KR20050105764A - Method of defect management in high density optical disc and appratus of the same - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to high density optical discs, and more particularly, to a method and apparatus for efficiently managing a defect area detected upon reproduction of a high density optical disc such as a Blu-ray Disc. According to the present invention, when a defective area is detected during real-time reproduction of the optical disc, the high-density optical disc can be managed more efficiently by recording and managing information on the defective area without replacing and recording data to be recorded in the defective area. There is an effect of performing recording and reproduction of data.

Description

Method and defect management in high density optical disc and Appratus of the same

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to high density optical discs, and more particularly, to a method and apparatus for efficiently managing a defect area detected upon reproduction of a high density optical disc such as a Blu-ray Disc.

As optical recording media, optical disks capable of recording large amounts of data are widely used. Among them, recently, a new high-density optical recording medium (HD-DVD) capable of recording and storing high-definition video data and high-quality audio data for a long time, for example, Blu-ray Disc (hereinafter referred to as "BD"). ) Is being developed.

Blu-ray Disc (BD), the next-generation HD-DVD technology, is a next-generation optical recording solution that can contain data that significantly surpasses the existing DVD. Recently, the world's standard technical specifications with other digital devices have been established.

In connection with this, various standard proposals relating to the rewritable Blu-ray Disc of the Blu-ray Disc have been prepared. In the case of the rewritable Blu-ray Disc, data is recorded in a cluster unit corresponding to a predetermined recording unit, and in view of the characteristic, data can be repeatedly recorded in a specific area of the disc.

If a defective area is detected during recording of data on a rewritable Blu-ray Disc having such characteristics, efficient management of the defective area will be required, but a unified standard for this will not be completed. In particular, it is urgently required to provide a management method for a case where a defective area is detected not only at the time of data recording but also at the time of data reproduction.

Accordingly, the present invention has been made in view of the above circumstances, and an object of the present invention is to provide a method and apparatus for managing a defective area of a high density optical disk such as a Blu-ray disk.

First, it is to propose an efficient management method of a defect area that can be detected during data recording and reproduction of a high density optical disc.

Secondly, an optical recording and reproducing apparatus for efficiently recording and reproducing data by using the proposed management method.

A method for managing a defective area of a high density optical disc according to the present invention for achieving the above object is a real time reproduction of the optical disc in a recordable high density optical disc which is divided into a lead-in area, a data area, and a lead-out area. When the defect area is detected, it is characterized in that the information on the defect area is recorded and managed without alternatively recording data to be recorded in the defect area.

The recording and reproducing apparatus according to the method for managing a defect area of a high density optical disc according to the present invention includes a memory in which management information of a high density optical disc is read and stored, and real time reproduction of a specific area in an optical disc that a user wants to reproduce through the stored management information. And a microcomputer that registers and manages the defective area in the RAD or NRD type, without recording data to be recorded in the detected defective area.

Hereinafter, a preferred embodiment of a method and apparatus for managing a defective area of a high density optical disc according to the present invention will be described in detail with reference to the accompanying drawings. In addition, the term used in the present invention was selected a general term that is widely used at present, but according to the emergence of a new technology, the term that the applicant deemed most appropriate in the present invention was arbitrarily used, and the meaning of the term in the corresponding description. It will be explained clearly. Therefore, in the understanding of the present invention, it is intended that the present invention should be understood as the meaning of terms rather than simple names of terms.

1 to 2 are diagrams showing the basic structure of the high density optical disk according to the present invention.

First, as shown in FIG. 1, an optical disk having a single layer among the high-density optical disks according to the present invention is largely classified into a lead-in zone and a lead-out area in which various types of management information of the disk are recorded. A lead-out zone is separately allocated, and a data zone (Data Zone 0) in which user data is recorded exists between the lead-in area and the lead-out area. In addition, the data zone Data Zone 0 includes an inner spare area ISA 0, a user data area in which actual user data is recorded, and an outer spare area. , OSA 0) may have a structure that is separately allocated.

In this case, the spare areas ISA 0 and OSA 0 in the data zone 0 are used to alternately record data to be recorded in a defect cluster that may occur in the user data area. This area is created by.

To this end, the inner spare area ISA 0 has a fixed size of 2048 physical clusters, and the outer spare area OSA 0 has a variable size of N * 256 physical clusters.

Also, as shown in FIG. 2, an optical disk having a dual layer among the high-density optical disks according to the present invention has two layers (layer 0, layer 1), each of which reads various management information of the disk. The lead in / out zone and the outer zone 1 and data zones 0 and 1 between the zones may be separately allocated.

The data zone 0 of the layer 0 is further divided into an inner spare area 0 (ISA 0), a user data area (User data area), and an outer spare area 0 (OSA 0). 1 (Data Zone 1) is divided into an inner spare area 1 (ISA 1), a user data area (User Data Area), and an outer spare area 1 (OSA 1).

At this time, the spare areas are used for the purpose of substituting the data to be recorded in the defect cluster that may occur in each user data area as described above.

To this end, the inner spare region 0 (ISA 0) has a fixed size of 2048 physical cluster, the outer spare regions 0 and 1 (OSA 0, 1) have a variable size of N * 256 physical cluster, and the inner spare region 1 (ISA 1) has a variable L * 256 physical cluster size.

In the high-density optical disc having such a structure, a method of managing a defective area that can occur in the data area will be described with reference to the accompanying drawings.

3A to 3B are diagrams showing a method for managing a defective area in a rewritable high density optical disc according to the present invention.

First, as shown in FIG. 3A, the rewritable high density optical disc according to the present invention has a lead-in zone, a data zone, and a lead-out zone as described above. In the case of a high-density optical disc that is separately allocated and particularly rewritable, it has a defect management area (DMA) as a defect management area in the lead-in zone and the lead-out zone. (For convenience of description, only DMAs present in the lead-in area are shown in FIG. 3A.)

In a high-density rewritable optical disc having such a structure, when defective areas A and B are generated in a user data area in the data area, data to be recorded in the defective areas A and B is spared. Alternate recording is used for the area (ISA 0, OSA 0). That is, in the case of Fig. 3A, the data to be recorded in the defective areas A and B generated in the user data area is alternatively recorded in the inner spare area 0 (ISA 0) (C, D) of the spare areas. .

The defective areas A and B may be caused by various factors such as damage or contamination of the disk surface. When the defective areas A and B are detected in the user data area, the defective areas A and B are detected. By re-allocating the data to be recorded in (A, B) in the spare area, it is possible to efficiently manage the defective area and to record the data. Such a case where the data to be recorded in the defective area is alternately recorded in the spare area is specifically called a RAD (Re-Allocatable Defect) type.

As described above, when data to be recorded in the defective area is recorded in the spare area, the position information or the like regarding the replacement recording is recorded as a defect list (DFL) entry in the defect management area (DMA) area.

In more detail, the DFL is composed of a list, and the list is composed of a plurality of entries in which the location information of the defective area is recorded as an entry of 8 bytes. At this time, one entry includes a field (status 1, status 2) for recording information on whether or not to substitute recording, and a "Defective Cluster" for recording the first physical sector number (PSN) of the defective area in the data area. first PSN "field and a" Replacement Cluster first PSN "field that records the first physical sector number of the location where the defective area is to be replaced.

Therefore, when data to be recorded in the defective area A is normally recorded in the replacement area C, "0000" is recorded in the "status 1" field as a field for informing such a normally recorded state, and "Defective Cluster". In the "first PSN" field, "a" which is the first physical sector number of the defective area is recorded.

In addition, in the case of a rewritable high-density optical disc, the "status 2" field is a field that has not been determined to be used yet, but it is preferable to record about "0000", but it will be obvious that the "status 2" field is used in various types of codes depending on whether it is used later. . Finally, in the "Replacement Cluster first PSN" field, "c", which is the first physical sector number of the replacement recording area, is recorded.

Meanwhile, in addition to such a case, there may be a case in which the data to be recorded in the defective area cannot be normally recorded. In this case, when the defective area B is detected, the replacement area D to be recorded and replaced is allocated, but the data There may be times when you do not record.

For example, in real time recording such as broadcast recording, in case of overwriting in an already recorded area, when a defective area previously registered in the RAD type is encountered, the time to be alternately recorded in the assigned replacement area is recorded. Since there is no room for it, the replacement record cannot be performed. That is, a replacement area is generated in which no replacement recording is performed for the defective area.

Therefore, in this case, after the real-time recording is completed, the state of the pre-registered status 1 is changed from "0000" to "1000" indicating that no replacement has been recorded.

In this way, the area to be recorded for replacement of the defective area is secured, and when non real-time recording is performed again, the data to be recorded in the defective area is secured without reassigning the replacement area. It will write to the replacement area.

3A, in the case of the defective area B, since data to be recorded in the defective area B is not recorded in the replacement area, “1000” is recorded in the “status 1” field. In the "Defective Cluster first PSN" field, "b" is used as the first physical sector number of the defect area, "0000" is not used in the "status 2" field, and "Replacement Cluster first PSN" field is replaced. "D" is written as the first physical sector number of the area.

On the other hand, there may be a case where the area to which the data to be recorded in the defective area is to be recorded is not allocated to the defective area occurring in the user data area.

In such a case, for example, there may be a case where the spare area to be alternately recorded is insufficient, or the alternative recording is prohibited during real time recording such as broadcast recording or by setting on the optical disc drive. A defect area management method for this case is shown in FIG. 3B.

As shown in FIG. 3B, when the defective areas A and B are generated in the user data area, when the replacement recording is not performed due to the factors described above, information about the defective area is registered as a DFL entry and recorded in the DMA area. Use the method.

That is, as shown in FIG. 3B, one entry is allocated to each defective area, indicating that no replacement has been recorded, and “0001” is recorded in the “status 1” field, and the “Defective Cluster first PSN” field. "A" and "b" are recorded as the first physical sector number of the defective area, respectively. In addition, since the "status 2" field is not used, "0000" will be recorded, and "0" will be recorded in the "Replacement Cluster first PSN" field because no replacement area is allocated.

In this way, the case where no area to be recorded alternately is allocated is specifically called NRD (Non Re-allocatable Defect) type, and in this NRD type, reproduction is performed by skipping the defective area with reference to the DFL entry information during subsequent reproduction. Will be.

3A to 3B illustrate a case of a single layer of a rewritable high-density optical disk, for example. However, even in the case of a dual-layer disk, there is no significant difference in the basic management method.

Meanwhile, according to the present invention, when a new defect area is detected at the time of real time reproduction of the recorded data as well as the defect area detected during data recording, the detected defect area is managed. Is as follows.

4A to 4B are diagrams showing a method of managing a defective area detected during real time reproduction of data in a rewritable optical disc according to the present invention.

As shown in Fig. 4A, when a new defective area A is detected during real time reproduction of data recorded on a rewritable high-density optical disc, the information on the defective area is registered in the DFL entry in the RAD type (status 1 = 1000). Use

In other words, if a defective area A is newly found during real-time reproduction of data, there is no time to substitute recording, so that only the replacement area B is allocated. At this time, of course, the information regarding the position of the defective area A and the assigned replacement area B is registered in the DFL entry.

As such, when information about the position of the defect area A found during real-time reproduction of data is registered in the DFL entry in the RAD (status 1 = 1000) type, the defect is subsequently overwritten when new data is overwritten. With reference to the information about the area A, a method of recording data to be recorded in the defective area A in the assigned replacement area B is used. Of course, you will need to change the "status 1" field of the DFL entry to "0000".

Therefore, as in the case of Fig. 4A, when a defective area found during real-time reproduction is registered in the RAD type, " 1000 " in which a replacement area is allocated but no data is recorded is recorded in " status 1 " In the "Defective Cluster first PSN", "a" which is the first physical sector number of the defective area is recorded. In the case of a rewritable high-density optical disc, a "0000" bit may be recorded in the "status 2" field, and a "0000" bit may be recorded in the "Replacement Cluster first PSN" field. b "is recorded.

On the other hand, as shown in Fig. 4B, when a defective area A is found during real time reproduction of a recorded area on a rewritable optical disc, a method of registering information on the defective area A as an NRD type may be used.

That is, by registering the position information of the defective area A found during real-time reproduction in the DFL entry in the NRD type, the new data for the area including the defective area A is recorded in the registered defective area. The information is referred to.

For this purpose, the "status 1" field of the DFL entry has a "0001" bit indicating that it is of NRD type, the "Defective Cluster first PSN" field has "a" which is the first physical sector number of the defective area, and the "status 2" field. The bit "0000" is recorded in the "Replacement Cluster first PSN" field.

Meanwhile, FIG. 5 is a diagram showing the configuration of an optical recording and reproducing apparatus in which the technical idea according to the present invention is implemented.

As illustrated in FIG. 5, the optical recording and reproducing apparatus according to the present invention includes a recording / reproducing device 10 for recording and reproducing an optical disk, and a controller 20 for controlling the recording / reproducing device 10. (The recording and playback section 10 is often referred to as an "optical disk drive.")

In the optical recording and reproducing apparatus having such a configuration, the control unit 20 issues a recording or reproducing command to a specific region to the recording and reproducing unit 10, and the recording and reproducing unit 10 commands the control unit 20. As a result, recording and reproduction of the specific area of the optical disc is performed.

In this case, the recording and reproducing unit 10 specifically includes an interface unit 12 which communicates data and commands with the control unit 20, and records or reads data directly on the optical disc. A pickup processor 11 and a data processor 13 for receiving a signal read out from the pickup unit 11 and restoring the signal to a desired signal value, or for modulating a signal to be recorded into a signal recorded on an optical disc. And a servo unit 14 for controlling the pick-up unit 11 to accurately read signals from the optical disc or to accurately record signals on the optical disc, and a memory 15 for temporarily storing various information and data including management information. ) And a microcomputer 16 that controls the components in the recording and playback section 10.

The recording process of data in the high-density optical disc rewritable by the method according to the present invention using the optical recording and reproducing apparatus configured as described above will be described in detail as follows.

First, when a rewritable optical disc is inserted into the optical recording / reproducing apparatus, all management information in the optical disc is read out and stored in the memory in the recording / reproducing section 10, and these management information is utilized in recording and reproducing the optical disc.

In this state, when the user wants to record to a specific area of the optical disc, the control unit 20 transfers the data to the recording and reproducing unit 10 together with the data to record the position information desired for recording as a recording command.

At this time, after receiving the recording command, the microcomputer 16 in the recording / reproducing section 10 determines whether the area in the optical disc that the control section 20 wants to record from the management information stored in the memory 15 is a defective area. And determining whether or not the recording is completed, and recording is performed according to the recording command of the controller 20 in an area other than the defective area or the completed recording area.

If a defective area is found during the recording as described above, the data to be recorded in the defective area is replaced by another area (spare area) in the data area, and related information is recorded in the DFL entry in the DMA area. Done.

Therefore, the microcomputer 16 transfers the position information and data of the area or defective area to be recorded alternately to the servo 14 and the data processor 13, and records or substitutes the recording at a desired position in the disc through the pickup unit 11. Allow this to complete.

A reproducing method according to the present invention for a rewritable optical disc recorded in this manner is as follows.

Initially, when a rewritable optical disc on which data is recorded is inserted into the recording / reproducing apparatus, all management information in the disk is read out and stored in the memory 15 in the recording / reproducing section 10, and these management information are recorded and reproduced in the optical disk. Are utilized.

In this state, when the user wants real time reproduction to a specific area of the optical disc, the control unit 20 transmits the position information desired for real time reproduction to the recording and playback unit 10 as a reproduction command. The microcomputer 16 in the recording / playback section 10 performs real-time reproduction of data recorded on the optical device according to the real-time reproduction command.

If a new defective area is detected during playback in this manner, the defective area is registered as a RAD (status 1 = 1000) type or an NRD type so that it can be referred to later when rewriting new data in the area. .

To this end, the microcomputer 16 transmits the location information of the new defective area and the location information of the replacement area to the servo 14 and the data processor 13 in the case of the RAD type, and the pickup unit 11 transmits the location information. Information is recorded in the DMA area of the optical disc.

As described above, the method and apparatus for managing a defective area of a high density optical disc according to the present invention proposes an efficient management method for a defective area that can be found not only at the time of data recording on the high density optical disc but also at the time of reproduction of the data, thereby providing a high density optical disc. There is an effect of more efficiently managing and recording and reproducing data.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the examples, but should be defined by the claims.

1 to 2 show the basic structure of the high density optical disk according to the present invention.

3A to 3B illustrate a method of managing a defective area in a rewritable high density optical disc according to the present invention.

4A to 4B illustrate a method of managing a defective area detected during real time reproduction of data in a rewritable optical disc according to the present invention.

5 is a diagram showing the configuration of an optical recording and reproducing apparatus according to the present invention.

-Explanation of symbols for the main parts of the drawing-

10: recording and playback section 11: pickup

12 interface 13 data-processor

14: Servo 15: Memory

16: microcomputer 20: host or control unit

Claims (7)

A high-density recordable optical disc allocated into a lead-in area, a data area, and a lead-out area, And recording and managing information on the defective area without alternately recording data to be recorded in the defective area when a defective area is detected during real time reproduction of the optical disc. The method of claim 1, And the information on the defective area is registered in the RAD type including the defective area and position information of the replacement area to replace the defective area. The method of claim 2, And the data is not recorded in the replacement area. The method of claim 2, And "1000" bits are recorded in the "status 1" field of the RAD type. The method of claim 1, And the information on the defect area is registered in the NRD type including the position information of the defect area. The method of claim 1, And the information on the defect area is registered in a DFL entry in a DMA area of the high density optical disc. A memory in which management information of the high density optical disc is read and stored; And a microcomputer that registers and manages the defective area in the RAD or NRD type, without recording data to be recorded in the defective area detected during real time reproduction of a specific area in the optical disc to be reproduced by the user through the stored management information. The defect area management apparatus of the high density optical disc, characterized in that the configuration.