KR100609857B1 - Optical recording medium and method for formatting - Google Patents

Abstract

A method of formatting a rewritable optical record carrier, and more particularly, by only registering SDL as a PDL during formatting and not sleeping to allocate a spare area to the user area as many defective sectors as registered in the PDL. The same state as in the case of purchase can be maintained, and there is no need of finding a sector corresponding to the first LSN or storing a starting sector number corresponding to the first LSN. If there is a sub spare area, the sub spare area may be allocated to the user area and used. Even if it is sleeping, only the region except for the predetermined predetermined region of the main spare region is obtained, thereby obtaining the same effect as in the case described above. In particular, converting only the first sector of a SDL defective block to PDL can reduce the probability of DMA overflow, thereby extending the life of the disk.

Description

Optical recording medium and method for formatting

The present invention relates to a rewritable optical record carrier and a method for formatting thereof.

In general, optical recording media can be classified into three types, such as read-only ROM, write-once worm type, and rewritable rewritable type. Lose.

Among them, freely and repeatedly rewritable discs include a rewritable compact disc (CD-RW) and a rewritable digital versatile disc (DVD-RAM, DVD-RW).

In the case of such a rewritable optical recording medium, the recording / reproducing operation of information is repeatedly performed due to its use characteristics, and thus, the mixing ratio of the mixtures constituting the recording layer formed for recording information on the optical recording medium is increased. It becomes different from the mixing ratio and loses its characteristics, resulting in an error in recording / reproducing information.

This phenomenon is called deterioration, and the deteriorated area appears as a defect area when the format, recording, and reproducing command of the optical recording medium is executed.

In addition to the deterioration phenomenon, defect areas of the rewritable optical recording medium may be generated due to scratches on the surface, dust such as dust, errors in production, and the like.

Therefore, in order to prevent data from being recorded / reproduced in the defective areas formed due to the above reasons, it is necessary to manage the defective areas.

To this end, as shown in FIG. 1, a defect management area (hereinafter referred to as a DMA) is provided in a lead-in area and a lead-out area of the optical recording medium. The defect area of the optical recording medium is managed. In addition, the data area is divided into a user area in which actual data is recorded and a spare area for use when a defect occurs in the user area. In addition, the data area is divided into groups, and each group is divided into a user area in which actual data is recorded and a spare area for use when a defect occurs in the user area.

In general, four DMAs exist in one disk, two DMAs exist in the lead-in area, and the other two DMAs exist in the lead-out area. Each DMA consists of two blocks, totaling 32 sectors.

Here, the first block of each DMA (called a DDS / PDL block) includes a Disc Definition Structure (DDS) and a Primary Defect List (PDL), and the second block of each DMA (called an SDL block) is an SDL (Secondary). Defect List).

In this case, PDL means main defect data storage, and SDL means defect data storage.

In general, the PDL stores entries created during the disc creation process and entries of all defective sectors that are identified during formatting, ie, initializing and re-initializing the disc. Here, each entry is composed of an entry type and a sector number corresponding to a defective sector as shown in Fig. 2A. The sector numbers are listed in ascending order. In addition, the entry type is the cause (Origin), one example 00b to open the P- list, 10b is G ₁ of the defective sector are sorted in a list-list if it is, 11b G _2.

That is, defective sectors defined by the disc manufacturer, for example, defective sectors created during the disc creation process, are stored in the P-list, and defective sectors found during the certification process when the disc is formatted are stored in the G ₁ -list, Defect sectors transferred from the SDL without verification are stored in the G ₂ -list.

On the other hand, the SDL is listed in units of blocks, and stores entries of defective areas that occur after the format or defective areas that cannot be stored in the PDL during the format. Each SDL entry includes an area for storing the sector number of the first sector of the block in which the defective sector has occurred, an area for storing the sector number of the first sector of the replacement block as shown in FIG. 2B, and an unused area ( Reserved). Each entry is also assigned with one bit for Forced Reassignment Marking (FRM).

In addition, a method of initializing a disk is divided into initial formatting and re-initialization. The reformatting is again performed by full formatting, such as initial formatting, and partial formatting. (partial certification) then the SDL without the verifying to the reduction in the time format of the PDL G ₂ - formatting move in list (SDL conversion of G to ₂ - list; hereinafter referred to as simple formatting) and the like. Here, the P-list does not change after any formatting, and in the case of the G ₂ -list, since a defective block of the SDL is stored as a defective sector as it is, a normal sector may be included, but is regarded as a defective sector.

That is, a simple or quick format for converting an SDL into a G ₂ -list without verification is shown in FIG. 3, and the sectors in the P-list, G ₁ -list, and G ₂ -list before the format remain intact even after the format. P-list, G ₁ -list, G ₂ -list are maintained. The old SDL entries are converted to 16 PDL entries, then the corresponding SDL entries are deleted and registered in the G ₂ -list. At this time, G ₂ - when an overflow occurs in the list G ₂ - the rest of the entry is not registered in the SDL list are left in the new (new) SDL.

Here, the overflow occurs because the number of entries that can be registered in the PDL is limited by the condition shown in Equation 1 below.

Here, S _PDL is the number of sectors used to hold the PDL entries, S _SDL is the number of sectors used to hold the SDL entries, E _PDL is the number of PDL entries, and E _SDL is the number of SDL entries. And, Denotes the largest integer not greater than P.

That is, the total number of sectors that can be used for the PDL and the SDL cannot exceed 16 sectors, and the PDL alone or the SDL alone cannot exceed 15 sectors.

Meanwhile, defective areas (ie, defective sectors or defective blocks) in the data area should be replaced with normal areas, and there are a sleeping replacement method and a linear replacement method.

The sleeping replacement method is applied when a defective area is registered in the PDL. If a defective sector exists in a user area in which actual data is recorded as shown in FIG. 4A, the defective sector is skipped. Instead, it is replaced by a good sector following the defective sector to record data. Then, the user area in which data is recorded occupies a spare area as much as the defective sector skipped and eventually skipped. That is, the spare area is allocated to the user area by the skipped defective sectors. For example, the list PDL P- or G ₁ - if two defect sectors are registered in the list data is recorded pushed up to two sectors of the spare area. If a defective sector is recorded in the G ₂ -list of the PDL, the data is recorded by pushing up to 16 sectors (= 1 block) in the spare area.

In addition, the linear replacement method is applied when the defective area is registered in the SDL. When a defective block exists in the user area as shown in FIG. 4B, the replacement of the block unit allocated to the spare area ( replacement) field to record the data.

On the other hand, in order to increase the data recording capacity of the optical disc, a method of allocating a spare area having a capacity smaller than that of the spare area of FIG. 1 described above to only one group of the data area or to a portion of the data area is proposed. have.

One of them is a method of positioning a spare area at the top of the data area, as shown in FIG. 5, and the spare area at this time is called a primary spare area (SA-pri). That is, the remaining data area except the main spare area becomes a user area.

Here, when the main spare area is positioned at the top of the data area, there are advantages as follows. First, since the defect is most likely to occur in the inner circumference of the disk, that is, the sector near LSN = 0, the travel distance of the optical pickup for linear replacement is shortened. Secondly, since the start position of the spare area can be fixed regardless of the size and capacity of the optical recording medium, the present invention can also be applied to the next large capacity disk (eg, HD-RAM) standard.

The primary spare area is an area allocated during the initial formatting process, and is not assigned a logical sector number (LSN). That is, the primary spare area may be allocated when the disc manufacturer manufactures the optical disc or may be allocated when the user formats the blank disc for the first time.

In this case, the capacity of the main spare area may be variously allocated. For example, 26 MB (MB is Mega Byte) is allocated to set 4.7 GB (G is Giga) as the initial data recording capacity (that is, the first user area). You can either allocate 145MB to make 4.5GB.

On the other hand, if the main spare area is to be solved by a slipping replacement or a linear replacement, a new spare area is allocated again near the end of the user area as shown in FIG. The spare area at this time is called a supplementary spare area (SA-sup). That is, since the important data is copied at the end of the user area, the sub spare area is allocated near the end of the user area.

If the sub spare area is to be pooled, the sub spare area is expanded as shown in FIG.

In this case, the spare blocks of the sub spare area used for the linear replacement are used in reverse order. This is to easily and continuously expand the sub spare area.

In addition, the main spare area and the sub spare area cannot be active at the same time. In addition, when the sub spare areas are expanded, the sub spare areas cannot be activated at the same time. Here, the active spare area means that the spare area has a spare block to be linearly replaced according to the linear replacement algorithm. For example, when the primary spare area in the active state remains slightly (about 1 MB or less) as shown in FIG. 7A, the sub spare area is allocated as shown in FIG. 7B, but is replaced by the linear spare area. Can't. That is, only when all of the primary spare regions are exhausted (exhausting), as shown in FIG. 7C, the secondary spare region may be activated and linear replacement may be performed on the secondary spare region.

At this time, the recording capacity of the user area is reduced by the capacity of the sub spare area. If the initial user area except the primary spare area is 4.7 GB and the newly allocated sub spare area is 32 MB, the user area is reduced to 4668 MB. That is, the capacity of the user area capable of recording actual data by the sub spare area to be expanded is reduced. At this time, if the start position and the end position of the sub spare area are known, the capacity of the user area can be known.

Then, if defective sectors are registered in the PDL by initial or reformatting, data is not recorded in the defective sectors, thereby reducing the recording capacity. Therefore, the main spare area is slipped to the user area by the defective sectors registered in the PDL during formatting to maintain the initial data recording capacity. In other words, the physical sector number PSN to which the logical start position LSN = 0 of the user area is assigned changes according to the defective sectors registered in the PDL. At this time, the main spare area is sleeped in the reverse order.

To this end, first, as shown in FIG. 8B, the sectors on the optical disk are checked from the inner circumference to the outer circumferential direction, and then the defective sectors are registered in the PDL (①). That is, all sectors of the defective block registered in the SDL are converted into the G ₂ -list of the PDL. Then, the last LSN determined as the user capacity is given to the last sector of the last ECC block in the data area (2). Then, except for sectors registered in the PDL, if LSN is given to each sector in the reverse order toward the top of the data area (3), a sector of LSN = 0 is determined (4). Therefore, a spare area from which the start sector of the data area to the sector before LSN = 0 can be replaced by the linear area. At this time, the assignment of the spare block for linear replacement is also performed in the reverse order.

That is, when reformatting is performed while the first LSN (LSN = 0) is allocated as shown in FIG. 8A, a sector (i.e., PSN) to which the first LSN is allocated by defective sectors registered in the PDL as shown in FIG. Will be different. For example, if there is a defective sector registered in the PDL by formatting, the sector to which the first LSN (LSN = 0) is given is changed.

Thus, the above-described method must record the starting sector number of the user area somewhere on the disc every time formatting is performed. In other words, a separate storage space is required. In addition, when formatting is performed, the optical pickup proceeds from the inner circumference to the outer circumferential direction as shown in FIG. 8B to find the starting sector number of the user area, and gives LSN to each sector while excluding the defective sectors registered in the PDL in reverse order. The process is necessary.

In addition, when there are many defects, the sub spare area may remain intact even after formatting for linear replacement, in which case the recording capacity is reduced.

For this reason, the state of the disc also varies considerably from the state at the time of purchase, for example, the initial state (that is, the start position of the user area and the end position of the user area). This means that the changes must be recorded somewhere else on the disc, which complicates the control.

In the simple format of converting the SDL into the G ₂ -list without verification, all sectors of the defect blocks registered in the SDL are converted into the G ₂ -list of the PDL, so that the PDL quickly approaches the condition as shown in Equation 1 above. This can easily cause overflow in the DMA. For example, since the SDL entry is 8 bytes and the PDL entry is 4 bytes, the PDL requires 64 (= 4x16) bytes in order for one SDL entry to be converted to a G ₂ -list of PDLs.

In addition, when overflow occurs, the disc may not be usable, resulting in shortening the life of the disc.

Thus, the reformatted when the first only G ₂ of PDL sector number of the sector on the defect blocks registered in the SDL as shown in Figure 9 in order to solve this problem - when converted to a list, and after the data recording / reproducing the PDL G ₂ - List A method for sleeping replacement of 16 sectors including a defective sector registered at has been filed by the applicant.

That is, according to the method of converting all the sectors of the SDL to the PDL, if the conditions of Equation 1 described above are applied, the defect area that can be managed by the PDL is approximately 15 MB (= 15 sectors * 512 entry / sector * 2048 bytes / entry). However, according to the method of converting only the first sector of the defective defect block of the above-described SDL to PDL, it is about 240MB (15 sectors * 512entry / sector * 32KByte / entry).

Therefore, if the formatting method of converting only the sector number of the first sector of the defective block registered in the SDL into the G ₂ -list of the PDL is applied to Fig. 8B, the starting sector number of the user area is in the sub spare area instead of the main spare area. May be assigned to a sector.

This is complicated because the data must be recorded from the sub spare area of the disc to the outer circumference and then come to the main spare area for recording. Similarly, the provision of LSNs is complicated.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems, and an object of the present invention is to convert an SDL into a PDL when formatting, and does not replace a sleeping sector for a defective sector registered in the PDL. In providing.

Another object of the present invention is to provide a method for formatting an optical recording medium in which only a part of the spare area except for a predetermined area of the main spare area is to be replaced when a defective sector is registered in the PDL.

The method for formatting an optical recording medium according to the present invention is characterized in that no sleeping replacement is performed for the defective sectors registered in the PDL after the formatting for transferring the defect information registered in the SDL to the PDL.

Only the first sector of the defect block registered in the SDL is registered in the PDL.

The method of formatting an optical recording medium according to the present invention is characterized in that for the defective sectors registered in the PDL only as much as a predetermined area of the spare area after formatting transferring the defect information registered in the SDL to the PDL.

The predetermined sleepable area may be an area excluding a capacity corresponding to at most one sector of the SDL.

The region excluded from the sleeping may be allocated from a start position of the data region.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention only registers the defect information of the SDL as a PDL during formatting, and does not replace a sleeping sector registered with the PDL as shown in FIG. 10. In other words, the main spare area is not allocated to the user area as many as the defective sectors registered in the PDL.

Thus, the PSN assigned to the first LSN (LSN = 0) at the time of initial formatting always remains the same even when reformatted. This means that it is not necessary to separately record the starting sector number of the user area on the disc every time formatting is performed.

Since the LSN is not assigned to the defective sector registered in the PDL, the data is simply skipped during recording.

In particular, the present invention is more effective in registering only the first sector of a defect block registered in the SDL as a PDL when converting the SDL into a G ₂ -list of the PDL without verification.

That is, since only the SDL is converted to the PDL but not sleeping, the sector of the sub spare area is allocated to the first LSN.

In addition, when only the first sector of a defect block registered in the SDL is registered as a PDL, all SDLs can be converted to PDLs, so even if a sub spare area is allocated before formatting, no replacement block is allocated to the sub spare area after formatting. do. Therefore, in the present invention, the sub spare area can be allocated to the user area again during formatting.

In this case, since the present invention does not perform the slipping replacement, the recording capacity of the user area may be reduced by the defective sectors registered in the PDL, but the sub spare area becomes the user area so that there is no big difference from the conventional method. That is, conventionally, if the sub spare area is maintained after formatting, the recording capacity of the user area is reduced by the sub spare area.

When only the first sector of the defect block registered in the SDL is registered as the PDL, more defect areas on the disc can be managed than in the prior art, thereby extending the life of the disc.

On the other hand, as another embodiment of the present invention, even in the case of slipping replacement as shown in FIG. 8B in order to increase the recording capacity, only the area except for the predetermined area of the main spare area is slipped as shown in FIG.

That is, a predetermined area, for example, about 8 MB is allocated to the main spare area in advance, and no sleeping is performed for the 8 MB. In this case, the sleeping replacement is performed in the reverse order, and the predetermined area is determined from the beginning of the data area to a part after that (that is, 8 MB).

Here, the predetermined area is about 8 MB, which corresponds to one sector of the SDL, and is for leaving a minimum linear replacement area under the condition of Equation 1 and for protecting the control block. The control block is a block in which file information is recorded and is distinguished from a block in which general data is recorded.

If the capacity of the defective sectors registered in the PDL is larger than the capacity except for the 8 MB of the main spare area, the system sleeps only until the predetermined predetermined area. After that, it is registered only in the PDL. That is, no sleeping occurs in the sub spare area.

In this case, since the LSN is not assigned to the defective sector registered in the PDL, the data is recorded while being skipped.

As described above, according to the optical recording medium and the formatting method according to the present invention, during formatting, a sleeping for registering only the defect information of the SDL as a PDL and allocating the spare area to the user area by the defective sectors registered in the PDL is performed. By not doing so, the optical recording medium can always be kept in the same state as when purchased, and the control becomes simple, and the process of finding a sector corresponding to the first LSN of the user area or additional information, in particular, the first LSN There is no need to store the starting sector number and the ending sector number corresponding to the last LSN. If there is a sub spare area, the sub spare area may be allocated to the user area and used. Even if it sleeps, only the predetermined area portion of the main spare area is allowed to obtain the same effect as the case described above.

When the formatting according to the present invention is applied to the method of converting only the first sector of the defective block of the SDL into the PDL, not only the aforementioned effects but also the probability of occurrence of a DMA overflow and the life of the disk can be extended.

1 is a view showing the structure of a typical optical disk

Figure 2a shows a general PDL entry structure

2b shows a general SDL entry structure

3 is a diagram illustrating a simple formatting method of converting an SDL list into a G ₂ -list without verification among general formatting methods.

4A illustrates a typical sleeping alternative method

4b illustrates a typical linear replacement method

5 illustrates an example in which a general spare area is allocated to a top position of a data area.

6 (a) and 6 (b) show an example in which a sub spare area is allocated to a disk having a main spare area as shown in FIG. 5 and the sub spare area is expanded.

7A to 7C illustrate a process in which only one of the spare regions is activated.

8A shows a disk structure in an initial state in which a general primary spare area is allocated.

FIG. 8B illustrates a process of finding a sector corresponding to the first LSN by sleeping as many defective sectors as registered in the PDL in the disk structure of FIG. 8A.

FIG. 9 is a diagram illustrating a structure of a PDL entry when only the first sector of a defective block of an SDL is registered as a PDL during formatting; FIG.

10 is a view showing a disk structure when formatting the optical recording medium according to the present invention;

11 is a view showing a disk structure when formatting an optical record carrier according to another embodiment of the present invention.

Claims (10)

In the formatting method of the optical recording medium for transferring the defect information registered in the defect data storage unit (SDL) to the primary defect data storage unit (PDL), And no sleeping replacement for defective sectors registered in the main defect data storage unit (PDL) after formatting. The method of claim 1, And registering only the first sector of the defect block registered in the defective data storage (SDL) in the primary defective data storage (PDL). In the formatting method of the optical recording medium for transferring the defect information registered in the defect data storage unit (SDL) to the primary defect data storage unit (PDL), And formatting only the defective sectors registered in the main defect data storage unit (PDL) as much as an area except the preset one of the spare areas after formatting. 4. The sleepable area of claim 3 wherein said sleepable area is And an area excluding a capacity corresponding to one sector of the defective data storage unit (SDL). The method of claim 3, wherein the region excluded from the sleeping is Formatting method of an optical recording medium, characterized in that the allocation from the start position of the data area. In a formatting mode in which defect information registered in the defect data storage unit SDL is transferred to the defect data storage unit PDL, a slip replacement is not performed for defect sectors registered in the defect data store PDL. An optical record carrier. 7. The optical recording medium according to claim 6, wherein only the first sector of the defect block registered in the defect data storage unit (SDL) is registered in the main defect data storage unit (PDL). In the formatting mode in which defect information registered in the defect data storage unit SDL is transferred to the defect defect data storage unit PDL, only the area of the spare area except the preset region after formatting is stored as much as the defect defect data storage unit PDL. And sleeping with respect to the defective sectors registered in the optical recording medium. The optical recording medium of claim 8, wherein the sleepable area is an area excluding a capacity corresponding to one sector of the defective data storage unit (SDL). 9. The optical recording medium of claim 8, wherein an area excluded from the sleeping is allocated from a start position of a data area.