KR20000031981A - Method for processing and formatting fraction sector of optical record media - Google Patents

Abstract

PURPOSE: A method for processing and formatting fraction sections of an optical record media is provided to effectively manage fraction sectors of an ECC block by registering the fraction sectors in a new PDL entry. CONSTITUTION: In a method for processing and formatting fraction sections of an optical record media, when an initializing command is input(701), it is determined if the command is an initial formatting command(702). When the command is an initial formatting command, ECC blocks are assigned to each zone(703) such that an initial position of a user area becomes the first sector. When the command is a reformatting command, it is determined the command is a full or partial formatting command(704). Then, PDL entries are deleted by ECC blocks in a former PDL(705). Finally, fraction sectors of the ECC blocks are registered in a new PDL(706).

Description

Partial sector processing and formatting method of optical record carrier

The present invention relates to a method of processing and formatting fraction sectors of a rewritable optical record carrier.

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. The data area is divided and managed by zones, and each zone 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 (eg, a DVD-RAM), two DMAs exist in a lead-in area, and the other two DMAs exist in a 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 initializing, 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. Here, 01b is not used.

That is, defective sectors defined by the disc manufacturer, such as those created during the disc creation process, are stored in a P-list, and defective sectors found during the certification process when the user formats the disc are stored in a 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 - is a - (SDL list conversion of G to ₂₎ such as to move in list formatting. Here, the P-list does not change after any formatting, and in the case of 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.

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 where actual data is recorded as shown in FIG. 3A, 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 illustrated in FIG. 3B, 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 disk, 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 zone of the data area or a portion of the data area is proposed. have.

One of them is a method of locating a spare area at the top of the data area, as shown in FIG. 4, 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. At this time, the user area is managed for each zone.

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. Therefore, general user data is not recorded in the main spare area.

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.

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. That is, the physical sector number (PSN) to which the logical start position LSN = 0 of the user area is given changes according to defective sectors registered in the PDL at the time of formatting. At this time, the main spare area is sleeped in the reverse order. In addition, the assignment of spare blocks in the main spare area for linear replacement is performed in the reverse order.

At this time, since data recording / reproducing to the optical disc is made in ECC block units (i.e., 16 sectors), a method of allowing the user area of each zone to start from the first sector of the ECC block for convenience of control is discussed. have. Therefore, sectors that are not ECC block units may occur near the boundary of each zone. That is, a case may occur where the remaining sectors are less than 16 sectors. This is called fraction sectors of the ECC block.

However, when a spare area is allocated for each zone as shown in FIG. 1 and there is a guard area for distinguishing a zone from zones as shown in FIG. 5A between each zone and the zone, partial sectors of the ECC block are divided into spare areas. It can also be used as a large problem does not occur.

However, when the spare area is allocated to a part of the data area as shown in FIG. 4, only the protection area exists between the zones as shown in FIG. 5B. Therefore, when partial sectors of the ECC block occur, they exist as they are, but data cannot be recorded in the partial sectors of the ECC block. This is because data recording / reproducing is performed in units of ECC blocks, because partial sectors of the ECC blocks do not constitute ECC blocks.

Therefore, in order to prevent data from being recorded in the partial sectors of the ECC block, LSNs should not be given to the partial sectors of the ECC block.

SUMMARY OF THE INVENTION An object of the present invention is to provide a method of processing a partial sector of an optical record carrier in which partial sectors of the ECC block are registered in the PDL such that the LSN is not given.

Another object of the present invention is to provide a partial sector formatting method of an optical recording medium which registers partial sectors of an ECC block differently from an existing PDL when registering them in a PDL.

It is still another object of the present invention to provide a partial sector formatting method of an optical recording medium in which only partial sectors of an ECC block newly generated through verification are registered in the PDL.

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

Figure 3a shows a typical sleeping alternative method

3b illustrates a typical linear replacement method

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

FIG. 5A illustrates an example of distinguishing between zones and zones in the disk structure of FIG. 1; FIG.

FIG. 5B illustrates an example of distinguishing between zones and zones in the disk structure shown in FIG.

6 illustrates a PDL entry structure according to the present invention.

7 is a flowchart for performing a method of formatting a partial sector of an optical record carrier according to the present invention.

A method of processing a partial sector of an optical recording medium according to the present invention for achieving the above object is to store the partial sectors of the ECC block generated in the formatting of the optical recording medium in which the user area is divided into zones in the defect area storage unit. It is characterized by.

The defective area storage unit is characterized in that the PDL.

The partial sectors of the ECC block are stored in the PDL, distinguished from information of defective sectors.

The method of formatting a partial sector of an optical recording medium according to the present invention comprises the steps of: registering the partial sectors of the ECC block generated by the verification in a new PDL as it is during the initial formatting of the optical recording medium in which the user area is divided into zones. The formatting may include deleting partial sectors of the ECC block from the old PDL and storing only the partial sectors of the newly generated ECC block through the verification in the new PDL.

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 is to register the partial sectors of the ECC block to the PDL so that the LSN is not granted. At this time, since the partial sectors of the ECC block are not actually defective, the existing defective sector should be registered as a PDL entry to be distinguished from a registered PDL entry.

FIG. 6 is a structure of a PDL entry according to the present invention for setting the entry type to 01b when registering partial sectors of an ECC block. That is, if the entry type is 01b, it means that a partial sector of the ECC block is registered. 01b is data that has not been used previously.

Therefore, in the present invention, if the entry type of the PDL entries 00b P- list, if the back portion 01b sector list, 10b of the ECC block G ₁ - are sorted in the list - the list is, 11b G _2. Here, in the G ₂ -list, only the first sector number of the defective ECC block including 16 consecutive sectors excluding the sectors registered in the P-list or the G ₁ -list may be registered.

In this case, the PDL entry in which the partial sectors of the ECC block are registered and the PDL entry in which the defective sector is registered may be distinguished by using an unused region instead of the entry type.

7 is a flowchart illustrating a method of formatting partial sectors of the ECC block.

That is, if an initialization command is input (step 701), it is determined whether it is the first formatting command (step 702). If it is determined in step 702 that it is the first formatting command, ECC blocks are designated for each zone such that the starting position of the user area of each zone becomes the first sector of the ECC block through verification. At this time, if partial sectors of the ECC block occur near the boundary of each zone, it is registered in the new PDL as shown in FIG. 6 (step 703). The entry type at this time is 01b.

Here, since the start of the user area of each zone is the first sector of the ECC block, a partial sector of the ECC block occurs at the end of the corresponding zone.

On the other hand, if it is determined in step 701 that the re-formatting, it is determined whether the re-formatted through verification, that is, full or partial formatting (step 704).

If it is determined in step 704 that it is reformatted through verification, first, PDL entries in which partial sectors of the ECC block are registered in the old PDL are deleted (step 705).

That is, if the reformatting through the verification is selected, the old DMA information is read and the ECC blocks are newly designated while excluding the defective sectors in each zone again through verification. Then, partial sectors of the ECC block may be newly generated near the boundary of each zone. Here, too, the start of the user area of each zone becomes the first sector of the ECC block. At this time, if the partial sectors registered in the old PDL are not deleted, data cannot be continuously recorded in the partial sectors of the ECC block even though they are not defective. In addition, since data is not recorded in a partial sector of the new ECC block, this results in a waste of the user area, and may increase the probability of occurrence of overflow of the PDL by increasing the number of PDL entries.

Therefore, when reformatting, partial sectors of the ECC block registered in the old PDL are first deleted from the old PDL, placed as normal sectors, and newly designated ECC blocks for each zone through verification.

Then, the ECC block is newly designated for each zone, and only partial sectors of the ECC block generated near the boundary of each zone are registered in the new PDL as shown in FIG. 7 (step 706).

On the other hand, when the start of the user area of each zone is not the first sector of the ECC block, a partial sector of the ECC block may occur even near the start of each zone. Even in this case, it can be registered and managed in the PDL as described above.

As described above, according to the method of processing and formatting a partial sector of the optical recording medium according to the present invention, each sector of the user area of each zone is in ECC block units, in particular, the user area of each zone starts from the first sector of the ECC block. By registering the partial sectors of the ECC block generated by specifying in the PDL so that defective sectors are distinguished from the registered existing PDL, data is recorded in the partial sectors of the ECC block since no LSN is given to the partial sectors of the ECC block. Can be prevented. In addition, during initial formatting, a partial sector of an ECC block generated through verification is registered in a new PDL as it is, and when reformatting, an old PDL entry in which a partial sector of the ECC block is registered is deleted and a newly generated ECC block is generated through verification. By registering only the partial sectors of the new PDL entry, the management of the partial sectors of the ECC block is efficiently performed.

Claims (9)

In a method of processing a partial sector of an ECC block generated when a spare area is allocated to a part of a data area and a user area is formatted for an optical recording medium managed for each zone, And storing a partial sector of the ECC block in a defective area storage. The method of claim 1, wherein the defective area storage unit Main defect data storage (PDL). A method of processing a partial sector of an optical record carrier. The method of claim 1, wherein the partial sector of the ECC block is A method of processing a partial sector of an optical record carrier, characterized by being stored in the main defect data storage unit (PDL), distinguished from information of a defective sector. The method of claim 3, wherein the partial sector of the ECC block is And sector information of the defective sector according to the entry type of the main defect data storage unit (PDL). The method of claim 3, wherein the partial sector of the ECC block is And sector information of the defective sector by the unused area of the main defect data storage unit (PDL). In the method of formatting a partial sector of an ECC block of an optical recording medium in which a spare area is allocated to a part of the data area and the user area is divided by zones, A partial sector formatting method of an optical record carrier, characterized in that a partial sector of a newly generated ECC block is stored in a main defect data storage unit (PDL) through verification. 7. The method of claim 6, wherein upon initial formatting A partial sector formatting method of an optical record carrier, characterized by storing partial sectors of an ECC block generated by verification in a main defect data storage unit (PDL). 7. The method of claim 6, wherein upon reformatting After deleting the partial sectors of the ECC block registered in the old defect data storage unit (PDL), only the partial sectors of the newly generated ECC block through verification are stored in the new defect data storage unit (PDL) A method of formatting a partial sector of an optical record carrier. 7. The method of claim 6, wherein the partial sectors of the ECC block are A method of formatting a partial sector of an optical record carrier, characterized in that it is stored in the main defect data storage unit (PDL) separately from information of a defective sector.