KR20040077345A - Method and apparatus for managing defect using temporary DFL and temporary DDS including recording prevention information, and disc thereof - Google Patents

Abstract

PURPOSE: A disk with a defect management method using a TDMA(Temporary Defect Management Area) is provided to accumulatively record defect information, and to read temporary defect information only which is recorded in a final temporary defect information area, while performing a finalizing process, thereby effectively using a DMA. CONSTITUTION: A DMA is disposed in at least one of a lead-in area and a lead-out area. A temporary DMA is disposed in at least one of the lead-in area and the lead-out area. The temporary DMA is used for recording temporary defect information repeatedly recorded by corresponding to a recording operation, and for recording temporary defect management information. In the DMA, temporary defect information finally recorded in the temporary DMA while finalizing and temporary defect management information are recorded as defect information and defect management information, respectively. Write protect information is further recorded in the DMA.

Description

Method and apparatus for managing defect using temporary DFL and temporary DDS including recording prevention information, and disc etc}

TECHNICAL FIELD The present invention relates to defect management of a disc, and more particularly, to a defect management method using the temporary defect management area in which write-protection information is recorded, an apparatus thereof, and a disc thereof.

Defect management refers to a process of supplementing data loss due to defects by rewriting user data recorded in a portion where a defect occurs when a defect occurs in user data recorded in the user data area. Conventionally, defect management is largely divided into a defect management method using linear replacement and a defect management method using skipping replacement. Linear replacement means that when a defect occurs in the user data area, the defective area is replaced with an area where a defect in the spare area does not occur. Skipping refers to the use of areas that are "skipped" and then the areas where no defects have occurred, without using the defective areas.

Both the linear replacement method and the skip method are applicable only to discs capable of repeatable recording such as DVD-RAM / RW and recording by the random access method. In other words, the conventional linear replacement method and the skip method are difficult to apply to a write once disc which can only be written once. This is because whether or not a defect has occurred is confirmed by actually recording data. However, in the case of write once disks, once data has been written, it cannot be erased and written again, and thus defect management according to the conventional method is impossible.

Recently, high-density write once discs with recording capacities of several tens of GB have been proposed following CD-R, DVD-R, and the like. These disks can be used for backup because they are relatively inexpensive, have random access when reading data, and have relatively fast read speeds. However, since defect management is not performed for the write once disk, if a defective area is generated during backup, the backup cannot be continued and is interrupted. Since backups occur, especially at times when the system is not used frequently, usually at night when there are no administrators, it is likely that backups will no longer be performed if a backup is interrupted due to a faulty zone.

On the other hand, when only the data can be played back without recording any more data on the recordable disk, recording protection information is recorded on the disk so that data recorded on the disk can not be deleted due to a user's operation error or the like. However, once the write-protection information is recorded on the disc, data cannot be recorded on the entire disc, and thus there is a problem in that the disc cannot be properly managed for various situations that may occur later. For example, there is a problem that defect management cannot be performed since no further recording is possible in the data area after the write protection information is recorded.

Accordingly, the technical problem of the present invention is to provide a defect management method, apparatus and disk which are applicable to a write once disk.

Another technical problem of the present invention is to provide a defect management method, an apparatus, and a disk thereof, in which a recording is smoothly performed by processing the defect even if a defect occurs during recording.

Another technical problem of the present invention is to provide a defect management method, an apparatus and a disk thereof, which enable to change already recorded write protection information.

Another technical problem to be solved by the present invention is to provide a defect management method, an apparatus and a disk thereof, which can perform defect management even after recording protection information is recorded.

1 is a block diagram of a recording apparatus according to a preferred embodiment of the present invention;

2 is a structural diagram of a disk 100 according to a preferred embodiment of the present invention,

3A is an example of a data structure of the disk 100 of FIG. 2,

FIG. 3B illustrates one embodiment of the temporary defect management area and the defect management area of FIG. 3A;

4A to 4D are data structure diagrams of a temporary defect management area according to an embodiment of the present invention;

5A is a data structure diagram of TDFL #i;

5B is a data structure diagram of TDFL #i;

6 is a data structure diagram of TDDS #i;

7 is a data structure diagram of a defect management information DDS;

FIG. 8 is a reference diagram for describing in more detail a process of writing data in a user data area A and a spare area B according to an embodiment of the present invention; FIG.

9 is a reference diagram for showing that the data area can be used more flexibly according to the present invention;

10 is a data structure diagram of TDFL # 0 and TDFL # 1 as temporary defect information;

11 is a data structure diagram of defect #i;

12 is a flowchart for explaining a defect management method according to a preferred embodiment of the present invention;

13 is a flowchart for describing a defect management method according to another exemplary embodiment.

According to the present invention, the lead-in area and the lead-out area in a single recording layer write once disk having a lead-in area, a data area and a lead-out area sequentially arranged according to the present invention. A defect management area provided in at least one of the; And a temporary defect management area provided in at least one of the lead-in area and the lead-out area, wherein the temporary defect management area includes repeatedly recorded temporary defect information and temporary defect management information corresponding to a recording operation. In the defect management area, the temporary defect information and the temporary defect management information finally recorded in the temporary defect management area at the time of finalizing are recorded as the defect information and the defect management information, respectively, and the record preventing information is recorded. Is achieved by a disc characterized in that.

In addition, the write once includes a first recording layer in which the lead-in area, the data area and the lead-out area are sequentially arranged, and a second recording layer in which the outer area, the data area and the lead-out area are sequentially arranged ( write once) A disk comprising: a defect management area provided in at least one of the lead-in area, lead-out area and outer area; And a temporary defect management area provided in at least one of the lead-in area, the lead-out area, and the outer area, wherein the temporary defect management area includes repeatedly recorded temporary defect information corresponding to a recording operation, and a temporary defect. In the defect management area, the temporary defect information and the temporary defect management information finally recorded in the temporary defect management area at the time of finalizing are recorded as the defect information and the defect management information, respectively. This is also achieved by the disc characterized in that the area is recorded.

On the other hand, according to another aspect of the present invention, the technical problem is a method of managing a defect of a disc, (a) the defect information on the data recorded in accordance with the first recording operation in the data area of the disc of the disc Recording as a plurality of first temporary defect information in a temporary defect management area provided in at least one of the lead-in area and the lead-out area; (b) recording management information for managing the first temporary defect information as first temporary defect management information in the temporary defect management area; (c) repeating steps (a) to (b) at least once by incrementing the ordinal number added to the recording operation, the temporary defect information, and the temporary defect management information by one; (d) recording the last recorded temporary defect management information and the last temporary defect information in a defect management area provided in at least one of a lead-in area, a lead-out area and an outer area of the disc; And (e) recording write protection information in the defect management area.

On the other hand, according to another field of the present invention, the technical problem is a recording / reading unit for recording or reading data on the disk in the recording device; And repeatedly recording defect information on data recorded according to a recording operation in the data area of the disc as temporary defect information in a temporary defect management area provided in at least one of a lead-in area and a lead-out area of the disc, Management information for managing the temporary defect information is recorded in the temporary defect management area as temporary defect management information, the temporary defect information recorded most recently among the temporary defect information and the temporary defect management information recorded so far at the time of finalizing, and And controlling the recording / reading unit to record temporary defect management information in a defect management area provided in at least one of a lead-in area and a lead-out area of the disc, and to record write protection information in the defect management area. It is also achieved by the device.

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

1 is a block diagram of a recording apparatus according to a preferred embodiment of the present invention.

Referring to FIG. 1, the recording apparatus includes a recording / reading section 1, a control section 2, and a memory section 3. The recording / reading section 1 records data on the disk 100, which is an information storage medium according to the present embodiment, and reads data to verify the recorded data. The control unit 2 performs defect management according to the present invention and records write protection information according to the present invention. In this embodiment, the control unit 2 conforms to the "verify after write method" in which the defect is found by recording the data in predetermined units and then verifying the recorded data. The control unit 2 records user data in units of one recording operation and then verifies it to check where a defect area occurs. The control unit 2 generates defect information indicating the defect area found as a result of the inspection, and stores the generated defect information in the memory unit 3, collects a predetermined amount, and records the predetermined defect information on the disc 100 as temporary defect information.

The recording operation is a unit of work determined by a user's intention, a recording operation to be performed, and the like. In this embodiment, the disc 100 is loaded into a recording device to perform recording of predetermined data, and then the disc 100 is ejected. Until point. The verification operation after recording during one recording operation is performed at least once, usually a plurality of times. The defect information obtained as a result of performing the verification operation after recording is temporarily stored in the memory unit 3 as temporary defect information.

When the user completes the recording of the predetermined data and then presses an eject button (not shown) provided in the recording apparatus to eject the disc 100, the control unit 2 predicts that one recording operation will end. When it is predicted that the recording operation will be finished, the control section 2 reads the temporary defect information stored in the memory section 3, provides it to the recording / reading section 1, and instructs the disk 100 to record these information.

When data recording is completed on the disc 100, that is, when no further data is to be recorded on the disc 100 (when finalizing), the control unit 2 records the temporary defect information recorded on the disc 100. And the temporary defect management information are recorded in the defect management area provided in the disc 100. Furthermore, recording prevention information is recorded in the defect management area as will be described later.

2 shows the structure of a disk 100 according to a preferred embodiment of the present invention.

Referring to FIG. 2A, when the disc 100 is a single recording layer disc having one recording layer L0, it has a disc structure composed of a lead-in area, a data area and a lead-out area. The lead-in area is located on the inner circumferential side of the disk 100 and the lead-out area is located on the outer circumferential side of the disk 100. The data area is located between the lead-in area and the lead-out area. The data area is divided into a spare area and a user data area. The user data area is an area where user data is recorded, and the spare area is a space provided to compensate for the loss of recording space due to a defect in the user data area, that is, a space provided for defect management, and is recorded in the user data area. If a defect occurs in the data, it is used as an alternative space for recording a new portion of the defect.

Referring to FIG. 2B, the structure of the disk 100 is the same as that of FIG. 2A except for the arrangement of the spare regions. The role of each area is also the same as that described with reference to FIG. Spare areas are located at both ends of the data area. The spare area located between the lead-in area and the user data area is called an inner spare area, and the spare area located between the user data area and the lead-out area is called an outer spare area.

Referring to FIG. 2C, when the disc 100 is a dual recording layer disc having two recording layers L0 and L1, the recording layer L0 includes a lead-in area, a data area, and an outer area of the disc 100. The outer peripheral side, the data region, and the lead-out area are sequentially disposed from the inner peripheral side to the outer peripheral side, and the outer region, the data region, and the lead-out area are sequentially arranged from the outer peripheral side of the disc 100 to the inner peripheral side. Unlike the single recording layer disc of Figs. 2A and 2B, the lead-out area is also arranged on the inner circumferential side of the disc 100. Figs. That is, the recording path for recording data is an OTP (Opposite Track Path) from the lead-in area of the recording layer L0 to the area outside of the recording layer L0, and then from the area outside of the recording layer L1 to the lead-out area of the recording layer L1. to be. Spare areas are allocated to recording layers L0 and L1, respectively.

Referring to FIG. 2D, the structure of the disk 100 is the same as that of FIG. 2C except for the arrangement of the spare areas. The role of each area is also the same as that described with reference to FIG. Spare areas are located at both ends of the data areas of each recording layer L0 and L1. The spare area located near the inner circumference of the disk 100 is called an inner spare area, and the spare area located near the outer circumference is called an outer spare area.

The spare area may be arranged by utilizing a separate space obtained by dividing the user area as needed, and the location may be changed in various ways.

3A is an example of the data structure of the disk 100 of FIG.

Referring to FIG. 3A, when the disc 100 is a single recording layer disc, at least one of the lead-in area and the lead-out area is provided with a defect management area, and at least one of the lead-in area and the lead-out area is provided. A temporary defect management area is provided, and in the case of a dual recording layer disk, a defect management area is provided in at least one of the lead-in area, the lead-out area, and the outer area, and in at least one of the lead-in area and the lead-out area. A temporary defect management area is provided. Preferably, in the case of a disc having a double recording layer as shown in Fig. 2B, the defect management area and the temporary defect management area are present in the lead-in area and the lead-out area located on the inner circumferential side of the disc 100, respectively.

In the defect management area, information that affects the entire disc is recorded, such as the structure of the disc for managing the defect, the position of the defect information, whether the defect is managed, the position and the size of the spare area, and the like. In the information recording method, since the disk 100 of the present embodiment is a write once disk, when the information is changed, a method of newly recording the changed information following the previously recorded information is applied.

Usually, when a disc is loaded into the apparatus, the recording or reproducing apparatus reads information in the lead-in area and the lead-out area to figure out how to manage the disc and how to record or play it. The larger the information recorded in the lead-in area and / or the lead-out area, the longer the time required for loading the disc and then preparing for recording or playback occurs. Therefore, the present invention introduces the concept of temporary defect management information and temporary defect information and records them in a temporary defect management area provided separately from the defect management area of the lead-in area and / or the lead-out area. That is, by finally recording only meaningful defect management information and defect information in the defect management area, it is possible to reduce the amount of information that the recording or reproducing apparatus should read in preparation for recording or reproduction.

In the present embodiment, since defect management is in accordance with the linear substitution scheme, the temporary defect information is composed of information indicating where the defect is generated and information indicating where the newly replaced region is. More preferably, the temporary defect information further includes information indicating whether the region in which the defect is generated is a single defect block or a continuous defect block in which a physically continuous defect is generated. The temporary defect management information is information for managing the temporary defect information and includes information for indicating a location where the temporary defect information is recorded. More preferably, the information further includes information indicating a position at which user data was last recorded in the user data area and information indicating a position of the last replaced area of the spare area. Detailed data structures of the temporary defect information and the temporary defect management information will be described later.

In this embodiment, the temporary defect information and the temporary defect management information are recorded each time the recording operation ends. In the temporary defect management area, information on defects occurring in the data recorded during recording operation # 0 and information on the replacement area is recorded as temporary defect information # 0, and data recorded while recording operation # 1 is performed. The information on the defect and the information on the replacement area generated in " n " Further, in the temporary defect management area, management information for managing the temporary defect information # 0, # 1, ... is recorded as the temporary defect management information # 0, # 1, .... If data can no longer be written to the data area or if you no longer want to write data to the data area, that is, when finalizing, the defect information that was recorded in the temporary defect information area and the temporary defect management information area will be deleted. The defect management information that has been recorded is finally recorded in the defect management area.

The reason for recording the temporary defect information and the temporary defect information again in the defect management area is as follows. When data is no longer needed to be recorded on the disc (finalizing), the recording or reproducing apparatus is moved by moving the last meaningful information of the temporary defect management information and the temporary defect information updated and recorded several times to the defect management area. This is because in the future, when the defect management information is read from the disk, only the last meaningful information can be read from the defect management area so that it can be initialized faster. By recording the defect management information in a plurality of places, the reliability of the information can be improved. This is because there is an advantage.

In this embodiment, defect information recorded in the previous temporary defect information # 0, # 1, # 2, ..., # i-1 is accumulated and recorded in any temporary defect information #i. Therefore, when finalizing, it is sufficient to read only the defect information recorded in the last temporary defect information #i and write it to the defect management area again.

An area in which the temporary defect management information #i is recorded is preferably about 1 cluster in the case of a disk capable of recording a high density of tens of gigabytes, and an area in which the temporary defect information #i is recorded is preferably allocated about 4-8 clusters. This is because the size of the information recorded as the temporary defect information #i is only a few KBytes, but when the minimum physical recording unit of the disk is a cluster, it is preferable to record in cluster units in order to record new information for updating. . On the other hand, the total amount of defects allowed for the disk is preferably about 5 percent of the disk recording capacity. In this case, about 8 bytes of information are needed to record information about one defect, and considering that the size of the cluster is 64K bytes, approximately 4-8 clusters are needed for temporary defect information #i.

In finalizing, the write preventing information is recorded together in the defect management area.

Meanwhile, post-recording verification may also be performed for the temporary defect information #i and the temporary defect management information #i, respectively. When a defect is generated, the information recorded in the portion where the defect is generated may be re-recorded in the spare area according to the linear replacement method, or may be re-recorded in the adjacent area of the temporary defect management area according to the skip substitution method.

FIG. 3B shows an embodiment of the temporary defect management area and the defect management area of FIG. 3A.

The temporary defect management area and the defect management area are provided in at least one of a lead-in area and a lead-out area in the case of a single recording layer disc as shown in FIG. 2A, a lead-in area in a double recording layer disc as shown in FIG. 2B, It is provided in at least one of a lead-out area and an outer area, Preferably it is provided in a lead-in area and a lead-out area, respectively.

Referring to FIG. 3B, two defect management areas (DMAs) 1 and 2 exist in order to further increase the robustness of the defect management information, the defect information, and the write protection information. TDMA indicates a temporary defect management area. The Test area is provided to measure the recording conditions of data, and the Drive and Disc information area is information about a drive used for recording and / or playback, and a disk such as a single recording layer disc or a double recording layer disc. Information is recorded, and Buffers 1, 2, and 3 are areas provided for the role of buffers indicating the boundaries between the areas.

Alternatively, information about the drive used for recording and / or playback recorded in the Drive and Disc information area and information about the disc such as whether it is a single recording disc or a double recording layer disc may be recorded in the defect management area. Can be recorded together.

4A to 4D are data structure diagrams of a temporary defect management area according to an embodiment of the present invention.

4A, the temporary defect management area TDMA is logically divided into a temporary defect information area and a temporary defect management information area. In the temporary defect information area, temporary defect information TDFL # 0, TDFL # 1, and TDFL # 2, ... are sequentially recorded from the beginning of the temporary defect information area. The temporary defect information TDFL # 0, TDFL # 1, and TDFL # 2 ... are repeatedly recorded a plurality of times in order to increase the robustness of the information. In TDFL # 0, TDFL # 0 is repeatedly recorded P times. In the temporary defect management information area, temporary defect management information TDDS # 0, TDDS # 1, and TDDS # 2, ... are sequentially recorded from the beginning of the temporary defect management information area. The temporary defect management information TDDS # 0, TDDS # 1, and TDDS # 2 correspond to the temporary defect information TDFL # 0, TDFL # 1, and TDFL # 2, respectively.

Referring to FIG. 4B, similar to FIG. 4A, the temporary defect management area is logically divided into a temporary defect information area and a temporary defect management information area, but the order in which information is recorded in each area is different from that in FIG. 4A. That is, in the temporary defect information area, temporary defect information TDFL # 0, TDFL # 1, and TDFL # 2, ... are sequentially recorded from the rear part of the temporary defect information area. Similarly, the temporary defect information TDFL # 0, TDFL # 1, TDFL # 2, ... are repeatedly recorded a plurality of times in order to increase the robustness of the information. In TDFL # 0, TDFL # 0 is repeatedly recorded P times. In the temporary defect management information area, temporary defect management information TDDS # 0, TDDS # 1, and TDDS # 2, ... are sequentially recorded from the rear part of the temporary defect management information area. The temporary defect management information TDDS # 0, TDDS # 1, and TDDS # 2 correspond to the temporary defect information TDFL # 0, TDFL # 1, and TDFL # 2, respectively.

Referring to Fig. 4C, temporary defect information and temporary defect management information corresponding to each other are recorded in pairs in the temporary defect management area. That is, the temporary management information TDMA # 0, TDMA # 1, ... is sequentially recorded in the temporary defect management area from the front of the temporary defect management area. The temporary defect management information TDDS # 0 and the temporary defect information TDFL # 0, the temporary defect management information TDDS # 1 and the temporary defect information TDFL # 1, respectively, are recorded in the temporary management information TDMA # 0 and TDMA # 1, respectively. It is. On the other hand, the temporary defect information TDFL # 0, TDFL # 1, and TDFL # 2, ... are repeatedly recorded a plurality of times in order to increase the robustness of the information. In TDFL # 0, TDFL # 0 is repeatedly recorded P times.

Referring to FIG. 4D, similar to the case of FIG. 4C, temporary defect information and temporary defect management information corresponding to each other are recorded in pairs in the temporary defect management area, but the order in which the information is recorded is different. That is, in the temporary defect management area, temporary management information TDMA # 0, TDMA # 1, ... are sequentially recorded from the rear part of the temporary defect management area. The temporary defect management information TDDS # 0 and the temporary defect information TDFL # 0, the temporary defect management information TDDS # 1 and the temporary defect information TDFL # 1, respectively, are recorded in the temporary management information TDMA # 0 and TDMA # 1, respectively. It is. On the other hand, the temporary defect information TDFL # 0, TDFL # 1, and TDFL # 2 ... are repeatedly recorded a plurality of times in order to increase the robustness of the information. In TDFL # 0, TDFL # 0 is repeatedly recorded P times.

5A and 5B are data structure diagrams of TDDS #i.

5A, in the case of a single recording layer disc, as the data structure of TDDS #i, any temporary defect management information TDDS #i indicates an identifier of TDDS #i and a recording position of corresponding temporary defect information TDFL #i. The information is stored. As described with reference to FIGS. 4A to 4D, in the present invention, since the TDFL #i is repeatedly recorded a plurality of times, the information indicating the recording position of the TDFL #i indicates the recording position of each TDFL #i recorded multiple times. It consists of pointers. As TDFL #i is recorded P times in FIG. 5A, P pointers respectively pointing to them are recorded.

Further, in the TDDS #i of the single recording layer disc, the address of the position where user data was last recorded in the user data area of the recording layer L0 and the address of the area which was last replaced in the spare area of the recording layer L0 are recorded. This facilitates disk use. Detailed description will be described later.

Referring to FIG. 5B, in the case of a dual recording layer disc, as the data structure of TDDS #i, any temporary defect management information TDDS #i indicates an identifier of TDDS #i and a recording position of corresponding temporary defect information TDFL #i. The information is stored. As described with reference to FIGS. 4A to 4D, in the present invention, since the TDFL #i is repeatedly recorded a plurality of times, the information indicating the recording position of the TDFL #i indicates the recording position of each TDFL #i recorded multiple times. It consists of pointers. As TDFL #i is recorded P times in FIG. 5, P pointers pointing to them are recorded.

In addition, the TDDS #i of the dual recording layer disk includes the address of the position where user data was last recorded in the user data area of the recording layer L0, the address of the area last replaced in the spare area of the recording layer L0, and the recording layer L1. The address of the position where user data was last recorded in the user data area, and the address of the area last replaced in the spare area of the recording layer L1 are recorded. This facilitates disk use. The detailed description will be described later.

6 is a data structure diagram of TDFL #i.

Referring to Fig. 6, arbitrary temporary defect information TDFL #i stores information about an identifier of TDFL #i, defect # 1, defect # 2, ..., defect #K. Information about Defect # 1, Defect # 2, ..., Defect #K indicates where the defect occurred and where it was replaced, or even whether it is a single defect block or a contiguous defect block. The detailed data structure as the status information will be described later.

7 is a data structure diagram of the defect management information DDS.

Referring to FIG. 7, the DDS recorded in the defect management area includes information recorded in the TDDS #i recorded last in the temporary defect management area and finalization prevention information at the time of finalizing.

The write protection information is information for preventing further data from being recorded on the disc 100. For example, the write protection information may be composed of flag information indicating whether recording protection is set or released for the entire disc, and recordable area information indicating a recordable area without being affected even if recording protection is set. For example, the first 1 bit of the write protection information may indicate whether or not write protection is set or released as flag information, and the remaining bits may each be implemented to indicate whether at least one predetermined area is a recordable area. For example, the second 1 bit may indicate whether the control data area is a recordable area when the write protection is set. As another example, the second 1 bit may indicate whether the control data area is a recordable area when the write protection is set, and the third 1 bit may indicate whether the defect management area is a recordable area. As another example, the third and fourth two bits may indicate whether the defect management area and the spare area are recordable areas. Of course, the write protection information can be expressed by various other bit values and combinations of bit values.

An example in which write protection information is recorded will be described below.

As a first example, write-protection information is recorded in the defect management area of the lead-in area of the single recording layer disc as shown in Figs. 2A or 2B. The defect management area can exceptionally record data even when write protection information is recorded so that data can no longer be recorded on the disc. Therefore, even if the recording protection information is recorded and recording protection is set, the defect management area is not affected. That is, data can be recorded in the defect management area. Therefore, it is possible to correct or change the write protection information.

As a second example, write-protection information is recorded in the defect management area of the lead-in area of the single recording layer disc as shown in Figs. 2A or 2B. Even if write protection information is recorded and recording protection is set, the area allocated for the write protection information in the defect management area is not affected. That is, data can be recorded in the area allocated for the write protection information. Therefore, it is possible to correct or change the write protection information.

As a third example, write-protection information is recorded in the defect management area of the lead-in area of the single recording layer disc as shown in Figs. 2A or 2B. Even if write protection information is recorded and recording protection is set, the defect management areas DMA, Drive and Disc information area and spare area are not affected. That is, data can be recorded in the defect management area, the drive and disc information area, and the spare area. Therefore, not only the correction or change of the recording protection information is possible, but also the defect management is possible even after the recording protection information is recorded. For example, if the error correction rate is less than or equal to the predetermined reference value when reproducing the data recorded in the user data area, the block is considered to have a high risk of occurrence of a defect, and the block is rewritten to the spare area in advance and the block is returned to the defective area. Defect management can be performed in a way that is handled.

However, when one or more spare areas are provided as in the case of FIG. 2D, only at least a part of the plurality of spare areas may be set as a recordable area.

As a fourth example, write-protection information is recorded in the defect management area of the lead-in area of the first recording layer of the dual recording layer. Even if write-protection information is recorded and record-protection is set, the defect management area is not affected. That is, data can be recorded in the defect management area. Therefore, it is possible to correct or change the write protection information.

As a fifth example, write protection information is recorded in the defect management area of the lead-in area of the first recording layer of the dual recording layer. Even if write protection information is recorded and recording protection is set, the defect management area DMA, Drive and Disc information area area and spare area are not affected. That is, data can be recorded in the defect management area DMA, drive and disc information area, and spare area. Therefore, not only the correction or change of the recording protection information is possible, but also the defect management is possible even after the recording protection information is recorded. For example, if the error correction rate is less than or equal to a predetermined reference value when reproducing data recorded in the user data area, the block is regarded as having a high risk of generating a defect, and the block is rewritten to the spare area in advance, and the block is returned to the defective area. Defect management can be performed in a way that is handled. Similarly, when one or more spare areas are provided, only at least some of the plurality of spare areas can be set as recordable areas.

FIG. 8 is a reference diagram for describing in more detail a process of writing data in a user data area A and a spare area B according to an embodiment of the present invention.

The unit for processing data may be divided into sectors and clusters. A sector is a minimal unit that can manage data in a computer's file system or application program. A cluster is a minimum unit that can be physically recorded on a disk at one time. Typically, one or more sectors make up a cluster.

Sectors are divided into physical sectors and logical sectors. The physical sector means space for recording one sector of data on the disk. The address for finding a physical sector is called a physical sector number (PSN). The logical sector refers to a sector unit for managing data in a file system or an application program. Similarly, a logical sector number (LSN) is given. A device for recording and reproducing data on a disc finds a location on the disc of a data to be recorded using a physical sector number. A computer or application for recording data manages the entire data in logical sector units. The position of is managed by the logical sector number. The relationship between the logical sector number and the physical sector number is converted by the controller of the recording or reproducing apparatus by using a defect status and a recording start position.

Referring to FIG. 8, A means a user data area, and B means a spare area. In the user data area and the spare area, there are a plurality of physical sectors (not shown) to which physical sector numbers are sequentially assigned. The logical sector number is given in at least one physical sector unit. However, since the logical sector number is assigned to include the spare area except the defective area generated in the user data area where the defect has occurred, even if the physical sector and the logical sector have the same size, the defective area occurs. The physical sector number and logical sector number do not match.

The method of recording the user data in the user data area is by a continuous recording mode or a random recording mode. In the continuous recording mode, the user data is sequentially recorded in succession, and the random recording mode is not necessarily continuous but in random recording. ① to ⑦ respectively indicate a unit in which a verification operation is performed after recording. The recording device records the user data by the interval ① and then returns to the first part of the interval ① to check whether the data is recorded correctly or whether a defect has occurred. If a part where a defect occurs is found, the part is designated as a defect area. Thus, defect # 1, which is a defect area, is designated. The recording apparatus also records the data recorded in the defect # 1 again in the spare area. The part where the data recorded in the defect # 1 is rewritten is called replacement # 1. Next, the recording apparatus records the user data for the interval ② and then returns to the first part of the interval ② again to check whether the data is properly recorded or whether a defect has occurred. If a defective part is found, that part is designated as defect # 2. In the same way, a replacement # 2 corresponding to defect # 2 is generated. In addition, defect # 3 and replacement # 3, which are defective areas, are generated in the section ③. In section ④, no part where a defect occurred is found and there is no defect area.

After recording and verifying up to interval ④, and when the end of recording operation # 0 is predicted (when the user presses the eject button or completes the recording of the user data assigned to the recording operation), the recorder records temporary defect information # 0, ie TDFL # 0. As a result, information about defects # 1, # 2, and # 3, which are defect areas generated in sections 1 to 4, is recorded in the temporary defect management area. In addition, management information for managing TDFL # 0 is recorded in the temporary defect management area as TDDS # 0.

When recording operation # 1 starts, data is recorded in the same manner up to sections ⑤ through ⑦ and defects # 4, # 5 and replacements # 4, # 5 are generated. Defects # 1, # 2, # 3, and # 4 are single defect blocks in which a single block has failed, and defect # 5 is a continuous defect block in which consecutive blocks have failed. Replace # 5 is a contiguous replace block replaced in response to defect # 5. A block is a physical or logical recording unit and can be variously determined. When the end of recording operation # 1 is predicted, the recording apparatus records information regarding defects # 4 and # 5 as temporary defect information # 1, that is, TDFL # 1, and accumulates the information recorded in temporary defect information # 0. To record more. Similarly, defect management information for managing TDFL # 1 is recorded in the temporary defect management area as TDDS # 1.

In finalizing, the temporary defect information and the temporary defect management information recorded last in the temporary defect management area are recorded in the defect management area as defect information and defect management information, respectively, while recording prevention information is recorded as described above.

9 is a reference diagram to show that the data area can be used more flexibly according to the present invention.

Referring to FIG. 9, if the address of user data last recorded in the user data area and the address of data last replaced in the spare area are known, the usable area can be easily known. In particular, in the user data area, user data is recorded from inner / outer to outer / inner, while data for replacing defects in the spare area is recorded from outer / inner to inner / outer, that is, user data is recorded. The effect is maximized when the direction and the direction in which data for fault replacement are recorded are opposite to each other.

If the physical address increases from inner to outer in the recording layer L0, and the physical address increases from outer to inner in the recording layer L1, the last recording address is the largest physical address of the user data in the user data area of the recording layers L0 and L1. Becomes On the other hand, suppose that in the spare area of the recording layer L0, from the outer circumference to the outer circumference, and in the spare area of the recording layer L1 from the inner circumference to the outer circumference, that is, the direction in which the physical address decreases, the last alternative address is replaced by It will be a small physical address.

For this reason, as described above, if the last recorded address and the last alternative address are recorded in the temporary defect management information TDDS #i, all the defect information of the temporary defect information TDFL #i is read and then the position is not calculated manually. It has the advantage of knowing where to record new data and where to replace. Furthermore, the usable remaining areas of the user data area and the spare area are physically arranged in succession, thereby increasing the use efficiency.

10 and 11 are data structure diagrams of TDFL # 0 and TDFL # 1, which are temporary defect information.

Referring to FIG. 10, information regarding defect # 1, information about defect # 2, and information about defect # 3 are recorded in TDFL # 0. The information about the defect # 1 refers to information indicating where the portion where the defect # 1 has occurred is located and information indicating where the portion where the replacement # 1 is recorded is located. Furthermore, the defect # 1 may further include information indicating whether the defect # 1 is a continuous defect block or a single defect block. Similarly, information about defect # 2 indicates whether defect # 2 is a contiguous defect block or a single defect block, where the location where defect # 2 occurred is located, and where replacement # 2 is recorded. Information about where the defect is located, information about defect # 3 indicates whether defect # 3 is a contiguous defect block or a single defect block, information about where defect # 3 is located, and replacement # 3. Information that tells where the recorded part is located.

The temporary defect information TDFL # 1 includes all the information recorded in TDFL # 0, and also records information about defect # 4 and information about defect # 5. That is, TDFL # 1 has all the defect information that has occurred so far, that is, information about defect # 1, information about defect # 2, information about defect # 3, information about defect # 4, and information about defect # 5. Are all recorded.

Referring to FIG. 11, in this embodiment, the information about defect #i includes status information indicating whether defect #i is a continuous defect block, a single defect block, a pointer to defect #i, and a pointer to replacement #i. do. The status information indicates whether defect #i is a contiguous defect block or a single defect block, and if it is a contiguous defect block, the corresponding defect #i pointer points to the beginning or end of the contiguous defect block, and further the replacement #i pointer is defective. Tells whether the start or end of a replacement block replaces #i. For example, if the status information indicates the start, the subsequent defect #i pointer is the memory sector number at which the consecutive defect blocks start, and the replacement #i pointer indicates the physical sector number at which the replacement #i starts. If the status information indicates that the end of the defect #i pointer is a contiguous sector number ends the consecutive defect block, the replacement # i pointer indicates the physical sector number ending the replacement # i. By defining the consecutive defect blocks through the state information, it is not necessary to record the information on defects in units of blocks, so that the efficiency of information recording and the saving of recording space can be achieved.

The fault #i pointer indicates where the fault #i starts and / or ends. For example, the defect #i pointer may include the physical sector number where defect #i begins. The alternate #i pointer indicates where the alternate #i begins and / or where the alternate #i ends. For example, it may include the physical sector number where the replacement #i begins.

Referring to the defect management method according to the present invention based on the above configuration as follows.

12 is a flowchart for explaining a defect management method according to a preferred embodiment of the present invention.

Referring to Fig. 12, the recording apparatus records defect information on data recorded according to the first recording operation in the temporary defect management area as the first defect information in order to manage the defect of the disc (step 1201). In addition, management information for managing the first temporary defect information is recorded in the temporary defect management area as the first defect management information (step 1202).

Until the finalizing is performed (step 1203), the operations added to the recording operation, the temporary defect information and the temporary defect management information are incremented by one, and the steps 1201 to 1202 are repeated (step 1204). When finalizing is performed (step 1203), the temporary defect management information recorded so far, the temporary defect management information recorded last among the temporary defect information, and the temporary defect information are recorded in the defect management area and the write prevention information is recorded (1205). step). That is, the last temporary defect management information and the last temporary defect information are recorded in the defect management area as the last defect management information and the last defect information, respectively. At this time, the last defect information, the last defect management information, and the write preventing information can be recorded repeatedly. This is to improve the reliability of data detection. Also, the final defect information, the final defect management information, and the record protection information are recorded and verified.If a defect occurs, all the data recorded after the defect and afterwards are ignored (all designated as defect areas). ), It is also possible to record the remaining final defect information, the last defect management information, and the record preventing information since it is designated as the defect area.

13 is a flowchart for describing a defect management method according to another exemplary embodiment.

Referring to FIG. 13, in operation 1301, a recording apparatus records user data in a data area in units in which verification after recording is performed. Next, the data recorded in step 1301 is verified to find a portion where a defect occurs (step 1302). The control unit 2 designates the defective area as a defective area, rewrites the data recorded in the defective area into the spare area to generate a replacement area, and then determines whether the defective area is a single defective block or a continuous defective block. The status information indicating and the pointer information indicating the defective portion and the replaced portion are generated (step 1303), and stored in the memory unit 3 as the first temporary defect information (step 1304). Steps 1301 to 1304 are repeated until the end of the recording operation is predicted (step 1305).

If the recording of the user data according to the user input or recording operation is completed and the end of the recording operation is predicted (step 1305), the control unit 2 of the recording device reads the first temporary defect information stored in the memory unit 3 to determine the temporary defect. The first temporary defect information TDFL # 0 is recorded a plurality of times in the management area (step 1306). In addition, the first temporary defect management information TDDS # 0 is recorded in the temporary defect management area as management information for managing TDFL # 0 (step 1307). Steps 1301 to 1307 are repeated until finalizing is performed (step 1308). However, each time the steps 1301 to 1307 are repeated, the ordinal numbers added to the temporary defect information, the temporary defect management information, the TDFL, and the TDDS are increased by one (step 1309). When finalizing is performed (step 1308), the last recorded temporary defect information TDFL #i and temporary defect management information TDDS #i are recorded in the defect management area as final defect information DFL and final defect management information DDS. Record and record-protection information (step 1310). The last defect information DFL, the last defect management information DDS, and the write preventing information can be repeatedly recorded a plurality of times in recording in the defect management area. This is to improve the reliability of data detection. Likewise, the final defect information, the final defect management information, and the record protection information are recorded and verified, and if a defect occurs, all data recorded after the defect occurrence and subsequent occurrence are ignored (all designated as defect areas). ), It is also possible to record the remaining final defect information, the last defect management information, and the record preventing information since it is designated as the defect area.

As described above, the present invention provides a defect management method applicable to a write once disc. By placing the temporary defect information area in the lead-in area and / or the lead-out area, defect information can be recorded cumulatively, and only the temporary defect information recorded in the last temporary defect information area during finalizing is read and the defect management area The defect management area can be efficiently used by the method of recording in the. Accordingly, even in the case of write once disk, defect management is performed while recording user data, thereby enabling a more stable backup operation without interruption of work.

On the other hand, according to the present invention, the defect management can be performed even if the record preventing information is recorded, and the already recorded record preventing information can be changed.

Claims (20)

In a single recording layer write once disc in which a lead-in area, a data area and a lead-out area are sequentially arranged, A defect management area provided in at least one of the lead-in area and the lead-out area; And A temporary defect management area provided in at least one of the lead-in area and the lead-out area, The temporary defect management area is an area for repeatedly recording temporary defect information and temporary defect management information corresponding to a recording operation; And wherein the defect management area is an area in which temporary defect information and temporary defect management information finally recorded in the temporary defect management area during finalizing are recorded as defect information and defect management information, respectively, and write protection information is recorded. Write once having a first recording layer in which the lead-in area, the data area and the lead-out area are sequentially arranged, and a second recording layer in which the outer area, the data area and the lead-out area are sequentially arranged. ) Disk, A defect management area provided in at least one of the lead-in area, lead-out area, and outer area; And A temporary defect management area provided in at least one of the lead-in area, the lead-out area, and the outer area; The temporary defect management area is an area for repeatedly recording temporary defect information and temporary defect management information corresponding to a recording operation; And wherein the defect management area is an area in which temporary defect information and temporary defect management information finally recorded in the temporary defect management area during finalizing are recorded as defect information and defect management information, respectively, and write protection information is recorded. The method according to claim 1 or 2, And a plurality of defect management areas exist in one area. The method according to claim 1 or 2, And the last recording address of the user area corresponding to each recording layer and the last replacement address of the spare area corresponding to each recording layer are recorded in the temporary defect management area. The method according to claim 1 or 2, And a pointer indicating a position where the temporary defect information is recorded in the temporary defect management area. The method according to claim 1 or 2, And the temporary defect management information is recorded in the temporary defect management area so as to correspond to the temporary defect information recorded for each recording operation. The method according to claim 1 or 2, And the temporary defect information includes status information on a defect, a pointer indicating a location of a defect, and a pointer indicating a location of a replacement. The method of claim 7, wherein The status information is information indicating whether the defect is a continuous defective block or a single defective block. The method of claim 7, wherein The status information is information indicating that the defect is a contiguous defect block and that the corresponding defect position pointer and the replacement position pointer indicate the start position of the defect and the start position of the replacement, respectively. The method of claim 7, wherein The status information is information indicating that the defect is a contiguous defect block and that the corresponding defect position pointer and the replacement position pointer indicate the end position of the defect and the end position of the replacement, respectively. In the method of managing a disk defect, (a) a plurality of first temporary information is stored in a temporary defect management area provided in at least one of a lead-in area and a lead-out area of the disc in the defect information on data recorded according to a first recording operation in the data area of the disc; Recording as defect information; (b) recording management information for managing the first temporary defect information as first temporary defect management information in the temporary defect management area; (c) repeating steps (a) to (b) at least once by incrementing the ordinal number added to the recording operation, the temporary defect information, and the temporary defect management information by one; (d) recording the last recorded temporary defect management information and the last temporary defect information in a defect management area provided in at least one of a lead-in area, a lead-out area and an outer area of the disc; And (d) recording the write protection information in the defect management area. The method of claim 11, And the step (d) is performed after recording the data according to the last recording operation in the data area. The method according to claim 11 or 12, wherein Step (a) is And sequentially recording the temporary defect information from the beginning in the temporary defect information area included in the temporary defect management area. The method of claim 13, Step (b) is And sequentially recording the temporary defect management information from the beginning into the temporary defect information management area included in the temporary defect management area. The method according to claim 11 or 12, wherein Step (a) is And sequentially recording the temporary defect information from the rear part in the temporary defect information area included in the temporary defect management area. The method of claim 15, Step (b) is And sequentially recording the temporary defect management information from the rear part in the temporary defect information management area included in the temporary defect management area. The method according to claim 11 or 12, wherein Steps (a) and (b) And sequentially recording the temporary defect information and the temporary defect management information corresponding to each other in the temporary defect management area from the front of the temporary defect management area in a sequential order. The method according to claim 11 or 12, wherein Steps (a) and (b) And sequentially recording the temporary defect information and the temporary defect management information corresponding to each other in the temporary defect management area sequentially from the rear of the temporary defect management area. The method according to claim 11 or 12, wherein Step (a) is (a1) recording data in a predetermined unit; (a2) verifying the recorded data to find out where the defect occurred; (a3) storing information indicating a defective area in a portion where a defect has occurred and information indicating a replacement area replacing the defective area in the memory as the first temporary defect information; (a4) repeating steps (a1) to (a3) at least once; And and (a5) reading the information stored in the memory and recording the plurality of pieces of first temporary defect information in the temporary defect management area. In the recording device A recording / reading unit for recording or reading data on the disc; And Defect information on data recorded according to a recording operation in the data area of the disc is repeatedly recorded as temporary defect information in a temporary defect management area provided in at least one of a lead-in area and a lead-out area of the disc, and The management information for managing the temporary defect information is recorded in the temporary defect management area as temporary defect management information, and the most recent recorded temporary defect information and temporary defect information and temporary defect management information recorded so far at the time of finalizing And an apparatus for controlling the recording / reading unit to record defect management information in a defect management area provided in at least one of a lead-in area and a lead-out area of the disc and to record write protection information in the defect management area. .