JP3165690B2 - Data recording method - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data recording method particularly suitable for a sample-servo type CD-RAM.

[Summary of the Invention]

The present invention particularly relates to a data recording method suitable for use in a CD-RAM of a sample servo system, a data recording method for performing recording / reproducing processing in units of a data sequence of a predetermined length, wherein the data sequence is included in a unit data sequence. Are provided at a plurality of locations, so that a desired sector can be accessed in a short time even when the sector size is large like a CD-RAM.

[Conventional technology]

For example, a CD (compact disk) capable of recording / reproducing data using a magneto-optical disk as a recording medium has been proposed. CD capable of recording / reproducing such data
Is called a CD-RAM. A feature of the CD-RAM is that data compatibility with a CD-ROM dedicated to data reproduction and a write-once CD-WO can be maintained.

In the CD-RAM, one subcode block in the CD format is defined as one sector. One subcode block is
98 frames. Then, data recording / reproduction is performed in sector units.

Note that an error correction code in a normal CD is not completed in one sector. Therefore, the inventor of the present application has proposed an error correction coding method capable of recording and reproducing data in sector units.
First, as disclosed in Japanese Patent Application No. 63-118567, a sector-completed CIRC (cross-interleaved Reed-Solomon code) has been proposed.

[Problems to be solved by the invention]

In a CD-RAM, it is necessary to provide a sector address so that data can be recorded / reproduced in a desired sector. In a normal optical disk, a header area is provided in, for example, the first segment of one sector, and a sector address is recorded in this header area. Therefore,
Also in a CD-RAM, for example, it is conceivable to record a sector address in the first segment of one sector.

However, in the CD-RAM, in order to maintain data compatibility, one subcode block has one sector (98
Frame). Therefore, the sector size is larger than that of a normal optical disk. When the sector size is large, the sector address is, for example, 1
If only the first segment of a sector is recorded,
Since the rotation waiting time until the segment in which the sector address is recorded is reproduced becomes longer, the access time until reaching the desired sector becomes longer.

Therefore, the object of the present invention is to
An object of the present invention is to provide a data recording method capable of accessing a desired sector in a short time even when the sector size is large.

[Means for solving the problem]

According to the present invention, a data sequence of a predetermined length is recorded /
A data recording method for performing a reproducing process, wherein a plurality of addresses indicating the data sequence are provided in a unit data sequence.

[Action]

Since the sector addresses are dispersedly recorded in a plurality of segments in one sector, the rotation waiting time for detecting the sector address is reduced, and a desired sector address can be detected in a short time.

〔Example〕

 Embodiments of the present invention will be described in the following order.

a.About servo area layout a1.Normal CD frame format a2.Example of servo area layout in EFM a3.Other example of servo area layout in EFM a4. Example of arrangement a5. Another example of arrangement of servo area in case of ESM b. Example of CD-RAM of sample servo system a. Regarding arrangement of servo area This invention is applied to CD-RAM of sample servo system .

When implementing a CD-RAM using the sample servo method, consideration must be given to the placement of the servo area, so that stable servos can be maintained and errors can be easily corrected when a defect occurs in the servo area. This is to facilitate data compatibility with other CD variations.

In order to facilitate error correction when a defect occurs in the servo area, it is necessary to prevent data of one segment from straddling a plurality of error correction coded sequences. In the CD recording format, data is expanded into a frame structure and subjected to error correction coding. Therefore, if one frame corresponds to one segment, one segment of data is completed by one error correction coded sequence.
Error correction processing when a defect occurs in the servo area is facilitated. Therefore, it is conceivable to associate one frame with one segment.

a1. Frame Format of Normal CD FIG. 5 shows a data structure of one frame of a normal CD. In the case of a CD, 1
Bytes (8 bits) are converted into 14 channel bits and data is recorded. Then, between the bytes, merging bits for three channel bits are arranged for DC suppression.

As shown in FIG. 5, in a normal CD recording format, a sync pattern area 11 corresponding to (24 + 3) channel bits is provided at the beginning of one frame, and (14 + 3) channel bits corresponding to (14 + 3) channel bits are provided after the sync pattern area 11. A subcode area 12 (corresponding to 1-byte data) is provided. Subsequently, a data area 13 corresponding to ((14 + 3) × 12) channel bits (corresponding to 12-byte data) is provided, and a ((14 + 3) × 4) channel bits (corresponding to a 4-byte parity). (Corresponding) parity area
14 are arranged. Further, a data area 15 for ((14 + 3) × 12) channel bits is provided, and ((14 + 3) × 12)
4) A parity area 16 for channel bits is provided.

Therefore, the capacity of one frame is: sync pattern (24 + 3) channel bits subcode (14 + 3) channel bit data (14 + 3) × 12 channel bits parity (14 + 3) × 4 channel bit data ( 14 + 3) × 12 channel bit parity ... (14 + 3) × 4 channel bits A total of 588 channel bits.

An area where a servo area is provided in this one frame data will be considered. In the sample servo method, a clock is reproduced using a reproduction signal of a clock reproduction pit in a servo area. Therefore, the sync pattern area 11 is unnecessary. Therefore, the sync pattern area 11 can be used as a servo byte.

In addition, if the sector address is recorded, the subcode becomes unnecessary. Therefore, the subcode area 12 can be a servo byte.

a2. Example of Servo Area Arrangement for EFM FIG. 6 is an example in which the sync pattern area 11 in the normal CD format is used as the servo area 21.

That is, in FIG. 6, a servo area 21 for (24 + 3) channel bits is provided at the beginning of one frame. After this servo area 21, a subcode area 22 corresponding to (14 + 3) channel bits (corresponding to 1-byte data) is provided. And following this ((14 + 3)
A data area 23 for (× 12) channel bits (corresponding to 12-byte data) is provided, and a parity area 24 for ((14 + 3) × 4) channel bits (corresponding to 4-byte parity) is provided. Is done. Furthermore, ((14 + 3) × 1
2) A data area 25 for channel bits is provided,
Parity area for ((14 + 3) × 4) channel bits
26 are arranged.

In this way, one segment corresponds to one frame, and error correction when a defect occurs in the servo area becomes easy, and compatibility with other CD variations can be ensured. In this case, 561 channel bits (33
A servo area of 27 channel bits (corresponding to 1.59 bytes) can be secured for data and parity (corresponding to bytes).

a3. Another Example of Servo Area Arrangement in EFM FIG. 7 shows an example in which the sync pattern area 11 and the subcode area 12 in the normal CD format are used as the servo area 31.

That is, in FIG. 7, a servo area 31 for ((24 + 3) + (14 + 3)) channel bits is provided at the beginning of one frame. After this servo area 31,
A data area 33 of ((14 + 3) × 12) channel bits (corresponding to 12 bytes of data) is provided, and ((14 + 3) × 12)
A parity area 34 of (3) × 4) channel bits (corresponding to 4-byte parity) is provided. Furthermore,
((14 + 3) x 12) Data area for channel bits 35
Are provided, and a parity area 36 for ((14 + 3) × 4) channel bits is provided.

In this case, a servo area of 44 channel bits (corresponding to 2.59 bytes) can be secured for data and parity corresponding to 544 channel bits (corresponding to 32 bytes).

a4. Example of Servo Area Arrangement in ESM In the above-described example, data is subjected to EFM similarly to a normal CD. However, in the EFM, it is necessary to provide three merging bits for DC component suppression between each byte, so that there is a limit in improving the recording density. So 1
A modulation method that converts bytes into 16 channel bits and does not require a merging bit for DC component suppression has been proposed. Such a modulation method is called ESM (8-16 modulation).
It is called.

FIG. 8 shows a case where the sync pattern area 11 is used when ESM is used.
Is an example in which a servo area 41 is used.

That is, in FIG.
Servo areas 41 for channel bits are provided. After this servo area 41, a subcode area 42 of 16 channel bits (corresponding to 1-byte data) is provided.
Subsequently, a data area 43 corresponding to (16 × 12) channel bits (corresponding to 12-byte data) is disposed, and a data area 43 corresponding to (16 × 4) channel bits (corresponding to 4-byte parity). A parity area 44 is provided. Further, a data area 45 for (16 × 12) channel bits is provided, and a parity area for (16 × 4) channel bits is provided.
46 are arranged.

In this case, 528 channel bits (equivalent to 33 bytes)
For data and parity, a servo area of 60 channel bits (equivalent to 3.75 bytes) can be secured.

a5. Another Example of Servo Area Arrangement in the Case of ESM FIG.
This is an example in which 1 and the subcode area 12 are servo areas 51 and 57. In this example, one frame is divided into two equal parts, and servo areas 51 and 57 are provided respectively.

That is, in FIG. 9, 38
Servo areas 51 for channel bits are provided. After the servo area 51, a data area 53 corresponding to (16 × 12) channel bits (corresponding to 12-byte data) is provided, and a data area 53 corresponding to (16 × 4) channel bits (corresponding to 4-byte parity). Parity area 54 is provided. Then, a servo area 57 for 38 channel bits is provided,
A data area 55 for (16 × 12) channel bits is provided, and a parity area 56 for (16 × 4) channel bits is provided.

In the CD recording format, since one frame has the same pattern of data and parity,
When the frame is divided into two equal parts and the servo areas 51 and 57 are provided respectively, the structure of each segment becomes the same. That is, in FIG. 9, the servo area 51, the data area 53,
One segment is constituted by the parity area 54. Another one segment is composed of the servo area 57, the data area 55, and the parity area 56. The configuration of these two segments is the same.

In this case, for data and parity of 256 channel bits (equivalent to 16 bytes) per segment,
A servo area of 38 channel bits (equivalent to 2.375 bytes) can be secured. As described above, since a servo area of 2 bytes or more is secured in 16 bytes, stable servo control can be performed.

b. Example of CD-RAM of Sample Servo System FIG. 1 shows a configuration of a CD-RAM to which the present invention is applied. This CD-RAM 1 uses a magneto-optical disk as a recording medium. The outer shape of the CD-RAM 1 is substantially the same as that of a normal compact disk.

The CD-RAM 1 is provided with a spiral or annular track T. Data is recorded along the track T in the form of a row of magneto-optical pits (the orientation of the magnetization of the perpendicular magnetization film). This CD-RAM1 is either a CAV (constant angular velocity) or C
Rotated at LV (constant linear velocity).

Data is recorded / reproduced in the CD-RAM 1 for each sector (corresponding to a subcode block in a normal CD) # 0, # 1, # 2,. ESM is used as a modulation method. As the error correction code, a sector complete CIRC code is used.

In the CD-RAM 1, a sample servo method is used as a tracking method. That is, one sector is further divided into a plurality of segments SG0, SG1, SG2,..., And a servo area is provided for each segment. As shown in FIG. 2, the servo pits P1 and
P2 is provided with a similar offset with respect to the track center, and a pit P3 for clock reproduction is provided. Tracking servo is performed using the reproduction signal levels of the servo pits P1 and P2. Further, a clock is formed from a reproduction signal of the pit P3 for clock reproduction, and data is recorded / reproduced using the clock.

 The recording format of the CD-RAM will be described in detail.

FIG. 3 shows an example of the recording format of such a CD-RAM1. This example corresponds to the example shown in FIG.

That is, as shown in FIG. 3A, one track is divided into, for example, ten sectors # 0, # 1, # 2,... # 9. Each sector # 0, # 1, # 2,... # 9 is shown in FIG.
As shown in the figure, 100 segments SG0, SG1, SG2, SG
3, divided into SG199. One segment corresponds to 1/2 frame.

In a CD, one subcode block is composed of 98 frames. Therefore, if one frame is simply divided into two segments, one sector is divided into 196 segments. However, in this example, since a servo area is also allocated to the subcode area, it is necessary to arrange a sector address. Although this sector address may be included in the servo area, in this example, four address segments are allocated so that the sector address can be detected at high speed and surely. Therefore, one sector is a (196 + 4 = 200) segment.

Of these segments, segment SG0, segment SG50, segment SG100, and segment SG150 are used for addresses. In this address segment, a sector address is recorded. The other 196 (98 frames) segments SG1, SG2, SG3, ..., SG51, SG52, ...
Is a segment for recording user data.

In this example, the segment SG for the address is thus
0, segment SG50, segment 100, segment SG150
Are distributed and arranged. In this manner, if the address segments SG0, SG50, segment 100, and segment SG150 are distributed, the rotation waiting time when detecting a sector address is reduced.

FIG. 3C shows segments SG0, SG50, 10 for the address.
0 shows the configuration of SG150. As shown in FIG. 3C, the area corresponding to the first 2.375 bytes of the address segment is a servo area 61. Subsequently, a 1-byte equivalent sector mark area 62, a 3-byte equivalent sector number area 63, a 2-byte equivalent parity area 64, a 1-byte equivalent sector mark area 65, a 3-byte equivalent sector number area 66, A parity area 67 corresponding to 2 bytes is provided. In these areas corresponding to 12 bytes, data is recorded by emboss pits. Then, an area corresponding to 4 bytes following this is set as a laser control area 68.

FIG. 3D shows the structure of a data segment. As shown in FIG. 3D, an area corresponding to the first 2.375 bytes of the data segment is a servo area 71. Subsequently, a user data area 72 corresponding to 12 bytes is provided. Then, an area equivalent to 4 bytes following this is set as a parity area 73.

When data is recorded / reproduced in such a format, as shown in FIG.
Is used to perform an error correction encoding process.

Segments SG1 and SG excluding segments for addresses
2, SG3,... Are data segments sg0, sg1, sg2,. When performing the error correction encoding process using the sector-completed CIRC, as shown in FIG. 4, each data of the data segments sg0, sg1, sg2,... Sg195 is two-dimensionally arranged. Then, the error correction encoding process in duplicate and C ₁ sequence and the C ₂ sequence is performed.

If a defect occurs in the servo area, the level of the reproduced RF signal decreases, and the data of the segment becomes an error.
As shown in FIG. 4, since one segment of data is completed with one error correction coded sequence, error information can be returned in units of 1/2 frame, and management for error correction thereafter is easy. In the case of the CD format, exactly one frame delay is inserted between adjacent bytes, so that the sequence is completed with two adjacent error correction coding sequences. Therefore, 1/2 frame x
Error information is returned in units of 2.

In such a recording format, each segment has a similar structure, and two segments constitute one frame.
This is suitable when data is duplicated or the corresponding data is recorded. That is, for example, in FIG.
If the Japanese data is recorded in the upper segment (even number segment) and the English data is recorded in the lower segment (odd number segment), the voice multiplexing process can be easily performed. .

Furthermore, if the error correction coding process is performed completely independently on each of the segment arranged at the upper part and the segment arranged at the lower part, the segment arranged at the upper part and the segment arranged at the lower part can be divided. Can be processed as completely independent data.

In this recording format, scrambling is performed in units of segments, so that the correspondence between physical format processing and logical format processing is good. Also,
In the present application, the so-called N
Input data such as RZ may be recorded.

〔The invention's effect〕

According to the present invention, since the sector addresses are distributed and recorded in a plurality of segments in one sector,
The rotation waiting time for detecting a sector address is reduced, and a desired sector address can be detected in a short time.

[Brief description of the drawings]

FIG. 1 is a plan view showing an external configuration of a CD-RAM to which the present invention is applied, FIG. 2 is a schematic diagram used for explaining a servo area,
FIG. 3 is a schematic diagram showing an example of a recording format of a CD-RAM to which the present invention is applied, FIG. 4 is a schematic diagram used to explain error correction encoding in a CD-RAM to which the present invention is applied, 5 to 9 show a CD-RAM to which the present invention is applied.
FIG. 4 is a schematic diagram used for describing the arrangement of servo areas in FIG. Explanation of main symbols in the drawings 1: CD-RAM, 21, 31, 41, 51, 61, 71: servo area.

Continuation of the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) G11B 20/12 G11B 21/08 G11B 27/10

Claims (1)

(57) [Claims] 1. A data recording method for performing recording / reproducing processing on a disk recording medium using a data sequence of a predetermined length as a unit, wherein a plurality of unit data sequences are recorded on each track of the disk, and The data sequence is composed of a plurality of segments. In the unit data sequence, an address area including a common address corresponding to the data sequence is set at a predetermined interval from the plurality of segments together with the parity area including the parity. A data recording method, wherein the data recording method is distributed and arranged so as to have: