KR100546570B1 - Method for formating and managing defect area of optical recording medium - Google Patents

Abstract

The present invention relates to a rewritable optical recording medium, a reformatting method thereof, and a defect area management method thereof, in which only the sector number of the first sector of a defect block registered in the SDL is converted into a PDL during reformatting, which is converted into an SDL without verification. Flag the PDL entry, mark it, and if it encounters a defect sector registered in the PDL during recording (or playback), check the flag to determine the sector number of the first sector of the defect block registered in the SDL when the flag is reformatted. When indicating that only the PDL is converted into a PDL, a sleep replacement of up to 16 sectors including the defective sectors is performed to efficiently manage the DMA list, thereby reducing the probability of occurrence of overflow of the DMA, thereby increasing the performance of the system.

Description

Method for formating and managing defect area of optical recording medium

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

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

The ROM type optical recording medium may include a compact disc read only memory (CD-ROM) and a digital versatile disc read only memory (DVD-ROM), and a worm type optical recording medium may be written once. Recordable Compact Disc (CD-R) and Recordable Digital Versatile Disc (DVD-R).

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

On the other hand, in the case of a rewritable optical recording medium, the recording / reproducing operation of information is repeatedly performed due to its use characteristics, whereby the mixing ratio of the mixture constituting the recording layer formed for recording information on the optical recording medium is initially mixed It becomes different from the 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 defect area formed due to the above reasons, it is necessary to manage the defect area.

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 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, Defective 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). In addition, one bit is allocated to each entry for Forced Reassignment Marking (FRM). If the value is 0b, the replacement block is assigned and there is no defect in the replacement block. 1b means that no replacement block is allocated or the allocated replacement block is defective.

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, as shown in FIG. 3A, the partial formatting of the P-list and the G ₁ -list before formatting remain in the P-list and G ₁ -list as it is after formatting, but the old G ₂ − before formatting. The defect blocks listed in the list and SDL are verified. After deleting all entries in the G ₂ -list and the SDL, only the defective sectors found in the verification process are registered in the G ₁ -list. This is because defective blocks in the G ₂ -list or SDL also contain sectors without defects. At this time, if an overflow occurs in the G ₁ -list, the rest is again listed in a new SDL, and null data is inserted into the G ₂ -list.

In addition, a simple or quick format for converting SDL into a G ₂ -list without verification is shown in FIG. 3B, and the sectors in the P-list, the G ₁ -list, and the G ₂ -list before formatting remain intact 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, the defective areas (ie, defective sectors or defective blocks) in the data area should be replaced with normal areas, which include a slipping 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. 4A, the defective sector is skipped. Instead, it is replaced by a good sector following the defective sector to record data.

Therefore, the user area in which data is recorded occupies a spare area as much as the defective sector skipped and eventually skipped. 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. And, G ₂ of the PDL - if it is a defective sector recorded in the list data is recorded to 16 sectors pushed (= one block) of 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. If the replacement block written in the SDL is later found to be defective, the direct pointer method is applied to the SDL registration. That is, by the direct pointer method, the defective replacement block is replaced with a new replacement block, and the SDL entry in which the defective replacement block is registered is modified with the sector number of the first sector of the newly replaced replacement block.

However, the above-described linear replacement method has to transfer the optical pickup to the spare area and then back to the user area in order to record the data of the defective block recorded in the SDL in the replacement block assigned to the spare area, and thus this process is repeated repeatedly. This can degrade the performance of the system.

Thus, one of the reasons for reformatting is to increase the performance of the system by moving defective sectors registered in the SDL to the PDL and reducing continuous linear replacement.

At this time, there may be a number of reformatting methods as described above, and since the formatting is complicated, there is a tendency to simplify the formatting process as a simple format method of converting SDL into G ₂ -list without verification.

However, the defect block registered in the SDL also contains sectors without defects. The simple format of converting an SDL to a G ₂ -list without the above-described verification is to convert all sectors of the defect block registered in the SDL to the G ₂ -list of the PDL. By converting, the PDL quickly approaches the condition as shown in Equation 1 above, which makes it possible to easily overflow the DMA. For example, since an SDL entry is 8 bytes and a PDL entry is 4 bytes, if one SDL entry is converted to a G ₂ -list of PDLs, the PDL requires 64 (= 4 × 16) bytes.

At this time, if the overflow occurs, the disk may not be used, so the simple format method described above has a problem of decreasing the utilization of DMA.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to convert a sector number of a first sector of a defective block registered in an SDL into a PDL and display it in the PDL entry. The present invention provides a formatting method.

It is another object of the present invention to provide a method for managing a defective area of an optical recording medium for slipping and replacing 16 sectors including defective sectors registered in a PDL in accordance with the contents indicated in the PDL entry during data recording / reproducing.

According to an aspect of the present invention, there is provided a method of formatting an optical recording medium, wherein the first sector of the defect block registered in the SDL is formatted when the optical recording medium transfers defect information registered in the SDL to the PDL. And registers only the first sector of the defective block in the unused area of the PDL entry.

According to the present invention, there is provided a method for managing a defective area of an optical recording medium, the method comprising: determining whether a defective sector represents only the first sector of a defective block if a defective sector registered in a PDL is found; And if it is determined that only the first sector is represented, a step of sleeping replaces the block including the defective sector.

The determining step determines whether the defective sector represents only the first sector of the defective block registered in the SDL by using a flag indicating that only the first sector of the defective block registered in the SDL is registered in the PDL during reformatting. It is characterized by.

In the sleeping replacement step, the block including the defective sector may include defective sectors registered in the P-list and the G ₁ -list of the PDL.

The sectors of the block including the defective sectors are not assigned logical sector numbers.

The sleeping replacement step is characterized in that if the defective sector is determined not to represent only the first sector of the defect block registered in the SDL, only the corresponding defective sector is replaced.

The PDL includes an entry for recording a defective sector in sectors and an entry for recording a defective sector in block units.

Only the defect information of the first sector of the defective block is recorded in the entry in which the defective sector is recorded in the block unit.

When a defective sector of the entry in which the defective sector is recorded in the block unit is encountered, the block containing the defective sector is replaced.

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 improves on a simple format method for converting SDL into a G ₂ -list of PDLs without verification. That is, in the simple formatting of converting the defect information registered in the SDL into the PDL without verification, the present invention may convert all sectors of the defect block registered in the SDL into the PDL, and only the first sector of the defect block registered in the SDL is PDL. You can also convert to. In addition, this difference can be distinguished by using a reserved area of the PDL entry. For example, after allocating 1 bit of the unused area of the PDL entry (referred to as G2F flag in the present invention as shown in FIG. 5A), the G2F flag is set to 1 or 0 so that a defective sector registered in the PDL is the first in the defective block. It can be distinguished whether it represents only sectors or only defective sectors.

In the present invention, an embodiment is a PDL entry type as shown in Fig. 5b G ₂ - list and if the G2F flag is 1, only the sector number of the first sector of the defective blocks registered in the SDL G ₂ - registered in the list, and subsequent The remaining 15 sectors mean that they are not registered. If 0, as shown in FIG. 5C, all sectors of a defect block registered in the SDL are registered in the G ₂ -list, and the defective sector number at this time represents any one of them.

Therefore, if the G2F flag is 1, only one PDL entry is needed when converting one SDL entry to PDL. That is, conventionally, in order to convert one SDL entry into a G ₂ -list of PDLs, PDL requires 64 (= 4 × 16) bytes, that is, 16 PDL entries, but according to the present invention, only one PDL entry is required. It is necessary. Thus, the probability of occurrence of overflow is reduced by that much.

FIG. 6 is a flow chart of the present invention showing such a formatting process. If a simple format method is selected during reformatting (step 601), the defective sectors registered in the P-list of the old PDL after reading the old DMA information are retained in the new PDL. P- registered in the list, the old PDL G ₁ - registered in the list of defective sectors as G ₁ in the new PDL - be registered in the list (step 602).

And, G ₂ of the old PDL-registers in the list (step 603) on the defective sector is also registered in the list as G ₂ in the new PDL.

In addition, the sectors in the defect blocks registered in the old SDL diagram of a new PDL G ₂ - to be converted to a list of all the sectors in the defect blocks registered in the old SDL by the system or the user's selection new PDL G ₂ - List And only the first sector of a defective block registered in the SDL can be converted to a G ₂ -list of new PDLs. If all sectors of the defective block registered in the SDL are registered in the G ₂ -list of the new PDL, the G2F flag may be reset to zero. In this case, 16 PDL entries are required for one SDL entry, which is processed in the same manner as in the prior art.

On the other hand, when converting only the first sector of the defective blocks registered in the SDL as a PDL, the only sector number of the first sector of the defective blocks registered in the old SDL G ₂ of the new PDL - registered in the list and the remaining 15 sectors is not registered Then set the G2F flag to 1 and delete the corresponding SDL entry (step 604). In this case, one PDL entry is required for one SDL entry.

If an overflow occurs in the G ₂ -list of the new PDL under the condition as shown in Equation 1 above (step 605), the remaining old SDL entries are registered in the new SDL entry as they are (step 606).

When the above process proceeds, simple formatting for converting the SDL into the G ₂ -list of the PDL is completed (step 607).

7 is a flowchart of the present invention for managing a defective area of an optical disc formatted in the above manner.

That is, when the system is turned on or the optical disk is loaded in the system (step 701), the initialization process reads the information of the defect sectors listed in the PDL and the defect sectors listed in the SDL from the DMA (step 702).

Therefore, it is possible to know whether the sectors encountered during data recording (or reproduction) are defective sectors registered in the DMA or normal sectors. If the sectors are defective sectors, it is also possible to know whether they are defect sectors registered in the PDL or defect sectors registered in the SDL.

Therefore, when the user selects recording (or reproduction) (step 703), data is recorded (or reproduced) on the optical disc (step 704).

At this time, when the defective sectors registered in the P-list or the G ₁ -list of the PDL are met, data is recorded or reproduced by a sleeping replacement method (step 705). That is, if a defective sector registered in the P-list or G ₁ -list is encountered during data recording, the defective sector is skipped and instead the data is recorded in a good sector following the defective sector. At this time, a logical sector number (LSN) is not assigned to the defective sector. Therefore, even during playback, data is not read from the defective sector.

On the other hand, if a defective sector registered in the G ₂ -list of the PDL is encountered during data recording (or reproduction) (step 706), it is determined whether the G2F flag is 1 (step 707).

If the G2F flag is 1 as shown in FIG. 5B, since only the first sector of the defect block registered in the SDL is registered in the G ₂ -list of the PDL, the defect sector is the first sector up to 15 sectors later, that is, the defect. Sleeping replaces all sectors of one block including the sector (step 708). Here, the LSN is not given to the 16 sectors (= 1 block) to replace the sleeping.

At this time, the 16 sectors (= 1 block) replacing the sleeping region exclude defective sectors registered in the P-list or the G ₁ -list. If there are defective sectors registered in the P-list or G ₁ -list within 16 sectors including the defective sectors registered in the G ₂ -list, the area for sleeping replacement is widened. For example, the _second G-18 sectors including the defective sector registered in the list - if there are 2, the defective sector registered in the list of the _second G-P- list or G ₁ in the 16 sectors, including the defective sector registered in the list It will replace sleeping. That is, the user area in which data is recorded occupies a spare area by 18 sectors skipped and eventually skipped.

In addition, if the G2F flag is 0 as shown in FIG. 5C, all sectors of the defect blocks registered in the SDL are registered in the G ₂ -list of the PDL, and only the defective sectors are slipped and replaced (step 710). That is, the defective sector is skipped and instead data is written to a good sector following the defective sector.

Then, it is determined whether recording (or reproduction) is completed, and if not, the process is repeated continuously, and if it is completed, the program is terminated (step 709).

On the other hand, as another embodiment of the present invention, the distinction between the G ₁ -list and the G ₂ -list among the entry types of the PDL is eliminated. That is, defective sectors registered in the PDL at the time of formatting can be distinguished by a sector unit or a block unit by distinguishing the difference by placing a flag (hereinafter referred to as PDL G2 flag) in the PDL entry.

In the present invention, when the defective sector is registered in the PDL in units of blocks during formatting, the PDL G2 flag is set to 1, and when the defective sector is registered in the sector unit, the PDL G2 flag is reset to zero. The PDL G2 flag is reset to zero even when only a defective sector is registered among the defective blocks registered in the SDL through verification. If the PDL G2 flag of the old PDL is 0 during formatting, the new PDL is converted to the new PDL.

Therefore, if the PDL G2 flag is 1, only the first sector of a defect block registered in the SDL is registered in the PDL, and the remaining 15 sectors are not registered. If the PDL G2 flag is 0, the SDL is registered without verification. It means that all of the sectors of the defective block are registered in the PDL or only the defective sectors of the defective block registered in the SDL by verification, respectively.

8 is a flowchart illustrating a method for managing a defective area at this time, when the system is turned on or an optical disk is mounted in the system (step 801), the defective sectors listed in the PDL from the DMA and the defective sectors listed in the SDL by the initialization process. Read the information (step 802).

When the user selects recording (or reproduction) (step 803), data is recorded (or reproduced) on the optical disc (step 804).

At this time, if a defective sector registered in the PDL is encountered (step 805), it is determined whether the PDL G2 flag of the PDL entry is 1 (step 806).

If the PDL G2 flag is determined to be 1, since only the first sector of the defective block registered in the SDL is registered in the PDL, the first sector including the defective sector up to 15 sectors after making the defective sector the first sector is included. Sleeping replaces all sectors of (step 807). For example, if the defective sector is encountered during data recording, the block containing the defective sector is skipped and instead the data is written to a good block following the defective block. At this time, since the LSN is not given to the 16 sectors (= 1 block) to replace the sleeping, data is not read from the block including the defective sector even during reproduction.

In this case, the defective sectors registered in sector units are excluded from the 16 sectors (= 1 block) replacing the sleeping.

On the other hand, if it is determined in step 806 that the PDL G2 flag is 0, all of the sectors of the defective block registered in the SDL are registered in the PDL, and only the defective sector is then slipped and replaced (step 808). That is, the defective sector is skipped and instead data is written to a good sector following the defective sector.

Then, it is determined whether recording (or reproduction) is completed. If not, the above process is repeated, and if it is completed, the program is terminated (step 809).

On the other hand, when a defective block registered in the SDL is encountered during recording (or reproduction) in Fig. 7 or Fig. 8, linear replacement is performed as shown in Fig. 4B. In the case of real-time data, another method may be used.

As described above, the present invention can manage the DMA list more efficiently by converting only the first sector of the defect block registered in the SDL into the PDL and flagging the PDL entry when reformatting.

As described above, according to the optical recording medium and its formatting and defect area management method according to the present invention, when reformatting SDL into PDL without verification, only the sector number of the first sector of the defect block registered in the SDL is converted into PDL. And display a flag (= G2F flag or PDL G2 flag) in the PDL entry, and if it encounters a defective sector registered in the PDL during recording (or playback), check the flag (G2F flag or PDL G2 flag) and check the flag. When 1 is set to 1, the system replaces up to 16 sectors including the defective sector by sleeping, thereby efficiently managing the DMA list and reducing the probability of occurrence of overflow of the DMA, thereby improving system performance.

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

3A illustrates a partial formatting method of a general formatting method.

3B is a view 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

5A illustrates an example of a PDL entry according to the present invention.

5B illustrates the meaning of a defective sector number when an entry type is a G ₂ -list and a G2F flag is 1 in a PDL entry according to the present invention.

5C illustrates the meaning of a defective sector number when an entry type is G ₂ -list and a G2F flag is 0 in a PDL entry according to the present invention.

6 is a flowchart illustrating a method of formatting an optical record carrier according to the present invention.

7 is a flowchart illustrating an embodiment of a method for managing a defective area of an optical record carrier according to the present invention.

8 is a flowchart illustrating another embodiment of a method for managing a defective area of an optical record carrier according to the present invention.

Claims (41)

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), 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, and the first sector of the defect block is assigned to the flag assigned to the main defect data storage unit PDL. A method of formatting an optical record carrier characterized by indicating that only sectors have been registered. The method of claim 1, And registering only the sector number of the first sector of the defective block registered in the defective data storage unit (SDL) in the G ₂ -list of the primary defect data storage unit (PDL). Determining whether the defective sector represents only the first sector of the defective block that has been registered in the defective data storage unit SDL when a defective sector registered in the primary defect data storage unit PDL is found during data recording / reproducing; , And if the defective sector is determined to represent only the first sector of the defective block, sleeping replacing the block containing the defective sector. The method of claim 3, wherein the determining step When formatting, the defective sector is defective by using a flag indicating that only the first sector of the defective block registered in the defective data storage SDL is registered in the primary defect data storage PDL. And determining whether only the first sector of the defective block registered in Fig. 2) is represented. The method of claim 4, wherein And wherein the indication flag is assigned to a specific area of a main defect data storage unit (PDL) entry in the determining step. The method of claim 3, wherein The defective sector block to be included in the list of P-, G ₁ of the primary defect data storage section (PDL) is in the sleeping alternative steps - for managing a defective area of the optical recording medium, characterized in that the excluded that a defective sector registered in the list method . The method of claim 6, And sectors of a block including the defective sectors are not assigned logical sector numbers. The method of claim 3, wherein The sleeping replacement step And if it is determined that the defective sector represents only the first sector of the defective block, then replacing the defective sector with the first sector by sleeping up to 15 sectors. The method of claim 8, The slipping replacement is 16 sectors, the primary defect data storage section (PDL) P- list, G ₁ a-defect area management method of an optical recording medium, characterized in that the list of registered defective sectors are excluded. The method of claim 3, wherein The sleeping replacement step And if it is determined that the defective sector does not represent only the first sector of the defective block registered in the defective data storage unit (SDL), only the corresponding defective sector is slipped and replaced. The method of claim 3, wherein And an entry for recording a defective sector in sectors and an entry for recording a defective sector in block units in the main defect data storage unit (PDL). The method of claim 11, In the entry in which the defective sector is recorded in the block unit, A defect area management method for an optical recording medium, characterized in that only defect information of the first sector of a defect block is recorded. The method of claim 11, The sleeping replacement step And when a defective sector of the entry in which the defective sector is recorded in the block unit is met, a block containing the defective sector is replaced by a slipping method. Primary Defect List (PDL), which stores entries of defects generated during manufacturing of the optical recording medium or all defective sectors identified upon formatting of the optical recording medium; A second defect list (SDL) for storing entries of a defective area generated after formatting or defect areas that cannot be stored in the main defect data storage PDL during formatting; When formatting the defect information registered in the defect data storage unit SDL to the main defect data storage unit PDL, only the first sector of the defect block registered in the defect data storage unit SDL is deleted. And a flag assigned to register in the data storage unit (PDL) and indicating that only the first sector of the defective block is registered in a specific area of the main defect data storage unit (PDL). 15. The method of claim 14, G ₂ of the sub-defect data storage unit (SDL) of a defect block first sector sector numbers only primary defect data storage section (PDL) of the register to-optical recording, characterized in that to register the list media. Primary Defect List (PDL), which stores entries of defects generated during manufacturing of the optical recording medium or all defective sectors identified upon formatting of the optical recording medium; A second defect list (SDL) for storing entries of a defective area generated after formatting or defect areas that cannot be stored in the main defect data storage PDL during formatting; In the data recording, if a defective sector registered in the main defect data storage unit (PDL) is found and it is determined that the found defective sector represents only the first sector of the defective block, the block containing the defective sector is replaced. Optical record carrier. The method of claim 16, And determining whether the defective sector represents only the first sector of the defective block registered in the defective data storage unit (SDL) by using a flag allocated to a specific area of the main defective data storage unit (PDL) entry. Optical record carrier. The method of claim 16, The sleeping during the replacement block including the defective sector is defective, the state data storage section (PDL) P- list, the G ₁ - the optical recording medium, characterized in that the defective sectors are registered in the exception list. The method of claim 18, And sectors of the block including the defective sector are not given a logical sector number. 17. The optical recording medium according to claim 16, wherein when it is determined that the defective sector represents only the first sector of the defective block during the replacing of the sleeping, the defective recording sector is replaced by up to 15 sectors. 21. The method of claim 20, wherein the slipping replacement is 16 sectors, the P- list, G ₁ of the primary defect data storage section (PDL) - optical recording medium, characterized in that the list of registered defective sectors are excluded. 17. The optical recording according to claim 16, wherein if it is determined that the defective sector does not represent only the first sector of the defective block registered in the defective data storage unit (SDL) during the slipping replacement, only the corresponding defective sector is replaced by the sleeping. media. 17. The optical recording medium of claim 16, wherein an entry for recording a defective sector in sectors and an entry for recording a defective sector in block units are present in the main defect data storage unit (PDL). The optical recording medium according to claim 23, wherein only the defect information of the first sector of the defective block is recorded in the entry in which the defective sector is recorded in the block unit. 24. The optical recording medium according to claim 23, wherein when replacing the sleeping, when the defective sector of the entry in which the defective sector is recorded in the block unit is encountered, the block including the defective sector is replaced by the sleeping. When the defect information registered in the defect data storage unit SDL is converted into the defect data storage unit PDL, all the sectors in the defect block registered in the defect data storage unit SDL are converted into the defect data storage unit PDL. Or only the first sector of the defective block registered in the defective data storage unit (SDL) to the major defect data storage unit (PDL). 27. The identification according to claim 26, wherein all the sectors of the defective block registered in the defective data storage SDL have been converted to the main defective data storage PDL or only the first sector of the defective block has been converted. And recording the information to the main defect data storage unit (PDL). 28. The method of claim 27, wherein the identification information indicates a case in which all sectors of a defect block registered in the defect data storage unit SDL are stored in the major defect data storage unit PDL. A defect area management method for an optical recording medium, characterized by storing only a defective sector in a main defect data storage (PDL). When converting the defect information registered in the defect data storage unit SDL to the defect data storage unit PDL, all the sectors registered in the defect data storage unit SDL in sector units or block units. And storing identification information for storing in the storage unit (PDL) and identifying the same in the main defect data storage unit (PDL). 30. The method of claim 29, wherein the identification information is that only the first sector of the defect block registered in the defective data storage unit SDL is registered in the major defect data storage unit PDL, and the remaining sectors are not registered. Meaningly or without verification, all the sectors of the defect block registered in the defect data storage SDL are registered in the main defect data storage PDL, respectively, or are verified in the defect data storage SDL by verification. And only defect sectors among the registered defect blocks are registered in the main defect data storage unit (PDL), respectively. 30. The method of claim 29, wherein data recording or reproducing is controlled differently according to the identification information. 32. The data recording or reproducing apparatus of claim 31, wherein when the identification information indicates that only the first sector of the defective block is registered, the data is recorded or reproduced in the next normal block while skipping the block containing the defective sector. A method for managing a defective area of an optical recording medium, characterized in that the. 32. The method as claimed in claim 31, wherein when the identification information indicates that all sectors of the defective block are registered, only the defective sector is slipped and replaced when data is recorded or reproduced. Primary Defect List (PDL), which stores entries of defects generated during manufacturing of the optical recording medium or all defective sectors identified upon formatting of the optical recording medium; A second defect list (SDL) for storing entries of a defective area generated after formatting or defect areas that cannot be stored in the main defect data storage PDL during formatting; When the defect information registered in the defect data storage unit SDL is converted into the defect data storage unit PDL, all sectors registered in the defect data storage unit SDL are stored in the defect data storage unit PDL. And only the first sector of the defect block stored or registered in the defect data storage (SDL) is stored in the major defect data storage (PDL). The method of claim 34, The identification information for indicating whether all sectors of the defective block registered in the defective data storage SDL have been converted into the primary defective data storage PDL or only the first sector of the defective block has been converted. An optical record carrier characterized in that it is recorded in a PDL. 36. The optical recording medium as claimed in claim 35, wherein the identification information indicates only a case in which all sectors of the defect block are registered in the main defect data storage unit (PDL). Primary Defect List (PDL), which stores entries of defects generated during manufacturing of the optical recording medium or all defective sectors identified upon formatting of the optical recording medium; A second defect list (SDL) for storing entries of a defective area generated after formatting or defect areas that cannot be stored in the main defect data storage PDL during formatting; When the defect information registered in the defect data storage unit SDL is converted into the defect data storage unit PDL, all sectors registered in the defect data storage unit SDL are stored. And sector-by-sector or block-wise stored in the main defect data storage unit (PDL) and identification information for identifying the main defect data is recorded in the main defect data storage unit (PDL). 38. The method of claim 37, wherein the identification information is that only the first sector of the defect block registered in the defect data storage unit SDL is registered in the major defect data storage unit PDL, and the remaining sectors are not registered. Meaningly or without verification, all the sectors of the defect block registered in the defect data storage SDL are registered in the main defect data storage PDL, respectively, or are verified in the defect data storage SDL by verification. And only defective sectors of the registered defective blocks are respectively registered in the main defect data storage unit (PDL). 38. The optical recording medium according to claim 37, wherein data recording or reproducing is controlled differently according to the identification information to record or reproduce. 40. The data recording or reproducing method according to claim 39, wherein when the identification information indicates that only the first sector of the defective block is registered, the data is recorded or reproduced in the next normal block while skipping the block containing the defective sector and recording the data. An optical record carrier, characterized in that. 40. The optical recording medium of claim 39, wherein when the identification information indicates that all sectors of the defective block are registered, only the defective sector is slipped and replaced during data recording or reproduction.