JP4120691B2 - Optical disc recording method and optical disc reproducing method - Google Patents

Description

  The present invention relates to a recording method for recording information on an optical disc and an optical disc reproduction method for reproducing the same, and more particularly to an information recording method for an optical disc on which moving image compressed data is recorded and an optical disc reproduction method for reproducing a moving image from the optical disc. .

  A typical example of a system for reproducing digital data using an optical disk is a so-called CD-ROM. The CD-ROM records computer data on an optical disk having the same physical format as an audio CD, and has a data format as described below. A data string recorded on the optical disc is composed of a minimum unit called a frame, and each frame includes synchronization data, subcode, digital data of main information, and error correction code. Furthermore, this frame is composed of 98 frames (2352 bytes) to form one sector, and each sector has 12 bytes of synchronization data, 4 bytes of header data indicating the address and mode, and 2048 bytes of digital data. It consists of error detection / correction codes of 288 bytes.

  On the other hand, as a coding method of moving image signals, a method in which orthogonal transformation, quantization, and variable length coding are combined with inter-frame prediction is well known, and the ISO (International Organization for Standardization) MPEG method conforms to this method. It has become a method. For example, in the case of MPEG2, the encoded image data bit stream is divided into six layers: a sequence layer, a GOP (Group of Pictures) layer, a picture layer, a slice layer, a macroblock layer, and a block layer. Of these, the GOP layer includes a P picture generated by performing prediction from an I picture, an I picture, or a P picture encoded only from the information without using inter-frame prediction, and B generated by bidirectional prediction. Three types of picture data are included. The sequence layer is composed of a GOP in which image data starting from the I picture and including the P picture and the B picture are grouped, and SH (Sequence Header) added to the head of the GOP.

  Also, when converting a moving image signal into highly efficient encoding and compressed image data, for example, in a scene with intense motion, the compression rate is reduced, that is, encoded at a high transfer rate, and in a scene with little motion, the compression rate is increased, That is, a method of encoding at a low transfer rate has been proposed. The compressed image data with the variable transfer rate encoded in this way reduces image deterioration due to compression compared with the compressed image data with the fixed transfer rate fixed and encoded with the average value of the compression rate. Can do.

  An apparatus for recording the compressed image data having the variable transfer rate or the fixed transfer rate as described above on the optical disk such as the CD-ROM and reproducing the same has already been announced.

  In the above prior art, so-called special reproduction of a moving image recorded on an optical disk has not been particularly taken into consideration. For example, in general, moving image reproduction requires n-times variable speed reproduction or reverse reproduction in addition to 1-times continuous reproduction, and a reproduction apparatus corresponding to this is required. Similarly, a high-speed search is required for the search operation.

  An object of the present invention is to provide an optical disc information recording method and an optical disc playback method capable of various special playbacks and a high-speed search operation on an optical disc on which compressed image data is recorded.

To achieve the above object, an optical disc recording method of the present invention is an optical disc recording method for recording main information on an optical disc, wherein the main information is recorded in a sector structure having a sector address, and the sector is a sync signal. The synchronization signal of the block including the head of the sector address is different from the synchronization signal of the block not including the head of the sector address, and the head of the sector address is added to the head of the sector. A block including the I picture of the compressed image data and a table showing the relationship between the sector address corresponding to the I picture is recorded.

The optical disc reproducing method of the present invention is an optical disc reproducing method in which main information is recorded, wherein the main information has a sector structure having a sector address, and the sector includes a block having a synchronization signal. The synchronization signal of the block including the head of the sector address among the blocks is different from the synchronization signal of the block not including the head of the sector address, and the head of the sector has a block including the head of the sector address. In addition, a table indicating the relationship between the I picture of the compressed image data and the sector address corresponding to the I picture is recorded on the optical disc, and desired image data is referenced with reference to the table. A sector address for reproducing the image, and searching for the detected sector address on the optical disc to obtain the desired address. The image data is reproduced.

  A special reproduction table is recorded on the optical disk of the present invention, and a sector address is added to each sector. Then, the optical disk reproducing apparatus of the present invention refers to the special reproduction table, obtains the sector address of the corresponding compressed image data, searches for the address on the optical disk, and reproduces it. This makes it possible to easily perform special playback and search operations such as high-speed playback, slow playback, and reverse playback.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a diagram showing a first embodiment of an optical disc according to the present invention. FIG. 2 shows a special reproduction table on the optical disk. The special reproduction table records the sector addresses corresponding to the numbers (indexes) of the songs and chapters for all the songs and chapters recorded on the optical disc. A sector address is added to each sector of the optical disk, and this special reproduction table is recorded in an area such as the TOC (Table of Contents) or the first sector (sector 0) of the disk.

  When this optical disk is loaded in the optical disk playback device, the system microcomputer first reads the special playback table and stores it in the work area. When performing special reproduction, the address of the sector to be read is obtained by referring to this special reproduction table, and the address is searched on the optical disk to reproduce the image.

  As a result, the address of the sector to be read is obtained by referring to the special reproduction table, so that the search can be performed at high speed.

  FIG. 2 is a diagram showing a second embodiment of the optical disk according to the present invention. FIG. 2 shows a special reproduction table on the optical disk. The special reproduction table records time codes (time information) corresponding to all sector addresses of data recorded on the optical disc. This special reproduction table is recorded in an area such as the TOC (Table of Contents) or the first sector (sector 0) of the disk.

  When this optical disk is loaded in the optical disk playback device, the system microcomputer first reads the special playback table and stores it in the work area. When performing special reproduction, the address of the sector to be read is obtained by referring to this special reproduction table, and the address is searched on the optical disk to reproduce the image.

  As a result, at the time of special reproduction other than normal reproduction, the address of the sector to be read is obtained by referring to the special reproduction table, so that special reproduction can be easily performed and the search can be performed at high speed.

  In addition, when reproducing compressed image data with a variable transfer rate, the sector address and the time code are not in a proportional relationship. Therefore, the sector address cannot be obtained from the time code, and an accurate search cannot be performed. By referring to the table, the corresponding sector address is obtained, and an accurate search can be performed.

  FIG. 3 shows a third embodiment of the optical disk according to the present invention. FIG. 2 shows a special reproduction table on the optical disk. The special reproduction table records all sector addresses and the contents of data recorded on the optical disk. This special reproduction table is recorded in an area such as the TOC (Table of Contents) or the first sector (sector 0) of the disk.

  When this optical disk is loaded in the optical disk playback device, the system microcomputer first reads the special playback table and stores it in the work area. When searching, the address of the sector to be read is obtained by referring to the special reproduction table, and the address is searched on the optical disc to reproduce the image.

  As a result, at the time of special reproduction other than normal reproduction, the address of the sector to be read is obtained by referring to the special reproduction table, so that special reproduction can be easily performed and the search can be performed at high speed.

  FIG. 4 is a diagram showing a fourth embodiment of the optical disk according to the present invention. FIG. 2 shows a special reproduction table on the optical disk. The special reproduction table records SH (Sequence Header) added to the head of the GOP recorded on the optical disc and its sector address. This special reproduction table is recorded in an area such as the TOC (Table of Contents) or the first sector (sector 0) of the disk.

  When this optical disk is loaded in the optical disk playback device, the system microcomputer first reads the special playback table and stores it in the work area. When searching, the address of the sector to be read is obtained by referring to the special reproduction table, and the address is searched on the optical disc to reproduce the image.

  As a result, at the time of special reproduction other than normal reproduction, the address of the sector to be read is obtained by referring to the special reproduction table, so that special reproduction can be easily performed and the search can be performed at high speed.

  FIG. 5 is a view showing a fifth embodiment of the optical disk according to the present invention. FIG. 2 shows a special reproduction table on the optical disk. The special reproduction table records the sector address of the I picture recorded on the optical disk. This special reproduction table is recorded in an area such as the TOC (Table of Contents) or the first sector (sector 0) of the disk.

  When this optical disk is loaded in the optical disk playback device, the system microcomputer first reads the special playback table and stores it in the work area. When searching, the address of the sector to be read is obtained by referring to the special reproduction table, and the address is searched on the optical disc to reproduce the image.

  As a result, at the time of special reproduction other than normal reproduction, the sector address of the I picture is obtained by referring to the special reproduction table, so that special reproduction can be performed by extracting only the I picture. Further, the sector address of B picture and P picture can be recorded in the special reproduction table, and smooth special reproduction can be performed.

  FIG. 6 is a diagram showing a sixth embodiment of the optical disc according to the present invention. This figure shows a plurality of special reproduction tables on the optical disc and their identification codes. When the optical disk is loaded into the optical disk playback device, the system microcomputer reads the special playback table recorded on the optical disk and stores it in the work area. At this time, the system microcomputer can identify each special reproduction table by this identification code and store it at a predetermined address in the work area. Therefore, the system microcomputer can identify each table and store it in the work area no matter how many types of special playback tables exist. Refer to the special playback table required for special playback to obtain the sector address. Special playback can be easily performed, and search can be performed at high speed.

  FIG. 7 is a view showing a seventh embodiment of the optical disc according to the present invention. FIG. 2A schematically shows tracks on the optical disk, and a spiral track is formed on the optical disk. FIGS. 7B and 7C show the data format recorded on the track. Each sector has a sync signal (Sync), a sector address (SA), a block address (BA), and a parity (P). , Digital data (Data), and error correction code (ECC). The same sector address is recorded for each block.

  FIG. 8 is a view showing an eighth embodiment of the optical disc according to the present invention. FIG. 2A schematically shows tracks on the optical disk, and a spiral track is formed on the optical disk. FIGS. 7B and 7C show the data format recorded on the track. Each sector has a sync signal (S0, S1), a sector address (SA), a block address (BA), a parity ( P), digital data (Data), and error correction code (ECC). Sector addresses are recorded over two blocks, and one address is represented by SA1, SA2, and SA3. For this reason, address redundancy is smaller than in the seventh embodiment, and the address area can be reduced.

  FIG. 9 is a diagram showing a ninth embodiment of the optical disc according to the present invention. FIG. 2A schematically shows tracks on the optical disk, and a spiral track is formed on the optical disk. FIG. 4B shows the data format recorded on the track. Each sector has a synchronization signal (S0, S1, S2), a sector address (SA), a block address (BA), and a parity (P). , Digital data (Data), and error correction code (ECC). Sector addresses are recorded over two blocks, and one address is represented by SA1, SA2, and SA3. For this reason, address redundancy is smaller than in the seventh and eighth embodiments, and the address area can be reduced.

  FIG. 10 is a diagram showing an embodiment of an optical disk reproducing apparatus according to the present invention. The figure schematically shows tracks on the optical disk, and a spiral track is formed on the optical disk. (X-1), x, (x + 1),... (X + y), (x + y + 1) represent sectors, and data is reproduced in this order during normal reproduction.

  Next, the special playback operation will be described taking the operation at the time of n-times speed playback as an example. In FIG. 10, it is assumed that an n-times speed playback command is input while sector x is being played back. First, after data of sector x is read, the next target sector (x + n) is searched by track jump or the like. The distance n from the initial position to the target sector is calculated by the system microcomputer according to how many times the reproduction is performed. After the search is performed, the data of the sector (x + n) is read, the next target sector (x + 2n) is searched again, and this operation is repeated in the same manner.

  When an optical disk is loaded in the optical disk playback device, the system microcomputer first reads the special playback table recorded on the optical disk and stores it in the work area. When performing special reproduction, an address of a sector to be read is obtained by referring to a necessary special reproduction table, and the address is searched on the optical disk to reproduce an image.

  FIG. 11 is a flowchart of the operation at the time of the n-times speed reproduction. Here, m is the number of I pictures included in the GOP. When an n × speed playback command is input from an external input device such as a remote controller, it is first determined whether m = n, and when m = n, only the I picture is retrieved from the special playback table and played back. When m <n, the I picture is searched for and reproduced by the special reproduction table. When m = 2n and m = 3n, it is sufficient to search and reproduce only the I picture. However, when m = 2.5n, not only the I picture but also the P picture is searched. Can be played back more smoothly at a variable speed. When m> n, in addition to the I picture by the special reproduction table, the P picture is searched for and reproduced. At this time, if the B picture is further searched and reproduced in addition to the I picture and the P picture, the variable speed reproduction can be smoothly performed. Thereafter, if the n-times speed reproduction command is continued, the above operation is repeated.

  Although the description has been made taking the n-times speed reproduction operation as an example, if n of n-times speed reproduction is set to be negative, it can be easily applied to the backward reproduction. Further, if | n | <1, slow playback can be performed.

  As described above, by performing a search with reference to the special reproduction table, it is possible to easily perform image reproduction in units of GOPs in image data encoded by, for example, the MPEG method. Therefore, in addition to the continuous playback at 1 × speed, special playback such as slow playback, high speed playback, reverse playback, and high-speed search operation are possible.

  The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.

  When an optical disk is loaded in the optical disk playback device, the system microcomputer first reads the special playback table recorded on the optical disk and stores it in the work area. When performing special reproduction, an address of a sector to be read is obtained by referring to a necessary special reproduction table, and the address is searched on the optical disk to reproduce an image.

  As a result, in special playback other than normal playback, the address of the sector to be read is obtained by referring to the special playback table, so that special playback can be easily performed, and quick search playback images can be obtained during search operations. Is possible.

The figure which shows the 1st Example of the optical disk by this invention. The figure which shows the 2nd Example of the optical disk by this invention. The figure which shows the 3rd Example of the optical disk by this invention. The figure which shows the 4th Example of the optical disk by this invention. The figure which shows the 5th Example of the optical disk by this invention. The figure which shows the 6th Example of the optical disk by this invention. Schematic diagram of a data format showing a seventh embodiment of the optical disc according to the present invention. Schematic diagram of data format showing an eighth embodiment of an optical disc according to the present invention. Schematic diagram of a data format showing a ninth embodiment of an optical disc according to the present invention. Schematic diagram of a track showing an embodiment of an optical disk reproducing apparatus according to the present invention. It is a flowchart of the operation | movement at the time of special reproduction.

Claims (2)

An optical disc recording method for recording main information on an optical disc,
The main information is recorded in a sector structure having a sector address,
The sector includes a plurality of blocks having a synchronization signal, and the synchronization signal of the block including the head of the sector address is different from the synchronization signal of the block not including the head of the sector address.
A block including the head of the sector address is recorded at the head of the sector,
A method of recording an optical disc, comprising: recording a table indicating a relationship between an I picture of the compressed image data and a sector address corresponding to the I picture. A method of reproducing an optical disc on which main information is recorded,
The main information has a sector structure having a sector address;
The sector includes a plurality of blocks having a synchronization signal, and the synchronization signal of the block including the head of the sector address among the blocks is different from the synchronization signal of the block not including the head of the sector address. It has a block that includes the beginning of the sector address,
The optical disc further includes a table indicating a relationship between an I picture of the compressed image data and a sector address corresponding to the I picture,
An optical disk reproduction characterized in that a sector address for reproducing desired image data is obtained by referring to the table, the detected sector address is searched on the optical disk, and the desired image data is reproduced. Method.

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