, and compressed left-eye video creation complementary information L1. To L4... In addition, the TV program P includes the 3D conversion permission key described above, and the information separation unit 121 may separate the 3D conversion permission key and temporarily record it in the authentication condition recording unit 1159.

  Next, the broadcast data decompression unit 122 decompresses the right-eye video information R1 to R4... Separated by the information separation unit 121, and temporarily stores them in the cache memory 124.

  Next, the 3D complementary information expansion unit 123 expands the left-eye video creation complementary information L1 to L4.

  Next, the 3D data integration unit 125 and the right-eye video information R1 to R4... Recorded in the cache memory 124 and the left-eye video creation complementary information L1 to L4 sent from the 3D-complementary information expansion unit 123. Are integrated and arranged so as to be reproduced as 3D video, and transmitted to the control unit 115.

  The 3D unit 130 includes the cache memory 124 as described above, and decompresses the right-eye video information R1 to R4... Separated by the information separation unit 121 when compressed, and cache memory 124. To make a temporary recording.

  As a result, the 3D data integration unit 125 adjusts the time for reading the right-eye video information R1 to R4... Recorded in the cache memory 124, so that the information separation unit 121 causes the right-eye video information R1 to R4. .. And (compressed) left-eye video creation complementary information L1 to L4... And the left-eye video creation complementary information L1 to L4 compressed by the 3D-ized complementary information decompression unit 123. It is possible to adjust the time difference that occurs between the point in time when the extension is completed.

  In the information recording / reproducing apparatus 1001 in which the 3D data integration unit 125 does not exist, the right-eye video information R1 to R4... Is transmitted to the control unit 115 via the tuner 118.

  Next, the memory control unit 1151 shown in FIG. 16 records recording reservation information related to the TV program P reproduced from the third information recording area 20B of the optical disc 200, and a medium identification number (which will be described below) acquired by the disc recognition unit 1157. Control for storing correspondence information (for example, correspondence table, not shown) indicating the correspondence between the disc identification number) and the recording reservation information is performed.

  In addition, the memory control unit 1151 reads out the stored recording reservation information and correspondence information, or notifies the invalidation information recognition unit 1156 described below that invalidation information has been recognized (invalidation information recognition notification). In response to this, the recording reservation information recorded in the memory 116 is deleted, and exchanges between the memory 116 and other components are controlled.

  Further, the memory control unit 1151 stores the left-eye video creation complementary information sent from the right-eye video information R1 to R4,... L1 to L4... Are read, 3D video is generated, and a function of outputting to the display unit 4 is also provided.

  Next, the date and time confirmation unit 1152 is linked with the timer 117, and the current date and time when the reservation date and time (reservation date and time information) is extracted from the output signal from the timer 117 among the recording reservation information recorded in the memory 116. It is determined whether or not it matches the information (current date and time information) indicating, and if it matches, that fact is transmitted to the memory control unit 1151 and the like.

  The memory control unit 1151 receives the notification that the reservation date / time information matches the current date / time information, and receives the TV program P (right-eye video information R1 to R1) received via the tuner 118 or the 3D data integration unit 125. R4... And / or left-eye video creation complementary information L1 to L4.

  Next, the broadcast station selection unit 1153 is recorded in the memory 116 by the memory control unit 1151 when the date and time confirmation unit 1152 determines that the reserved date and time match the current date or time, or a few minutes before that. Based on broadcast local presence information (for example, reception frequency) indicating the location of the broadcast station where the reserved TV program P is broadcast among the recording reservation information, the tuner 118 is operated to adjust the reception frequency, etc. The TV program P from the broadcasting station can be received.

  Next, the medium writing control unit 1154, for the right-eye video information R1 to R4..., The left-eye video creation complementary information L1 to L4. Read information. Further, the medium writing control unit 1154 shows the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4... According to the 3D data arrangement information shown in FIG. Then, the data are transmitted to the control unit 115 and the data recording circuit 119.

  Further, when an instruction to cancel recording is input via the operation unit 126, the medium writing control unit 1154 drives the data recording circuit 119 and the like to invalidate information in the invalidation information recording area 40B of the optical disc 200. Are recorded, and control such as writing of data to the optical disc 200 is performed. Further, the present invention is not limited to the left one, but also when other external input information (for example, information from a camcorder) is input. Information is transmitted to the data recording circuit 119.

  When the invalidation information recognition unit 1156 does not recognize the invalidation information, the invalidation information recognition unit 1156 drives the memory control unit 1151 (or may be configured to transmit a notification that the invalidation information has not been recognized). In the case where various processes such as reception of the TV program P are performed or invalidation information is recognized, a notification to that effect (invalidation information recognition notification) is transmitted to the memory control unit 1151, and “invalidation” is performed. It controls the exchanges with other components related to “information”.

  The disc recognizing unit 1157 recognizes (detects) whether or not the optical disc 200 is loaded in the information recording / reproducing apparatus 1001 or the information recording / reproducing device 1002, and when the optical disc 200 is loaded, drives the memory control unit 1151. Thus, the medium identification number is acquired from the optical disc 200, or the medium identification number is transmitted to the invalidation information recognition unit 1156 or the like.

  Further, when invalidation information is recorded on the optical disc 200, the disc recognition unit 1157 transmits invalidation information to the invalidation information recognition unit 1156, or when invalidation information is not recorded on the optical disc 200. For example, the memory control unit 1151 is directly driven to control various processes related to loading / unloading of the optical disc 200.

  Next, a case where the medium writing control unit 1154 has an authentication function will be described with reference to FIG.

  In this case, the medium writing control unit 1154 includes an authentication unit 1158, an authentication condition recording unit 1159, a decryption unit 1160, and a write instruction unit 1161.

  The TV program P described above includes a 3D conversion permission key and compressed left-eye video creation complementary information L1 to L4... As attached information. Further, it is assumed that the compressed left-eye video creation complementary information L1 to L4... Is further subjected to encryption processing.

  The authentication unit 1158 reads the 3D conversion permission key that is separated from the TV program P by the information separation unit 121 and temporarily stored in the authentication condition recording unit 1159, and is recorded in the third information recording area 20B of the optical disc 200. It is confirmed whether or not it matches the permission key, and authentication is performed as to whether or not the information recording medium is permitted to make the TV program P 3D.

  In the present embodiment, the “authentic 3D conversion permission key” acquired from the data broadcast corresponding to the TV program P is recorded in the authentication condition recording unit 1159. In addition, the “key” is acquired from data such as program information corresponding to the TV program P in the electronic program guide (EPG), bar code information corresponding to the TV program P published in a TV program introduction magazine, and the like. It may be a thing.

  Further, when the optical disc 200 or the optical disc 201 is purchased, when the user enters a state in which the user can know a valid 3D conversion permission key and the user inputs the valid 3D conversion permission key via the operation unit 126, the TV program P You may allow 3D.

  Next, when the authentication unit 1158 authenticates that the optical disc 200 is an information recording medium licensed for 3D conversion of the TV program P, is the decryption unit 1160 transmitted from the 3D conversion complementary information expansion unit 123? Alternatively, the encrypted left-eye video creation complementary information L1 to L4... Recorded in the memory 116 is decrypted and recorded in the memory 116 again.

  The write instructing unit 1161 instructs the data recording circuit 119 and the like, and the left-eye video creation complementary information L1 to L4... And the right-eye video information R1 to R4 decoded by the decoding unit 1160 read from the memory 116. .. And 3D data arrangement information is read out, and the TV program P is recorded in the content recording area 40A of the optical disc 200 in accordance with the 3D data arrangement information as shown in FIG.

  Next, the flow of the recording operation (recording operation) of the 3D video viewing system 1 will be described based on the flowchart of FIG.

  In step S11 (hereinafter, “step” is omitted), the user loads the optical disc 200 in the information recording / reproducing apparatus 1001 or the information recording / reproducing apparatus 1002, and proceeds to S12.

  In S12, when the disc recognition unit 1157 receives an output (disc loading signal) from a disc detection unit (medium detection means) (not shown), “medium detection notification” indicating that the optical disc 200 is loaded in the memory control unit 1151. And proceeds to S13. At this time, the “medium detection notification” is also notified to the invalidation information recognition unit 1156.

  In S13, when the memory control unit 1151 receives the “medium detection notification” from the disk recognition unit 1157, the data reproduction circuit 110 and the like are driven to control data (OPC processing: A step of Optimum Power) from the lead-in area of the optical disk 200. Information necessary for control and defect management processing) is read and recorded in the memory 116, and the process proceeds to S14.

  In S14, when the invalidation information recognition unit 1156 receives the “medium detection notification” from the disc recognition unit 1157, the data reproduction circuit 110 or the like is driven to reserve reservation invalidation information (invalidation information in the invalidation information recording area 40B of the optical disc 200). Is recorded, the “reservation cancellation notification” is notified to the memory control unit 1151, and the process proceeds to S15.

  In S15, when the invalidation information recognition unit 1156 reads the reservation invalidation information by driving the data reproduction circuit 110 or the like, “YES” is determined, and the process proceeds to S24.

  In S24, the disc recognition unit 1157 reads the medium identification information (disc identification information) from the optical disc 200 inserted by driving the data reproduction circuit 110 and the like, and matches the medium identification number recorded in the memory 116. In this case, “YES” is determined, the disk recognition unit 1157 notifies the memory control unit 1151 of “medium match notification”, and the process proceeds to S25.

  On the other hand, if the medium identification information and the medium identification number recorded in the memory 116 do not match in S24, "NO" is determined and the process proceeds to S26. In S26, the state waits for an input from the operation unit 126 and becomes “END”.

  In S25, the memory control unit 1151 receives the “medium match notification” from the disk recognition unit 1157, and the correspondence information (for example, correspondence table) indicating the correspondence between the medium identification number recorded in the memory 116 and the recording reservation information. ), The recording reservation information corresponding to the inserted optical disk 200 is erased from the memory 116, and the process proceeds to S26. In S26, the state waits for an input from the operation unit 126 and becomes “END”.

  On the other hand, if the invalidation information recognizing unit 1156 does not read the reservation invalidation information in S15, “No” is determined, and the process proceeds to S16.

  In S16, the memory control unit 1151 reads the recording reservation information recorded in the third information recording area 20B of the optical disc 200, records it in the memory 116, and proceeds to S17.

  In S17, if the memory control unit 1151 has not read the recording reservation information, “No” is determined and the process proceeds to S26. In S26, the state waits for an input from the operation unit 126 and becomes “END”.

  On the other hand, if the memory control unit 1151 reads the recording reservation information, the determination is YES, and the process proceeds to S18.

  In S18, the memory control unit 1151 confirms whether or not the TV program P corresponding to the recording reservation information is already recorded in the content recording area 40A of the optical disc 200.

  Thereafter, if the TV program P has already been recorded on the optical disc 200, the memory control unit 1151 determines “YES” and proceeds to S26. In S26, the state waits for an input from the operation unit 126 and becomes “END”.

  On the other hand, if the TV program P has not yet been recorded on the optical disc 200 in S18, the memory control unit 1151 becomes “No” and proceeds to S19.

  In S 19, the date confirmation unit 1152 extracts the “current date” from the output signal from the timer 117, and the “current date” is the “reservation date” included in the recording reservation information recorded in the memory 116. If it has not elapsed, the memory control unit 1151 is notified of a “content acquisition command”.

  Upon receiving the “content acquisition command”, the memory control unit 1151 indicates to the broadcast station selection unit 1153 the location of the broadcast station that is scheduled to broadcast the TV program P corresponding to the reservation information among the recording reservation information. Information such as program frequency is transmitted.

  Upon receiving information such as the program frequency, the broadcast station selection unit 1153 adjusts the reception frequency of the tuner 118 to the program frequency so that the TV program P can be received at any time from a communication unit (communication control means) (not shown).

  In the case of the information recording / reproducing apparatus 1001, the tuner 118 thereafter notifies the medium writing control unit 1154 of a “reception availability notification” that is information indicating that the communication unit can communicate.

  On the other hand, in the case of the information recording / reproducing apparatus 1002, the tuner 118 notifies the information separating unit 121 of a “reception availability notification” that is information indicating that the communication unit can communicate.

  Next, in the case of the information recording / reproducing apparatus 1001, when the medium writing control unit 1154 receives the “reception availability notification” from the tuner 118, the medium writing control unit 1154 enters a standby state until reaching the reservation date and time (reservation standby state), and proceeds to S20.

  In S20, the medium writing control unit 1154 displays the recording reservation information (FL: Fluorescent Lighting) on a display unit (not shown), and proceeds to S21.

  In S21, if the user has input an intention to cancel the reservation via the operation unit 126, “YES” is determined, and the process proceeds to S26. In S26, the state waits for an input from the operation unit 126 and becomes “END”.

  On the other hand, if it is determined in S21 that the user does not input an intention to cancel the reservation via the operation unit 126, the determination is “NO”, and the process proceeds to S22.

  In S 22, the date and time confirmation unit 1152 extracts “current date and time” from the output signal from the timer 117, and the “current date and time” is the “reservation date and time” included in the recording reservation information recorded in the memory 116. If they do not match, or if the “current date and time” is not a few minutes before the “reservation date and time”, “NO” is returned and the process returns to S21.

  On the other hand, in S 22, the date and time confirmation unit 1152 extracts “current date and time” from the output signal from the timer 117, and the “current date and time” is included in the recording reservation information recorded in the memory 116. "3D preparation instruction" is notified to the memory control unit 1151 a few minutes before. Next, in response to the “3D preparation instruction”, the memory control unit 1151 drives the data reproduction circuit 110 and the like, and the 3D data arrangement information and the 3D conversion permission key are stored in the third information recording area 20B of the optical disc 200. Are read, recorded in the memory 116, left-eye video creation complementary information L1 to L4... In the first information recording area 20A, and decompression processing software in the third information recording area 20B. Are recorded and recorded in the memory 116 or the like, and a “3D preparation completion notification” is notified to the date and time confirmation unit 1152.

  Next, the date confirmation unit 1152 extracts the “current date” from the output signal from the timer 117, and the “current date” is included in the recording reservation information recorded in the memory 116. When the date and time match, the medium writing control unit 1154 is notified of “date and time match notification”, and the process proceeds to S23.

  In S23, in the case of the information recording / reproducing apparatus 1001, the medium writing control unit 1154 receives the “date and time coincidence notification” from the date and time confirmation unit 1152, and receives the TV program P (right-eye video corresponding to the recording reservation information via the tuner 118). Information R1 to R4... Are received, and the received right-eye video information R1 to R4.

  On the other hand, in the case of the information recording / reproducing apparatus 1002, the TV program P is transmitted to the information separation unit 121 via the tuner 118.

  Next, in the information separation unit 121, the TV program P is separated into (compressed) right-eye video information R1 to R4... And compressed left-eye video creation complementary information L1 to L4. .. Are transmitted to the broadcast data decompression unit 122, and after decompression processing, are stored in the cache memory 124 in order to adjust the decompression time difference with the left-eye image creation complementary information. To be recorded.

  At the same time, the compressed compressed left-eye video creation complementary information L1 to L4... Is transmitted to the 3D supplementary information decompression unit 123, and the 3D supplementary information decompression unit 123 preliminarily stores the When the 3D-complementary information expansion unit 123 includes a memory, the expansion processing software recorded in the memory) is read, and the compressed left-eye video creation complementary information L1 to L4. The expanded left-eye video creation complementary information L1 to L4... Is sent to the 3D data integration unit 125.

  Next, the 3D data integration unit 125 decompresses the right-eye video information R1 to R4... Reproduced in synchronization with the cache memory 124 in accordance with the 3D data arrangement information recorded in the memory 116 in advance. The left-eye complementary video information L1 to L4... Are integrated and arranged so as to be reproduced as 3D video, and are transmitted to the medium writing control unit 1154 or temporarily recorded in the memory 116.

  As described above, the transfer rate of the TV program P (main broadcast) is about 15 Mbps, and the transfer rate of the data broadcast including 3D supplementary information is about 2 Mbps. Is different.

  Next, in the case of the information recording / reproducing apparatus 1001, the medium writing control unit 1154 first reads the right-eye video information R1 to R4... And the 3D data arrangement information recorded in the memory 116, and the right-eye video information is read out. Information R1 to R4... Is recorded in the content recording area 40A of the optical disc 200 while leaving recording spaces E1 to E4... As shown in FIG.

  Next, the medium writing control unit 1154 reads the left-eye video creation complementary information L1 to L4... Recorded in the memory 116, as shown in FIG. The left eye image creation complementary information L1 to L4... Is inserted in the positions of the recording spaces E1 to E4... And recorded in the content recording area 40A of the optical disc 200 as “END”. Become.

  On the other hand, in the case of the information recording / reproducing apparatus 1002, the medium writing control unit 1154 directly receives the 3D video data transmitted from the 3D data integration unit 125 or recorded in the memory 116 and subjected to the 3D data arrangement shown in FIG. As shown in b), the content is recorded (recorded) in the content recording area 40A of the optical disc 200 and becomes “END”.

  In this embodiment, the right-eye data information when the 3D data arrangement information is alternately arranged with the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4. The video information R1 to R4... And the left-eye video creation complementary information L1 to L4... Are described as data provided for array processing, such as recording start positions and recording end positions. .

  In this case, the recording end position of the right-eye video information R1 may be set as the recording start position of the recording space E1, and the recording start position of the right-eye video information R2 may be set as the recording end position of the recording space E1.

  However, when the 3D data array processing information is 3D data array processing software (array processing information), the control unit 115 reads the 3D data array processing software. Then, the control unit 115 activates the 3D data arrangement processing software, drives the data recording circuit 119, etc., and records the right-eye video information R1 to R4... And 3D data arrangement information recorded in the memory 116. , And the compressed left eye image creation complementary information L1 to L4... Are decompressed by the decompression processing software, and according to the 3D data arrangement information, as described above, FIG. 2 (a) and FIG. 2 (b). And recording (recording) in the content recording area 40A of the optical disc 200 is executed.

  Next, the flow of the reproduction operation of the 3D video viewing system 1 will be described based on the flowchart of FIG.

  First, in step S41, the user loads the optical disc 200 in the information recording / reproducing apparatus 1001, and proceeds to S42.

  In S42, when the disc recognition unit 1157 of the information recording / reproducing apparatus 1001 receives an output from a disc detection unit (not shown), it transmits a “medium detection notification” indicating that the optical disc 200 is loaded to the memory control unit 1151. Proceed to S43.

  In S43, upon receiving “medium detection notification” from the disc recognition unit 1157, the memory control unit 1151 drives the data reproduction circuit 110 and the like to read control data from the lead-in area of the optical disc 200 and record it in the memory 116.

  Further, the memory control unit 1151 reads the left-eye video creation complementary information L1 to L4... From the first information recording area 20A and the 3D data array information from the third information recording area 20B and records them in the memory 116. Then, the process proceeds to S44.

  In S44, the memory control unit 1151 confirms whether or not the TV program P is already recorded in the content recording area 40A of the optical disc 200.

  Thereafter, if the TV program P has already been recorded on the optical disc 200, the memory control unit 1151 determines “YES” and proceeds to S45.

  In S45, the memory control unit 1151 reads the right-eye video information R1 to R4..., The left-eye video creation complementary information L1 to L4..., And the 3D data arrangement information from the memory 116. move on.

  Next, in S46, the memory control unit 1151 arranges the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4 as shown in FIG. In synchronization, the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4... Are output to the display unit 4 as the TV program video 2 and + α moving image video 3, respectively. 3D video is played and becomes “END”. Note that the output destination of the 3D video may be an external hard disk drive (HDD) instead of the display unit 4.

  On the other hand, if the TV program P has not already been recorded on the optical disc 200 in S44, the memory control unit 1151 sets “NO” and proceeds to S47.

  In S47, the state waits for input from the operation unit 126 and becomes “END”.

  In this embodiment, the right-eye data information when the 3D data arrangement information is alternately arranged with the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4. The video information R1 to R4... And the left-eye video creation complementary information L1 to L4... Are described as data provided for array processing, such as recording start positions and recording end positions. .

  However, when the 3D data arrangement information is 3D data arrangement processing software, the control unit 115 reads the 3D data arrangement processing software. Then, the control unit 115 activates the 3D data arrangement processing software, drives the memory control unit 1151 and the like, and the right-eye video information R1 to R4. The information L1 to L4... And the 3D data arrangement information are read, and synchronization is performed while arranging them as shown in FIG. 2B according to the 3D data arrangement information. By such operations, the right-eye video information R1 to R4... And the left-eye video creation complementary information L1 to L4. Output and play 3D video.

  Next, the flow of the authentication operation of the 3D video viewing system 1 will be described based on the flowchart of FIG. Here, it is assumed that the left-eye video creation complementary information L1 to L4... In the first information recording area 20A are encrypted and recorded.

  First, the process proceeds from S22 or S44 to S31.

  In S31, the authentication unit 1158 reads the 3D conversion permission key recorded in the memory 116, confirms whether or not the 3D conversion permission key matches the one recorded in the authentication condition recording unit 1159. If it does, the 3D conversion permission key is determined to be “valid”, and if it does not match, it is determined to be “invalid”.

  Here, if the authentication unit 1158 determines that the 3D conversion permission key is “valid”, the determination is “YES”, the fact is notified to the decryption unit 1160, and the process proceeds to S32.

  In S32, the decoding unit 1160 reads the left-eye video creation complementary information L1 to L4... Recorded in the memory 116, decodes them, and again creates the decoded left-eye video in the memory 116. .. Are recorded and notified to the write instruction unit 1161 or the memory control unit 1151.

  In S32, the write instruction unit 1161 or the memory control unit 1151 records the right-eye video information R1 to R4... Recorded in the memory 116, the decoded left-eye video creation complementary information L1 to L4. The 3D data arrangement information is read, and 3D conversion is started according to the 3D data arrangement information, and the process proceeds to S23 or S45.

  On the other hand, if the authentication unit 1158 determines that the 3D permission key is “invalid” in S31, “NO” is determined, and the process proceeds to S26 or S47.

  The present invention can also be expressed as follows.

  That is, the information recording medium of the present invention may be a combination disk (multilayer optical information recording medium comprising a ROM layer and an RE layer or an R layer).

  Further, a + α moving image (complementary information) for converting the 2D video to be recorded in the RE layer into 3D may be recorded in the ROM layer.

  Moreover, the usage method of an information recording medium may be as follows.

  First, a user records 2D video from a TV broadcast (broadcast content) or the like on the RE layer.

  In the case of 3D playback, the + α moving image is played from the ROM layer and recorded in a cache (temporary recording memory) by a dedicated information recording / playback apparatus that can handle 3D.

  Thereafter, the RE layer is reproduced, and the 2D video and the + α moving image are combined and output to the 3D compatible TV.

  In addition, information is recorded so that 3D video can be output in an easy-to-display format such that the recorded TV broadcast is finally 2D, + α, 2D, + α,... (2D + α is one frame) on the RE layer. For recording, it is performed only at a predetermined 2D data position.

  Next, the + α moving image of the ROM layer is temporarily recorded in a cache or a hard disk, and then the + α moving image is inserted into a predetermined + α data position in the RE layer to obtain 2D, + α, 2D, + α,・ Record 3D video in a format that is easy to display. The recording processing software for the RE layer may be recorded on the ROM layer or may be recorded on a predetermined recording medium in the information recording / reproducing apparatus.

  The ROM layer also includes expansion processing software for data broadcasting (assuming that data for converting 3D TV broadcasting into a compressed format) is broadcast simultaneously with TV broadcasting (2D video). Also good.

  Further, although it is separated from the combination disc, the decompression processing software may be recorded in the information recording / reproducing apparatus. In this case, it is possible to substantially view the 3D broadcast by performing the chasing reproduction. become.

  Note that the ROM layer may include software that pseudo-converts 2D video into 3D and software that pseudo-converts 2D photo data into 3D for a 3D photo frame.

  The present invention can also be expressed as follows.

  The disc structure (see FIGS. 1, 3 and 4) of the information recording medium of the present invention may be as follows.

  (1) An RE layer, an intermediate layer made of a transparent resin, a ROM layer, and a cover layer are sequentially laminated on the substrate.

  (2) A + α moving image for converting a 2D video of a predetermined TV program scheduled to be broadcast into 3D is recorded in the data area of the ROM layer.

  (3) Reservation information for recording a predetermined TV program in the RE layer may be recorded in the ROM layer.

  (4) The recording position for + α is a space so that a predetermined TV program is recorded in an area that is easy to perform 3D playback of the RE layer, for example, 2D, + α, 2D, + α,. In this way, arrangement processing software for enabling recording of + α moving image may be recorded.

  (5) A 3D conversion permission key that permits editing of 2D TV broadcasts into 3D video may be recorded in the ROM layer.

  The structure of the information recording / reproducing apparatus of the present invention (see FIGS. 13 to 17) may be as follows.

  (1) It has at least an information recording / reproducing mechanism (recording / reproducing circuit group) and a cache or a hard disk.

  (2) When 3D playback of a recorded TV program is performed, the + α moving image recorded in the ROM layer of the information recording medium is temporarily recorded in a cache or a hard disk, and then 3D compatible with playback information from the RE layer There is a function to output to TV.

  (3) Or, according to the arrangement processing software recorded from the beginning on the ROM layer or the device itself, the TV broadcast is recorded for + α so that the information is recorded in an arrangement that can output 3D video in an easy-to-display format. Record while leaving space. Thereafter, the + α moving image recorded in the ROM layer of the information recording medium is automatically recorded temporarily in a cache or a hard disk, and then recorded in the + α recording space of the RE layer of the information recording medium.

  Further, the information recording / reproducing apparatus (3D compatible TV) of the present invention may have a function capable of displaying 3D video when 2D video for each frame and + α moving image video are sequentially input.

  The basic operation of this 3D-compatible TV may be as follows.

  (1) A user loads the information recording medium into an information recording / reproducing apparatus corresponding to the information recording medium.

  (2) The information recording / reproducing apparatus recognizes that the RE layer is empty by reproducing the management information on the inner periphery, for example.

  (3) The information recording / reproducing apparatus reads reservation information recorded in the ROM layer (when recorded in the ROM layer).

  (4) It is determined by a clock provided in the information recording / reproducing apparatus whether or not the present time is the date and time when it is necessary to perform reserved recording.

  (5) If it is not the recording time, the information recording / reproducing apparatus enters the reserved recording standby state according to the reservation information.

  (6) When broadcasting is started, a program is recorded in the recording area of the information recording medium based on the reservation information.

  (7) When the information recording medium is reproduced after the recording, the + α moving image recorded in the ROM layer is first temporarily recorded in the cache or hard disk according to the user's selection.

  (8) After that, the content recorded on the RE layer of the information recording medium is reproduced by the information recording / reproducing mechanism of the information recording / reproducing apparatus, and the + α moving image recorded on the cache or the hard disk is output in conjunction with the reproduction. As a result, the 3D video is output to the 3D compatible TV. There may be an authentication operation for permitting 3D editing using the 3D conversion permission key of the ROM layer at the time of reproduction.

  The 3D-compatible TV may have operations other than the following basic operations in addition to the basic operations.

  (A) During the recording of the basic operation (6), information is recorded in an array that can output 3D video in a format that can be easily displayed in accordance with the array processing software recorded in the ROM layer or the device itself from the beginning. As such, the TV broadcast is recorded while leaving a recording space for + α. After that, the + α moving image recorded in the ROM layer of the information recording medium may be temporarily recorded in a cache or a hard disk and then recorded in the + α recording space of the RE layer of the information recording medium.

  In this case, it is not necessary to perform the basic operations (7) and (8), and 3D data is output only by reproducing the RE layer of the information recording medium (for example, a 3D BD-ROM compatible player). 3D playback becomes possible.

  (B) Recording the TV broadcast on the RE layer in (B) is temporarily recorded on the cache or the hard disk, and then the + α moving image recorded on the ROM layer is further temporarily recorded on the cache or the hard disk. In order to facilitate 3D output to a layer, it may be arranged and recorded as 2D, + α, 2D, + α.

  (C) The reservation information of the basic operation (3) may be in a format input by the user.

  The present invention can also be expressed as follows.

  The disc structure (see FIGS. 1, 3 and 4) of the information recording medium of the present invention may be as follows.

  (1) An RE layer, an intermediate layer made of a transparent resin, a ROM layer, and a cover layer are sequentially laminated on the substrate.

  (2) Decompression processing software (decompression processing software) capable of decompressing (decompressing) the compressed data of the + α moving image broadcast as data broadcast is recorded in the data area of the ROM layer.

  (3) A 3D conversion permission key for permitting 3D editing of 2D TV broadcasts may be recorded in the ROM layer.

  The structure of the information recording / reproducing apparatus of the present invention (see FIGS. 13 to 17) may be as follows.

  (1) There are at least an information recording / reproducing mechanism and a cache or a hard disk.

  (2) There is a mechanism for dividing a TV broadcast into a main broadcast portion and a data broadcast, and a route for processing each for recording after the TV broadcast is divided.

  (3) There is a decompression mechanism for at least temporarily recording the decompressed processing software from the information recording / reproducing apparatus and decompressing compressed data input from the outside.

  (4) There is a cache that can temporarily store data after the data of the main broadcast is decompressed by a decompression mechanism different from the decompression mechanism.

  (5) Data input from two routes for recording is synchronized and arranged in a data arrangement that facilitates 3D playback so that it becomes 2D, + α, 2D, + α... A mechanism for outputting to the mechanism;

  (6) At the time of 3D reproduction, there is a function of reproducing data recorded on the RE layer of the information recording medium and outputting it to an information recording / reproducing apparatus (3D compatible TV).

  Further, the information recording / reproducing apparatus (3D compatible TV) of the present invention may have a function capable of displaying 3D video when 2D video for each frame and + α moving image video are sequentially input.

  The basic operation of this 3D-compatible TV may be as follows.

  (1) A user loads an information recording medium into the information recording / reproducing apparatus corresponding to the information recording medium.

  (2) The information recording / reproducing apparatus recognizes that the RE layer is empty by reproducing the management information on the inner periphery.

  (3) The information recording / reproducing apparatus reads reservation information recorded in the ROM layer (when recorded in the ROM layer).

  (4) It is determined by a clock provided in the information recording / reproducing apparatus whether the current time is the date / time at which the reserved recording is necessary.

  (5) If it is not the recording time, the information recording / reproducing apparatus enters the reserved recording standby state according to the reservation information.

  (6) When the clock provided in the information recording / reproducing apparatus confirms that it is several minutes before the recording time, the information recording / reproducing apparatus reproduces the ROM layer of the information recording medium, and is recorded in the ROM layer. The decompression processing software is recorded in the mechanism of the device structure (3).

  (7) When the broadcast is started, a TV broadcast is input to the information recording / reproducing apparatus based on the reservation information to be recorded on the RE layer of the information recording medium.

  (8) The input TV broadcast is divided into a main broadcast and a data broadcast by the device structure (2), and is output to each recording processing route.

  (9) In this broadcast, data is decompressed by a normal decompression mechanism (it becomes 2D video after decompression) and is temporarily stored in the cache of the device structure (4) (time adjustment based on the difference in compression rate from the data broadcast) .

  (10) In the data broadcasting, the compressed data is expanded by the expansion mechanism of the device structure (3) (after the expansion, the 3D + α moving image is obtained).

  (11) Thereafter, 3D video data (2D, + α, 2D, + α...) Is output to the information recording / reproducing mechanism by the device structure (5).

  (12) The 3D video data input to the information recording / reproducing mechanism according to (11) is sequentially recorded on the RE layer of the information recording medium, and the recording ends when the broadcast ends.

  (13) During 3D playback, the RE layer of the information recording medium is played back, and 3D video data is output to a 3D-compatible TV.

  (14) Further, when recording on the information recording medium, there may be an authentication operation for permitting 3D editing using a 3D conversion permission key of the ROM layer.

  The 3D-compatible TV may have operations other than the following basic operations in addition to the basic operations.

  (A) The decompression processing software recorded in the basic operation (6) may be originally recorded in the information recording / reproducing apparatus.

  (B) The destination to which 3D video data is output in the basic operation (11) may be an HDD or a 3D-compatible TV.

  As described above, a TV program that cannot originally be broadcast in 3D can be substantially viewed as 3D video. In addition, a 3D-compatible disc can be produced from TV broadcasting (it can be rented out to others). Furthermore, it can be used legitimately for editing 3D video of TV broadcasting.

  The present invention can also be expressed as follows.

  The information recording medium of the present invention can read various information having a first information recording area in which the first content is recorded in advance and a second information recording area in which the second content as 2D video information can be recorded. In the information recording medium, the first content may be complementary information for converting the second content into a three-dimensional image.

  In the information recording medium of the present invention, the first information recording area may be an area where only information can be read.

  In the information recording medium of the present invention, the first content and the second content are recorded in the first information recording area in the second information recording area in an array that can be easily output as 3D video information. Information may be recorded.

  In the information recording medium of the present invention, recording reservation information for recording the second content in the second information recording area may be recorded in the first information recording area.

  The information recording medium reproduction method of the present invention is a reproduction method for reproducing the information recording medium, and at the time of three-dimensional video reproduction, the first content recorded in the first information recording area first is recorded. Recording is performed by reproducing the step of recording on a temporary recording medium provided in the playback device, the first content output from the temporary recording medium, and the second content recorded in the second information recording area. It may consist of the process of synchronizing with the 2nd contents and outputting outside.

  The information recording medium recording / reproducing apparatus of the present invention may have a program for executing the reproducing method.

  In addition, the information recording medium of the present invention can read various information having a first information recording area in which the first content is recorded in advance and a second information recording area in which the second content as 2D video information can be recorded. The first content may be a program for decompressing complementary information for converting the compressed second content into a three-dimensional video.

  In the information recording medium of the present invention, the first information recording area may be an area where only information can be read.

  In the information recording medium of the present invention, the first content and the second content are recorded in the first information recording area in the second information recording area in an array that can be easily output as 3D video information. Information may be recorded.

  The recording method of the present invention is a recording method for recording on the information recording medium, wherein the external input data is separated into two-dimensional video information and complementary information for converting the two-dimensional information into a three-dimensional video. A step of recording the 2D video information on a temporary recording medium in the recording / reproducing apparatus, a step of expanding the compression of the complementary information, the expanded complementary information, and a 2D video output from the temporary recording medium The information may be recorded on an information medium in an array that facilitates 3D video reproduction by synchronizing with the information.

  In addition to the above configuration, the information recording / reproducing apparatus of the present invention further includes an input unit for inputting an instruction to cancel recording of the broadcast content in the second information recording area, via the input unit. When the instruction to cancel the recording is input, the invalidation information may be recorded in the second information recording area.

  As a result, when the broadcast content recorded by the reservation information is not in accordance with the user's expectation, the invalidation information is recorded on the information recording medium of the present invention, so that the content not in accordance with the user's expectation is recorded. Broadcast content can be prevented from being recorded on an information recording medium, and user convenience can be improved.

  In addition to the above configuration, the information recording / reproducing apparatus of the present invention may further include the reservation information recorded in the first information recording area of the information recording medium and the reservation when there are a plurality of the information recording media. A recording unit that records correspondence information indicating a correspondence relationship between information and the information recording medium, and when the invalidation information is recorded in the second information recording area of the information recording medium, Based on the correspondence information, the reservation information corresponding to the information recording medium may be erased from the recording unit.

  As a result, the reservation information corresponding to the information recording medium in which the invalidation information is recorded is erased from the recording unit, so that broadcast content having contents that do not meet the user's expectation is mistakenly recorded on the information recording medium. It is possible to prevent erroneous operations such as

  Also, with the above configuration, the information recording / reproducing apparatus of the present invention does not recognize the reservation information corresponding to the broadcast content that does not meet the user's expectation and is recorded on the information recording medium on which the invalidation information is recorded. Therefore, the second information recording area where the broadcast content is scheduled to be recorded can be recognized as a recording area where normal recording is possible.

  Therefore, the second information recording area corresponding to the reservation information can be diverted for recording other contents.

  Finally, each block of the information recording / reproducing apparatus 1001 and the information recording / reproducing apparatus 1002 constituting the 3D video viewing system 1, in particular, the control unit 115 may be configured by hardware logic, and uses a CPU as follows. It may be realized by software.

  That is, the information recording / reproducing apparatus 1001 and the information recording / reproducing apparatus 1002 constituting the 3D video viewing system 1 are a CPU (central processing unit) that executes a command of a control program that realizes each function, and a ROM (read only memory), a RAM (random access memory) for expanding the program, and a storage device (recording medium) such as a memory for storing the program and various data.

  An object of the present invention is the program code (execution format program, intermediate code) of the control program for the information recording / reproducing apparatus 1001 and the information recording / reproducing apparatus 1002 constituting the 3D video viewing system 1, which is software that implements the functions described above. A recording medium in which a program and a source program are recorded so as to be readable by a computer is supplied to the information recording / reproducing apparatus 1001 and the information recording / reproducing apparatus 1002 constituting the 3D video viewing system 1, and the computer (or CPU or MPU) records the recording medium. This can also be achieved by reading and executing the program code recorded on the medium.

  Examples of the recording medium include a tape system such as a magnetic tape and a cassette tape, a magnetic disk such as a floppy (registered trademark) disk / hard disk, and a compact disk-ROM / MO / MD / digital video disk / compact disk-R. A disk system including an optical disk, a card system such as an IC card (including a memory card) / optical card, or a semiconductor memory system such as a mask ROM / EPROM / EEPROM / flash ROM can be used.

  The information recording / reproducing apparatus 1001 and the information recording / reproducing apparatus 1002 constituting the 3D video viewing system 1 may be configured to be connectable to a communication network, and the program code may be supplied via the communication network. The communication network is not particularly limited. For example, the Internet, intranet, extranet, LAN, ISDN, VAN, CATV communication network, virtual private network, telephone line network, mobile communication network, satellite communication. A net or the like is available. Further, the transmission medium constituting the communication network is not particularly limited. For example, even in the case of wired such as IEEE 1394, USB, power line carrier, cable TV line, telephone line, ADSL line, etc., infrared rays such as IrDA and remote control, Bluetooth ( (Registered trademark), 802.11 wireless, HDR, mobile phone network, satellite line, terrestrial digital network, and the like can also be used. The present invention can also be realized in the form of a computer data signal embedded in a carrier wave in which the program code is embodied by electronic transmission.

  The present invention can also be expressed as follows.

  That is, the information recording medium of the present invention is an information recording medium having a single layer, or a plurality of recording layers from which at least information can be read, to which a plurality of information recording areas are allocated, The recording area includes a first information recording area and a second information recording area. In the first information recording area, complementary information for converting a 2D video content into a 3D video is recorded in advance. The second information recording area may be an area in which the 2D video content related to the complementary information can be recorded.

  According to the above configuration, the information recording medium of the present invention is an information recording medium having a single layer or a plurality of recording layers to which at least information can be read, to which a plurality of information recording areas are allocated. Therefore, if information is recorded in each recording layer, the information can be read out.

  The plurality of information recording areas include a first information recording area and a second information recording area.

  The plurality of information recording areas may include information recording areas other than the first information recording area and the second information recording area.

  Next, regarding the allocation of the first information recording area and the second information recording area, in the case of an information recording medium having a single recording layer, all the information recording areas are allocated to the single recording layer. Will be.

  In the case of an information recording medium having a plurality of recording layers, when the two information recording areas of the first information recording area and the second information recording area are assigned to different recording layers, the first information recording area And two information recording areas of the second information recording area may be assigned to a single recording layer.

  Next, in the first information recording area, for example, complementary information for converting a predetermined 2D video content that is generally distributed and is scheduled to be acquired from the outside by broadcasting or Internet distribution into 3D video is recorded in advance. ing.

  Note that information other than complementary information may be recorded in the first information recording area.

  Further, the second information recording area is an area in which 2D video content related to the complementary information can be recorded.

  Note that information other than the 2D video content may be recorded in the second information recording area.

  According to the above configuration, it is possible to easily record 3D video by converting 2D video content into 3D video by simply recording 2D video content related to (specific) complementary information in the second information recording area. Substantially possible.

  Further, this makes it possible to read complementary information and two-dimensional video content related to the complementary information from the information recording medium of the present invention, so that the three-dimensional video obtained by converting the two-dimensional video content into a three-dimensional video can be read. Viewing is possible.

  Furthermore, since the 2D video content that is generally distributed can be converted into a 3D video, it is not necessary to change the standard or communication method of the 2D video content.

  Therefore, it is possible to easily record and view three-dimensionally without changing the standard or communication method of the two-dimensional video content that is generally distributed.

  In Patent Documents 1 to 3 mentioned above, when a two-dimensional TV is occupied as in the present situation, if a three-dimensional broadcast is performed, it is impossible to view on most TVs. There is no description about a point or a method for obtaining “complementary information” of the present application, which is a solution thereof.

  Incidentally, as described above, the transfer rate of terrestrial digital broadcasting is a maximum of 17 Mbps, and the breakdown of the entire transfer rate is that the transfer rate of the main broadcast is about 15 Mbps, and the transfer rate of the data broadcast is about 2 Mbps. The transfer rate of data broadcasting is about 13% of the main broadcasting.

  Therefore, when converting a terrestrial digital broadcast into a three-dimensional image without increasing the maximum transfer rate, if the transfer rate of the data broadcast (complementary information) is about 2 Mbps, the transfer rate of the main broadcast (broadcast content) is about There is a secondary problem that the image quality of this broadcast is significantly deteriorated because it becomes 6.7 Mbps or less.

  However, according to the information recording medium of the present invention, it is assumed that the broadcast content actually broadcasted (generally two-dimensional video) is used as it is, and it is not necessary to reduce the transfer rate of the main broadcast. Can be recorded and viewed in a three-dimensional manner without deteriorating the above, and the above-mentioned secondary problems do not occur.

  Here, examples of “2D video content” include moving images (including music, audio data, text data such as subtitles), and still images such as images for frame-by-frame playback.

  The data format or data compression scheme for “2D video content” includes Flash (video animation software sold by Macromedia), JPEG (Joint Photographic Experts Group) scheme for still image compression, An example is the Moving Picture Experts Group (MPEG) system for video compression.

  The MPEG system is a standard for compressing / decompressing video and audio, which is recommended as a standard technology by ITU-T (International Telecommunication Union Telecommunication Standardization Sector) and ISO (International Standard). Currently, the MPEG system includes MPEG1 used for media such as a video CD (Compact Disk), MPEG2 used for DVD (Digital versatile disc) and broadcast media, network distribution, and MPEG4 for portable terminals.

  Furthermore, as a delivery method of “2D video content”, Bluetooth (registered trademark), Felica, PLC (power line communication), Wireless LAN (wireless LAN: WLAN), IrDA (infrared wireless), IrSS (infrared wireless), and Examples include distribution by wired or wireless communication such as WCDMA (communication network).

  Examples of “broadcast content” in “2D video content” include NTSC (national television system committee) method, PAL (phase alternation by line) method, SECAM (sequential couleur a memoire system) method, HD- TV (high definition-multiple analogue component), ATV (advanced television), TV broadcasting, dual audio multiplex broadcasting, stereophonic audio multiplex broadcasting, broadcasting satellite (BS) or communication satellite (CS) Satellite broadcasting using radio waves from TV, cable broadcasting TV (cable television: CATV), high definition television (extended definition TV: EDTV), high definition television (high definition TV: HDTV), MUSE system, 1Seg, 3 Examples include broadcasting programs such as Seg and digital terrestrial broadcasting.

  Examples of “complementary information” include pseudo 3D information for pseudo 2D video content to be converted to 3D video, and 2D video content as either right eye video or left eye video. Examples include a left-eye image or a right-eye image.

  That is, “complementary information” for realizing 3D conversion need not be actual video data, and may be differential information for 2D video content (right-eye video or left-eye video), or video data in the first place. The supplemental information for realizing the 3D visualization of the 2D video may be used.

  The information recording medium of the present invention is an information recording medium having a single layer, or a plurality of recording layers from which at least information can be read, to which a plurality of information recording areas are allocated. The recording area includes a first information recording area and a second information recording area. In the first information recording area, compressed complementary information for expanding a 2D video content into a 3D video is expanded. The second information recording area may be an area where the 2D video content related to the compressed complementary information can be recorded.

  According to the above configuration, a decompression processing program for decompressing the compressed complementary information for converting the predetermined 2D video content into a 3D video in the first information recording area is recorded in advance, and The second information recording area is different from the above-described information recording medium only in that the second information recording area is an area where the 2D video content related to the compressed complementary information can be recorded.

  Here, it is assumed that the compressed complementary information is transmitted as data accompanying the 2D video content (for example, data broadcast in the case of broadcast content).

  According to the above configuration, the (specific) 2D video content is recorded in the second information recording area, and the compressed complementary information accompanying the 2D video content is recorded in the first information recording area. By decompressing with a program, it is possible to record 3D video in which 2D video content is easily converted into 3D video.

  In addition, this makes it possible to read the decompression processing program from the information recording medium of the present invention, decompress and read the compressed complementary information, and read the 2D video content related to the compressed complementary information. Therefore, it is possible to view a 3D video obtained by converting 2D video content into a 3D video.

  Furthermore, for example, since it is possible to make a 3D video using a data broadcast accompanying the broadcasting of a 2D video broadcast content, there is no need to change the broadcast format of the broadcast content.

  Therefore, it is possible to easily record and view three-dimensionally without changing the broadcast format of the broadcast content actually broadcast.

  Further, for example, according to the MPEG method described above, if the compression rate is suppressed to about 1/100 to 1/200, complementary information can be compressed without degrading the image quality, and transfer of about 2 Mbps is possible. Data broadcasting at a rate is also possible.

  Therefore, according to the information recording medium of the present invention, it is possible to easily record and view three-dimensionally without changing the standard or communication method of the two-dimensional video content that is generally distributed.

  Here, as an example of “compression method”, DCT (discrete cosine transform) conversion is mainly performed on a pixel-by-pixel basis or a plurality of pixel block units to cut color change data and high-frequency components, and compress still images. The JPEG system that performs the motion compensation process in the time direction and the MPEG system that compresses the moving image can be exemplified.

  Examples of the MPEG system include MPEG1, MPEG2, and H.264. For example, MPEG4 adopted in standards such as H.264, Windows (registered trademark), Quick Time (registered trademark), and DivX (registered trademark) can be exemplified.

  In particular, for example, in the case of 3D video using parallax where the broadcast content is the right-eye video and the complementary information is the left-eye video, image compression by the MPEG method is performed using difference information between the right-eye video and the left-eye video. Preferably it is done. Thereby, the compression rate of 3D video can be increased.

  In the information recording medium of the present invention, the first information recording area may be an area where only information can be read.

  According to the configuration, the first information recording area is an area where only information can be read, that is, an area where writing is impossible, so the complementary information (or information for array processing) is It is possible to prevent an erroneous operation in which another data is overwritten by mistake.

  Further, since information can be recorded at the time of manufacturing the stamper, it is possible to distribute a large amount at a low cost in a short time as compared with the case where information is recorded after the information recording medium is manufactured or information distribution via the Internet or the like.

  In the information recording medium of the present invention, the first information recording area has the two-dimensional video content and the complementary information (or the compressed complementary information expanded) in the first information recording area. Complementary information) may be arranged so as to be reproducible as a three-dimensional video, and array processing information for recording in the second information recording area may be recorded in advance.

  According to the above-described configuration, the 2D video content and the complementary information (or the complementary information obtained by expanding the compressed complementary information) are arranged so as to be easily reproduced as a 3D video using the array processing information. Thus, it is possible to record in the second information recording area.

  Therefore, if the 2D video content and the complementary information (or the complementary information obtained by expanding the compressed complementary information) are arranged and recorded in the second information recording area in this way, the 3D video is recorded. In order to reproduce the data, it is not necessary to read and record the supplementary information from the information recording medium. Therefore, the recording capacity of the memory attached to the information recording / reproducing apparatus corresponding to the information recording medium of the present invention Savings are possible.

  Here, “array processing” means that when there are a plurality of pieces of complementary information, the 2D video content is divided into a plurality of pieces of divided information corresponding to each piece of complementary information. This is a process of inserting complementary information corresponding to the specific divided information between the divided information and alternately arranging the divided information and the complementary information. Through such processing, for example, broadcast content can be recorded so that it can be easily three-dimensionally reproduced.

  The “array processing information” is used for array processing such as the recording start position and the recording end position of each division information and each complementary information when each division information and each complementary information are alternately arranged. The recording space may be a space between a specific division information and the next division information, and each division is performed by inserting complementary information corresponding to the specific division information into the recording space. An array processing program that performs processing for alternately arranging information and each complementary information may be used.

  In the information recording medium of the present invention, reservation information for recording the 2D video content in the second information recording area may be recorded in the first information recording area in advance.

  Thus, for example, if broadcast content reservation information corresponding to complementary information (or compressed complementary information) is recorded at the time of manufacturing the information recording medium, the user can record the broadcast content reservation information by some means. There is no need to record.

  Further, if the information recording / reproducing apparatus corresponding to the information recording medium of the present invention is configured so that the broadcast content can be recorded using the reservation information when broadcasting of the broadcast content is started, the information recording medium is provided. It is possible to record broadcast content in the second information recording area without requiring user operation simply by loading the information recording / reproducing apparatus.

  In the information recording medium of the present invention, the second information recording area includes invalidation information for determining cancellation of recording of the 2D video content corresponding to the reservation information in the second information recording area. May be provided as an invalidation information recording area.

  According to the above configuration, when the 2D video content recorded by the reservation information is not in accordance with the user's expectation, the reservation information is invalidated by the invalidation information, so that the reservation information can be recorded. The recording area used can be diverted to recording of other contents.

  Thus, for example, after the broadcast content corresponding to the reservation information is broadcast, it becomes an information recording medium having a recording area in which only the reservation information is recorded and cannot be diverted to the recording of other content. It can prevent becoming a recording medium.

  Here, the “invalidation information” is information for determining cancellation of recording of the 2D video content corresponding to the reservation information in the second information recording area. For example, when “invalidation information” exists, the recording of the 2D video content corresponding to the reservation information in the second information recording area is not performed, or the reservation information is reserved. The recording area used can be diverted for recording other contents.

  Here, as described above, converting a generally distributed 2D video into a 3D video may correspond to editing of a 2D video.

  Therefore, for example, the 3D visualization of broadcast content has a secondary problem that it may be necessary to consider copyrights and neighboring rights.

  If it does so, the device etc. which a user can convert 2D video into 3D video in peace, without worrying about copyright, copyright right adjacent to a work, etc. are needed.

  Therefore, in the information recording medium of the present invention, permission information indicating that it is permitted to convert the 2D video content into a 3D video may be recorded in the first information recording area in advance.

  According to the above configuration, the license information recorded in advance on the information recording medium is information indicating that the 2D video content acquired from the outside by broadcasting, Internet distribution, or the like is licensed to be converted into a 3D video, That is, the information guarantees to the user that the 2D video content is converted into a 3D video.

  Therefore, if the 2D video content is converted into a 3D video by using the information recording medium in which the permission information is recorded in the first information recording area in advance, without worrying about the copyright or the copyright right, The user can convert the 2D video content into a 3D image with peace of mind.

  Further, the supplementary information recorded in the first information recording area of the information recording medium in which the permission information is recorded in the first information recording area in advance is surely produced by a broadcasting station or a distribution site. Therefore, it is possible to convert the 2D video content that matches the user preference according to the service provision of the broadcasting station or the distribution site into a 3D video.

  Here, “3D visualization” means that 2D video content such as broadcast content and complementary information (or complementary information obtained by expanding compressed complementary information) are reproduced as 3D video, For example, it is arranged and recorded so that it can be reproduced as a three-dimensional video.

  Examples of “permission information” include complementary information (compressed complementary information) or array processing information, a three-dimensional permission key (encryption key) that permits the expansion of compressed complementary information, You can list information about license agreements.

  Further, the information recording medium of the present invention includes a plurality of recording layers, an intermediate layer separating each of the plurality of recording layers, and a light-transmitting layer provided at a position farthest from the substrate on the substrate. And the plurality of recording layers are capable of reading information by reproducing light, and at least one of the plurality of recording layers is a layer from which information can be read, and the other recording layers At least one of the layers is a layer capable of recording information, the first information recording area is allocated to a layer that can only read the information, and the second information recording area can record the information May be assigned to different layers.

  Here, a more preferable structure of the information recording medium of the present invention will be described.

  In recent years, in the technical field of multilayer optical information recording media, in addition to a rewritable recording layer, a recording layer in which various contents are recorded and a playback-only recording layer that can only be played back or additionally can be recorded. There is a need for an optical information recording medium (hereinafter referred to as a hybrid optical information recording medium) in which a recording layer is added to improve the recording capacity.

  Hereinafter, the rewritable recording layer is referred to as an RE (RE-writable) layer, and a read-only layer, that is, a read-only information recording layer is referred to as a ROM (Read Only Memory) layer. Such a recording layer is called an R (Recordable) layer.

  The information recording medium of the present invention is preferably a so-called hybrid optical information recording medium. That is, the information recording medium of the present invention is a layer in which at least one recording layer of the plurality of recording layers can only read information, and at least one of the other recording layers stores information. It may be a recordable layer, and may have a structure in which a translucent layer is provided at a position farthest from the substrate.

  Here, the “layer capable of recording information” includes a layer (R layer) capable of only additional recording and a rewritable layer (RE layer).

  Further, “only additional recording is possible” means that information can be read and only additional recording can be performed in recording.

  In the information recording medium of the present invention having the structure as described above, the first information recording area is allocated to a layer that can only read the information, and the second information recording area can record the information. It is preferable to be assigned to a different layer.

  This is because the second information recording area needs to be recorded in the R layer or the RE layer because it is necessary to record the 2D video content acquired from the outside by broadcasting or Internet distribution.

  Further, by assigning the first information recording area to the ROM layer, it is possible to prevent erroneous operation in which another data is mistakenly overwritten on the pre-recorded complementary information (or information for array processing). it can.

  Furthermore, since supplementary information (or information for sequence processing) can be recorded in advance at the time of manufacturing the information recording medium of the present invention, the user can obtain supplementary information (or information for sequence processing) of broadcast content by some means. There is no need to record on a recording medium, and since complementary information (or information for array processing) is recorded on the ROM layer, there is a recordable area in the second information recording area of the R layer or RE layer in which broadcast content is recorded. There is no shaving.

  As an example of the ROM layer, a case where information is recorded using an embossed prepit row or a case where information is recorded using a laser can be listed.

  Further, since information can be recorded at the time of manufacturing the stamper, it is possible to distribute a large amount at a low cost in a short time as compared with the case where information is recorded after the information recording medium is manufactured or information distribution via the Internet or the like.

  The playback method of the present invention is a playback method for playing back 3D video using the information recording medium, and when the 2D video content is recorded in the second information recording area, The complementary information related to the three-dimensional video content is read from the first information recording area and recorded in the temporary recording memory; the complementary information recorded in the temporary recording memory in the temporary recording step; The 2D video content recorded in the second information recording area is read out, and the read out 2D video content and the supplementary information are arranged so as to be reproduced as 3D video, and synchronized, And a playback step of playing back 3D video.

  The information recording / reproducing apparatus of the present invention is an information recording / reproducing apparatus for recording / reproducing a 3D video using an information recording medium, wherein the 2D video content is recorded in the second information recording area. In addition, the complementary information related to the 2D video content is read from the first information recording area and recorded in the temporary recording memory, and the memory control means records the complementary information in the temporary recording memory. The complementary information and the 2D video content recorded in the second information recording area are read out, and the read out 2D video content and the complementary information are arranged and synchronized so as to be reproduced as a 3D video. And a playback control means for playing back the 3D video.

  Here, it is assumed that 2D video content is recorded in the second information recording area of the information recording medium.

  At this time, in the temporary recording step of the method or the memory control means having the above configuration, the complementary information related to the 2D video content is read from the first information recording area and recorded in the temporary recording memory.

  Next, in the reproduction step of the method or the reproduction control means having the above configuration, the supplementary information recorded in the temporary recording memory in the temporary recording step or by the reproduction control means is recorded in the second information recording area. The 2D video content that has been read is read out, and the broadcast content and the supplemental information that have been read out are arranged so as to be played back as a 3D video, and the 3D video is played back in synchronization.

  Thereby, it is possible to read the complementary information and the two-dimensional video corresponding to the complementary information from the information recording medium and view the three-dimensional video.

  The recording method of the present invention is a recording method for recording information on the information recording medium, wherein information separation is performed to separate the 2D video content and the compressed complementary information from content acquired from the outside. A temporary recording step of recording the 2D video content separated in the information separation step in a temporary recording memory, a decompression step of decompressing the compressed complementary information separated in the information separation step, and the decompression The supplementary information expanded in the process and the 2D video content recorded in the temporary recording memory in the temporary recording process are read, and the 2D video content and the expanded complementary information are reproduced as a 3D video. And a recording step of recording in the second information recording area so as to be arranged.

  The information recording / reproducing apparatus of the present invention is an information recording / reproducing apparatus for recording / reproducing 3D video using the information recording medium, wherein the 2D video content is compressed from the content acquired from the outside and the compressed. Information separating means for separating the complementary information, memory control means for recording the 2D video content separated by the information separating means in a temporary recording memory, and the compressed complement separated by the information separating means Read out the expansion processing means for expanding information, the complementary information expanded by the expansion processing means, and the 2D video content recorded in the temporary recording memory by the memory control means, and read the 2D video content and the expansion A recording system in which the supplementary information is arranged so as to be reproduced as a three-dimensional video and recorded in the second information recording area. It may be provided with the means.

  According to the method or the configuration, in the information separation step or the information separation means, the 2D video content and the compressed complementary information are separated from the content acquired from the outside.

  Next, in the temporary recording step or the memory control means, the 2D video content separated in the information separation step or by the information separation means is recorded in the temporary recording memory.

  Next, in the decompression step or the decompression processing means decompresses the compressed complementary information separated in the information separation step or by the information separation means.

  Next, in the recording step or the recording control means, the supplementary information expanded in the expansion step or by the expansion processing means, and the 2 recorded in the temporary recording memory in the temporary recording step or by the memory control means. The two-dimensional video content is read out, and the two-dimensional video content and the expanded complementary information are arranged so as to be reproduced as a three-dimensional video and recorded in the second information recording area.

  Accordingly, the 2D video content separated from the content acquired from the outside and the complementary information obtained by decompressing the compressed complementary information separated from the content are arranged so as to be reproduced as a 3D video, and the first 2 It becomes possible to record in the information recording area.

  Further, the information recording / reproducing apparatus of the present invention records the 2D video content in the second information recording area based on the reservation information recorded in the first information recording area of the information recording medium. The 2D video content may be recorded in the second information recording area of the information recording medium based on the reservation information recorded in the first information recording area of the recording medium.

  According to the above configuration, if reservation recording of 2D video content acquired from the outside by broadcasting, Internet distribution, or the like is troublesome, for example, the information recording medium of the present invention is used before the broadcast of broadcasting content is started. It is possible to create an information recording medium on which 2D video content acquired from the outside is automatically recorded by broadcasting, Internet distribution, or the like simply by loading the information recording / reproducing apparatus corresponding to the above.

  In the information recording / reproducing apparatus of the present invention, when the invalidation information is recorded in the second information recording area of the information recording medium, the reservation information corresponding to the invalidation information is invalid. It may be determined and the recording of the 2D video content corresponding to the reservation information in the second information recording area may be canceled.

  According to the above configuration, for example, when the 2D video content acquired from the outside by broadcast or Internet distribution recorded by the reservation information is content that does not meet the user's expectation, the invalidation information is the information of the present invention. By recording on the recording medium, it is possible to prevent the two-dimensional video content acquired from the outside by broadcasting or internet distribution of contents not meeting the user's expectations from being recorded on the information recording medium. Can be improved.

  The information recording / reproducing apparatus of the present invention may further include the two-dimensional video content and the complementary information when it is confirmed that the permission information is recorded in the first information recording area of the information recording medium. Are arranged so that they can be reproduced as a three-dimensional video, and it is confirmed that the license information is recorded in the first information recording area of the information recording medium to be recorded in the second information recording area In addition, the 2D video content licensed for 3D video by the license information and the complementary information related to the 2D video content (or the content acquired from the outside, the broadcast content, and the compression Separated supplemental information, and the separated broadcast content and the supplementary information obtained by decompressing the compressed supplemental information can be reproduced as 3D video. Are arranged in, it may be recorded in the second information recording area.

  According to the above configuration, the license information recorded in advance on the information recording medium is information indicating that the 2D video content acquired from the outside by broadcasting, Internet distribution, or the like is licensed to be converted into a 3D video, That is, the information guarantees to the user that the 2D video content is converted into a 3D video.

  Therefore, if the 2D video content is converted into a 3D video by using the information recording medium in which the permission information is recorded in the first information recording area in advance, without worrying about the copyright or the copyright right, The user can convert the 2D video content into a 3D image with peace of mind.

  Further, the supplementary information recorded in the first information recording area of the information recording medium in which the permission information is recorded in the first information recording area in advance is surely produced by a broadcasting station or a distribution site. Therefore, it is possible to convert the 2D video content that matches the user preference according to the service provision of the broadcasting station or the distribution site into a 3D video.

  As described above, in the information recording medium of the present invention, the plurality of information recording areas include the first information recording area and the second information recording area, and the first information recording area (generally distributed). In addition, supplementary information for converting a predetermined 2D video content acquired from the outside by broadcasting or Internet distribution into a 3D video is recorded in advance, and the second information recording area is related to the supplemental information. It may be an area where the 2D video content can be recorded.

  In the information recording medium of the present invention, the plurality of information recording areas include a first information recording area and a second information recording area, and the first information recording area includes (generally distributed and broadcast). And a decompression processing program for decompressing the compressed complementary information for converting the predetermined 2D video content acquired from outside by internet distribution or the like into a 3D video, and recording the second information recording The area may be an area in which 2D video content related to the compressed complementary information can be recorded.

  Therefore, there is an effect that it is possible to easily record and view in a three-dimensional manner without changing the standard and communication method of the two-dimensional video content that is generally distributed.

  Each means, each function, each process, and each step and each step in the information recording / reproducing apparatus, reproducing method, and recording method may be realized by a computer. The information recording / reproducing apparatus, the reproducing method, and the recording method are operated by causing the computer to realize the functions or causing the computer to execute the processes, steps, or steps. An information processing program realized by the above and a computer-readable recording medium on which the information processing program is recorded also fall within the scope of the present invention.

  Further, the present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and the present invention can be obtained by appropriately combining technical means disclosed in different embodiments. Such embodiments are also included in the technical scope of the present invention. For example, left-eye video information for realizing 3D imaging and complementary information such as + α data need not be actual video data, and may be difference information with respect to right-eye video information. It does not have to relate to video information, and may be supplemental information for realizing 3D visualization of 2D video.

  The present invention relates to an optical information recording medium including an optical disc such as a compact disc-ROM, MO, MD, digital video disc, compact disc-R, and Blu-Ray, and an information recording / reproducing apparatus corresponding to the optical information recording medium. Can be widely applied. Further, it can be widely applied to a magnetic recording medium that uses magnetism for recording, a light / heat-assisted magnetic recording medium that performs magnetic recording using light and heat, and an information recording / reproducing apparatus corresponding to the magnetic recording medium. .

1 3D video viewing system (information recording / reproducing device, information recording device)
2 TV program video (2D video content)
3 + α video image (complementary information)
6R Right-eye video (2D video content)
6L left eye image (complementary information)
10 translucent layer 20 first information recording layer (layer that can only read information, recording layer)
120 1st information recording layer (layer which can only read information, recording layer)
20A First information recording area (area where information can only be read)
20B Third information recording area (first information recording area, area where information can only be read)
30 Intermediate layer 40 Second information recording layer (layer capable of recording information, recording layer)
40A content recording area (second information recording area)
40B Invalidation information recording area (second information recording area)
50 substrate 60 third information recording layer (layer capable of recording information, recording layer)
200 Optical disc (information recording medium)
201 Optical disc (information recording medium)
100 reproduction system (information recording / reproducing apparatus, information recording apparatus)
116 memory (temporary recording memory)
121 Information separator (information separator)
123 3D-complementary information expansion unit (expansion processing means)
124 cache memory (temporary recording memory)
125 3D data integration unit (recording control means, array processing means)
130 3D unit (3D unit)
1001 Information recording / reproducing apparatus (information recording apparatus)
1002 Information recording / reproducing apparatus (information recording apparatus)
1151 Memory control unit (memory control means, reproduction control means)
1154 Medium writing control unit (recording control means)
L1 to L4 ... Complementary information for creating video for left eye (complementary information)
P TV program (2D video content)
R1-R4 ... Right eye video information (2D video content)

Claims (3)

A 3D unit for converting 2D video content into 3D images,
The 2D video content is obtained from data including 2D video content in a format that can be handled by a television receiver that supports only 2D video acquired from the outside, and complementary information compressed in accordance with the maximum transfer rate. And information separating means for separating and outputting the compressed complementary information;
Decompression processing means for decompressing the compressed complementary information output by the information separation means;
A time difference generated between the time when the information separating unit outputs the 2D video content and the compressed complementary information and the time when the expansion processing unit completes expansion of the compressed complementary information is adjusted. And an array processing means for performing array processing for arranging the 2D video content and the complementary information so as to be reproduced as a 3D video. A memory control means for performing control to record information in a predetermined temporary recording memory;
The memory control means performs control to record the 2D video content separated by the information separation means in a temporary recording memory;
2. The three-dimensional unit according to claim 1, wherein the array processing unit adjusts the time difference by adjusting a time for reading the 2D video content recorded in the temporary recording memory. 3. An information recording apparatus comprising the three-dimensional unit according to claim 1 or 2,
And a recording control means for recording the 2D video content subjected to the array processing by the array processing means and the complementary information expanded by the expansion processing means on a predetermined information recording medium. Information recording device.

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