JPH0536210A - Method for accessing optical disk - Google Patents

Abstract

PURPOSE:To shorten the access time of the optical disk by executing the generation of the physical address of the optical disk during accessing when the physical address of the optical disk is generated form a logical address imparted by a host computer and the optical disk is accessed moving an optical head. CONSTITUTION:When an optical disk 2 is accessed, a temporary physical address is generated from the logical address without considering a defect, an optical head 12 is moved to the temporary physical address and while moving it, a target physical address is calculated by CPU 15 referring to the list of defect stored in a RAM 16. The temporary physical address is corrected to the target physical address and the optical head 12 is moved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for accessing a target physical address of an optical disk, and more particularly, to an access method for an optical disk having a defect list which is position information of a defective sector and a replacement area of the defective position.

[0002]

2. Description of the Related Art Generally, an optical disk has a much higher frequency of occurrence of defective sectors due to a defect in a recording film, a substrate, etc., as compared with a magnetic disk. Therefore, it is desired to efficiently replace a large number of defective sectors. Because of this, ISO
In ISO / IEC DIS 10090, a disk management definition area is provided on the optical disk, and the information indicating where the defective sector position information called the primary defect list and secondary defect list is recorded and the data of the defective sector are rewritten. It records the position information about the replacement sector. Here, the primary defect list is position information regarding defective sectors generated at the time of pre-shipment inspection of the optical disc, that is, manufacturing, and the secondary defect list is position information regarding defective sectors generated thereafter.

In ISO, when the position information of the defective sector is recorded in the primary defect list, the data is sequentially shifted to the normal sector next to the defective sector by using the slip method, and the data is written in the secondary defect list. When the position information of the sector is recorded, the data is rewritten and written in the replacement sector using the group replacement method. Conventionally, the optical head has accessed the optical disc having the two defect lists as follows. When the serial address logical address is given from the host computer,
The two defect lists are searched to check the position and number of defective sectors, the target physical address is calculated from the logical address according to a predetermined calculation procedure in consideration of it, and the optical head is set to the obtained target physical address. Move and access the optical disc. That is, the optical head is moved after calculating the target physical address.

[0004]

The physical address of an optical disk consists of a track address and a sector address,
If there is no defect, the logical address is divided by the number of sectors and the quotient is used as the track address and the remainder is used as the sector address. Since the data of the defective sector recorded in the secondary defect list is written by the group replacement method, the target physical address can be easily obtained by the physical address in the replacement sector depending on the number and position of the defective sectors.

However, since the data of the defective sector recorded in the primary defect list is written by the slip method, an accurate target physical address cannot be obtained only by a simple remainder calculation. That is, it is necessary to check the primary defect list to find the number and position of defective sectors, and to correct the quotient and the remainder value accordingly. Therefore, if a large number of defective sectors are written in the primary defect list, the calculation becomes complicated, it takes a long time to move the optical head, and the access time of the optical disk device becomes long. The present invention has been made in view of the above circumstances, and temporarily converts a logical address into a physical address without considering a defect list and starts moving the optical head.
An object of the present invention is to provide an optical disc access method capable of shortening the access time by moving an optical head and address calculation in parallel by generating an accurate target physical address in consideration of a defect list during movement. ..

[0006]

An optical disc access method according to the present invention generates a temporary physical address from a logical address before referring to a defect list, and moves an optical head to the generated temporary physical address. During the movement, the defect list is referred to, the generated temporary physical address is corrected to generate the target physical address, and the optical head is moved to the generated target physical address. ..

[0007]

In the present invention, the optical head first moves toward the temporary physical address, the defect list is referred to during the movement to generate the target physical address, and the optical head is set to the target physical address. To move. In other words, since the movement of the optical head and the generation of the target physical address are performed at the same time,
The access time is shortened as compared with the case of performing them separately.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail with reference to the drawings showing the embodiments. FIG. 1 is a block diagram showing a schematic configuration of an optical disk drive device used for carrying out an optical disk access method according to the present invention. In the figure, reference numeral 1 is an optical disk drive, which is connected to a host computer 3 via a SCSI bus 4. The host computer 3 sends various control signals and data to the optical disk drive device 1 via the SCSI bus 4, and receives reproduction data from the optical disk drive device 1 via the SCSI bus 4. Optical disk drive 1
Is an ISO standard optical disk 2 stored in a cartridge
Is installed. The optical disk 2 is rotationally driven by a disk motor 11 in a predetermined direction at a constant number of rotations, and an optical head 12 which irradiates a spot light having a predetermined diameter and receives the reflected light is exposed on the lower surface thereof. The optical head 12 can be reciprocally moved in the radial direction of the optical disc 2 by a carriage 13 so that the recording surface of the optical disc 2 can be accessed.

The laser light received by the optical head 12 is converted into an electric signal and given to the access controller 14. The access control unit 14 identifies the position of the optical head 12 with respect to the optical disc 2 based on the received electric signal, and gives a movement command to the carriage 13 according to a command from the CPU 15. The CPU 15 is connected to the host computer 3 via the SCSI bus controller 17 and SCSI bus 4.
Connected with. Also, CPU 15 has RAM 16 connected,
Information on a primary defect list (hereinafter referred to as PDL) and a secondary defect list (hereinafter referred to as SDL), which will be described later, is stored in the RAM 16. Based on the contents stored in the RAM 16, the CPU 15 converts the logical address included in the control signal given from the host computer 3 into the physical address of the optical disc consisting of the track address and the sector address, and the access control unit 14 is given as the command.
When the above-mentioned command is given, the carriage 13 moves the optical head 12 in the radial direction of the optical disc 2 to perform a seek operation on the optical disc 2.

FIG. 2 is a schematic diagram showing the area structure of the optical disc 2. The optical disk 2 is divided into, for example, 25 sectors in the circumferential direction and, for example, about 10,000 tracks in the radial direction, and has a total of about 250,000 physical addresses, for example. One sector has a total capacity of 512 bytes, of which the user area is 374 bytes. The optical disc 2 is provided with two disc management areas DD1, DD2, DD3, DD4 on the inner side and the outer side, respectively, and a user area UA between them. The user area UA is a rewritable area and has a structure in which magnetic layers are stacked. Further, the user area UA is divided into blocks each including a data recording area DR and a replacement area RS. Serial numbers of logical addresses 1, 2, 3 ... N ... M ... are assigned to the user area UA.

In the figure, x indicates a defective sector recorded on the PDL, and □ indicates a defective sector recorded on the SDL. The logical address assigned to the defective sector recorded in the PDL is sequentially shifted and assigned to the normal sector following the slip method. Therefore, as shown in the figure, when the sector addresses 2 and 3 of the track address 5 are defective sectors, the logical address 27 is the track address 5,
Instead of the sector address 2, the track address 5 and the sector address 4 are shifted and assigned. In this way, if a defect occurs during manufacturing, the data is recorded in the user area UA while being sequentially shifted. On the other hand, if a defect occurs during user use, the data of the defective sector is recorded in the replacement area RS. For example, if the physical addresses of the track address 6 and the sector address 2 are defective, the logical address 49 assigned to them is reassigned to the replacement area RS.

FIG. 3 is a schematic diagram showing the data arrangement of the disk management areas DD _{1 to} DD ₄ . Disk management area DD _i (i
= 1 to 4) is a sector management definition area D _i , j of 1 sector
(J = 1, 2 ...) Sector DDL area P _ij , j sector SD
It is composed of an L area S _ij and an empty area. In the disk management definition area D _i , information on grouping in the user area UA, information on the replacement area RS, and PDL and SDL areas P _ij ,
Address information of S _ij is stored. Address information of a defective sector at the time of manufacturing is stored in the PDL area P _ij and
The area S _ij stores address information of the defective sector when the user uses it.

For example, if there is a defect as shown in FIG.
Information of physical addresses of track address 5, sector address 2, track address 5, sector address 3, ... Is stored in the PDL area P _ij , and information of physical address of track address 6, sector address 2 is stored in the SDL area S _ij. It is stored. Therefore, the CPU 15 uses the disk management definition area D
_{Based on} the information of _i , the address information of the PDL area P _ij and the SDL area S _ij is read, its position and number are known, and the PDL area P _ij is read.
If the address of the defective sector is recorded in, the correction is applied when converting the logical address to the physical address according to the position and the number. When the address of the defective sector is recorded in the SDL area S _ij , the logical address assigned to the defective sector is converted into the physical address of the replacement area RS depending on the position and the number.

Further, when a defective sector is recorded in the SDL area S _ij , it is only necessary to assign a logical address to the replacement area RS, so that generation of a physical address requires only a simple remainder calculation and is a simple operation. Although the calculation time is not required so much, the optical head 12 needs to be moved in the radial direction at the time of access, and the access time becomes longer than that in the case where the defective sector is recorded in the PDL area P _ij . On the other hand, when a defective sector is recorded in the PDL area P _ij , since the logical address is shifted and allocated by the slip method, the physical address cannot be generated from the logical address by a simple remainder calculation, and the number and position of defective sectors Requires more complicated calculation. However, since the access can be performed only by waiting for the rotation, the access time is shorter than that in the case where there is a defective sector in the SDL area S _ij as described above.

Next, the access operation of the optical disk drive device 1 will be described. FIG. 4 is a flowchart for explaining the access procedure by the CPU 15. First, a temporary physical address is generated from a logical address by a simple remainder operation without referring to PDL and SDL (S1), and the generated temporary physical address is generated. The access operation to the address is started (S2), and the optical head 12 is moved in the radial direction. And stored in RAM 16 during that move
By referring to the PDL and SDL areas P _ij and S _ij , an accurate physical address is calculated according to the number and position of defective sectors to obtain a target physical address (S3). Then, it is checked whether it is being accessed (S4), and if it is being accessed, the temporary physical address is corrected to the target physical address and the access operation is continued (S6).
When the access is completed, re-access to the calculated target physical address is executed (S5). Then, it is checked whether the access is being performed again (S7), and the operation is continued until the end. In the present embodiment, the case where there are PDL and SDL has been described as an example, but it goes without saying that the present invention is not limited to this and can be applied to an access method of a ROM type optical disc having only PDL.

[0016]

As described above, according to the present invention, the target physical address is calculated and generated during access, so that even if it takes a long time, the access time can be shortened, which is an excellent effect. ..

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an optical disc drive device used for carrying out an optical disc access method according to the present invention.

FIG. 2 is a schematic diagram showing an area structure of an optical disc.

FIG. 3 is a schematic diagram showing an area configuration of a disc management area.

FIG. 4 is a flowchart showing an access procedure of a CPU.

[Explanation of symbols]

 1 optical disk drive 2 optical disk 12 optical head 13 carriage 14 access control unit 15 CPU 16 RAM

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Koji Yamana 3-7-3 Nakamachi, Musashino-shi, Tokyo Inside TAITSUKU Co., Ltd. (72) Inventor Makoto Mashi 3-3-3 Nakamachi, Musashino-shi, Tokyo Tay Atsuku Co., Ltd. (72) Inventor ▲ Kichisuke Kyosuke Moto, 8-1, Tsukaguchi Honcho, Amagasaki City, Hyogo Prefecture Sanryo Electric Co., Ltd. Industrial Systems Research Institute (72) Inventor Masaharu Ogawa 8-chome, Tsukaguchi Honmachi, Amagasaki City, Hyogo Prefecture No. 1-1 Sanryo Electric Co., Ltd. Industrial Systems Research Center (72) Inventor Teruo Furukawa 8-1-1 Tsukaguchihonmachi, Amagasaki City, Hyogo Prefecture Sanryo Electric Co., Ltd. Industrial System Research Center

Claims (1)

Claim: What is claimed is: 1. A target physical address of an optical disk having a defect list indicating the defect position and an area for recording the information recorded at the defect position, and a logical address is determined by referring to the defect list. In the method of generating an address, moving the optical head to the generated target physical address, and accessing the optical disc, a temporary physical address is generated from the physical address in a predetermined procedure, and the temporary physical address is generated to the temporary physical address. The optical head is moved, and during the movement, the generated physical address is corrected by referring to the defect list, the target physical address is generated, and the optical head is moved to the generated target physical address. A method of accessing an optical disc, characterized by: