JPH056626A - Method for rewriting defect controlling region of optical disk in compliance with ecma standard - Google Patents

Abstract

PURPOSE:To prevent the mixed presence of a defect control region having the first information and a defect controlling region having the third information by writing the third information after the entire first information in four defect regions has been erased. CONSTITUTION:When defective sector information to be rewritten is formed in each DMA with a RAM 5, a controller 7 moves an optical head 2 to the leading position of the DMA 1 through a head driving means 4. At this time, when power failure occurs after new defective sector information has been written, the DMAs having the different pieces of defective sector information are mixed in the same disk. Then, the optical head 2 is moved to the leading position of the DMA 3, and the contents of the DMA 3 and the DMA 4 are sequentially erased. In this way, the DMAs having the different pieces of defective sector information do not exist on the optical disk 1 even if the power failure occurs.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rewritable type, partial ROM type or full ROM type optical disc conforming to the ECMA standard.
Rewriting method of one defect management area.

[0002]

2. Description of the Related Art ANSI standard X3B11 / 89-120
Is a rewritable type, partial ROM type, and full ROM type optical disk, and has a layout of defective sectors and is compatible with 90 mm.
A defective sector management method for providing an optical disc is proposed. The ANSI standard complies with the ECMA standard. The outline will be described below.

As shown in FIG. 3, the pre-addressed E
The data zone of the optical disc of the CMA / TC31 / 91/32 standard has four defect management areas (DMA), a rewrite area, and a ROM area. The "data sector" is a sector in which a user records information.
The "spare sector" is a replacement sector for a defective sector that is found during medium inspection or that occurs during use.
A "group" is an element that associates a data sector with a spare sector.

Each DMA contains 3 pieces of defective sector information.
It consists of 6 sectors. Each DMA has a disk definition sector (DDS) and an initial defect list (PDS).
DL) and a second defect list (SDL). DM
A1 starts from (track No. 0, sector No. 0). DMA2 (track No. 1, sector No. 1
It starts from 14). DMA3 (Track No. 999
7, sector No. It starts from 0). DMA4 starts from (Track No. 9998, Sector No. 14). The DDS of each DMA is arranged at each of the above positions. The PDL is arranged following the DDS by a predetermined number of defective sectors. The SDL is arranged following the PDL by a predetermined number of defective sectors. "DDS" is a table of contents of defective sector information as shown in FIG. “PDL” is shown in FIG.
3 is a list of defective sectors found at the time of media inspection or disk formatting. "SDL"
6 is a list of defective sectors generated when the medium is used, as shown in FIG. Therefore, DDS and PDL are changed when a defective sector is found during the medium inspection or the disk formatting. However, defective sectors that occur more than the number of spare sectors in each group are registered in SDL, and in this case, DDS, PDL and SDL are changed. If a defective sector occurs when using the medium, the SDL and DDS are changed. When the number of groups in the rewriting area or the number of groups in the ROM area is rewritten, only the DDS is changed. DDS, P
When DL or SDL is changed, a part of DMA is not overwritten and the entire DMA is rewritten. that time,
In the conventional DMA rewriting method, first, the DMA1
The contents of are erased and new contents are written, and the contents of DMA2 are erased and the contents of DMA2 are written. Then, the DMA3 is sought by the address track, the contents of DMA3 are erased and new contents are written, and the contents of DMA4 are erased and the contents of DMA4 are written. The same defective sector information is written in DMA1 to DMA4.

[0005]

However, the above-mentioned conventional D
The MA rewriting method has the following problems. That is, due to a power failure while moving the optical head from DMA2 to DMA3, DM
When the rewriting of A is interrupted, DMA1 and 2 and DMA3 and 4
The defective sector information is different. As a result, DMAs having different defective sector information cannot be mixedly used on the optical disc.

Therefore, it is an object of the present invention to provide a method of rewriting a defect management area so that an optical disk conforming to the ECMA standard does not have a defect management area having different defective sector information.

[0007]

In view of the above problems, the method of the present invention is applied to the above-mentioned four methods for an optical disk according to the ECMA standard in which a data zone is divided into four defect management areas, a rewriting area and a ROM area. First information having substantially the same content recorded in the defect management area is stored, second information to be added to the first information is stored, and first information and second information are stored. 3 information is generated, the optical head erases all the first information recorded in the four defect storage areas, and the optical head sequentially writes the third information in the four defect management areas. It was a complicated configuration.

[0008]

According to the present invention, since the third information is written after all the first information in the four defect management areas is erased, the defect management area having the first information and the defect having the third information are written. The management area does not coexist on the optical disc.

[0009]

EXAMPLE A DMA of an optical disk is mainly rewritten when a defective sector is found by a medium inspection or format, when a defective sector occurs when a medium is used, or when the number of groups in a rewriting area and a ROM area is changed. Be done.

The medium inspection is performed according to a so-called "verify" program, and the format is performed according to the format program by moving the optical head from the innermost position to the outermost position of the optical disk. When the optical head finds a defective sector, the PDL and DDS are substantially
Is changed.

When recording information on the optical disk, the optical head records information on the next sector while sequentially verifying whether the information is properly recorded on each sector.
When the optical head finds a defective sector when using the medium, the SDL and DDS are substantially changed.

The user can change the number of groups in the rewriting area and the ROM area at any time. In order to change the number of such groups, the DDS must be changed substantially.

The D of the present invention will be described below with reference to FIGS. 1 and 2.
The MA rewriting method will be described. As shown in FIG. 2, the optical disk device of the present invention includes an optical disk 1, an optical head 2, a disk drive unit 3, a head drive unit 4, and a RAM 5.
And a processing means 6, a controller 7 and a host computer 8. The optical disc is connected to the disc drive means. The optical head 2 is connected to the optical disc 1, the head driving unit 4, the RAM 5 and the controller 7. RAM
5 is connected to the processing means 6. The disk drive unit 3, the head drive unit 4, and the processing unit 6 are connected to the controller 7. The controller 7 is connected to the host computer 8.

The optical disc 1 may be inserted into and removed from the optical disc device. In this embodiment, a 90 mm partial ROM type optical disk according to the ANSI standard or ISO standard is used. A
NSI standard and ISO standard are ECMA / TC31 / 91
As shown in FIG. 3, the recording surface of the optical disc is pre-addressed by the DMA1 to DMA1.
4, a rewriting area and a ROM area are formed.

The optical head 2 performs a predetermined process on the optical disc 1 according to a program executed by the host computer 8. Further, the optical head 2 outputs the processing result to the controller 7.

The disk drive means 3 rotates the optical disk 1 at a predetermined rotation speed in accordance with an instruction from the controller 7.
The head driving means 4 moves the optical head 2 to a desired position according to a command from the controller 7.

The RAM 5 is the current DMA of the optical disk 1.
Stores the contents of. The processing means 6 performs the below-described processing on the RAM 5 so as to be compatible with the DMA when the content of the RAM 5 is changed.

The controller 7 controls the disk drive means 3, the head drive means 4 and the processing means 6 according to the program of the host computer 8. Host computer 8
Has the above-mentioned medium inspection program, format program, recording / reproducing program, program for changing the number of groups in the rewriting area and ROM area.

The operation of the optical disk device to which the method of the present invention is applied when the optical head 2 finds a defective sector will be described below with reference to FIG. When the optical head 2 finds a defective sector (step S1), information indicating the position of the defective sector is first stored in the RAM 5 (step S).
2). The RAM 5 has already stored the contents of the previous DMA1 to DMA4.

For example, assume that there is no PDL initially and the optical head 2 finds a defective sector during formatting. In the initial state, FF is set in 21-24 bytes of the DDS shown in FIG. 4 and a few bytes of the PDL shown in FIG. The RAM 5 stores the contents of each DMA in the initial state in the area 1, for example. On the other hand, the position information of the defective sector found by the optical head 2 is stored in, for example, the area 2 of the RAM 5.

When the optical head 2 finds a defective sector, it outputs a defective sector existence signal to the controller 7. The controller 7 commands the processing means 6 to rewrite the RAM 5 in response to the defective sector existence signal. In response to the instruction from the controller 7, the processing means 6 incorporates the position information of the defective sector stored in the area 2 of the RAM 5 into the area 1 (step S).
3). If necessary, the processing unit 6 rearranges the position information of defective sectors. For example, when the optical head 2 finds a defective sector during recording, the SDL is changed.
At this time, in the initial state, the SDL has defective sectors (track No. 10, sector No. 10), (track No. 10).
10, sector number. 30) is written. The defective sector found by the optical head 2 is (Track No. 1
0, sector number. If 20), the processing means 6 sorts the defective sectors in ascending order.

When the defective sector information to be rewritten in each DMA is formed in the RAM 5, the controller 7 moves the optical head 2 to the head position (track No. 0, sector No. 0) of the DMA 1 via the head driving means 4. (Step S4). Subsequently, the optical head 2 is DMA1, D
The contents of MA2 are erased in sequence (steps S5, S
6). The conventional optical head 2 thereafter writes new defective sector information in the DMA1 and DMA2. However, when a power failure occurs after writing new defective sector information, DMAs having different defective sector information are mixed in the same disk. Therefore, in the method according to the present invention, next, the optical head 2 is moved to the head position (track No. 9997, sector No. 0) of the DMA 3 (step S7), and the contents of the DMA 3 and DMA 4 are erased in order (step S8, S9). As a result, even if a power failure occurs during steps S5 to S9, there is no DMA having different defective sector information on the optical disc 1.

RA after all DMA contents have been erased
The new contents stored in M5 are written to each DMA. At that time, in this embodiment, in order to shorten the writing time,
New information is written from the DMA near the optical head 2. Specifically, the optical head 2 is moved to the DMA3 and new information is sequentially written from the DMA3 to the DMA4 (steps S10 to S12). After that, DM the optical head 2
It moves to A1 and sequentially writes new information from DMA1 to DMA2 (steps S13 to S15).

Unlike the present embodiment, the contents of the DMA may be erased from the outer circumference of the optical disc 1 by moving the optical head to the DMA 3 or DMA 4 in step S4. Also,
In step S10, the optical head 2 may be moved to the head position of the DMA 4 (step No. 9998, sector No. 12) to write new information from the DMA 4.

If a power outage occurs after step S6 or step S12, D1 is written to DMA1 and DMA2 after the power outage ends.
The contents of MA3 and DMA4 may be written. If power failure occurs after step S12, DMA3 and DMA4
The information written in DMA1 and DMA2 with reference to is new information. On the other hand, when a power failure occurs after step S6, the information written in DMA1 and DMA2 is old information. In this case, the optical disc 1 may be bayed by the inspection program of the host computer 8 or the information may be overwritten again. This is because the user knows in what process the optical head 2 found the defective sector in step S1.

If only the DDS is desired to be changed, the contents of the RAM 5 may be changed directly by the processing means 6 via the host computer 8 and the controller 7. After the contents of the RAM 5 are changed, the same procedure as that in and after step S6 in FIG. 1 can be applied.

[0027]

As described above, according to the present invention, since DMAs having different defect information are not mixed in the optical disc 1, it is possible to always form an optical disc complying with the ANSI standard or the ISO standard.

[Brief description of drawings]

FIG. 1 is a flow chart showing the method of the present invention.

FIG. 2 is a block diagram of a disk device to which the method of the present invention is applied.

FIG. 3 is a diagram showing a configuration of a recording surface of an optical disc of ECMA / TC31 / 91/32 standard.

FIG. 4 is a diagram showing the contents of DDS.

FIG. 5 is a diagram showing the contents of PDL.

FIG. 6 is a diagram showing the contents of SDL.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 optical disk 2 optical head 3 head driving means 4 head driving means 5 RAM 6 processing means 7 controller 8--host computer

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Hiroyuki Onda Inventor Hiroyuki Onda 3-7-3 Nakamachi, Musashino-shi, Tokyo Teiatsuku Inc. (72) Inventor Koji Yamana 3-7-3 Nakamachi, Musashino-shi, Tokyo Tayatsuk Incorporated (72) Inventor Takuya Nagata 3-7-3 Nakamachi, Musashino-shi, Tokyo Inside ATAK Corporation (72) Inventor Hidehiko Murata 3-7-3 Nakamachi, Musashino City in Tokyo Inside ATAK Corporation ( 72) Inventor Yutaka Kobayashi 3-7-3 Nakamachi, Musashino city, Tokyo

Claims (1)

Claims: 1. A defect management area having four data zones,
The first information having substantially the same contents recorded in the four defect management areas of the optical disc according to the ECMA standard, which is divided into a rewriting area and a ROM area, should be stored and added to the first information. The second information is stored, the third information is generated from the first information and the second information, and the optical head erases all the first information recorded in the four defect storage areas. A method of sequentially writing the third information in the four defect management areas by the optical head.