JPH0628776A - Sychronous method in optical recording and reproducing device and its optical recording medium - Google Patents

Abstract

PURPOSE:To eliminate difference in a servo characteristic due to the difference in a reference pattern and to obtain a method without having redundancy in rotational synchronism information and with high resistance for a damage in an optical disk. CONSTITUTION:In a synchronous method in an optical recording and reproducing device and its optical recording medium, a set of unique information and segment number information are stored and formed at every sector 2 on the disk 1, and the position of the unique information in a track is specified. The unique information is stored and formed by the form of the access code 31 of a servo area 3 incorporated in a prescribed segment 5, and the segment number information is stored and formed by the form of 1 out of 4X2 similarly. In the access codes 31 except it, a track address LSB is stored and formed in proportion to one at every other two segments 5, a track address 3SB to one at every other four segments 5, a track address 2SB to one at every other eight segements 5 and, a track address MSB to one at every other 16 segments 5.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical storage device, and more particularly to a method of synchronizing a storage device using an optical disk and its optical storage medium.

[0002]

2. Description of the Related Art For example, a method of synchronizing an optical storage device and an optical storage medium thereof are known, as disclosed in Japanese Patent Laid-Open No. 3-130929. FIG. 7 is a diagram illustrating a conventional method of synchronizing an optical storage device and a format of the optical storage medium. The optical storage medium used here is an optical disc 1 such as a write-once optical disc or a magneto-optical disc. The optical disc 1 is rotationally driven by a spindle motor or the like at a constant angular velocity (CAV), and data is recorded / reproduced on a storage track concentrically provided on the optical disc 1. A sample servo method or a discrete block method is used as a clock synchronization method at the time of storing and reproducing data.

In FIG. 7, one track of the optical disc 1 is composed of sectors 2 _i which are n recording units of data, and one sector is composed of m segments 5 _j .
Further, one segment is composed of a servo area 3 and a data area 4. In the servo area 3, as shown in FIG.
A clock pit 30 for clock synchronization, a wobble bit 32 for obtaining a tracking error signal,
An access code 31 composed of pits 31a to 31d for recording a track address (track number) is provided in advance when the disc is formed. Data is recorded / reproduced in the data area 4.

The access code 31 of the servo area 3 has a capacity for storing 4-bit information. Here, each bit of the track address is set to B ₀ , B ₁ ,
And B ₂ · · ·, pits 31a of the access code 31 by dividing the track address, to take into 31b. Here, the lower 2 bits B ₁ of the track address,
B ₀ (hereinafter, represented as (1, 0) as shown in FIG. 7)
Is stored in each servo area in one track by using the lower 2 bits of the access code 31. Further, using the upper 2 bits of the access code 31 as the track address bits (3, 2), the track address bits (1,
The recording is performed at a cycle twice as long as that in 0). Further, using the upper 2 bits of the access code 31 as the track address bits (5, 4), the track address bits (3,
Recording is performed with a cycle twice as long as in 2). Hereinafter, similarly, recording is continuously performed up to the most significant bit of the track address. As a result, the lower side of the track address is recorded more times than the upper side.

FIG. 8 is a diagram for explaining storage formation of reference position information on a track. Since the reference position information on the track is recorded and formed, the reference position information on the track is inserted by using the synchronization pattern 10. Here, the reference position information is information serving as a reference for defining the position of the segment in the same track. Specifically, as shown in FIG. 8, eight types of reference patterns P _{0 to} P ₈ having different patterns are provided as the synchronization pattern 10, and, for example, the reference pattern P ₁ is provided in the servo area 3 at the head of the track.
, P ₀ is previously recorded and formed in all other servo areas 3,
The beginning of the track can be identified.

Further, as a recording method of the reference position information,
In addition to the above, the reference pattern P ₁ at the beginning of the servo area 3 of the first sector is the leading sector of the track, in the remaining sectors, the reference pattern P ₂ at the beginning of the servo area 3 of the third sector, Servo area 3 at the beginning of the fifth sector
There is a method of recording and forming different reference patterns for each of a plurality of sectors in advance, such as recording and forming the reference pattern P ₃ in the above. By adopting this method, when the reference pattern of the head sector of the track cannot be read due to a defect of the disk, the sector information can be obtained by identifying the reference patterns of other sectors.

In addition to the above-described optical storage device synchronization method and the configuration of the optical storage medium, a segment provided with an access code containing segment information and a segment provided with an access code not containing segment information Mark information for distinguishing between is added to the servo area 3,
There is also known an optical storage device synchronization method and an optical storage medium for extracting the segment information based on the mark information and performing rotation synchronization control.

[0008]

Since the conventional method of synchronizing the optical storage device and the optical storage medium thereof are configured as described above, the method of using a plurality of reference patterns and the optical storage. In the medium, the servo characteristics differ due to the difference in the reference pattern. Further, in the method of using the mark information and the optical storage medium, there is a problem in that the redundancy of the synchronization information increases due to the use of the mark information. The present invention has been made in view of the above problems, and provides a synchronization method for an optical storage device that uses one reference pattern, eliminates the difference in servo characteristics, and further reduces redundancy of synchronization information. It is an object to provide the optical storage medium.

[0009]

In order to achieve the above object, in a method of synchronizing an optical storage device and an optical storage medium thereof according to the present invention, a storage area portion for dividing a storage area of the optical storage medium is provided. A synchronization information storage area is provided for each, unique code information is stored as information stored in a certain synchronization information storage area, and position information of a storage area portion storing the unique code information is stored in another synchronization information storage area. The position of each storage area part is defined based on the stored unique code information and the position information of the storage area part storing the unique code information.

Further, a synchronization information storage area is provided in each of the storage area portions that divide the storage area of the optical storage medium,
Unique code information is stored and formed as information stored in a certain synchronization information storage area, and position information of a storage area portion storing the unique code information is stored and formed in another synchronization information storage area. . Further, a synchronization information storage area is provided in each of the storage area portions that divide the storage area of the optical storage medium, the area is divided into two, and the information is stored in the synchronization information storage area.
Unique code information represented as one exception of the divided synchronization information is stored, and position information of a storage area portion storing the certain unique code information is stored in another synchronization information storage area, and the unique code is stored. It is characterized in that the position of each storage area portion is defined based on the information and the position information of the storage area portion that stores the unique code information.

Further, a synchronization information storage area is provided in each of the storage area portions dividing the storage area of the optical storage medium,
The area is divided into two and used, and as the information stored in the synchronization information storage area, unique code information represented as an exception to both of the divided synchronization information is stored, and the unique code information is stored. The position information of the storage area portion is stored in another synchronization information storage area, and the position of each storage area portion is defined based on the unique code information and the position information of the storage area portion that stores the unique code information. It is characterized by

Further, in particular, a code (1 out of 5) represented as an exception to a 5-bit alternating code in the unique code.
Is used. In addition, in particular, a code (2 out of 9) represented as an exception to a 9-bit alternating code is used for the unique code. Further, in particular, it is characterized in that 1 out of 5 is stored in the unique code. Further, in particular, it is characterized in that 2 out of 9 is stored as a unique code.

[0013]

By storing unique code information in the information stored in one of the synchronization information storage areas, and by storing position information of a storage area portion storing the unique code information in another synchronization information storage area, The position in the track of the synchronization information storage area including the unique code is defined. Further, the position of each storage area portion in the track is defined in relation to the position of the synchronization information storage area including the unique code in the track.
Further, by using the unique code, the reference pattern is made one type, the difference in the servo characteristics caused by the difference in the reference pattern is eliminated, the area for storing the synchronization information is reduced, and the redundancy of the synchronization information is reduced. .

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the method of synchronizing an optical storage device and the optical storage medium of the present invention will be described below. FIG. 1 is a diagram for explaining a disc format of an optical storage medium of this embodiment, for example, an optical disc. In FIG. 1, the optical disc 1 is an optical disc such as a write-once optical disc or a magneto-optical disc. This optical disc 1
In the same manner as described in the conventional example, the data is recorded / reproduced on the storage tracks concentrically provided on the optical disc 1 by being rotationally driven by a spindle motor or the like at a constant angular velocity (CAV). ing. A sample servo method or a discrete block method is used as a clock synchronization method at the time of storing and reproducing data.

The sector 2 _i is a sector which equally divides a plurality of tracks 6 _k arranged concentrically on the optical disk 1 into n parts. In this embodiment, the track 6 _k is 1
It is assumed to be divided into 6 (n = 16) sectors 2 _i . The servo area 3 is a storage area included in each segment 5 _j and placed in front of the data area 4 in the rotation direction of the optical disc 1. Each servo area 3 includes a synchronization pattern 10 and an access code 31, and information for clock synchronization, tracking error detection, and rotation synchronization of the optical disc 1 is stored therein. The data area 4 is an area where data is stored / reproduced. The segment 5 _j is a unit storage area (segment) that further divides the sector 2 _i into m parts. Each segment 5
_j is composed of a servo area 3 and a data area 4, respectively. In this embodiment, each sector 2 has 64 (m = 64)
It is assumed that it is divided into segments 5 of. That is,
Each track 6 _k is assumed to be composed of 1024 segments 5. The sector 2 _i and the segment 5 _j define the position of the optical disc 1 in the rotation direction. The tracks 6 _k are tracks arranged concentrically on the optical disc 1. The track 6 _k defines the radial position of the optical disc 1.

FIG. 2 is an enlarged view of the servo area 3. In FIG. 2, the synchronization pattern 10 is composed of a clock pit 30 and a pair of wobble bits 32a and 32b, and stores information for clock synchronization of the optical disc 1 and detection of a tracking error. The clock pit 30 is a pit which is arranged on the center line of the track shown in the figure and is for synchronizing the clock of the optical disc 1. The access code 31 is composed of pits 31a to 31i, and stores and stores information for synchronizing the rotation of the optical disc 1. The wobble bits 32a and 32b are before and after the clock pit 30,
It is placed at a position in contact with the center line of the track shown in the figure,
It is a pit for detecting a tracking error of the optical disc 1. The guard bands 33a and 33b are arranged on both sides of the data storage portion 40 and are guard bands for detecting tracking errors. The data storage portion 40 is a pit string in which data is stored / reproduced.

The operation will be described below. FIG. 3 is a diagram showing information stored in the access code 31 of the servo area 3 included in each segment 5 _j on the track 6 _k . Note that, in FIG. 3, the sectors are actually widely expressed for the sake of explanation. Here, in the present embodiment, the track address is represented by 16 bits (1 out of 4 × 2 × 4). In FIG. 3, the track address L
SB50 is 1 out of 4x2 format with pit 31
The pits are stored in a to 31d and 31f to 31i and represent bits 3 to 0 of 16-bit information indicating a track address. Here, the relationship between each bit of the track address LSB 50 and the pits 31a to 31i is as shown in FIG. In the figure, this relationship is expressed as (3, 2, 1, 0). This relationship and expression are common to the track address 3SB51, the track address 2SB52, and the track address MSB53. It is assumed that the track address LSB 50 exists every other segment, that is, one in two segments.

The track address 3SB51 is bit 7 to bit 4 of 16-bit information representing the track address.
It is a pit that represents. In the figure, (7, 6, 5,
It is expressed as 4). Track address 3SB51
Is present every 3 segments, that is, one in every 4 segments. Track address 2SB52 is
Bit 11 of 16-bit information that represents the track address
~ A pit representing bit 8. In the figure, (b,
a, 9, 8). Track address 2S
B52 is every 7 segments, that is, 1 every 8 segments
Shall exist. Track address MSB53
Are pits representing bits 15 to 12 of 16-bit information representing a track address. In the figure,
It is expressed as (f, e, d, e). It is assumed that the track address MSB53 exists every 15 segments, that is, one in 16 segments. In order to store and form the above-mentioned information indicating the track address, the pit 31a
~ 31d and 31f to 31i are used, and the pit 31
e is not used and there is no pit itself (only the interval is 1
The pit is open).

The unique information 54 includes pits 31a-31.
This information is stored on i and is paired with the segment number information 55 to indicate the position of the segment 5 _j that includes the unique information 54 in the servo area 3. This corresponds to the reference pattern in the conventional example. The segment number information 55 includes pits 31a to 31d and 31f to 3f.
This is information indicating the order on the track 6 _k of the segment 5 _j stored and formed on the 1 _i and including the unique information 54. As described above, in order to express the unique information 54 and the segment number information 55, the pits 31a ...
31i or pits 31a to 31d, 31f to 31
i is used. It is assumed that the pits that are not used here do not exist, like the pits indicating the track address described above. The unique information 54 and the segment number information 55 are every 63 segments, that is,
It is assumed that there is one in 64 segments. The configuration of each information described above is the same for the portion of the optical disc 1 not shown in FIG.

FIG. 4 is a diagram showing a gray code (alternating code) represented by 9 bits. In FIG. 4, track address LSB50, track address 3SB51,
Track address 2SB52, track address MSB
53 and the segment number information 55 is shown in FIG.
The codes shown in (1 out of 4 × 2, 1 out of 4 × 2) are used. Also, unique information 5
4 is an exception to the gray code shown in FIG. 4A, that is, the code (1 out of 5, 1 out of 5) in FIG. 4B is used. Representing each of the above signals by a gray code enables highly reliable detection. This code does not exist in each of the above pit arrays that represent the track address and the pit string that represents the segment number information 55. Therefore, the unique information 54 is not confused with the pit string of the access code 31 representing other information.

FIG. 5 summarizes the number of each of the above-mentioned information items existing in the servo area 3 of each segment 5 per track. In FIG. 5, the track address LSB
Since 50 exists in two segments, 512 exist in one track. Track address 3SB5
Since one exists in four segments, there are 256 per track. Track address 2SB52
Since there is one in every 8 segments, there are 128 per track. Track address MSB53
Since there is one in 16 segments, there are 64 per track.

The reason for setting the number of each piece of information per track as described above is that the lower bits of the track address, the more access is required when searching for a track on the optical disk 1. That is, the higher the bit, the wider the width of the continuous track (the length in the radial direction of the optical disc 1) that is used at the beginning of the search on the optical disc 1 and that can be searched with the same information. Therefore, once a search can be performed within a certain range, basically no determination is required thereafter. On the other hand, since it is necessary to finally determine each adjacent track, the track address LSB 50 needs to be determined to the end.

There are 64 remaining servo areas 3 used for the above information. Half of these, 32, are not used as spares. 16 of the remaining 32 servo areas 3
The unique information 54 is stored and formed in each piece, and the segment number information 55 is stored and formed in the remaining 16 pieces. That is, the unique information 54 and the segment number information 55 are 1
There is one in the sector. Here, it is assumed that the unique information 54 is placed in the head segment 5 ₀ of each sector 2 and the segment number information 55 is placed in the 32nd segment 5 ₃₁ . The 1-out-of-5 code is stored and formed in the unique information 54, and the segment number information 55 includes the number (0 to 15) of the sector 2 in which each segment number information 55 exists.
Is formed in memory. Since there are 16 sectors 2 in one track, they can be represented by the code shown in FIG.

[0024] With above-described configuration, it is possible to indicate the leading segment 5 ₀ of each sector 2 on each track 6 _k. Also, in order from the head segments 5 ₀ of each sector, it is possible to identify the location of all segments 5 of each track 6 _k. Also, since 16 unique information 54 and 16 segment number information 55 exist in one track, the position of the segment on the track can be specified even if a failure occurs due to slight damage on the optical disc 1. By not being able to do so, the situation in which the entire truck becomes unusable rarely occurs.

FIG. 6 is a flow chart for searching a target segment on the optical disk 1 by the synchronizing method of the optical storage device of this embodiment. In FIG. 6, in step 00 (S00), the track 6 _k on which the target segment 5 exists on the optical disc 1 is searched. In step 01 (S01), detects the unique information 54 on the track 6 _k. In step 02 (S02), the segment number information 55 corresponding to the unique information 54 is detected. This segment number information 55
_Corresponds to the sector 2 number on the track 6 _k . In step 03 (S03), it is determined based on the segment number information 55 whether the target sector has been searched. When the search is performed, the process proceeds to S04. If no search has been performed, the process proceeds to S01. Step 04
In (S04), the position of the unique information 54,
The target segment 5 is searched from the relationship of the target segment 5. Thus, the search for the target segment 5 is completed.

The second embodiment will be described below. Here, the 2 out of 9 code shown in FIG. 4C is used in place of the 1 out of 5 code used for the unique information 54 in the first embodiment. Even with this configuration, it is possible to obtain the same method of synchronizing the optical storage device and the optical storage medium as in the first embodiment.

In addition to the embodiments described above, the method of synchronizing the optical storage device and the optical storage medium of the present invention can have various configurations. Further, the above-described embodiments are examples. In particular, in a similar configuration, 1 out of 4 above
In addition to the codes, the application to 1 out of 3 codes is also possible.

[0028]

As described above, according to the method of synchronizing the optical storage device and the optical storage medium of the present invention, the reference pattern is set to 1 by using the unique code.
It is possible to obtain the method of synchronizing the optical storage device and the optical storage medium thereof, which can be of different types, have no difference in the servo characteristics caused by the difference in the reference pattern, and have little redundancy of the synchronization information. Further, since there are many pieces of segment position information for each track, there is an accompanying effect that the method of synchronizing the optical storage device and the optical storage medium thereof, which is resistant to damage of the optical disc, can be obtained.

[Brief description of drawings]

FIG. 1 is a diagram illustrating a disc format of an optical storage medium (optical disc) of the present invention.

FIG. 2 is an enlarged view showing a servo area of the present invention.

FIG. 3 is a diagram showing information stored and formed in an access code of a servo area included in each segment on a track of the present invention.

FIG. 4 is a diagram showing a gray code (alternating code) represented by 9 bits.

FIG. 5 is a summary of the number of pieces of information existing in the servo area of each segment per track of the present invention.

FIG. 6 is a flowchart illustrating a segment search in the synchronization method for the optical storage device of the present invention.

FIG. 7 is a diagram illustrating a disc format of a conventional optical storage medium (optical disc).

FIG. 8 is a diagram illustrating a synchronization pattern of a conventional optical storage medium.

[Explanation of symbols]

 1 ... Optical disc 2 ... Sector 3 ... Servo area 4 ... Data area 5 ... Segment 6 ... Track 10 ... Synchronization pattern 30 ... Clock pit 31 ... Access code 32 ... Wolble bit 33 ... Guard band 40 ... Data storage portion 50 ... Track address LSB 51 ... Track address 3SB 52 ... Track address 2SB 53 ... Track address MSB 54 ... ..Unique information 55 ... Segment number information

[Procedure amendment]

[Submission date] February 16, 1993

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

Title: Method of synchronizing optical recording / reproducing apparatus and optical recording medium thereof

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to an optical recording / reproducing apparatus,
In particular, the present invention relates to a method of synchronizing a recording / reproducing apparatus using an optical disk and its optical recording medium.

[0002]

2. Description of the Related Art For example, a method of synchronizing an optical recording / reproducing apparatus and an optical recording medium thereof are known as disclosed in Japanese Patent Laid-Open No. 3-130929. FIG. 7 is a diagram illustrating a synchronization method of a conventional optical recording / reproducing apparatus and a format of the optical recording medium. The optical recording medium used here is, for example, an optical disc 1 such as a write-once optical disc or a magneto-optical disc. The optical disc 1 is rotationally driven by a spindle motor or the like at a constant angular velocity (CAV), and data is recorded / reproduced on a storage track concentrically provided on the optical disc 1. Also, as a clock synchronization method when recording and reproducing data,
A sample servo method or a discrete block method is used.

In FIG. 7, one track of the optical disc 1 is composed of sectors 2 _i which are n recording units of data, and one sector is composed of m segments 5 _j .
Further, one segment is composed of a servo area 3 and a data area 4. In the servo area 3, as shown in FIG.
A clock pit 30 for clock synchronization, a wobble bit 32 for obtaining a tracking error signal,
An access code 31 composed of pits 31a to 31d for storing a track address (track number) is provided in advance when the disc is formed. Data is recorded / reproduced in the data area 4.

The access code 31 of the servo area 3 has a capacity for storing 4-bit information. Here, each bit of the track address is set to B ₀ , B ₁ ,
And B ₂ · · ·, pits 31a of the access code 31 by dividing the track address, to take into 31b. Here, the lower 2 bits B ₁ of the track address,
B ₀ (hereinafter, represented as (1, 0) as shown in FIG. 7)
Is stored in each servo area in one track by using the lower 2 bits of the access code 31. Further, using the upper 2 bits of the access code 31 as the track address bits (3, 2), the track address bits (1,
The memory is formed with a cycle twice as long as that of 0). Further, using the upper 2 bits of the access code 31 as the track address bits (5, 4), the track address bits (3,
The memory is formed in a cycle twice as long as in 2). Hereinafter, similarly, memory formation is continuously performed up to the most significant bit of the track address. As a result, the lower side of the track address is recorded more times than the upper side.

FIG. 8 is a diagram for explaining storage formation of reference position information on a track. Since the reference position information on the track is stored and formed, the reference position information on the track is inserted by using the synchronization pattern 10. Here, the reference position information is information serving as a reference for defining the position of the segment in the same track. Specifically, as shown in FIG. 8, eight types of reference patterns P _{0 to} P ₈ having different patterns are provided as the synchronization pattern 10, and, for example, the reference pattern P ₁ is provided in the servo area 3 at the head of the track.
, P ₀ is stored in advance in all other servo areas 3,
The beginning of the track can be identified.

Further, as a method of storing the reference position information,
In addition to the above, the reference pattern P ₁ at the beginning of the servo area 3 of the first sector is the leading sector of the track, in the remaining sectors, the reference pattern P ₂ at the beginning of the servo area 3 of the third sector, Servo area 3 at the beginning of the fifth sector
There is a method of previously storing and forming a different reference pattern for each of a plurality of sectors, such as storing and forming the reference pattern P ₃ in the above. By adopting this method, when the reference pattern of the head sector of the track cannot be read due to a defect of the disk, the sector information can be obtained by identifying the reference patterns of other sectors.

In addition to the above-described method of synchronizing the optical recording / reproducing apparatus and the configuration of the optical recording medium, a segment provided with an access code containing segment information and a segment provided with an access code not containing segment information There is also known a synchronization method of an optical recording / reproducing apparatus and its optical recording medium, in which mark information for distinguishing between and is added to the servo area 3, segment information is extracted based on this mark information, and rotation synchronization control is performed. .

[0008]

Since the conventional method of synchronizing the optical recording / reproducing apparatus and the optical recording medium thereof are configured as described above, the method of using a plurality of reference patterns and the optical method. In the recording medium, the servo characteristics differ due to the difference in the reference pattern.
Further, the method of using the mark information and the optical recording medium have a problem that the redundancy of the synchronization information increases due to the use of the mark information. The present invention has been made in view of such a problem, and has one reference pattern, eliminates the difference in servo characteristics, and further reduces the redundancy of synchronization information. And an optical recording medium therefor.

[0009]

In order to achieve the above object, in the method of synchronizing an optical recording / reproducing apparatus of the present invention and the optical recording medium thereof, a storage area provided in advance in the optical recording medium is divided. A synchronization information storage area is provided in each of the storage area portions to be stored, unique code information is stored as information stored in the certain synchronization information storage area, and the position information of the storage area portion storing the unique code information is stored in the other storage area portion. The position of each storage area part is defined based on the unique code information and the position information of the storage area part storing the unique code information, which is stored in the synchronization information storage area.

Further, a synchronization information storage area is provided in each of the storage area portions that divide the storage area provided in advance on the optical recording medium, and unique code information is stored as information stored in a certain synchronization information storage area. However, the position information of the storage area portion for storing the unique code information is stored and formed in another synchronization information storage area. In addition, a synchronization information storage area is provided in each of the storage area portions that divide the storage area provided in advance in the optical recording medium, and the area is divided into two and used as the information stored in the synchronization information storage area. Storing unique code information represented as one exception of the divided synchronization information, and storing position information of a storage area portion storing the certain unique code information in another synchronization information storage area, The position of each of the storage area portions is defined based on the code information and the position information of the storage area portion that stores the unique code information.

Further, a synchronization information storage area is provided in each of the storage area portions that divide the storage area provided in advance on the optical recording medium, and the area is divided into two and used for storage in the synchronization information storage area. As the information, the unique code information represented as an exception to both of the divided synchronization information is stored, the position information of the storage area portion that stores the unique code information is stored in another synchronization information storage area, The position of each storage area portion is defined based on the unique code information and the position information of the storage area portion storing the unique code information.

[0012]

By storing unique code information in the information stored in one of the synchronization information storage areas, and by storing position information of a storage area portion storing the unique code information in another synchronization information storage area, The position in the track of the synchronization information storage area including the unique code is defined. Further, the position of each storage area portion in the track is defined in relation to the position of the synchronization information storage area including the unique code in the track.
Further, by using the unique code, the reference pattern is made one type, the difference in the servo characteristics caused by the difference in the reference pattern is eliminated, the area for storing the synchronization information is reduced, and the redundancy of the synchronization information is reduced. .

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of a method of synchronizing an optical recording / reproducing apparatus and an optical recording medium thereof according to the present invention will be described below. FIG. 1 is a diagram for explaining the disc format of an optical recording medium of the present embodiment, for example, an optical disc. In FIG. 1, the optical disc 1 is, for example, a write-once optical disc,
An optical disc such as a magneto-optical disc. This optical disc 1 is rotationally driven at a constant angular velocity (CAV) by a spindle motor or the like as described in the conventional example, and data is recorded / reproduced on a storage track spirally or concentrically provided on the optical disc 1. It is supposed to be done.
A sample servo method or a discrete block method is used as a clock synchronization method at the time of recording / reproducing data.

The sector 2 _i is a sector which divides a plurality of tracks 6 _k arranged on the optical disk 1 in a spiral or concentric circles into n parts. In this embodiment,
It is assumed that the track 6 _k is divided into 16 (n = 16) sectors 2 _i . Servo area 3 is each segment 5
It is a storage area included in _j and placed in front of the data area 4 in the rotation direction of the optical disc 1. Each servo area 3 includes a synchronization pattern 10 and an access code 31, and information for clock synchronization, tracking error detection, and rotation synchronization of the optical disc 1 is stored therein. The data area 4 is an area where data is stored / reproduced. The segment 5 _{j further} includes the above sector 2 _i by m
It is a unit recording / reproducing area (segment) that is equally divided into individual parts. Each segment 5 _j is composed of a servo area 3 and a data area 4, respectively. In this embodiment, each sector 2
Are divided into 64 (m = 64) segments 5. That is, each track 6 _k is assumed to be composed of 1024 segments 5. The sector 2 _i and the segment 5 _j define the position of the optical disc 1 in the rotation direction. The tracks 6 _k are tracks arranged concentrically on the optical disc 1. The track 6 _k defines the radial position of the optical disc 1.

FIG. 2 is an enlarged view of the servo area 3. In FIG. 2, the synchronization pattern 10 is composed of a clock pit 30 and a pair of wobble bits 32a and 32b, and stores information for clock synchronization of the optical disc 1 and detection of a tracking error. The clock pit 30 is a pit which is arranged on the center line of the track shown in the figure and is for synchronizing the clock of the optical disc 1. The access code 31 is composed of pits 31a to 31i, and stores and stores information for synchronizing the rotation of the optical disc 1. The wobble bits 32a and 32b are before and after the clock pit 30,
It is placed at a position in contact with the center line of the track shown in the figure,
It is a pit for detecting a tracking error of the optical disc 1. The guard bands 33a and 33b are arranged on both sides of the data recording portion 40 and are guard bands that eliminate the influence from adjacent tracks. The data storage portion 40 is a pit string in which data is stored / reproduced.

The operation will be described below. FIG. 3 is a diagram showing information stored in the access code 31 of the servo area 3 included in each segment 5 _j on the track 6 _k . Note that, in FIG. 3, the sectors are actually widely expressed for the sake of explanation. Here, in the present embodiment, the track address is represented by 16 bits (1 out of 4 × 2 × 4). In FIG. 3, the track address L
SB50 is 1 out of 4x2 format with pit 31
The pits are stored in a to 31d and 31f to 31i and represent bits 3 to 0 of 16-bit information indicating a track address. Here, the relationship between each bit of the track address LSB 50 and the pits 31a to 31i is as shown in FIG. In the figure, this relationship is expressed as (3, 2, 1, 0). This relationship and expression are common to the track address 3SB51, the track address 2SB52, and the track address MSB53. It is assumed that the track address LSB 50 exists every other segment, that is, one in two segments.

The track address 3SB51 is bit 7 to bit 4 of 16-bit information representing the track address.
It is a pit that represents. In the figure, (7, 6, 5,
It is expressed as 4). Track address 3SB51
Is present every 3 segments, that is, one in every 4 segments. Track address 2SB52 is
Bit 11 of 16-bit information that represents the track address
~ A pit representing bit 8. In the figure, (b,
a, 9, 8). Track address 2S
B52 is every 7 segments, that is, 1 every 8 segments
Shall exist. Track address MSB53
Are pits representing bits 15 to 12 of 16-bit information representing a track address. In the figure,
It is expressed as (f, e, d, e). It is assumed that the track address MSB53 exists every 15 segments, that is, one in 16 segments. In order to store and form the above-mentioned information indicating the track address, the pit 31a
~ 31d and 31f to 31i are used, and the pit 31
e is not used and there is no pit itself (only the interval is 1
The pit is open).

The unique information 54 includes pits 31a to 31.
It is stored on i and is paired with the segment number information 55.
The segment that includes the unique information 54 in the servo area 3
To 5 _jIs information for indicating the position of. This is a conventional example
Corresponding to the reference pattern in. Segment
The number information 55 includes pits 31a to 31d and 31f to 3
Segme stored on 1i and containing unique information 54
5_jOf truck 6_kInformation indicating the order above
is there. As mentioned above, unique information 54 and segment
The pits 31a ...
31i or pits 31a to 31d, 31f to 31
i is used. The pits that are not used here are
Like the pits that show track addresses, the pits themselves
It does not exist. Unique information 54 and
The segment number information 55 is every 63 segments, that is,
It is assumed that there is one in 64 segments. Mentioned above
The structure of each information is shown in FIG.
The same applies to the portion of the disk 1.

FIG. 4 is a diagram showing a gray code (alternating code) represented by 9 bits. In FIG. 4, track address LSB50, track address 3SB51,
Track address 2SB52, track address MSB
53 and the segment number information 55 is shown in FIG.
The codes shown in (1 out of 4 × 2, 1 out of 4 × 2) are used. Also, unique information 5
4 is an exception to the gray code shown in FIG. 4A, that is, the code shown in FIG. 4B is used. This code does not exist in each of the above pit arrays that represent the track address and the pit string that represents the segment number information 55. Therefore, the unique information 54 is not confused with the pit string of the access code 31 representing other information.

FIG. 5 summarizes the number of each of the above-mentioned information items existing in the servo area 3 of each segment 5 per track. In FIG. 5, the track address LSB
Since 50 exists in two segments, 512 exist in one track. Track address 3SB5
Since one exists in four segments, there are 256 per track. Track address 2SB52
Since there is one in every 8 segments, there are 128 per track. Track address MSB53
Since there is one in 16 segments, there are 64 per track.

The reason for setting the number of each information per track as described above is that the lower bits of the track address, the more access is required when searching for the track on the optical disk 1. That is, the higher the bit, the wider the width of the continuous track (the length in the radial direction of the optical disc 1) that is used at the beginning of the search on the optical disc 1 and that can be searched with the same information. Therefore, once a search can be performed within a certain range, basically no determination is required thereafter. On the other hand, since it is necessary to finally determine each adjacent track, the track address LSB 50 needs to be determined to the end.

There are 64 remaining servo areas 3 used for the above information. Half of these, 32, are not used as spares. 16 of the remaining 32 servo areas 3
The unique information 54 is stored and formed in each piece, and the segment number information 55 is stored and formed in the remaining 16 pieces. That is, the unique information 54 and the segment number information 55 are 1
There is one in the sector. Here, it is assumed that the unique information 54 is placed in the head segment 5 ₀ of each sector 2 and the segment number information 55 is placed in the 32nd segment 5 ₃₁ . The 1-out-of-5 code is stored and formed in the unique information 54, and the segment number information 55 includes the number (0 to 15) of the sector 2 in which each segment number information 55 exists.
Is formed in memory. Since there are 16 sectors 2 in one track, they can be represented by the code shown in FIG.

With the above structure, the head segment 5 ₀ of each sector 2 on each track 6 _k can be shown. Also, in order from the head segments 5 ₀ of each sector, it is possible to identify the location of all segments 5 of each track 6 _k. Also, since 16 unique information 54 and 16 segment number information 55 exist in one track, the position of the segment on the track can be specified even if a failure occurs due to slight damage on the optical disc 1. By not being able to do so, the situation in which the entire truck becomes unusable rarely occurs.

FIG. 6 is a flow chart showing the processing at the time of starting the sample servo. In FIG. 6, in step 00 (S00), the spindle is turned on and the spindle is locked. In step 01 (S01), continuous focus servo is performed.

In step 02 (S02), the PLL
Locks. In step 03 (S03), sampling focus servo is performed. Step 04 (S0
In 4), sampling tracing servo is performed. In step 05 (S05), rotation synchronization is established. The processing of S03 to S05 is performed in parallel.

In step 06 (S06), tracking is turned off. In step 07 (S07), seek is performed. In step 08 (S08), tracking is turned on. In step 09 (S09),
Writing / reading (W / R) is performed.

In step 10 (S10), it is determined whether or not the process is finished. In step 11 (S11), the servo is turned off and the spindle is turned off.

Here, the unique code is mainly used for the rotation synchronization pull-in (S05). Of S06-S09,
In the seek (access) to W / R operations, the rotation synchronization loss is detected, but the re-pull-in process is not performed here. In this part, rotation synchronization should have already been obtained, otherwise the address cannot be read and seek cannot be performed.

PLL is basically used in the sample servo,
When the servo or more occurs, it is common to return to the PLL lock operation (or continuous focus servo pull-in processing).

The second embodiment will be described below. Here, FIG. 4 used for the unique information 54 in the first embodiment.
The code shown in FIG. 4C is used instead of the code shown in FIG. Even with such a configuration, it is possible to obtain the same method of synchronizing the optical recording / reproducing apparatus and the optical recording medium thereof as in the first embodiment.

In addition to the embodiments described above, the synchronizing method of the optical recording / reproducing apparatus of the present invention and the optical recording medium can have various configurations. Further, the above-described embodiments are examples. In particular, in the same configuration, it can be applied to the 1-out-of-3 code as well as the 1-out-of-4 code.

[0032]

As described above, according to the synchronizing method of the optical recording / reproducing apparatus and the optical recording medium thereof of the present invention, the reference pattern can be made into one type by using the unique code, and the reference pattern can be obtained. It is possible to obtain a synchronization method for an optical recording / reproducing apparatus and an optical recording medium therefor, in which there is no difference in the servo characteristics caused by the difference between the two and the redundancy of synchronization information is small. Further, since there are a lot of segment position information for each track, there is an accompanying effect that the method of synchronizing the optical recording / reproducing apparatus and the optical recording medium thereof which are resistant to damage of the optical disc can be obtained.

[Brief description of drawings]

FIG. 1 is a diagram illustrating a disc format of an optical recording medium (optical disc) of the present invention.

FIG. 2 is an enlarged view showing a servo area of the present invention.

FIG. 3 is a diagram showing information stored and formed in an access code of a servo area included in each segment on a track of the present invention.

FIG. 4 is a diagram showing a gray code (alternating code) represented by 9 bits.

FIG. 5 is a summary of the number of pieces of information existing in the servo area of each segment per track of the present invention.

FIG. 6 is a flowchart showing a process at the time of starting a sample servo.

FIG. 7 is a diagram illustrating a disc format of a conventional optical recording medium (optical disc).

FIG. 8 is a diagram illustrating a synchronization pattern of a conventional optical recording medium.

[Description of Codes] 1 ... Optical disc 2 ... Sector 3 ... Servo area 4 ... Data area 5 ... Segment 6 ... Track 10 ... Sync pattern 30 ... Clock pit 31・ ・ ・ Access code 32 ・ ・ ・ Walble bit 33 ・ ・ ・ Guard band 40 ・ ・ ・ Data recording part 50 ・ ・ ・ Track address LSB 51 ・ ・ ・ Track address 3SB 52 ・ ・ ・ Track address 2SB 53 ・ ・ ・Track address MSB 54 ... Unique information 55 ... Segment number information

[Procedure Amendment 2]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 4

[Correction method] Change

[Correction content]

[Figure 4]

[Procedure 3]

[Document name to be corrected] Drawing

[Name of item to be corrected] Figure 6

[Correction method] Change

[Correction content]

[Figure 6]

Claims (8)

[Claims] 1. A synchronization information storage area is provided in each of the storage area portions that divide the storage area of an optical storage medium, and unique code information is stored as information stored in a certain synchronization information storage area. Position information of a storage area portion that stores information is stored in another synchronization information storage area, and based on the unique code information and the position information of the storage area portion that stores the unique code information, A method for synchronizing an optical storage device, characterized by defining a position. 2. A synchronization information storage area is provided in each of the storage area portions that divide the storage area of the optical storage medium, and unique code information is stored as information stored in a certain synchronization information storage area. An optical storage medium, wherein position information of a storage area portion for storing code information is stored in another synchronization information storage area. 3. A synchronization information storage area is provided in each of the storage area portions that divide the storage area of the optical storage medium, and the area is divided into two areas for use as information stored in the synchronization information storage area. Unique code information represented as one exception of the divided synchronization information is stored, position information of a storage area portion storing the certain unique code information is stored in another synchronization information storage area, and the unique code is stored. A method for synchronizing an optical storage device, characterized in that the position of each storage area portion is defined based on the information and the position information of the storage area portion that stores the unique code information. 4. A synchronization information storage area is provided in each of the storage area portions that divide the storage area of the optical storage medium, and the area is divided into two areas for use as the information stored in the synchronization information storage area. Unique code information represented as an exception to the entire divided sync information is stored, position information of a storage area portion storing the unique code information is stored in another synchronization information storage area, and the unique code information is stored. , And the position of each storage area portion is defined based on the position information of the storage area portion storing the unique code information. 5. The synchronization method according to claim 3, wherein a code (1 out of 5) represented as an exception of a 5-bit alternating code is used as the unique code. 6. The synchronization method according to claim 4, wherein a code (2 out of 9) represented as an exception of a 9-bit alternating code is used as the unique code. 7. The optical storage medium according to claim 2, wherein 1 out of 5 is stored as a unique code. 8. The optical storage medium according to claim 2, wherein 2 out of 9 is stored as a unique code.