KR100917892B1 - Optical information storage medium and information reproduction / recording method - Google Patents

Abstract

Disclosed is an optical information storage medium dedicated to reproduction.

The disclosed optical information storage medium is a reproduction-only optical information storage medium having a plurality of areas, characterized in that a transition area is provided in at least one of the areas between the plurality of areas.

With this arrangement, it is possible to ensure the compatibility between storage media by reducing the error occurrence rate when data is reproduced in the optical information storage medium dedicated to reproduction, and presenting a standard for the transition area.

Description

Optical information storage medium and method of reproducing / recording information from / onto the same}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical information storage medium for reproduction only and a method of reproducing information stored therein. More particularly, the present invention relates to an optical information storage medium having a transition region connecting the regions constituting the storage medium and the information stored therein. It is about a method.

Optical information storage medium For example, an optical disk is widely used as an information storage medium of an optical pickup apparatus for recording / reproducing information in a non-contact manner, and includes a compact disk (CD) and a digital multifunction disk (DVD) according to the information recording capacity. digital versatile disk). In addition, optical discs capable of recording, erasing and reproducing include 650MB CD-R, CD-RW, 4.7GB DVD + RW, and the like. Furthermore, HD-DVD with a recording capacity of 23GB is also being developed.

By the way, the various types of optical information storage media as described above have standardized specifications for each type of storage media in consideration of economic convenience or economic convenience of users, and standardize the storage media that are not yet defined. Efforts are underway. Therefore, for standardization, development of the format is required in order to ensure compatibility or consistency with existing storage media.

The conventional read-only optical disc includes a burst cutting area (BCA) 10, a lead-in area 20, a user data area 30, and a lead-out area 40 as shown in FIG. The BCA 10 records information on the serial number of the optical disc, and the disc related information is recorded in the lead-in area 20. Here, the serial number of the optical disc is recorded as a barcode.

On the other hand, in the conventional reproduction-only optical disc, the BCA 10, the lead-in area 20, the user data area 30 and the lead-out area 40 are continuously arranged without transition areas in the boundary area between the respective areas. have. However, when the pits of the BCA 10, the lead-in area 20, and the user data area 30 are formed in different pit patterns, there may be a problem in data reproduction if data is continuously reproduced without a transition area. .

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and includes an optical information storage medium including a plurality of areas, and having a transition area therebetween so as to facilitate data reproduction, and a method of reproducing information stored therein. The purpose is to provide.

In order to achieve the above object, the optical information storage medium according to the present invention is a reproduction-only optical information storage medium having a plurality of areas, wherein a transition area is provided in at least one of each area between the plurality of areas. It is characterized by.

Further, data is recorded in pits in the plurality of areas and the transition area.

Here, the pit pattern of the transition region is preferably the same as the pit pattern of the region in front of the transition region or the pit pattern of the region behind the transition region.

In addition, the transition region may be formed as a mirror region.

Further, the pits of the transition region are formed in a straight pattern or wobbling pattern.

In addition, the track pitches of the pits formed in the transition region and two regions adjacent to the transition region may be the same or different. In particular, it is preferable that the track pitch of the pit formed in the transition region gradually increases or decreases from the track pitch of the pit formed in the region before the transition region to the track pitch of the pit formed in the region behind the transition region.

In order to achieve the above object, an optical information storage medium according to the present invention includes a BCA, a lead-in area, a user data area, and a lead-out area, and in the reproduction-only optical information storage medium in which the entire area is formed of pits,

A transition area is provided in at least one of a boundary area between the BCA and the lead-in area, a border area between the lead-in area and the user data area, and a border area between the user data area and the lead-out area.

In addition, a first transition region is provided between the BCA and the lead-in region, and the pits formed in the BCA, the lead-in region and the first transition region are each a straight pattern or a wobbling pattern.

In addition, a second transition region is provided between the lead-in area and the user data area, and the pits formed in the lead-in area, the user data area, and the second transition area are each a straight pattern or a wobbling pattern.

On the other hand, when the pattern of the pit formed in the first transition region or the second transition region is a wobbling pattern, it is preferable to gradually reduce or increase the amplitude of the wobble.

In order to achieve the above object, the optical information storage medium according to the present invention includes a BCA, a lead-in area, a user data area, and a lead-out area, and in the reproduction-only optical information storage medium in which the entire area is formed of pits,

At least one of the BCA, the lead-in area, the user data area, and the lead-out area is divided into a plurality of small areas, and a transition area is provided in a boundary area between the plurality of small areas.

As described above, the optical information storage medium according to the present invention includes a plurality of areas according to a function or purpose, and includes a transition area in the boundary area between the plurality of areas so that the data can be smoothly reproduced and the data is reproduced. There is an advantage in reducing the error occurrence rate. In addition, by providing a standard for the transition region in a reproduction-only optical information storage medium, it is possible to ensure compatibility between storage media.

Hereinafter, an optical information storage medium according to the present invention will be described in detail with reference to the accompanying drawings.

The optical information storage medium according to the present invention is applied to a storage medium used exclusively for reproduction, and an entire area of the storage medium is formed of pits. In addition, the optical information storage medium according to the present invention may be divided into a plurality of areas according to functions. For example, as shown in FIG. 1, the BCA (Burst Cutting Area) 10, the lead-in area 20, the data area 30 in which user data is recorded, and the lead-out area from the inner circumference of the optical information storage medium. It is divided into 40.

In the BCA 10, a serial number of an optical information storage medium, for example, an optical disc is recorded or data called a BCA area is recorded. Disc-related information, copy protection information, and the like are recorded in the lead-in area 20. Disc-related information includes, for example, information on types of storage media such as recordable discs, write once discs, and playback-only discs, information on the number of recording layers, recording speed information, and disc size information. have.

In the optical information storage medium according to the first embodiment of the present invention, a first transition zone is provided between the BCA 10 and the lead-in area 20.

First, when data is recorded in the BCA 10 as a first straight pit, and data is recorded in the lead-in area 20 as a second straight pit or wobbling pit having a different pattern from the first straight pit. There can be. In addition, data is recorded in the BCA 10 as a first wobbling pit, and data is recorded in the lead-in area 20 as a second wobbling pit or a straight pit having a pattern different from that of the first wobbling pit. There may be occasions. Here, the straight pit represents a case where the pits are arranged in an red line, and the wobbling pit represents a case where the pits are arranged in a wave form.

 The first and second straight pits and the first and second wobbling pits may be arranged in a single pattern, a specific pattern, or a random pattern. A single pattern means a pattern in which pits having the same length of nT are arranged at regular intervals. Where n is a natural number and T is the minimum length of the pit. For example, a straight single pattern represents a case where a single pattern is arranged in a straight line, and a wobbling single pattern represents a case where a single pattern is arranged in a wave form. A particular pattern is a pattern in which arrays of pits of different lengths appear repeatedly. For example, the pit patterns by the combination of 3T and 6T can be repeatedly arranged. Here, the straight specific pattern represents a case where the specific pattern is arranged in a straight line, and the wobbling specific pattern represents a case where the specific pattern is arranged in a wave form. The pit of the random pattern means a pattern in which an arrangement of pit having different lengths is irregular. For example, the straight random pattern represents a case where the random patterns are arranged in a straight line, and the wobbling random pattern represents a case where the random patterns are arranged in a wave form.

Meanwhile, a first transition region 15 is formed between the BCA 10 and the lead-in region 20. Since the patterns of the BCA 10 and the lead-in area 20 are different from each other, the first transition area 15 is provided in preparation for the continuous reproduction of data. In the first transition region 15, information indicating a transition region is recorded.

Hereinafter, the pattern of the pits formed in the BCA 10, the first transition region 15 and the lead-in region 20 will be described in detail.

2A to 2E illustrate examples of a pit pattern formed in the first transition region 15 when the BCA 10 is formed in a single straight pattern and the lead-in area 20 is formed in a straight random pattern. It is shown.

As shown in FIG. 2A, data is written to the BCA 10 in a straight single pattern pit, and data is recorded in the lead-in area 20 in a straight random pattern pit. A first transition region 15 formed in a straight single pattern is provided between the lead-in regions 20. In addition, the first transition region 15 may be formed as a pit (not shown) of a single wobbling pattern.

As shown in FIG. 2B, data is written to the BCA 10 as a straight single pattern pit, data is written to the lead-in area 20 as a straight random pattern pit, and the BCA 10 is read. A first transition region 15 formed of pits of a straight random pattern is provided between the in regions 20. In addition, the first transition region 15 may be formed as a pit (not shown) of a wobbling random pattern.

As shown in FIG. 2C, data is written to the BCA 10 in a straight single pattern pit, and data is recorded in the lead-in area 20 in a straight random pattern pit, and the BCA 10 is read. A first transition region 15 formed as a mirror region is provided between the phosphorous regions 20.

As shown in FIG. 2D, data is written to the BCA 10 as a straight single pattern pit, and data is written to the lead-in area 20 as a straight random pattern pit, and the BCA 10 is read. A first transition region 15 is formed between the phosphorous regions 20 by a pit of a straight specific pattern.

In addition, the pits of the first transition region 15 may be formed in a single wobbling pattern, a wobbling random pattern, or a wobbling specific pattern. 2E illustrates a case where the first transition region 15 is formed in a wobbling random pattern.

2A to 2E illustrate the case in which the BCA 10 is formed in the pit of a straight single pattern, but the same applies to the case in which the BCA 10 is formed in the wobbling single pattern.

3A to 3E illustrate a pit pattern formed in the first transition region 15 when the BCA 10 is formed in a straight specific pattern and the lead-in area 20 is formed in a straight random pattern. An example is shown. As shown in FIG. 3A, the first transition region 15 is formed in a straight single pattern, or as shown in FIG. 3B, the first transition region 15 is formed in a straight random pattern, or illustrated in FIG. 3C. As described above, the first transition region 15 may be formed as a mirror region, or as illustrated in FIG. 3D, the first transition region 15 may be formed in a straight specific pattern. In addition, the pits of the first transition region 15 may be formed in a single wobbling pattern, a wobbling random pattern, or a wobbling specific pattern. 3E illustrates a case where the first transition region 15 is formed in a wobbling random pattern. Although not shown, the pits of the first transition region 15 may be formed in a single wobbling pattern, a wobbling random pattern, or a wobbling specific pattern.

 4A to 4E illustrate an example of a pit pattern formed in the first transition region 15 when the BCA 10 is formed in a straight random pattern and the lead-in area 20 is formed in a straight random pattern. It is shown. As shown in FIG. 4A, the first transition region 15 is formed in a straight single pattern, or as shown in FIG. 4B, the first transition region 15 is formed in a straight random pattern, or illustrated in FIG. 4C. As shown in FIG. 4D, the first transition region 15 may be formed as a mirror region, or as illustrated in FIG. 4D, the first transition region 15 may be formed in a straight specific pattern. In addition, the pits of the first transition region 15 may be formed in a single wobbling pattern, a wobbling random pattern, or a wobbling specific pattern. 4E illustrates a case where the first transition region 15 is formed in a wobbling random pattern. Although not shown, the BCA 10 may be formed of pits of a wobbling random pattern instead of pits of a straight random pattern.

As described above, when the BCA 10 is formed in a straight random pattern or a wobbling random pattern, information, for example, 00h or BCA, may be recorded.

In the above description, only the case where the BCA 10 is formed of a pit of a straight pattern has been described, but it may be formed of a pit of a wobbling pattern. For example, the BCA 10 may be formed in a wobbling single pattern, a wobbling specific pattern, or a wobbling random pattern.

On the other hand, the BCA 10 may be recorded as a pit of a straight pattern or a wobbling pattern, and the lead-in area 20 may be recorded as a pit of a wobbling pattern. A first transition region 15 is provided between the BCA 10 and the lead-in region 20, in which case the BCA 10, the first transition region 15 and the lead-in region 20 are provided. The pattern of the pit formed in the concretely described as follows.

5A to 5E illustrate examples of pit patterns formed in the first transition region 15 when the BCA 10 is formed in a straight single pattern and the lead-in region 20 is formed in a wobbling random pattern. It is shown. As illustrated in FIG. 5A, the first transition region 15 may be formed in a straight single pattern, or as illustrated in FIG. 5B, the first transition region 15 may be formed in a straight random pattern. In addition, as illustrated in FIG. 5C, the first transition region 15 may be formed as a mirror region, or as illustrated in FIG. 5D, the first transition region 15 may be formed in a straight specific pattern. In addition, the first transition region 15 may be formed of a single wobbling pattern, a wobbling specific pattern, or a wobbling random pattern. For example, as illustrated in FIG. 5E, the first transition region 15 may be formed as a pit of a wobbling random pattern. 5A to 5E illustrate the case in which the BCA 10 is formed in a straight single pattern, it may be formed in a wobbling single pattern.

6A to 6E illustrate examples of pit patterns formed in the first transition region 15 when the BCA 10 is formed in a straight specific pattern and the lead-in region 20 is formed in a wobbling random pattern. It is shown. As shown in FIG. 6A, the first transition region 15 is formed in a straight single pattern, or as shown in FIG. 6B, the first transition region 15 is formed in a straight random pattern, or in FIG. 6C. As illustrated, the first transition region 15 may be formed as a mirror region, or as illustrated in FIG. 6D, the first transition region 15 may be formed in a straight specific pattern. In addition, the first transition region 15 shown in the example illustrated in FIGS. 6A, 6B, and 6D may be formed by replacing a single wobbling pattern, a wobbling specific pattern, or a wobbling random pattern. For example, FIG. 6E illustrates a case where the first transition region 15 is formed of pits of a wobbling random pattern. Here, although the case in which the BCA 10 is formed in a straight specific pattern has been described, it may be formed in a wobbling specific pattern.

7A to 7E illustrate a pit pattern formed in the first transition region 15 when the BCA 10 is formed in a straight random pattern and the lead-in area 20 is formed in a wobbling random pattern. An example is shown. As shown in FIG. 7A, the first transition region 15 may be formed in a straight single pattern, or as shown in FIG. 7B, the first transition region 15 may be formed in a straight random pattern. In addition, as illustrated in FIG. 7C, the first transition region 15 may be formed as a mirror region, or as illustrated in FIG. 7D, the first transition region 15 may be formed as a straight specific pattern. In addition, the first transition region 15 shown in the example illustrated in FIGS. 7A, 7B, and 7D may be formed by replacing a single wobbling pattern, a wobbling specific pattern, or a wobbling random pattern. For example, the case where the first transition region 15 is formed of pits of a wobbling random pattern is illustrated in FIG. 7E. Here, although the case in which the BCA 10 is formed in a straight random pattern has been described, it may be formed in a wobbling random pattern. As described above, when the BCA 10 is formed in a straight random pattern or a wobbling random pattern, information, for example, 00h or BCA, may be recorded.

In addition, when the BCA 10, the first transition region 15, or the lead-in region 20 are formed as pits of a wobbling pattern, the amplitude of the wobble may be gradually increased or decreased. In particular, as shown in FIG. 7F, it is preferable that the amplitude of the wobble is gradually increased when the first transition region 15 is formed as a pit of the wobble pattern.

Meanwhile, the pitches of the tracks formed in the BCA 10, the first transition region 15, and the lead-in region 20 may be the same. Alternatively, the pitch of the tracks formed in the BCA 10, the first transition region 15, and the lead-in region 20 may be different. For example, the track pitches of the BCA 10 and the first transition region 15 are the same, and the track pitch of the lead-in region 20 may be different. In addition, the track pitches of the first transition region 15 and the lead-in region 20 may be the same, and the track pitches of the BCA 10 may be different. In addition, when the track pitches of the BCA 10 and the lead-in area 20 are different, the track pitch of the first transition area 15 may be gradually decreased or increased. In other words, when the track pitch in the BCA 10 is a, the track pitch in the lead-in area 20 is b, and a <b, the track pitch in the first transition region is from a to b. It is formed to increase gradually.

Next, the optical information storage medium according to the second embodiment of the present invention includes a BCA 10, a lead-in area 20, a user data area 30, and a lead-out area 40. The second transition region 25 is provided between the 20 and the data region 30.

 Hereinafter, the pattern of the pits formed in the lead-in area 20, the second transition area 25 and the lead-out area 30 will be described in detail.

First, when the lead-in area 20 is formed of a pit of a third straight pattern, and the data area 30 is formed of a pit of a fourth straight pattern, the second transition area 25 is a straight single pattern. It may be formed of a straight specific pattern, a straight random pattern, a wobbling single pattern, a wobbling specific pattern, a wobbling random pattern, or a mirror area.

The third and fourth straight patterns may be any one of a straight single pattern, a straight specific pattern, and a straight random pattern.

8A to 8F illustrate an example of a pit pattern formed in the second transition area 25 when the lead-in area 20 is formed in a straight random pattern and the data area 30 is formed in a straight random pattern. It is shown. As shown in FIG. 8A, the second transition region 25 may be formed in a straight single pattern, or as shown in FIG. 8B, the second transition region 25 may be formed in a straight random pattern. In addition, as illustrated in FIG. 8C, the second transition region 25 may be formed as a mirror region, or as illustrated in FIG. 8D, the second transition region 25 may be formed in a straight specific pattern. In addition, the pits of the second transition region 25 may be formed in a single wobbling pattern, a wobbling random pattern, or a wobbling specific pattern. For example, an example in which the second transition region 25 is formed in a wobbling random pattern is illustrated in FIG. 8E.

Here, when the second transition region 25 is formed in the wobbling pattern, it is preferable that the amplitude of the wobble is gradually reduced as shown in FIG. 8F.

Next, when the lead-in area 20 is formed of a pit of a wobbling pattern, and the data area 30 is formed of a pit of a straight pattern, between the lead-in area 20 and the data area 30. The case where the second transition region 25 is formed will be described.

The lead-in area 20 may be formed of a single wobbling pattern, a wobbling specific pattern, or a wobbling random pattern, and the data area 30 may form a straight single pattern, a straight specific pattern, or a straight random pattern. have.

9A to 9F illustrate a pit pattern formed in the second transition area 25 when the lead-in area 20 is formed in a wobbling random pattern and the data area 30 is formed in a straight random pattern. An example is shown. As shown in FIG. 9A, the second transition region 25 may be formed in a straight single pattern, or as shown in FIG. 9B, the second transition region 25 may be formed in a straight random pattern. In addition, as illustrated in FIG. 9C, the second transition region 25 may be formed as a mirror region, or as illustrated in FIG. 9D, the second transition region 25 may be formed as a straight specific pattern. In addition, the pits of the second transition region 25 may be formed in a single wobbling pattern, a wobbling random pattern, or a wobbling specific pattern. For example, an example in which the second transition region 25 is formed in a wobbling random pattern is illustrated in FIG. 9E.

In this case, when the second transition region 25 is formed in the wobbling pattern, it is preferable to gradually decrease the amplitude of the wobble as shown in FIG. 9F.

Next, when the lead-in area 20 is formed of a pit of a straight pattern, and the data area 30 is formed of a pit of a wobbling pattern, between the lead-in area 20 and the data area 30. The case where the second transition region 25 is formed will be described.

The lead-in area 20 may be formed as a straight single pattern, a straight specific pattern, or a straight random pattern, and the data area 30 may form a wobbling single pattern, a wobbling specific pattern, or a wobbling random pattern. have.

10A to 10F illustrate a pit pattern formed in the second transition region 25 when the lead-in area 20 is formed in a straight random pattern and the data area 30 is formed in a wobbling random pattern. An example is shown. As shown in FIG. 10A, the second transition region 25 may be formed in a straight single pattern, or as shown in FIG. 10B, the second transition region 25 may be formed in a straight random pattern. In addition, as illustrated in FIG. 10C, the second transition region 25 may be formed as a mirror region, or as illustrated in FIG. 10D, the second transition region 25 may be formed as a straight specific pattern. In addition, the pits of the second transition region 25 may be formed in a single wobbling pattern, a wobbling random pattern, or a wobbling specific pattern. For example, an example in which the second transition region 25 is formed in a wobbling random pattern is illustrated in FIG. 10E.

Here, when the third transition region 27 is formed in the wobbling pattern, it is preferable to increase the amplitude of the wobble as shown in FIG. 10F.

 In addition, when the lead-in area 20 and the data area 30 are formed of pits of a wobbling pattern, the second transition area 25 provided between the lead-in area 20 and the data area 30 is provided. The wobbling single pattern, the wobbling specific pattern, the wobbling random pattern, the straight single pattern, the straight specific pattern, the straight random pattern or the mirror area may be formed.

In addition, when the lead-in area 20, the second transition area 25, or the data area 30 are formed of pits of a wobbling pattern, the amplitude of the wobble may be gradually increased or decreased.

Meanwhile, the pitches of the tracks formed in the lead-in area 20, the second transition area 25, and the data area 30 may be the same. Alternatively, the pitches of the tracks formed in the lead-in area 20, the second transition area 25, and the data area 30 may be different. For example, the track pitches of the lead-in area 20 and the second transition area 25 are the same, and the track pitches of the data area 30 may be formed differently. In addition, the track pitches of the second transition area 25 and the data area 30 are the same, and the track pitches of the lead-in area 20 may be different. In addition, when the track pitches of the lead-in area 20 and the data area 30 are different, the track pitch of the second transition area 25 may be gradually decreased or increased. In other words, when the track pitch in the lead-in area 20 is c, the track pitch in the data area 30 is d, and c <d, the track pitch in the second transition area 25 is It is formed to increase gradually from c to d.

Next, the optical information storage medium according to the third embodiment of the present invention is divided into a plurality of regions, at least one of the plurality of regions is divided into a plurality of small regions according to a function, and a third transition between the plurality of small regions. An area is provided. As shown in FIG. 11, the optical information storage medium according to the present invention includes, for example, a BCA 10, a lead-in area 20, a user data area 30, and a lead-out area 40. The lead-in area 20 includes the first area 20a and the second area 20b.

Transition regions may be provided between the BCA 10 and the lead-in area 20 and between the lead-in area 20 and the data area 30. For these transition areas, in the first and second embodiments, The same may be applied as described.

Meanwhile, a third transition region is provided between the first region 20a and the second region 20b of the lead-in region 20. The pattern of the pits formed in the first region 20a, the second region 20b, and the third transition region will be described in detail.

The first and second regions 20a may be formed of pits of a straight pattern or a wobbling pattern. The straight pattern may be a straight single pattern, a straight specific pattern, or a straight random pattern. The wobbling pattern may be a wobbling single pattern, a wobbling specific pattern, or a wobbling random pattern.

For example, when the first region 20a is formed of a pit of a straight pattern, and the second region 20b is formed of a pit of a wobbling pattern, the first region 20a and the second region ( A case where the third transition region 27 is formed between 20b) will be described.

12A to 12F illustrate a pit pattern formed in the third transition region 27 when the first region 20a is formed in a straight random pattern and the second region 20b is formed in a wobbling random pattern. An example is shown. As shown in FIG. 12A, the third transition region 27 may be formed in a straight single pattern, or as shown in FIG. 12B, the third transition region 27 may be formed in a straight random pattern. In addition, as illustrated in FIG. 12C, the third transition region 27 may be formed as a mirror region, or as illustrated in FIG. 12D, the third transition region 27 may be formed as a straight specific pattern. In addition, the pits of the third transition region 27 may be formed in a single wobbling pattern, a wobbling random pattern, or a wobbling specific pattern. For example, an example in which the third transition region 27 is formed in a wobbling random pattern is illustrated in FIG. 12E. Here, it is preferable that the amplitude of the wobble is gradually increased or decreased when the third transition region 27 is formed in the wobble pattern. For example, when the third transition region 27 is formed in the wobbling random pattern, it is preferable to increase the amplitude of the wobble as shown in FIG. 12F.

 In addition, when the first region 20a is formed of a pit of a wobbling pattern, and the second region 20b is formed of a pit of a straight pattern, the first region 20a and the second region 20b are formed. The third transition region 27 provided therebetween may be formed of a wobbling single pattern, a wobbling specific pattern, a wobbling random pattern, a straight single pattern, a straight specific pattern, a straight random pattern, or a mirror region.

In addition, when the first region 20a is formed of a pit of a straight pattern, and the second region 20b is formed of a pit of a straight pattern, between the first region 20a and the second region 20b. The provided third transition region 27 may be formed of a single wobbling pattern, a wobbling specific pattern, a wobbling random pattern, a straight single pattern, a straight specific pattern, a straight random pattern, or a mirror region.

In addition, when the first region 20a and the second region 20b are formed as pits of a wobbling pattern, a third transition region provided between the first region 20a and the second region 20b ( 27) may be formed of a wobbling single pattern, a wobbling specific pattern, a wobbling random pattern, a straight single pattern, a straight specific pattern, a straight random pattern, or a mirror area.

Furthermore, when the first region 20a, the third transition region 27, or the second region 20b is formed as a pit of a wobbling pattern, the amplitude of the wobble may be gradually increased or decreased.

In the above, the case where the lead-in area 20 is divided into two areas has been described. However, when the BCA 10, the data area 30, or the lead-out area 40 are divided into a plurality of areas, the boundary of each area is described. Transition regions may be formed.

Meanwhile, the pitches of the tracks formed in the first region 20a, the third transition region 27, and the second region 20b may be the same. Alternatively, the pitches of the tracks formed in the first region 20a, the third transition region 27, and the second region 20b may be different. For example, the track pitches of the first region 20a and the third transition region 27 are the same, and the track pitch of the second region 20b is smaller than the track pitch of the first region 20a. Can be. In addition, the track pitches of the third transition region 27 and the second region 20b may be the same, and the track pitches of the first region 20a may be different. In addition, when the track pitches of the first region 20a and the second region 20b are different, the track pitch of the third transition region 27 may be gradually decreased or increased. In other words, when the track pitch in the first region 20a is e, the track pitch in the second region 20b is f and e <f, the track pitch in the third transition region 27 is Is formed to increase gradually from e to f.

As described above, the optical information storage medium according to the present invention includes a plurality of regions, and includes at least one transition region between the plurality of regions. For example, a boundary area between the BCA 10 and the lead-in area 20, a boundary area between the lead-in area 20 and the data area 30, and the first area 20a and the second area 20b. At least one region of the boundary region of () is provided with a transition region. In addition, the pit pattern of the transition region may be the same as the pit pattern of the region in front of the transition region or the pit pattern behind the transition region. Here, the area in front of the transition area means an area that is inside the transition area based on the radial direction of the storage medium. In addition, the region behind the transition region means an region outside the transition region with respect to the radial direction of the storage medium.

Meanwhile, the present invention can be applied to not only a single storage medium but also a multi-layered storage medium.

1 shows the physical structure of a read-only optical information storage medium.

2A to 2E illustrate the BCA and the lead-in area when the pit of the BCA is formed in a single pattern and the pit of the lead-in area is formed in a straight random pattern in the optical information storage medium according to the first embodiment of the present invention. The pit pattern of the transition area provided is shown.

3A to 3E illustrate the BCA and the lead-in area when the pit of the BCA is formed in a specific pattern and the pit of the lead-in area is formed in a straight random pattern in the optical information storage medium according to the first embodiment of the present invention. The pit pattern of the transition area provided is shown.

4A to 4E illustrate a gap between the BCA and the lead-in area when the pit of the BCA is formed in a random pattern and the pits of the lead-in area are formed in a straight random pattern in the optical information storage medium according to the first embodiment of the present invention. The pit pattern of the transition area provided is shown.

5A to 5E illustrate the BCA and the lead-in area when the pit of the BCA is formed in a single pattern and the pit of the lead-in area is formed in the wobbling random pattern in the optical information storage medium according to the first embodiment of the present invention. The pit pattern of the transition region provided in FIG.

6A to 6E illustrate the BCA and the lead-in area when the pit of the BCA is formed in a specific pattern and the pit of the lead-in area is formed in the wobbling random pattern in the optical information storage medium according to the first embodiment of the present invention. The pit pattern of the transition area provided between them is shown.

7A to 7F illustrate a gap between the BCA and the lead-in area when the pit of the BCA is formed in a random pattern and the pits of the lead-in area are formed in the wobbling random pattern in the optical information storage medium according to the first embodiment of the present invention. The pit pattern of the transition region provided in FIG.

8A to 8F illustrate a lead-in area when the pits of the lead-in area are formed in a straight random pattern and the pits of the user data area are formed in a straight random pattern in the optical information storage medium according to the second embodiment of the present invention. The pit pattern of the transition area provided between the user data areas is shown.

9A to 9F illustrate a lead-in area when the pits of the lead-in area are formed in a wobbling random pattern and the pits of the user data area are formed in a straight random pattern in the optical information storage medium according to the second embodiment of the present invention. And a pit pattern of the transition area provided between the and user data areas.

 10A to 10F illustrate a lead-in area when the pits of the lead-in area are formed in a straight random pattern and the pits of the user data area are formed in the wobbling random pattern in the optical information storage medium according to the second embodiment of the present invention. And a pit pattern of the transition area provided between the and user data areas.

11 shows the physical structure of an optical information storage medium according to a third embodiment of the present invention.

12A to 12F illustrate a case in which the pits of the lead-in first region are formed in a random pattern and the pits of the lead-in second region are formed in a wobbling random pattern in the optical information storage medium according to the third embodiment of the present invention. The pit pattern of the transition region provided between the BCA and the lead-in region is shown.

<Description of the symbols for the main parts of the drawings>

10 ... BCA, 15,25,27 ... transition area

20 ... Lead-in area, 30 ... User data area

40 ... Leadout area

Claims (10)

delete delete delete delete delete delete A lead-in area, a user data area, and a lead-out area provided with a BCA, a first area having a first track pitch, and a first area having a disk-related information recorded thereon, and a second area having a second track pitch smaller than the first track pitch. And a first transition region is provided between the first region and the second region and a second transition region is provided between the BCA and the lead-in region. And recording information in at least one of the second area, the user data area, and the lead-out area of the lead-in area. delete The method of claim 7, wherein And the track pitch of the user data area is the second track pitch. The method according to claim 7 or 9, And the track pitch of the lead-out area is the second track pitch.

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