KR100667507B1 - Rewritable high density digital versatile disc - Google Patents

Abstract

An HD(High-Density) DVD(Digital Versatile Disk)-RW(Rewritable) is provided to differently configure servo calibration marks recorded in a WDU(Wobble Data Unit) for inner marks and a WDU for outer marks according to each zone, thereby quickly discriminating a zone where an optical pickup is currently positioned through the servo calibration marks. A data area where user data is recorded is divided into plural zones. A WDU for outer marks and a WDU for inner marks are recorded in each zone. At least one servo calibration mark for distinguishing each zone is recorded in the WDU for the outer marks and the WDU for the inner marks. The at least one servo calibration mark is recorded by being configured to indicate numbers for the respective zones.

Description

Rewritable high density digital versatile disc

1 shows a disc structure for a rewritable high density digital multifunction disc (HD DVD-RW);

FIG. 2 is a view for explaining the structure of a wobble data unit (WDU) for an outer mark on which a servo calibration mark is recorded according to the present invention;

3 is a view for explaining the structure of a wobble data unit (WDU) for the inner mark on which the servo calibration mark is recorded according to the present invention;

4 is a view illustrating a section in which a servo calibration mark is recorded according to the present invention, and

5 is a diagram showing the shape of a servo calibration mark according to a preferred embodiment of the present invention.

The present invention relates to a rewritable high density digital multifunction disc (HD DVD-RW), and more particularly, to a rewritable high density digital multifunction disc which enables to quickly and easily determine the zone in which an optical pickup is currently located. It is about.

In general, CD and DVD are widely used as optical recording media for recording and storing digital audio and video data. Recently, new high-density optical discs, such as high-density high-density, which can store high-quality video data and high-quality audio data for a long time. The standardization of high-definition digital versatile discs (HD DVDs) is progressing rapidly.

High-density Digital Versatile Disc (HD DVD), which is emerging as the next-generation optical recording medium, is a high-density Digital Versatile Disc (HD DVD-ROM) for playback and a recordable high-density Digital Versatile Disc (HD DVD-R) according to the physical structure and recording method And a rewritable high density digital multifunction disc (HD DVD-RW). The rewritable high-density digital multi-function disc (HD DVD-RW) is different from the high-density digital multi-function disc (HD DVD-ROM) for exclusive use of reproduction or the write-once high-density digital multi-function disc (HD DVD-R). overwrite) is possible.

FIG. 1 shows a disc structure for a general rewritable high density digital multifunction disc (HD DVD-RW).

As shown in FIG. 1, a rewritable high density digital multi-function disc (HD DVD-RW) includes a system lead-in area, a data lead-in area, and a data area. ) And a data lead-out area.

Grooves and land tracks are formed in the data lead-in area, the data area, and the data lead-out area except the system lead-in area, and each track is divided into a plurality of physical segments. In each physical segment, a physical address is recorded in the form of a wobble, which is called a periodic wobble address (WAP: Wobble Address Periodic Position). The WAP is composed of 17 wobble data units (WDUs). The information content of the WAP is composed of a sync field, an address field, and a unity field.

On the other hand, the data area is divided into 19 zones, and the rotational speed of the spindle motor in each zone is defined. Therefore, the system can be operated stably by rotating the HD DVD-RW at the speed specified for each zone. In order to operate the system in such a stable state, it is necessary to quickly identify which zone is the zone in which the optical pickup is currently located.

By the way, in the case of the HD DVD-RW, a zone address indicating 19 zone numbers divided in the data area is recorded in the wobble form in the address field constituting the above-described wobble data unit (WDU).

Therefore, in order to read the zone address information, since all the wobble data units (WDUs) must be demodulated and decoded, the operation for determining the corresponding zone cannot be performed quickly. Accordingly, there is an urgent need for the preparation of an efficient method for more quickly identifying the zone where the optical pickup has moved.

Accordingly, the present invention has been created in view of the above situation, and an object of the present invention is to rewrite a zone in which a current optical pickup is located quickly without performing wobble decoding during track jump or search. To provide the highest density digital multifunction discs possible.

In order to solve the above technical problem, in the rewritable digital multifunction disc according to the present invention, a data area in which user data is recorded is divided into a plurality of zones, each zone having a wobble for an outer mark. A wobble data unit for a Wobble Data Unit and an inner mark is recorded, and a wobble data unit for the outer mark or a wobble data unit for the inner mark includes at least one for identifying each zone. One Servo Callibration Mark is recorded.

The at least one servo calibration mark is configured and recorded to indicate a number for each zone.

The at least one servo calibration mark is configured and recorded so that the number for each zone can be represented in the form of n-bit binary number.

The wobble data unit for the outer mark is recorded in the last groove track of each zone, and the wobble data unit for the inner mark is recorded in a track adjacent to the inner side of the last track of each zone.

Hereinafter, with reference to the accompanying drawings will be described the present invention in more detail. However, in describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

First, a rewritable digital multifunction disc (HD DVD-RW) according to the present invention is divided into a system lead-in area, a data lead-in area, a data area, and a data lead-out area as described above with reference to FIG. have. The data area is divided into 19 zones.

In addition, a plurality of grooves and land tracks are formed in each divided zone, and each track is divided into a plurality of physical segments. Each physical segment is composed of a Wobble Address Periodic Position (WAP). The WAP is composed of 17 wobble data units (WDUs).

In the last groove track of each zone, an outer mark is recorded for every 14th wobble data unit (WDU) among the 17 wobble data units (WDU). Inner tracks are recorded for every 14th wobble data unit WDU among the 17 wobble data units WDU in tracks adjacent to the inside of the last track of each zone.

The wobble data unit (WDU) for the outer mark or the wobble data unit (WDU) for the inner mark is characterized in that a servo calibration mark (SCM), which is an identification mark for identifying each zone, is recorded. .

2 is a diagram illustrating a wobble data unit (WDU) for an outer mark in which a servo calibration mark is recorded according to the present invention, and FIG. 3 is a wobble data unit for an inner mark in which a servo calibration mark is recorded according to the present invention. WDU).

As shown in FIGS. 2 and 3, a wobble data unit (WDU) for the outer mark and a wobble data unit (WDU) for the inner mark have a first address indicating a zone address divided in a data area. And second servo calibration marks (SCM) SCM1 and SCM2 are recorded. As shown in FIG. 4, the first and second servo calibration marks SCM1 and SCM2 are recorded in a portion where a zone address transitions.

The first or second servo calibration marks SCM1 and SCM2 are preferably recorded in a form that can indicate the number of the zone divided in the data area. At this time, the first or second servo calibration marks SCM1 and SCM2 may record each zone number in the form of n-bit binary number. The first and second servo calibration marks SCM1 and SCM2 are made by removing a part of the groove structure to make a land portion in the groove track.

The number of each zone may be represented by each of the first servo calibration mark SCM1 or the second servo calibration mark SCM1, or may be represented by a combination of the two marks SCM1 and SCM2.

For example, the zone numbers may be configured by combining the first and second servo calibration marks SCM1 and SCM2. The first calibration mark SCM1 is recorded in a form capable of representing ten digits, and the second calibration mark SCM2 is recorded in a form capable of representing one digit. As described above, the current HD DVD-RW is divided into 19 zones. Therefore, the first servo calibration mark SCM1 may be configured and recorded to indicate 0 and 1, and the second servo calibration mark SCM2 may be configured and recorded to represent 0 to 9.

5 is a diagram illustrating an example of a form of a servo calibration mark according to an exemplary embodiment of the present invention.

As shown in FIG. 3, the first and second servo calibration marks SCM1 and SCM2 according to the present invention may record a number from 0 to 9 in the form of 4-bit binary number. At this time, the first and second servo calibration marks SCM1 and SCM2 are recorded over two wobble intervals, that is, wobble intervals of 186T (T = channel bits). Therefore, in order to configure the servo calibration mark for indicating 0 in the form of 4-bit binary number, all of the allocated section of 186T may be formed by NAND as shown in Fig. 3A.

On the other hand, in order to form a servo calibration mark showing 1 to 9, lands having a length of 23T are formed in both outermost sections of the allocated 186T sections, and in the remaining 140T sections, FIGS. As shown in j), grooves having a length of 20T can be made by forming lands so that the numbers 1 to 9 can be represented in the form of 4-bit binary numbers.

As described above, the first or second servo calibration mark SCM1, which is recorded in the wobble data unit WDU for the outer mark and the wobble data unit WDU for the inner mark, which is recorded in the zone where the zone is transitioned. When SCM2) is configured in such a way that the number of the zone to which it belongs, it is possible to easily determine the current zone without performing a separate decoding process to determine the zone information. For example, the wobble data unit (WDU) or the inner mark for the outer mark in which the optical pickup moved to a specific target position in response to the track jump command is recorded on the first or second servo calibration marks SCM1 and SCM2. After moving to the wobble data unit (WDU), the pattern of the first or second servo calibration marks SCM1 and SCM2 is read while tracking is performed according to the tracking servo control signal. Then, the zone in which the current optical pickup is located can be determined through the read first or second servo calibration marks SCM1 and SCM2. Therefore, it is possible to shorten the time for stabilizing the disk rotation speed during track jump or search operation.

Although the present invention has been described in detail with reference to exemplary embodiments above, those skilled in the art to which the present invention pertains can make various modifications to the above-described embodiments without departing from the scope of the present invention. I will understand. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

As described so far, according to the present invention, the servo calibration marks recorded in the wobble data unit (WDU) for the outer mark and the wobble data unit (WDU) for the inner mark are configured differently for each zone. When performing a jump or search operation, it is possible to quickly determine the zone where the current optical pickup is located through the servo calibration mark without performing wobble decoding on the WAP. Therefore, even in a situation where track jump or search operation is performed, the rotational speed of the disc can be stabilized quickly.

Claims (4)

The data area in which user data is recorded is divided into a plurality of zones, Each zone has a wobble data unit for an outer mark and a wobble data unit for an inner mark. And a wobble data unit for the outer mark or at least one servo calibration mark for identifying each zone in the wobble data unit for the outer mark. The method of claim 1, And the at least one servo calibration mark is configured and recorded to indicate a number for each zone. The method of claim 2, And the at least one servo calibration mark is configured and recorded such that the number for each zone can be represented in the form of n-bit binary number. The method of claim 1, The wobble data unit for the outer mark is recorded in the last groove track of each zone, and the wobble data unit for the inner mark is recorded in a track adjacent to the inner side of the last track of each zone. High density digital multifunction discs available.

Images