KR100925211B1 - High density multi layer optical disc and method for managing a spare area - Google Patents

Abstract

The present invention relates to a high density multilayer optical disc and a spare area management method according to the present invention, wherein the inner spare area and the outer spare area are respectively divided into a plurality of recording layers respectively formed on the high density multilayer optical disc such as a BD-RW Dual Layer or the like. In addition, by separately recording and managing management information suitable for multi-layering, the management information for linking or separately using a plurality of spare areas separately assigned to each recording layer or separately for each recording layer is allocated to each recording layer. It is a very useful invention to be able to use and manage a plurality of spare areas each assigned separately.

Multi-layer, BD-RW Dual Layer, Disc Definitive Structure (DDS) information, spare area full flags, spare area state information

Description

High density multi layer optical disc and method for managing a spare area}             

1 shows a disc structure for a general rewritable Blu-ray disc (BD-RW),

FIG. 2 is a table showing disc definition structure (DDS) information recorded and managed in a lead-in area of a general rewritable Blu-ray disc.

3 shows a disc structure for a high density dual layer optical disc,

FIG. 4 conceptually illustrates a state in which a disc defining structure (DDS) information is included in a lead-in area of a high density dual layer optical disc according to the present invention.

FIG. 5 is a table showing disk limitation structure (DSS) information recorded and managed in the lead-in area of the high density dual layer optical disk according to the present invention;

6 illustrates a configuration of an optical disk device to which a spare area management method according to the present invention is applied.

7 is a flowchart illustrating an operation of a spare area management method according to the present invention;

8 is a table illustrating disk definition structure (DDS) information according to another embodiment of the present invention.

※ Explanation of code for main part of drawing

11: objective lens 12: collimator lens

13: laser diode 50: optical pickup

51: VDR system 52: encoder

100: BD-RW single layer 200: BD-RW dual layer

The present invention relates to a high density multilayer optical disc in which a plurality of recording layers are formed, and a spare area management method accordingly.

Recently, the standardization of new high-density rewritable optical discs, such as 'Blu-ray Disc Rewritable' (hereinafter referred to as 'BD-RW'), capable of recording and storing high-quality video data and high-quality audio data for a long time. As work progresses rapidly, it is expected that related products will be developed, released and commercialized.

On the other hand, in a typical BD-RW Single Layer, as shown in Fig. 1, one data recording layer is formed at a position spaced 0.1 mm apart in a direction opposite to the objective lens 11 of the optical pickup. .

In addition, in an optical disc apparatus for reading, reproducing, or recording data recorded on the recording layer of the BD-RW Single Layer 100, a defect is present in the data area of the optical disc while data is being recorded. In this case, as shown in FIG. 2, data is instead recorded in an inner spare area (ISA) or an outer spare area (OSA) allocated separately in the data area.

In addition, a defect list entry (DL entry) for identifying clusters of a recording unit block (RUB) recorded instead in the spare area is generated and recorded.

Meanwhile, the management information on the spare areas used as described above is recorded and included in rewritable disc definition structure (DDS) information of the lead-in area as shown in FIG. 2. In the DDS information, spare area pool flags for identifying whether the record size (ISA_size) information of the inner spare area, the record size (OSA_size) information of the outer spare area, and whether data is recorded in each spare area ( Spare Area Full Flags) are recorded.

In addition, the spare area pool flags have a recording size of 1 byte including an inner spare area full flag of 1 bit, an outer spare area full flag of 1 bit, and a spare area of 6 bits.

Therefore, in the optical disk apparatus, as described above, when there is a defect while recording data in the data region of the optical disk, after checking and checking the spare region full flags included in the DDS information, By selecting an inner spare area or an outer spare area that can be recorded, a series of data recording operations are performed to record data in the spare area instead.

On the other hand, recently, a high-density multilayer optical disc, for example, a BD-RW Dual Layer, capable of recording and storing a large amount of video and audio data twice as large as a BD-RW Single Layer for a long time, has been developed. As shown, the first recording layer (Layer 1) and the second recording layer (Layer 2) formed in the BD-RW Dual Layer 200 has a predetermined distance (d2), the objective lens of the optical pickup It is formed in the position biased in the direction opposite to (11), respectively.

In addition, an inner spare area and an outer spare area may be separately allocated to data areas of the first recording layer and the second recording layer of the BD-RW Dual Layer 200. There is no way to use and manage a plurality of allocated spare areas more efficiently.

Accordingly, the present invention was created in view of the above circumstances, and separately assigns an inner spare area and an outer spare area to a plurality of recording layers formed on a high density multilayer optical disc, such as a BD-RW Dual Layer. It is an object of the present invention to provide a high-density multilayer optical disc and a spare area management method according to the same, so as to efficiently use or separately use a plurality of spare areas allocated separately.

In the high density multilayer optical disc according to the present invention for achieving the above object, in the high density multilayer optical disc in which a plurality of recording layers are formed, an inner spare area and an outer periphery are respectively assigned to a data area separately assigned to the plurality of recording layers. Spare areas are individually assigned, and management information specifying that the spare areas are linked to each other or used separately for each recording layer is additionally recorded in the lead-in area.

In addition, the spare area management method according to the present invention comprises: a step of detecting a defect while recording data in a data area of a multilayer optical disc; Detecting and checking spare area management information read from a lead-in area of the high density multilayer optical disc when the defect is detected; And determining, based on the identified spare area management information, whether to use the spare area divided into different recording layers in a cooperative manner or to use only the spare area divided into the current recording layer. It is done.

Hereinafter, a preferred embodiment of a high density multilayer optical disc and a spare area management method according to the present invention will be described in detail with reference to the accompanying drawings.

First, the high-density multilayer optical disc according to the present invention, for example, the BD-RW Dual Layer 200, has a lead-in area and a second recording layer in the first recording layer, as shown in FIG. A lead-out area may be separately allocated to the data area of the first recording layer, and the first inner spare area ISA 1, the first outer spare area OSA 1, and the second recording area may be allocated to the data area of the first recording layer. In the data area of the layer, a second inner spare area ISA 2 and a second outer spare area OSA 2 may be separately allocated.

As described above, the management information for managing the plurality of spare areas separately allocated to the data areas of each recording layer is rewritable, which is recorded and managed in the lead-in area as shown in FIG. 5. Recorded in the DDS information.

On the other hand, the DDS information includes information on the recording size (ISA 1_size) of the first inner spare area, information on the recording size (OSA 1_size) of the first outer spare area, and information on the recording size (ISA 2_size) of the second inner spare area. And recording size (OSA 2_size) information of the second outer spare area is recorded.

In addition, spare area full flags may be recorded and included in the DDS information, wherein the spare area full flags include one bit of the first inner spare area full flag b0 and one bit. First outer spare area full flag (b1), and one bit second inner spare area full flag (b2), one bit second outer spare area full flag (b3), and two bit spare area state (Spare) Area State) information b3 b4 may be recorded.

On the other hand, when the space area state information is 'b3 b4 = 00', for example, the first inner and outer spare areas and the second inner and outer spare areas respectively allocated to the first and second recording layers, respectively. In this case, when b3 b4 = 11, the first inner and outer spare areas and the second inner circle respectively allocated to the first recording layer and the second recording layer are separately designated. And the outer spare area to be used and managed in association.

In addition, when 'b3 b4 =' 01 ', it indicates that both the first inner and outer spare areas allocated to the first recording layer are used, and when' b3 b4 = '10', the second recording layer is divided. It indicates that both of the allocated second inner and outer spare areas are used.

Accordingly, in the optical disk device, the spare area state information recorded in the DDS information is checked as described above, and the plurality of space areas separately allocated to the first recording layer and the second recording layer are used. Or, or will be used in conjunction, which will be described in detail below.

FIG. 6 shows a configuration of an optical disk apparatus to which a spare area management method according to the present invention is applied. For example, a video disc recorder (VDR) for recording or reproducing a signal on a BD-RW Dual layer. An optical disk apparatus such as an optical pickup 50 for reading a signal recorded on a high density multilayer optical disk 200 such as a BD-RW Dual layer or recording a data stream processed from an external signal; A VDR system (51) for reproducing signal processing the signal read out from the optical pickup (50) or converting the data stream input from the outside into a data stream suitable for recording; The encoder 52 may be configured to encode an analog signal input from the outside and output the analog signal to the VDR system.

On the other hand, in the VDR system 51 of the optical disk device, as shown in Figure 7, when a high-density multilayer optical disk, for example, BD-RW Dual layer 200 is inserted and seated, a series of optical disk loading (Loading) After performing the operation, the lead-in area is accessed (S10).

Then, the disk information DI and the defect management information (DMA) recorded in the lead-in area are read out and stored in a memory (not shown) provided in the apparatus (S11). In this case, since the defect management information includes the DDS information described above with reference to FIG. 5, the management information for the spare area allocated to each recording layer is eventually stored in the memory.

Subsequently, when the VDR system 51 receives a request for data recording from the user (S12), the VDR system 51 performs a corresponding data recording operation (S13). A corresponding series of operations is performed (S14).

On the other hand, in the VDR system 51, when there is a defect in the data area of the corresponding recording layer during the data recording operation according to the user's request (S15), the spare included in the DDS information is recorded. The area pool flags are searched and confirmed, and at this time, the spare area state information described above with reference to FIG. 5 is searched and confirmed (S16).

In addition, the spare area of each recording layer may be linked or used according to the identified spare area state information (S17). For example, when the spare area state information is 'b3 b4 = 00', The first inner and outer spare areas and the second inner and outer spare areas are separately used and managed. When 'b3 b4 = 11', the first inner and outer spare areas and the second inner and outer spare areas are used and managed in association.

In addition, when 'b3 b4 =' 01 ', it is determined that both the first inner and outer spare areas allocated to the first recording layer are used, and when' b3 b4 = '10', the second recording layer It is determined that both the second inner and outer spare areas allocated to are used, and a spare area of another recording layer is used in conjunction, or an OSD image for generating a recording error is generated and output. You will be performing a series of actions to confirm.

In the VDR system 51, a record list entry (DL entry) for identifying clusters of the recording unit block (RUB) recorded instead in the spare area through the process as described above is recorded and managed. After that (S18), it is confirmed whether or not the data recording is completed (S19), so that the data recording operation is terminated or the data recording operation is maintained.

FIG. 8 is a diagram illustrating disk limited structure (DDS) information according to another embodiment of the present invention in a table form, wherein the spare area state information is recorded and included in the DDS information. By using a separate recording field other than the Spare Area Full Flags, for example, any one free area recorded in the DDS information, recording management may be performed in a different recording field from the spare area full flags.

In the spare area state information, if the data to be recorded in the spare area is normal A / V data while a defect is detected in the data area, the operation of recording the spare area state information is omitted. In the case of information data such as file data or the like, recording management may be performed as information specifying to perform an operation of recording in the spare area.

For reference, the DDS information included in the lead-in area may be recorded in the lead-out area.

As mentioned above, preferred embodiments of the present invention are disclosed for purposes of illustration, and those skilled in the art can improve and change various other embodiments within the spirit and technical scope of the present invention disclosed in the appended claims below. , Replacement or addition would be possible.

The high-density multilayer optical disc and the spare area management method according to the present invention constructed and constructed as described above include an inner spare area and an outer spare in a plurality of recording layers respectively formed on a high-density multilayer optical disc such as a BD-RW Dual Layer. By separately assigning and separately assigning areas, management information for separately connecting and assigning a plurality of spare areas to each recording layer or separately for each recording layer is additionally recorded and managed according to a multi-layer. It is a very useful invention to be able to use and manage a plurality of spare areas separately assigned to each recording layer more efficiently.

Claims (18)

In a multilayer optical disc in which a plurality of recording layers are formed, In the data areas separately allocated to the plurality of recording layers, an inner spare area and an outer spare area are separately allocated, And the management information specifying that at least the outer spare areas are linked to each other or used separately for each recording layer is additionally recorded in the lead-in area. The method of claim 1, And said management information is included in disc control information recorded and included in said lead-in area. The method of claim 2, The disc control information includes recording size information for the inner spare area and the outer spare area separately allocated in the data area of each recording layer, and spare area pool flag information for indicating whether the spare area can be used. Multi-layer optical disk, characterized in that. The method of claim 3, wherein And the spare area full flag information includes spare area management information for designating that at least the outer spare areas are linked to each other or used separately for each recording layer. The method of claim 3, wherein In the disc control information, a spare specifying that at least the outer spare areas are linked to each other or used separately for each recording layer, apart from spare area pool flag information for indicating whether the spare areas are available. A multilayer optical disc, comprising: area management information recorded therein. The method according to any one of claims 4 and 5, The spare area management information skips the operation of recording in the spare area when the recording data to be recorded in the spare area is A / V data, and the information for designating that the spare area management information is to be recorded in the spare area. Multi-layer optical disc characterized in that. Detecting defects while recording data in a data area of the multilayer optical disc; And Based on the spare area management information recorded in the lead-in area of the multilayer optical disc, the spare area divided into the current recording layer or the spare area allocated to the other recording layer for the detected defect is used. Spare area management method comprising the step of determining to use only. The method of claim 7, wherein And said determining step searches for and determines spare area management information in the disc control information read out from the lead-in area of said multilayer optical disc. The method of claim 8, And, when the data is recorded in any one spare area after the determining step, generating and recording and managing a defect list entry for managing the defect. The method of claim 7, wherein And when the spare areas are linked to each other, the spare areas of each recording layer are linked to each other in a predetermined order of use. The method of claim 7, wherein A method of managing a spare area, wherein data is recorded using the spare area of the current recording layer when only the spare area allocated to the current recording layer is used. An optical disk apparatus for detecting defects while recording data on a multilayer optical disk, A signal processor for converting the input data into data suitable for recording; An optical pickup for recording the data from the signal processing unit into a data area of the multilayer optical disc; And Control unit for controlling the signal processing unit and the optical pickup for data recording Including, When the defect is detected, the controller is configured to associate or use a spare area allocated to another recording layer with respect to the detected defect based on spare area management information recorded in the lead-in area of the multilayer optical disc. And determining to use only the spare area allocated to the recording layer separately. The optical disc apparatus according to claim 12, wherein the control unit searches for and determines spare area management information in the disc control information read out from the lead-in area of the multilayer optical disc. The optical disc apparatus according to claim 13, wherein, when the data is recorded in any one spare area after the determination, the control unit generates and records a defect list entry for managing the defect. The optical disc apparatus according to claim 12, wherein the control unit uses the spare areas of the respective recording layers in a predetermined order of use when the spare areas are linked to each other. The optical disc apparatus according to claim 12, wherein the control unit controls to record data using the spare area of the current recording layer when using only the spare area divided and allocated to the current recording layer. As a method of performing defect management on a multilayer optical disc, (a) Only a spare area recorded in at least one specific area of the multilayer optical disc and linked to a spare area divided into different recording layers with respect to the detected defect or assigned separately to the current recording layer Reading disc structure information including spare area management information for specifying division to use and storing in the memory; (b) determining whether the detected defects are to be used in association with a spare area allocated to another recording layer or to use only a spare area allocated to a current recording layer, based on the detected disk structure information; And (c) processing the defects according to the determination How to include. 18. The method of claim 17, wherein the step (c) further comprises, when recording data in any one spare area, generating and managing a defect list entry for managing the defect.

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