1. Field of the Invention
The present invention relates to a rewritable optical recording medium and more particularly, to a method for real time recording/playback of data to/from an optical recording medium and a method for managing a file thereof.
2. Background of the Related Art
An optical recording medium includes a Read Only memory (ROM), a Write Once Read Many (WORM) time memory, and a rewritable memory which allows repeated writing. The ROM type of optical recording medium further includes a Compact Disc Read Only Memory (CD-ROM) and a Digital Versatile Disc Read Only Memory (DVD-ROM). The WORM type of optical recording medium further includes a Recordable Compact Disc (CD-R) and a Recordable Digital Versatile Disc (DVD-R). The rewritable type further includes a Rewritable Compact Disc (CD-RW) and a Rewritable Digital Versatile Disc (DVD-RW, DVD-RAM and DVD+RW).
For the rewritable optical recording mediums, the repeated recording and playback (R/P) of information to and from the rewritable optical recording medium changes an initial mixture ratio of a recording layer formed to write data on the optical disk. This change degrades performance of the optical recording medium, causing errors in R/P of the data information. A degraded region of an optical disk creates a defective area for formatting, writing to and playback from the optical recording medium. Moreover, a defective area in a rewritable optical recording medium can also be caused by scratches on the surface, dusts and defects in production.
To prevent R/P of data to/from a defective area formed by any of the above causes, management of the defective area is required. Thus, Defect Management Areas (DMAs) are provided in lead-in areas and in lead-out areas of the optical recording medium for managing defective regions of the optical recording medium, as shown in
Typically, one disc (e.g. DVD-RAM) has four DMAs, two in the lead-in area and two in the lead-out area. Since managing defect areas is important, the same data are held in all four DMAs, for data protection. Each DMA includes two blocks of 32 sectors, wherein one block consists of 16 sectors. The first block (DDS/PDL block) of each DMA includes a disc definition structure (DDS) and a primary defect list (PDL), and the second block (SDL block) includes a secondary defect list (SDL).
More specifically, the PDL represents a primary defect data storage area, and the SDL represents a secondary defect data storage area. The PDL stores entries of all defective sectors generated during manufacture and identified during formatting such as initialization or re-initialization. Each entry includes a sector number corresponding to a defective sector and an entry type.
On the other hand, the SDL is arranged by blocks and stores entries of either defective areas which may be generated after initialization, or defective areas which cannot be entered in the PDL during initialization. Each entry of the SDL includes an area storing the sector number of a first sector of the block having a defective sector, and an area holding the sector number of a first sector of an alternate block. Defective areas in the data area (i.e. defective sectors or defective blocks) are replaced with new sectors or blocks, respectively by slipping replacement or linear replacement.
The slipping replacement is utilized when a defective area or sector is listed in the PDL. As shown in
The linear replacement is utilized when a defective area or block is recorded in the SDL. As shown in
Also, a host may be connected to the interface of the optical disc R/P device to transfer commands and data to and from the host and R/P device. Such a host can be any kind of personal computer, and would manage the optical disc R/P device.
Referring to
Namely, the physical sectors listed on the PDL are skipped during the writing. As shown in
Referring to
In order to write data by replacing defective blocks listed on the SDL with a replacement block assigned in the spare area, the optical pickup must be shifted to the spare area and returned back to the user area. However, the time period required for shifting and returning back interferes with a real time recording. Accordingly, many defective area management methods for real time recording are suggested. One of such methods is a skipping method in which the linear replacement is not performed when using the SDL, but data of an encountered defective block is written on a good block subsequent to the defective block as in the slipping replacement. As a result, the shifting time of the optical pickup in a real time recording can be reduced because the optical pickup is not required to shift to the spare area every time the optical pickup encounters a defective block.
At this time, the defective block retains the LSN and PSN. However, from the viewpoint of the host, the number of logical sectors in an optical disc is fixed. Thus, skipping causes losses of LSN in view of the host, equivalent to the number of skipped blocks, because LSNs are allocated to the skipped defective blocks even if data is not written on the defective block. For example, even if data of 100 sectors are transmitted for writing from the host and if there is one defective block in the area, only 84 sectors (1 block=16 sectors) are written.
Therefore, for file 1 in
Consequently, if file 1 size is represented with ‘N’ as in the first case of
Also, the LSNs retained by the defective areas during a real time recording cannot be utilized and an amount of data corresponding to such LSNs cannot be recorded. Therefore, effectively, a reduction of the disk size occurs. This is because data is written in fixed units in response to write command from the host regardless of whether defective blocks or defective sectors exists in an area in which the data is written.
Accordingly, an object of the present invention is to solve at least the problems and disadvantages of the related art.
An object of the present invention is to provide a method for real time R/P of data to/from an optical recording medium, by providing a write command using information from a defective area returned from a device for R/P of data on an optical disk.
Another object of the present invention is to provide a method for real time management of files in an optical disk.
A further object of the present invention is to provide a method for managing files in an optical disk with the capability to manage real time data using defective block information.
A still further object of the present invention is to provide a method for managing files in an optical disk with the capability to manage real time data using skipped defective block information.
A still further object of the present invention is to provide a method for real time R/P of data on an optical recording medium, in which a device for R/P of data on an optical disk reads out and excludes defective areas before writing the data when a real time data is provided.
Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention. The objects and advantages of the invention may be realized and attained as particularly pointed out in the appended claims.
These and other objects of the present application will become more readily apparent from the detailed description given hereinafter. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the invention will become apparent to those skilled in the art from this detailed description.
The invention will be described in detail with reference to the following drawings in which like reference numerals refer to like elements wherein:
Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.
In a first embodiment of the present invention, if a data for a real time writing is provided, a host provides, in advance, a signal requesting information regarding defective areas to a device for R/P of data to/from an optical disk. The host generates a write command using the information on the defective area returned from the R/P device to write the data. In a second embodiment of the present invention, if a data for real time writing is provided, the host provides in advance, a command for real time recording. The host then provides a new write command when information on defective area within blocks corresponding to the command is returned from the R/P device to write the data.
The present invention further includes methods to process a newly encountered defective block during writing of data. In one method, the defective block is skipped and data is written on a good block subsequent the defective block. Another method terminates a write command if a new defective block is encountered and receives a new write command for continuation of data writing from the host. Also, a further method writes data on the defective block as is. Such methods for processing a newly encountered defective block is applicable both to the first and second embodiments of the present invention. The first and second embodiments will next be explained.
When data for real time recordation is provided (step 501), the host provides a control signal requesting information on defective areas of the disk to the device for R/P of data in/from an optical disk before the host provides a write command (step 502). As a supplementary signal, the control signal requesting information on defective areas may or may not be provided in a similar manner to a command type for returning the PDL information.
Upon reception of the control signal from the host, the R/P device returns the information on the defective area listed on a DMA (step 503). The information on the defective area returned to the host may be a positional information of the defective blocks and defective sectors listed on the SDL and PDL, or may be positional information of defective blocks listed on the SDL. As shown in
The microcomputer may convert the PSN of the first sector of the defective block listed on the SDL to a LSN for use as the positional information of the defective blocks. In this case, the LSN returned to the host and 15 subsequent sectors are determined to be defective. Also, by setting a predetermined signal, information on defective areas can be returned to the host when the host provides the predetermined signal to the R/P device, even if a real time writing is not being performed.
The host generates a write command with reference to the returned information on the defective area and to an existing file architecture. The write command is forwarded to the R/P device together with real time data (step 504 and 505). Namely, the host generates the write command such that data is not written on either defective areas listed on the SDL nor on newly encountered defective areas.
Referring to
If a defective block with a high possibility of errors is found, even if the defective block is not listed on the SDL, the new defective block may be skipped and the data would be written on a good block subsequent the defective block. Alternatively, as shown in
For example, when a new defective block, especially with a Physical Identification (PID) error, is encountered, the block may be skipped without writing the data therein, as shown in
Also, by a predetermined protocol or signal rather than a command, the host may make requests for the present status of writing during the writing of data. Thus, upon the generating of the signal, the R/P device would provide the requested information to the host. If there is no protocol, the information on the writing is provided to the host after the write command is finished.
The information on the defective block may be returned to the host in one of various methods. In one method, the information is returned utilizing a request sense data as shown in
For example, the R/P device writes the data in real time according to a write command from the host by a skipping method, as shown in
Namely, the information on skipped defective blocks is written starting from the 15th byte in an additional area of the request sense data and returned to the host. This is possible because a byte length of the request sense data is variable and an additional length due to the addition of the information may be written on a 7th byte additional sense length. Accordingly, the present invention utilizes, but maintains the existing request sense data to return the information on defective areas.
Because the R/P device returns information on defective blocks skipped during the execution of the command to the host each time a write command terminates, the number of the skipped blocks varies. Therefore, starting from the 15th byte, the information may be written on the request sense data in units of three or four bytes. Also, the information on each defective block written on the request sense data includes an LSN of the first sector in a skipped block. If two defective blocks are found during the execution of one write command, two LSNs are written on the additional area of the request sense data and returned to the host. The host then regards the LSN returned to the host and the 15 sectors thereafter as defective.
Referring back to
As shown in
Accordingly, the host may have to generate and provide numerous write commands to complete writing one file. However, even if the write command is divided by the defective area, the present invention can easily be incorporated into the existing system without significant changes. The microcomputer provides a command execution report to the host each time a write command is completed according to the aforementioned process. Most of such a report would include information representing good states because the write command is provided from the host, excluding the defective areas.
Upon completion of the writing of the file, the host writes an ICB, as shown in
Eventually, an ICB of file 1 is made divided into a subfile having a starting position ‘A’ and a size H, a subfile having a starting position ‘G’ and a size T, a subfile having a starting position ‘D’ and a size P, and a subfile having a starting position ‘E’ and a size U. Namely, the defective areas sblkA, sblkB, sblkE present in the writing area of file 1 are not written on the ICB. As a result, inconsistencies between the size of a written file and the size of an actual file and inconsistencies of the LSNs due to defective regions do not occur. As a result, mistakes made by the file manager due to such inconsistencies are also eliminated.
Moreover, such ICB can be made while maintaining the existing UDF file system. Even in the existing system, one file is often written by shifting to empty areas rather than in succession, resulting in a fragmentation of the file. Similarly, the ICB simply fragmentizes one file. The present invention regards the defective areas as skipped areas caused by shifting of areas in making the ICB, thereby creating no conflicts with an existing file system. Also, as the defective areas maintain the LSN without being written on the ICB, the defective area can be used during writing by linear replacement. By replacing the defective blocks encountered during writing with a spare block in the spare area, linear replacement allows use of the whole user area of the disk. Thus, utilization efficiency of the disk can be improved. Since the host receives information on defects of the disk during a state in which a disk architecture is not known in making a real time recording control, a load on the host can be reduced.
Referring to
The information on defective area may be provided to the host in a variety of methods, one of which is by using a request sense data, as shown in
The request sense data has 15 bytes, of which the 8th, 9th, 10th and 11th bytes are reserved for use in transmission of the defect information. Since the R/P device stops the write command and returns to the host the information on defective area each time a defective block is encountered, the defect information is written on the reserved 8th˜11th bytes of the request sense data and returned to the host.
For example, the numbers of sectors (written sector number) on which data was recorded according to a write command may be written on the 8th and 9th bytes and consecutive defect sector numbers may be written on the 10th and 11th bytes. The consecutive defect sector number is returned to prevent the host from generating and providing a command for writing data on the same consecutive defect sector. If a block with a high possibility of defect is encountered during writing, the microcomputer regards the written sector number and 16 sectors of the defective block as the consecutive defect sector number and returns the same to the host. This is because, if a defective sector is encounter during writing, a whole block to which the defective sector belongs is considered defective and listed on the SDL.
Upon reception of the request sense data with the defect information written thereon from the microcomputer, the host provides a new write command referring to the written sector number and the defect sector number. Particularly, utilizing the defect information from the microcomputer, the new command includes the LBA of the first sector number of a next good block subsequent to a defective sector or block. Accordingly, upon reception of the new write command from the host, the microcomputer in the R/P device continues writing the data starting from a designated position, i.e. from the good block subsequent the defective block.
The R/P device and the host repeats the aforementioned process each time a defective area is encountered during writing of data on the optical disk. If the write command from the host terminates normally (step 610), i.e. if no defective block is encountered during the execution of the write command, the microcomputer returns a good state to the host (step 611). By a predetermined protocol or signal rather than a command, the host may request the present status of writing during the writing of data. Thus, upon the generating of the signal, the R/P device would provide the requested information to the host. If there is no protocol, the microcomputer provides defect information on the writing to the host after the write command terminates.
When writing of one file is completed (step 612), the host writes out an ICB, indicating a starting position and size of the file in an UDF file system, with reference to the defect information provided on the optical disk in the R/P device (step 613). An example ICB of file 1 shown in
Eventually, an ICB of file 1 is made divided into a subfile having a starting position ‘A’ and a size H, a subfile having a starting position ‘G’ and a size T, a subfile having a starting position ‘D’ and a size P, and a subfile having a starting position ‘E’ and a size U. Namely, the defective areas sblkA, sblkB, sblkE present in the writing area of file 1 are not written on the ICB. As a result inconsistencies between the size of a written file and the size of an actual file and inconsistencies of the LSNs due to defective regions do not occur. As a result, mistakes made by the file manager due to such inconsistencies are also eliminated.
According to this method, even if a defective block with a high possibility of error occurrence is encountered during writing of data at a position designated by the write command, the data is simply written on the defective block as is (step 706). Shown in
Similar to the previous methods, by a predetermined protocol or signal rather than a command, the host may make requests for the present status of writing during the writing of data. Thus, upon the generating of the signal, the R/P device would provide the requested information to the host. If there is no protocol, the microcomputer provides the defect information on writing to the host after the write command has been executed.
If a request from a user or writing of a file is not completed, the host continues to generate and provide a write command. As defective blocks sblkA and sblkB of
The microcomputer provides a command execution report to the host each time the write command terminates. Most of the command execution report would indicate a good state since defective areas are excluded when the write command is generated from the host.
Upon completion of the writing of the file (step 709), the host writes an ICB, as shown in
Sectors Q, R, S shown in
When data to be written in real time is provided, the host provides the data to be written on the optical disk to the R/P device together with a command for controlling a real time recording (step 801). In order to manage files, the R/P device checks for the presence of defective blocks listed on the SDL before writing the data at a position designated by the write command (step 802). If at least one defective block is listed on the SDL, the positional information of the defective block is returned to the host (step 803).
For example, referring to
Namely, as shown in
Accordingly, upon reception of the request sense data having the positional information of defective blocks from the microcomputer, the host generates a new write command, i.e. a command such that data is not written on defective blocks. The new write command is forwarded to the R/P device (step 804). The write command may be a command for writing data starting from the ‘D’ position for P sectors or a command for writing data starting from any empty area of an existing file. As the host may provide numerous write commands for one file, the write command for one file would be divided.
If the new write command is a command for writing data starting from position ‘A’ for M sectors as shown in
When the write command is completed, i.e. the data is written for M sectors (step 806), the microcomputer provides a command execution report to the host (step 807). Also, by a predetermined protocol or signal rather than a command, the host may make requests for the present status of writing during the writing of data. Thus, upon the generating of the signal, the R/P device would provide the requested information to the host. If there is no protocol, the R/P device provides defect information on writing to the host after the execution of the write command terminates.
Using file 1 of
Upon completion of writing a file according to the aforementioned process (step 808), the host writes an ICB indicating a starting position and the size of the file in a UDF file system on the optical disk as shown in
As a result, inconsistencies between the size of a written file and the size of an actual file, and inconsistencies of the LSNs due to defective regions do not occur. As a result, mistakes made by the file manager due to such inconsistencies are also eliminated. Moreover, such ICB can be made while maintaining the existing UDF file system. Even in the existing system, one file is often written by shifting to empty areas rather than in succession, resulting in fragmentation of the file. Similarly, the ICB simply fragmentizes one file. The present invention regards the defective areas as skipped areas caused by shifting of areas in making the ICB, thereby creating no conflicts with an existing file system. Also, as the defective areas maintain the LSN without being written on the ICB, the defective area can be used during writing by linear replacement. By replacing the defective blocks encountered during writing with a spare block in the spare area, linear replacement allows use of the whole user area of the disk. Thus, utilization efficiency of the disk can be improved. Since the host receives information on defects of the disk during a state in which disk architecture is not known in making a real time recording control, a load on the host can be reduced.
The present invention has been explained with reference to both a host and a device for recording/playback of data to/from an optical disk. When only a R/P device is provided without a host, such as a disk player, a microcomputer in the R/P device directly controls the above procedure. Thus, having the information on defective areas written on the DMAs, the microcomputer in the R/P device reads the information on the defective blocks and the information on a present file architecture to provide a write command. Namely, the write command would write data on the present file architecture without writing the data on defective areas during real time recording. In such a case, the command may differ from a command provided to the host.
The ICB write out is also made by the microcomputer, wherein a sector number representing a file size is written, divided by the defective blocks, and adding sectors numbers in the write commands for two or more continuous write commands, as shown in
In sum, the method for real time R/P of data to/from an optical recording medium and a method for managing a file thereof according to the present invention have the following advantages. Because the host controls data writing by providing a signal to the R/P device requesting information on defective areas when a real time data is provided, the host can provide a write command such that data is not written on a defective area based upon the information on the defective area returned from the R/P device. Alternatively, because the host controls data writing by providing a write command to the R/P device upon which the R/P device returns information on defective areas, the host can provide a write command such that data is not written on a defective area based upon the information on the defective area is returned from the R/P device.
Moreover, in making a real time recording, there is no occurrence of a difference between an actual file size and a written file size or an inconsistency between LSNs. Because a defective area remains as an empty area on the ICB while the defective area retains an LSN, efficiency can be improved by allowing use of the defective area in the next linear replacement. Furthermore, since an ICB is written by regarding a defective area as a skipped area caused by shifting, no conflict with an existing file system is occurs, thereby maintaining interchangeability with an existing UDF file system as is. Finally, since the host receives defect information in a state when disk architecture is unknown during real time recording control, load on the host can be reduced.
The foregoing embodiments are merely exemplary and are not to be construed as limiting the present invention. The present teachings can be readily applied to other types of apparatuses. The description of the present invention is intended to be illustrative, and not to limit the scope of the claims. Many alternatives, modifications, and variations will be apparent to those skilled in the art.
Number | Date | Country | Kind |
---|---|---|---|
1998-30607 | Jul 1998 | KR | national |
1998-31783 | Aug 1998 | KR | national |
1998-33312 | Aug 1998 | KR | national |
1998-34724 | Aug 1998 | KR | national |
This application is a continuation of application Ser. No. 10/613,090, filed on Jul. 7, 2003; which is a continuation of application Ser. No. 09/362,375, filed on Jul. 28, 1999 (now U.S. Pat. No. 6,625,094). The entire contents of each of these applications are hereby incorporated by reference. Priority is claimed under 35 U.S.C. § 120; and this application claims priority of Application Nos. 30607/1998 filed in Republic of Korea on Jul. 29 1998; 31783/1998 filed in Republic of Korea on Aug. 4, 1998; 33312/1998 filed in Republic of Korea on Aug. 17, 1998; and 34724/1998 filed in Republic of Korea on Aug. 26, 1998, under 35 U.S.C. § 119.
Number | Name | Date | Kind |
---|---|---|---|
4774700 | Satoh et al. | Sep 1988 | A |
5237553 | Fukushima et al. | Aug 1993 | A |
5715221 | Ito et al. | Feb 1998 | A |
5818654 | Reddy et al. | Oct 1998 | A |
5859823 | Yamamuro | Jan 1999 | A |
5966358 | Mine | Oct 1999 | A |
6094317 | Chung | Jul 2000 | A |
6160778 | Ito et al. | Dec 2000 | A |
6279118 | Kang | Aug 2001 | B1 |
6282365 | Gotoh et al. | Aug 2001 | B1 |
6292625 | Gotoh et al. | Sep 2001 | B1 |
6314235 | Gotoh et al. | Nov 2001 | B1 |
6377524 | Ko | Apr 2002 | B1 |
6389569 | Chung et al. | May 2002 | B1 |
Number | Date | Country |
---|---|---|
0 383 298 | Aug 1990 | EP |
0 798 710 | Oct 1997 | EP |
0 837 472 | Apr 1998 | EP |
0 559 468 | Sep 1998 | EP |
0 866 456 | Sep 1998 | EP |
2 332 555 | Jun 1999 | GB |
4-28061 | Jan 1992 | JP |
07-057398 | Mar 1995 | JP |
10-125006 | May 1998 | JP |
WO 9707505 | Feb 1997 | WO |
WO-9814938 | Apr 1998 | WO |
WO 9814938 | Apr 2003 | WO |
Number | Date | Country | |
---|---|---|---|
20040264332 A1 | Dec 2004 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 10613090 | Jul 2003 | US |
Child | 10896984 | US | |
Parent | 09362375 | Jul 1999 | US |
Child | 10613090 | US |