DE19860991B4 - Rewritable optical disk comprises recording area divided into groups by annular boundaries with spare area with sectors to be allocated in place of defective sections - Google Patents

Abstract

The disk recording area is divided into groups by annular boundaries, each group has a spare area with sectors to be allocated in place of defective sections. The number of sectors per track differ from one group to another. Several radially innermost and outermost tracks of a zone are guard areas not used for recording or reproducing data. A control data area, holding information to control recording/reproduction, is provided at the radially innermost read-only area. In the rewritable areas inside the radially innermost zone and outside the radially outermost zone are defect management areas (DMAs) that hold information needed to control replacement of defective sectors. Two DMAs are on the radially inward side and two on the radially outward side. The control data contains information on the number, sizes and start positions of the DMAs. The start position of the control data area is always at the same position regardless of the disk recording capacity. The sizes of spare areas are specified at initialization of the optical disk by the disk processing apparatus. The sizes or first addresses of the spare areas are recorded in the defect management areas. The position of the spare area used in place of a defective sector and the defective sector position are managed by a defect list in a DMA.

Description

The The present invention relates to a drive device for one optical disc, in particular a rewritable optical disc, their recording surface in several groups by annular Borders is divided, with each of the aforementioned groups a Substitute area with Sectors, which instead of bad sectors of the disc can be assigned having.

The data zone format of the conventional optical disk will be described. 16 shows the data zone configuration of an optical disc described in "STANDARD ECMA-201, DATA INTERCHANGE ON 90 mm OPTICAL DISC CARTRIDGES". Although the standard refers only to the read-only type, the partially rewritable type, and the fully writable type, the following description applies to the fully rewritable type only.

Referring to the figure, one data zone contains four defect handling areas (DMA). Two of these are in front of a user interface and the other two are behind the user interface. Buffer marks are on the radially inner side of the defect handling surface 1 and on the radially outer side of the defect handling surface 4 arranged. An area between the defect handling area 2 and the defect handling area 3 is referred to as a user interface constituting a recording / reproducing surface in which user data is recorded and reproduced. Each defect handling area includes a disk definition structure (DDS), a primary defect list (PDL), and a secondary defect list (SDL). The DDS is recorded in the first sector of each DMA after the disk has been initialized. The information stored therein contains a code which indicates the disc type of each group as being rewritable or readable, and the first addresses of PDL and SDL. PDL contains the addresses of all defective sectors that are detected during initialization. SDL is located immediately after PDL and contains the addresses of defective sectors and the addresses of spare sectors for use in handling defective sectors detected during recording. PDL and SDL are defective (handling) information for handling defective sectors on the optical disk. The sizes of PDL and SDL are determined by the length of information stored therein. Identical PDLs and identical SDLs are recorded in the four defect handling areas of the disk.

DMAes are located at positions with the first addresses predefined on the disk. 17 shows the positions of DMAs on the conventional optical disk. The ECMA-201, which explains an example, specifies fixed values as in 17 is shown.

The ISO / IEC 15041 standard, which concerns the same type of optical disk with different capacity, defines a similar group configuration with two options of 512 bytes per sector 2048 bytes per sector. 18A and 18B show the positions of DMAs on a different type of conventional optical disk. As in 18A and 18B is shown, the disk has fixed values which are different from the values of the example described above.

The Drive device, which for the reproduction of the two previously described Types of discs is capable of containing information that includes the memory locations of DMAen the disk types in their firmware.

The size of the replacement area in each zone of these slices is substantially proportional to the size of the user area in the same zone. 19 shows the size of the replacement area of the conventional ECMA-201 optical disk. As shown in the figure, the number of spare tracks is determined so that the ratio of the number of spare tracks to the number of data tracks is not less than 0.2%. The replacement surfaces are located at the ends of the respective zones.

at the device, which the above-described optical disc medium drives is that of the host machine a position information sent as a parameter of a read / write command logical address and this must be through the drive into a physical Address to be converted. additionally must the Group configuration can be specified to the location of spare sectors for defects Identify sectors.

There the conventional ones optical disks configured as described above, it is required to add the firmware of the optical disk device or to modify what the conversion between physical Addresses and logical addresses as well as the defect handling, which controls the allocation of replacement surfaces when a medium is introduced with a different group configuration.

Also is the size of the defect handling area for each group set, and the sizes of Defect management areas a disc with a special group configuration may be for some Applications larger than to be required.

If a medium with a new group configuration is introduced, is an optical disc device, which only with the conventional group configuration can not be used by the medium of the new one Group configuration, since the information which the Position of the surface containing the position information of the area containing the position information of bad sectors, and of the area containing the the group configuration indicating information does not indicate from the disk can be obtained.

There Data usually in a zone containing a sector with a lowest logical address have zones containing sectors with lower levels logical addresses a higher Probability of using the replacement surface. However, the sizes of replacement surfaces in the different zones of the disc essentially proportional to the sizes of user surfaces in the zones. Accordingly, the Error rates of data recorded in the zones of the disc are not uniform.

The Zone containing the sector with the lowest logical address value, e.g. the value "0", contains different Control data and requires a higher Reliability. But because the size of the replacement area in each Zone of the disc is substantially proportional to the size of the user interface in the Zone is, reliability is the control data insufficient.

The EP 0 798 714 A2 describes an optical disc and the handling of errors on such an optical disc. According to this document, the position and the size of replacement surfaces are set in advance at the time of manufacture or at the time of initialization.

The US 5,235,585 also discloses an optical disk and method for replacing secondary defects on the disk. To do this, a list of bad sectors is created to find replacement sectors that were previously used. The replacement sectors are already fixed in advance. The EP 0 813 189 A1 also discloses an optical disk. This document is essentially concerned with an improvement to minimize the degradation of the disc upon repeated writing.

It The object of the invention is a drive device for an optical To provide disc, which is used for recording and playback itself without changing the firmware of the conventional device if optical discs with different group configuration introduced become. This should allow the size of a replacement face changed using application programs and the replacement area accordingly the user access frequency and the degree of importance of the recording Data can be assigned.

These Task is solved by the drive device according to claim 1. advantageous Further developments are given by the dependent claims.

According to one Aspect of the present invention is an optical disk drive apparatus provided, the actuated is to data in user interfaces an optical disk to read and / or write, and replacement surfaces instead of user interfaces to use in the case of defects in the user interfaces, the Disk drive device operable is to read information from a disc making up the Position and size of replacement surfaces determined can be.

at the above arrangement it is possible the position and size of the replacement surface the basis of the information read by the optical disk to determine.

According to the present invention, there may be provided a rewritable optical disk whose recording surface is divided into a plurality of groups by annular boundaries, the number of sectors per track being different from one group to another, the optical disk having a read-only area containing a control data area Holding information for controlling the recording / reproducing operation of the optical disk,
wherein the control data area includes a parameter that expresses a linear function of the group number to obtain the number of tracks in a given group, or a linear function of the group number to obtain the number of sectors in a given group.

In the above arrangement, the number of tracks in particular groups or the number of sectors per track is a linear function of the group number. The zone configuration is identified by using the constant of this function as information indicating the group structure. Accordingly, the disk allows the identification of the zone configuration from fewer parameters than a slice with a table of the number of sectors for the respective zones. In addition, by maintaining linear relationships for all Pa parameters determining the zone configuration of the optical disk, the firmware routine of the optical disk drive apparatus can be simplified.

According to one Another aspect of the invention is a rewritable optical Slice provided, the recording surface in several groups through annular Boundaries is divided, where the number of sectors per track of one group is different from the other, with the optical disc an only readable area comprising a control data area contains what information to control the recording / playback process holding the optical disc, and wherein the defect handling area contains information to the Number of sectors in the replacement area of a given group to obtain.

at In the above arrangement, the number of sectors of the spare surface can be made special Groups are obtained by using the stored in the defect handling area Information. This disc allows that the Group structure identified with a smaller amount of information becomes.

The Arrangement can be made so that the Information is a parameter of a linear or quadratic Function of a group number to the number of sectors in the replacement area of the given group.

at In the above arrangement, the number of spare surface sectors is special Groups a linear or quadratic function of a group number. The number of sectors of the spare area in each group may be known by using constants of the function as the group configuration indicating information. This disc allows the group structure to be filled with a less information is identified than the disc with a table of the number of sectors for the respective zones. In addition, through Maintaining linear relationships for all parameters that determine the number of sectors of the replacement area in the optical disk determine the firmware routine of the drive device for one optical disc can be simplified.

The Arrangement can be made in such a way that the information is a ratio of Number of sectors belonging to the replacement area to the total number of sectors includes.

at the above arrangement is the number of sectors in the spare area of particular groups proportional to the number of sectors in the same Group, and the relationship is recorded in the area, the position information about the replacement face each group has, so that the zone configuration can be identified with a smaller amount of information as in the case where the firmware of the drive device for one optical disc tables over the size or position the replacement area used.

Even when the drive device for an optical disk an optical disk with an unknown Disk Group Structure drives the data through use the position information about the replacement area recorded and played back.

The Invention will be described below with reference to FIGS Embodiments explained in more detail. It demonstrate:

1 a zone configuration of an optical disc for the first embodiment of the present invention,

2 an example of the configuration of a zone of the optical disk for the first embodiment of the present invention,

3 an example of information about the physical format of the optical disc for the first embodiment of the present invention,

4 an example of configurations of DMA and DDS of the optical disk for the first embodiment of the present invention,

5 a processing flow when a disk is loaded on the optical disk driving apparatus according to the first embodiment of the present invention;

6 an example of the DDS configuration for the optical disk for a second embodiment of the present invention,

7A and 7B Examples of Zone Sizes of the Optical Disc for a Third Embodiment of the Present Invention

8th an example of zone sizes of the optical disk for a fourth embodiment of the present invention,

9 the design of parameters indicating the number of sectors in the spare areas of the optical disk zones for the fourth embodiment of the present invention;

10 an example of zone sizes of the op table disc for the fifth embodiment of the present invention,

11 the configuration of the DMA and the control data area of the optical disc for the first embodiment of the present invention,

12 an example of the configuration of DMA and DDS of the optical disk for the first embodiment of the present invention;

13 the configuration of the optical disk handler according to the first embodiment of the present invention;

14 an example of the configuration of the respective zones of the optical disc for a sixth embodiment of the present invention,

15 another example of the configuration of the respective zones of the optical disk for the sixth embodiment of the present invention,

16 the configuration of a data zone of a conventional optical disk,

17 the DMA design of a conventional optical disk,

18A and 18B Examples of the DMA design of another conventional optical disk, and

19 the size of the replacement surface of the conventional optical disk.

Embodiment 1

1 Fig. 15 shows a zone configuration of the optical disc medium for the first embodiment of the present invention. The zones are a plurality of annular surfaces divided according to their radial positions on the disk, and each zone is formed by a plurality of tracks. Each track consists of recording / playback units such as sectors. In 1 zone 0 consists of four sectors, zone 1 consists of five sectors and zone 2 consists of six sectors. The number of sectors per track depends on the group. 2 Fig. 16 shows an example of the configuration of a zone of the optical disc medium for the first embodiment of the present invention. Each zone consists of a group formed by a user area and a spare area as well as protection areas on both sides of the group. The guard surfaces are provided to prevent crosstalk from a track in an adjacent zone across the boundary of zones. For example, in a ZCAV format pre-formatted optical disk, the headers are in angular positions that are different between adjacent tracks across a zone boundary, resulting in crosstalk. Accordingly, a plurality of radially innermost and outermost tracks of a zone are not used for recording or reproducing data and serve as protection areas. The user interface is an area in which the user is allowed to record and play back data. The substitute area is an area with sectors used for sectors in the user area in the case where the user area has sectors which have defects or the like and can not be suitably used for recording or reproducing.

In the radially innermost read only surface of the disc is a control data surface provided for Holding information necessary to control the recording / playback needed such as the speed of rotation of the disc and the recording or playing needed Laser power.

In the rewritable areas within the radially innermost zone and outboard of the radially outermost zone, defect handling areas (DMAs) are provided for holding information needed to control the replacement of defective sectors. 11 shows the configuration of DMAs and the control data area on the optical disk medium for the first embodiment of the present invention. In the first embodiment, four DMAs with identical contents are provided to increase the reliability. DMA1 and DMA2 are on the radially inner side of the disc, while DMA3 and DMA4 are on the radially outer side.

The control data area contains information about the physical format including the position information recorded to indicate the positions of the above-described defect management areas DMA1 to DMA4. 3 Fig. 13 shows the physical format information in the control data area of the optical disc medium for the first embodiment of the invention. As shown in the figure, the position information includes the information about DMAs such as the number, sizes, and start positions of the DMAs. The control data area storing the information on the physical format is always recorded in the same position irrespective of the recording capacity of the optical disk.

• – Anzahl von Zonen auf einer Scheibe: zn
• – Anzahl von Spuren in einer Schutzfläche: gtn(N)
• – Anzahl von Spuren in jeder Zone: tn(N)
• – Anzahl von Sektoren in jeder Spur: sn(N)
• – Erste Adresse der Benutzerfläche in jeder Zone: ua(N)

The physical format information stored in the control data area Parameters that can be used to identify the group configuration of the disk. The parameters include the following:

• - Number of zones on a disk: zn
• - Number of tracks in a protection area: gtn (N)
• - Number of tracks in each zone: tn (N)
• - Number of sectors in each track: sn (N)
• - First address of the user interface in each zone: ua (N)

Here N represents the zone number.

These values and functions indicate the physical configuration of the disk and are not changed as long as the same disk substrate is used. The disk is designed so that the number of tracks in each zone, tn (N), and the number of sectors in each track sn (N), can be expressed in the form of a linear function. In 3 only constants of a linear function are stored for the number tn (N) of tracks in each zone, or the number sn (N) of sectors in each track. If the number tn (N) of tracks in each zone is given, for example, by t1 · N + t0, the constant t1 and the constant t0 are stored as parameters. For the number sn (N) of sectors in each track, the constant s1 and the constant s0 are stored as parameters in the same way. The first address of the user interface in each zone is also recorded only by storing the constants of a corresponding function.

One of the elements that define the group configuration of a disk is the size of the replacement surface. The sizes and positions of the replacement surfaces are defined in the prior art. However, in this embodiment, the size of the spare surfaces in the initialization of the optical disk is determined by means of an optical disk handling apparatus, which is not shown. The determined sizes or first addresses of the spare surfaces are recorded in the defect handling areas. As described above, these surfaces are used to compensate for disk defects. When a sector in the user interface can not be suitably used for recording or reproducing due to contamination or defect of the medium, a sector in the spare area is used in place of the sector which can not be used for recording or reproducing. The position of the defective sector and the spare area used instead of the defective sector are usually handled by means of a defect list in a defect handling area or DMA. 4 Fig. 14 shows an example of the configuration of a DMA and DDS of the optical disc medium according to the first embodiment of the present invention. Each DMA contains a defect list and a slice definition structure (DDS) that defines the structure of the data area of the slice. In this embodiment, the spare area defining parameters are stored in this area. The number spn (N) of sectors in the replacement area should preferably be set so that the ratios between the user area and the replacement area are identical for all zones. The reason for this is as follows: if a certain zone has a smaller replacement area, the replacement area in this zone is used up earlier than in other zones. Since the spare area must be allocated to another area, the frequency of seeking the header increases, thereby reducing the data transfer speed.

Since the number tn (N) of the tracks per zone and the number of sectors per track are at best linear functions, the number of sectors per zone is at best a quadratic function. In 4 For example, the number of spn (N) of sectors in the spare area of each zone is expressed by a quadratic function, spn (N) = sp2 * N * N + sp1 * N + sp0. If the number of tracks per zone is constant, then spn (N) can be represented by a linear function.

12 Fig. 14 shows an example of the configuration of DMA and DDS of the optical disc medium for the first embodiment of the present invention.

Like the size of the replacement area, the number of tracks in the protection area is determined by recording the parameters of the function. In 4 For example, the number of tracks in a guard area is a constant, as indicated by gtn (N) = gt0. This results from the fact that the required protection area is constant, regardless of the position of the zone.

The Number of sectors in the replacement area of a zone may alternatively as a relationship expressed in terms of the number of sectors in the user area who the. By using From this expression, the functional record area can be reduced.

The replacement face Each zone can be determined by means other than the number of sectors be expressed as a function by using the first address of the spare area instead the size of the replacement area.

As the replacement area increases, the freedom of the disk generally increases, but the area the user can use decreases. That is, the user data capacity of the disc decreases. The size of the replacement surface of the conventional optical disk is set to such a value that sufficient reliability can be ensured on the basis of the user data error rate, which is calculated from the defect rate of the disc. When recording image or sound information, some applications require a longer recording capacity (time) even if the defect ratio slightly increases. The usability can be increased by making it possible to make the position and size of the replacement area variable in each zone instead of defining it. This can be achieved by recording the layout information of the spare area for each zone in a rewritable area, as in FIG 4 is shown. The information is recorded when the disk is initialized.

The Start position of the replacement surface Each zone can be in the DDS area be saved, but the starting position of the replacement area needs not to be stored if the replacement surface is designed to be instantaneous according to the user interface starts without one Gap between these is left.

On in this way, the user or the application program can determine the size of the replacement area, when the disk is initialized. This does it for example possible, the size of the replacement surface 0 and to maximize the user interface, and in addition build a unique defect handling system in which e.g. just the file system of the host computer handles defects.

The Disc is designed so that the Zone configuration only from the parameters of the information for the physical Format and the DDS is known. This makes it easy to get the firmware to set up a disk drive device which is capable is to record and reproduce on media which ones to use a variety of formats in the future can be used. The disk group structures corresponding to the plural formats do not need to be saved. If a disc with a new group structure introduced is needed after the device is manufactured Firmware less modifications than before. When playing with the physical Properties that are the same as before, is possible can no modification for the playback will be required.

To obtain the group configuration from the information described above, the DDS contained in the DMA must be read correctly. As in 3 4, when there are four DMAs, and when DMA1 and DMA2 are on the radially inner side of the disk and DMA3 and DMA4 are on the radially outer side of the disk, the positions of the radially outer DMA3 and DMA4 change corresponding to the disk capacity or the disc radius. Accordingly, the position information of DMAen in the physical format information section of the control data zone is recorded in the read-only area of the disc. The size and number of DMAs are also recorded together. By doing so, the positions of DMAs are detectable by first reading the physical format information section, even if the slice size varies. Since the position information is recorded as prepits in the read-only area, the risk of accidental erasure can be eliminated. The recording position of the physical format information section is set to an identical address in each type of slices.

If several types of discs different rotational speeds or different modulation methods, but it would be difficult, the Read control data zone. Accordingly, it is desirable, that this Modulation method is standardized, so that the compatibility easily can be made sure and at least the data in the control data zone be recorded in such a format that the data is read can, even if the disc type is unknown.

5 Fig. 12 shows the flow of processing when a disk is loaded in the optical disk driving apparatus according to the first embodiment of the present invention. 13 FIG. 10 shows a configuration of the optical disk handling apparatus according to the first embodiment of the present invention. FIG. In 13 denotes the reference number 1 an optical disk, the reference number 2 denotes a disc motor, the reference numeral 3 denotes an optical head and the reference numeral 4 denotes an information recording / reproducing apparatus including an error corrector and a modulator / demodulator. The reference number 5 denotes a group configuration identification section that identifies the group configuration of an optical disk based on the following information: number zn of zones; Number tn (N) of tracks in each zone; Number sn (N) of sectors in each track; Number gtn (N) of tracks in a protection area; and first address, among others, (N) of the user area in each zone. The reference number 6 denotes a physical / logical address converter which locates the spare area of each zone according to the spare area information in the DMAs and converts the logical address sent from the host computer into a physical address when reading or writing to the disk.

The reference number 7 denotes a RAM which stores a defect list. The reference number 8th denotes a control device that controls the various sections. In the 13 The handling device shown reads and writes data to an optical disk as will be described below. When a disc is loaded, first the physical format information section in the control data area is read. The read information provides the number zn of zones, the number tn (N) of tracks in each zone, the number sn (N) of sectors in each track, the number gtn (N) of tracks in a protection area, and the first address and the like (N) of the user area in a zone corresponding to the group configuration identification section 5 be sent. Then the position of each DMA is located from the delivered positions, numbers and sizes of the DMAs. Access is made to the DMA to read the information including the defect handling information, from which the number of spn (N) of sectors in a spare area is obtained. At the same time, a defect handling table in the RAM 7 saved. Based on the information, the physical / logical address converter identifies 6 the group configuration, and the positions and sizes of the spare surfaces are known. Accordingly, the logical address of a sector to be read or written sent by the host computer may be in a physical address with respect to the defect handling table in the RAM 7 being transformed.

Embodiment 2

In the first embodiment, the number of sectors in the spare area of each zone is defined as at best a quadratic function, and the constants of the function are recorded as parameters in the DDS area. In the second embodiment, the number of sectors in the spare area of each zone is set to be proportional to the total number of sectors in the zone, and the ratio is recorded in the DDS area as a parameter indicating the group configuration. 6 Fig. 16 shows an example of the configuration of the DDS of the optical recording medium for the second embodiment of the present invention. As shown in the figure, the number of sn (N) of sectors in the replacement area of each zone is the k (constant) times the number of sectors in the zone, tn (N) * sn (N), and only those Constant k is stored in the DDS area. Compared to the first embodiment, the second embodiment requires less parameters to be stored and makes it easier to determine the group configuration.

Embodiment 3

In the first embodiment, the size of the replacement area is set as a linear function, so that the ratio of the replacement area to the user area is constant. 7A and 7B show examples of combinations of zone sizes of the optical disk medium for the third embodiment of the present invention. At the in 7A As shown, the radially inner zones are assigned lower logical addresses. Both the number us of sectors in a user area and the number ss of sectors in a spare area are linear functions of the zone number. However, the ratio of the number of sectors in an equivalent area to the number of sectors in a user area is higher in the radially inner zones than in the radially outer zones.

The logical address is an address value that succeeds from the beginning of the user interface assigned. In the optical disk according to this embodiment are the logical addresses from the radially inner position to the radially outer position assigned. Data is successively from the radially inner Position of the disc recorded. Accordingly, radially inner surfaces are more common Subject to recording or reproduction. If the sizes of the replacement surfaces set in the manner according to this embodiment This group configuration can easily be represented by parameters and recorded on the disc. By increasing the ratio the replacement area in the radially inner zones, reducing the recording / playback error rate in the zones, which are more common recording or playback is reduced it is possible the replacement area at a ratio to the user interface according to the frequency of Provide access to the zone.

It is rare that the entire surface of the Disk is used, and surfaces with lower logical addresses are used more often. The above Procedure uses the spare surfaces effective and adapted to the practical condition of use. A similar Effect can be obtained if additional spare surfaces are added to the zones allocated, where the frequency of replacement is higher, for a disk with more spare surfaces than the number of replacements, which can be recorded in the defect list.

At the in 7A As illustrated, the logical addresses are assigned from the radially inner position to the radially outer position of the disk. When the logical addresses are assigned from the radially outer position to the radially inner position, the radially outer zones have a larger ratio of the replacement area size to the user area size. An example is 7B shown.

In the 7A or 7B The tables shown may be recorded in the DDS if the capacity of the DDS permits.

Embodiment 4

When the disk for the fourth embodiment is used as a storage medium for computers, user data is recorded in files according to a logical format such as the total disk format (UDF) or the DOS. In the logical format used in this embodiment, descriptors such as a file record position, size, attribute, and the like are recorded in the vicinity of the location with the lowest logical address value, eg, "0". For example, in a disk where logical addresses are sequentially allocated from the radially inner position to the radially outer position, such descriptors are stored in the radially innermost zone. 8th FIG. 16 shows an example of zone sizes of the optical disc medium according to the fourth embodiment of the present invention. In the disk having zones, as shown in the figure, descriptors are stored in the radially innermost zone, and the ratio of the replacement surface to the user surface in the radially innermost zone 0 is greater than the corresponding ratios in other zones. 9 Fig. 12 shows the configuration of parameters indicating the number of sectors in the spare area of each zone of the optical disc medium according to the fourth embodiment of the present invention. As shown in the figure, the function spn (N) included in the spare area of each zone, which is included in the DDS area, is used only when N is 1 or more. If N equals 0, a separately recorded value is used.

In the 8th The tables shown may be recorded in the DDS if the capacity of the DDS permits.

With This disk configuration can reduce the degree of deterioration in the access performance, which is due to an increase in the number of defective sectors due to a defect or contamination in the zone containing the important descriptors of the logical Format is effected considerably be lowered. As it becomes rarer that time to read or write Descriptors is long, a disc with a high degree of freedom be provided by defects.

To the for The file handling descriptors are used each time Access when the data is played back on a disc, recorded or deleted become. If the number of bad sectors in the zone, in which the descriptors are stored increases, and when a spare area of a other zone as a result of replacing defects will, often occurs a search over a big Distance up. This situation can be avoided by the substitute area allocation method according to the fourth embodiment.

Embodiment 5

In the disc for the fifth embodiment, the descriptors such as file record position, size and attribute are recorded near the place of the lowest logical address, eg "0", and nearer the place with the highest logical address. 10 FIG. 16 shows an example of zone sizes of the optical disk medium for the fifth embodiment of the present invention. The disk shown in the figure stores the descriptors in both the radially innermost zone and the radially outermost zone. The ratios of the replacement surface to the user surface are higher in the radially innermost zone 0 and the radially outermost zone 6 than those in other zones. Accordingly, it is possible to obtain a disk using a file format having such a logical format that the descriptors are stored in the radially innermost zone and the radially outermost zone of the disk, and having less deterioration in the access performance against defects.

With This disc configuration can be a disc with increased freedom across from Defects are provided, as in the fourth embodiment, because the number of bad sectors due to a defect or an impurity which is allowed to be contained in the zone the important descriptors of the logical format, is increased, and it becomes rarer that the time used to read or write the descriptors.

In the 10 The tables shown may be recorded in the DDS if the capacity of the DDS permits.

Of the mentioned in this description Sector means a recording / reproducing unit. In one System in which multiple sectors are treated as a single block to which an error-correcting code is added, For example, the word "sector" may be read to include a Block means.

Embodiment 6

14 shows a zone and group config ration applied to an optical disc having a diameter of 120 mm, and an example of the assignment of the user area and the replacement area in each group. As shown in the "zone number" column of the figure, the disk surface is divided into 35 zones in which the zone numbers extend from 0 to 34, and a group consisting of a user area and a spare area is formed in each zone. The logical addresses are sequentially allocated to the sectors of the user area from the radially inner sector to the radially outer sector, beginning with the radially innermost part of the disk.

The Track pitch is 0.59 μm and Zone 0 starts from a slice position with one Radial position (radial distance from the center) of 24 mm. In the "radius" column of the figure the radial starting position of each zone is indicated. In every zone if a single track consists of sectors whose number is represented as sn (N) expressed in the figure is. For example, in zone 0, a single track has 25 sectors, and the number of sectors per track decreases with each transition to an adjacent outer zone one too. Because the number of tracks in each zone is set to 1632 is, each zone has a radial width of about 0.96 mm, as in the figure is shown. The zone 34, however, has 1344 tracks. This it follows that the radial position of the outermost Track is set to 57.53 mm so that it is at a position about 2.5 mm inside the disc edge is, taking into account variations in the properties of the recording film of the disc.

at This example shows 16 sectors with consecutive logical addresses as a single block when reading or playing handled by data. The number of blocks in each zone will be in the "bn (N)" column of the figure displayed. The value bn (N) of each zone is given by this expression given: bn (N) = sn (N) × tn (N) / 16. In zones 0 through 33, bn (N) = sn (N) × 1632/16. In zone 34, which has fewer tracks is bn (N) = sn (N) × 1344/16.

The from bn (N) blocks area in each zone is made up of user blocks UB, which is the user interface represent, spare blocks SB, which the replacement area represent, and protection blocks GB1 and GB2, which are the protective surfaces, on the radially inner side and the radially outer side of the user and Replacement surfaces positioned are. UB and SB form a single group.

Everyone Guard block GB1 and GB2 is formed of sectors of an integer Number of blocks, so that you at least one length of two tracks, i. to satisfy gtn (N) = gt0 = 2. Accordingly radially outer zones one gradually increasing number of blocks in GB1 and GB2. GB1 of zone 0 contains the introductory block, the is located at the radially innermost position of the disc, as well of the blocks the ordinary one Protective surface. Therefore, the number of blocks elevated and is 256. Located in the introductory area yourself the defect handling area and other surfaces, which are necessary for the control of the optical disc.

The Number of blocks in the protective area, which meets the requirements described above, can be obtained by calculation become. In this embodiment can calculate the number by the following calculation using the Number of sn (N) to be obtained from sectors per track: GB1 = GB2 = INT [(sn (N) × gt0 - 1) / 16] + 1. The symbol INT [.] Means that all digits to the right of the decimal point be omitted. Therefore, at an actual Device with an optical disc GB1 and GB2 each zone off the number sn (N) of sectors per track are calculated.

The Number SB of spare blocks in each zone 75 in the zone 0, and the other spare blocks are allocated so that the number at every transition to an adjacent outer zone three increases, each time the zone number increases by one, as shown in the figure. The number spn (N) of sectors in the replacement area with the group number N is expressed as spn (N) = (3N + 75) × 16 = 48N + 1200. If the values "48" and "1200" of this expression in the defect handling area as parameters indicating the replacement area size, can store the number of spare sectors in each group be easily obtained.

Instead of of spn (N), the number spb (N) of spare blocks can be defined as spb (N) = spn (N) / 16, and can be determined by spb (N) = 3N + 75. The one in the defect handling area as the parameters that indicate the size of the replacement area, stored values are "3" and "75", and they are thus smaller and can be handled easily, as they have a smaller number of bits can be recorded. Of course spb (N) can be used in the same way as spn (N) to get the Calculate the size of the replacement area.

In the "SB / UB" column of the figure, the ratio of the number of spare blocks SB to the number of user blocks UB is displayed in each group. In the example shown, the number of spare blocks allocated in each group of zones 1 to 33 is equal to 3.04% of the number of corresponding user blocks. In the radially innermost zone 0 and the radially outermost zone 34, in which the information for handling the on the Disk recorded files and other important information used for the file system, the ratios of the number of allocated spare blocks to the number of user blocks are equal to 3.39% and 3.72%, respectively, which are higher than those in other zones.

hereby can be an optical disc with a high freedom from defects be provided as in connection with the above fourth and fifth embodiment explained is.

15 FIG. 16 shows another example of the allocation of user area blocks and spare area blocks in an optical disk having the same zone configuration as that in FIG 14 . shown The number of zones, number of lanes in each zone, lane division, radial positions, number of sectors per lane and number of sectors per block are not changed. The logical addresses are sequentially allocated in the same ways, ie from radially inner sectors to radially outer sectors in the user surfaces, starting with the radially innermost sector of the disk. Accordingly, the "bn (N)" value of each zone is the same as that in FIG 14 shown example.

The Number SB of spare blocks, allocated to each zone is 90 in zone 0, as in the figure is shown, and at each transition to an adjacent outer zone at two, and each time the zone number increases by one. Accordingly, the Number spn (N) of sectors in the spare area of group N as follows expressed: spn (N) = (2N + 90) × 16 = 32N + 1440. If the values are "32" and "1440" in this expression in the defect handling area as parameters indicating the size of the replacement area, can store the number of spare sectors in each group be easily obtained.

As in the preceding example, the number spb (N) of spare blocks may be used instead used by spn (N), and this is defined as spb (N) = 2N + 90. When this happens, those in the defect handling area are considered Parameters indicating the size of the replacement area, stored values equal to "2" and "90".

In the "SB / UB" column of the figure is the relationship the number SB of the spare blocks to the number UB of user blocks displayed in each group. In the example shown, the allocation is too the groups in the zones 1 to 33 such that the replacement block ratio SB / UB gradually to the radially outer zones with higher logical addresses decreases. The replacement blocks are in such a way assigned that relationship to the number of user blocks varies from about 3.61% to 2.72%. In the radially innermost zone 0 and the radially outermost zone 34, where the information for the handling of the files recorded on this disc and other important information about that The ratios of allocated spare blocks are the same 4.09% and 3.78% respectively, whichever is higher are as the relationships in other zones.

This can provide an optical disk with a high freedom from errors, as in connection with 14 is described. In addition, more spare surfaces near the user surfaces can be arranged in radially inner groups, which are used more frequently, and the deterioration of the average access performance can be minimized even if the spare surfaces become short.

If the allocation of replacement surfaces as in 14 is shown, the total number of replacement area blocks is 4410. When the allocation of spare areas as in 15 is shown, the total number of spare surface blocks 4362 is. The number of defects that can be stored in the list provided for defect setting in the defect handling area of the disk is limited by the maximum length of the list. In general, when the disk is loaded in the drive, the entire list is read, stored in the memory of the device and used. Accordingly, the size of the memory of the device that is estimated for use generally determines the maximum length of the list for the defect setting.

If as a typical example, the information for the entry of a single Defect is represented by eight bytes in the list and if a 32K byte memory is used the replacement information of up to 4096 defects to the same Time to be saved. When the number of spare surface blocks 4410 or 4362 is how described above, the list for the defect can be full since the number of spare blocks is larger than the number of defect setting information entries, which is 4096.

There more than 4096 spare blocks provided and assigned to the groups can be groups with higher incidence of defects the replacement area in the same group with higher ones priorities use and use groups with a lower incidence of defects the replacement area in the same group with a lower frequency. Accordingly, the Probability of replacement in replacement surfaces across the boundaries of the group down, and the deterioration in average access performance can be minimized even if many defects occur.

Claims (8)

An optical disk drive apparatus operable to read and / or write data in user surfaces of an optical disk and to use spare surfaces instead of user surfaces in the event of defects in the user surfaces, the drive apparatus being operable to receive information from a disk read and / or recorded on it, characterized in that the position and the size of replacement surfaces can be determined from the information read. Drive device according to claim 1, characterized in that that the recording surface the optical disc in several groups by annular boundaries is divided, where the number of sectors per track of a group different from one another, that the optical disc a has only readable area, the one control data area contains what information to control the recording / playback process at the optical disc stops, and that the control data area a Contains parameters that a linear function of the group number to the number of tracks in a given group, or a linear function the group number to the number of sectors in a given Get group expresses. Drive device according to claim 1, characterized in that that the recording surface the optical disc in several groups by annular boundaries is divided, where the number of sectors per track of a group different from one another, that the optical disc a only readable area owns a control data area contains what information to control the recording / playback process at the optical disc stops, and that the defect handling area contains information to the Number of sectors in the replacement area of a given group to obtain. Drive device according to claim 3, characterized in that that the Information a parameter of a linear or quadratic Function of the group number to the number of sectors in the replacement area of the given group. Drive device according to claim 3, characterized in that that the Information a ratio of Number of sectors belonging to the replacement area to the total number of Sectors belonging to the given group have. Drive device according to claim 1, characterized in that that the optical disc is a single-spiral bridge / groove disc, which is a Offset header information and a memory area comprising: one Control data area, a recording area that is in a Variety of annular Zones is divided, each annular zone a different Number of sectors per track, and includes a user area in which the user can record and play back information, and one Spare area that owns sectors instead of faulty ones Sectors can be assigned to the disc; the said Control data area includes a spare area size field, the on the selected one Size of said Spare area refers. Drive device according to claim 1, characterized in that that the optical disc is a single-spiral bridge / groove disc, which is a Has offset header information and has a memory area, which includes: one Control data area, a recording area that is in a Variety of annular Zones is divided, each annular zone a different Number of sectors per track and a storage area includes, in the user can record and play information, and one Spare area, which has sectors instead of faulty ones Sectors of the disc can be assigned; the said Spare area has a size, the dependent can be varied according to need, and where the total space, the occupied by the said recording area and the spare area is substantially constant, so that the reduction in the size of said Spare area the size of said Recording area increased. Drive device according to claim 1, characterized in that that the optical disc has a recording area in annular zones is formed and contains user areas and replacement areas, for Use in case of errors in the user areas, where the ratio of Spare area to user area in at least one of the following Zones, namely a zone that contains a sector that has the lowest logical Address, and a zone containing a sector, the the biggest logical Owns address, is larger as the corresponding ratios in other zones.