JPH03119523A - Optical disk - Google Patents

Abstract

PURPOSE:To correctly detect a position information code by increasing the number of kinds of pattern of the position information code based on relations between mark positions of two position information codes adjacent in the diametral direction of an optical disk. CONSTITUTION:The position information code provided on each track of the optical disk has a preliminarily determined number N of marks in the range having a preliminarily determined channel bit length M. The optical disk is so constituted that at least two of four cases (1) to (4) are satisfied. In the case (1), positions of N-number of, for example, two marks A and B coincide with each other between two position information codes adjacent in the diame tral direction of the optical disk; and in the case (2), positions of one of two marks are different by the extent corresponding to one channel bit between them; and in the case (3), they have one or more continuous two or more long marks and position of the one long mark is different by the extent correspond ing to one channel bit between them; and in the case (4), they have three or more long marks. By the cases (2) and (3), 15 kinds of patterns are available.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an optical disc having one or more positional information codes on each track.

[Conventional technology]

Generally, an optical disk has concentric or spiral tracks, and about 1,000 to 2,000 servo areas are provided per I-rank round.

FIG. 12 shows an example of the configuration of a servo area in the sample servo system. In this example, each servo area has a position information code of 1.
1. Wobble mark 12, 1.3 and clock mark 1
4 is provided at or slightly shifted from the center 15 of the track, and the position information code 11 is 6 channel bits 1-. This location information code 11 is the 13th
As shown in the figure, there are marks a and b for two of the six channel bits. Location information code 11
There are 8 types, which change from 1 to every rack (one round of a track), and have the same pattern every 8 tracks from track numbers (n+o) to (n+7).

This optical disc is loaded into an optical disc drive device, which rotates the optical disc and uses an optical pickup to read information from the optical disc. The position information code 11 is a code that indicates the track position, and the optical disk drive device uses the optical pickup to detect the position information code 11 while seeking the optical pickup in the radial direction of the optical disk, and determines the number of tracks that the optical pickup has traversed. The seek ends when this count value reaches the value corresponding to the target track.

In a conventional optical disc, the position information code 1- is N marks (in the example of FIG. 13, two marks a).

b), between each position information code of two tracks adjacent in the radial direction of the optical disc, only the position of one mark changes by one channel pit 1, and the positions of other marks change. There is a relationship between not doing so. This means that even if the light spot caused by the optical pink-up on the optical disk passes between two tracks without passing through the center of the track during a seek, the position information code provided on either track will be ignored.
This is to make it possible to detect.

FIGS. 14 to 16 show reproduction signals obtained from the optical pickup when the light spot passes through position information codes 1 to 11 of tracks (n+7) and (n+0) of the optical disk.

The optical disk drive device detects the amplitude (amount of decrease from the mirror level) of the reproduced signal from the optical pink-up for the position information code 11, and detects the amplitude of the reproduced signal from the optical pink-up for each channel pit position (2
The number of racks traversed by the optical pickup is counted up to 1 by determining that the racks up to 1) are 1' and the others are 0'.

Optical spora 1- tracks (n+7) as shown in Figure 14 ■
When the signal passes through the center of .

The light spot is 1 to easy (n+0) as shown in Figure 14 ■.
When the signal passes through the center of Ru.

The light spot is 1 to easy (n+7) as shown in Figure 14 ■.
, (n+o), the reproduced signal becomes the 16th
As shown in the figure, the amplitude is maximum at channel pit position 3, and the next largest amplitude is at channel bit positions 7 and 8. Therefore, the reproduced signal is at channel bit positions 3 and 7.
Or 3,8 is determined to be 1', and the position information code 11 of track (n+7) or (n+o) is detected.

[Problem to be solved by the invention]

In the optical disc mentioned above, the relationship between the position information codes of two adjacent tracks is such that only the position of one mark changes by one channel bit, and the positions of other marks do not change. Combinations of position information codes between two adjacent tracks are limited, leading to various problems. For example, there should be Ga4-15 combinations of patterns with two marks in 6-channel bit 1, but two adjacent
Because the relationship between the position information codes from 1 to 3 is a bipedal relationship, 3 out of 15 combinations cannot be used as shown in Figure 18, and only 12 patterns can be created. Can not. As a result, the speed of the seek operation performed by detecting the position information code is reduced, causing problems such as slow reproduction of information.

Also, if the optical spoiler 1- passes obliquely through tracks (n + 7) and (n 10) as shown in Fig. 14 (■) during seek, the reproduced signal will be shifted to the channel pit position 3 as shown in Fig. 17. maximum at channel bit positions 4, 7, .
At 8, the amplitude is almost the same and becomes the next largest amplitude. Therefore, the reproduced signal is at channel bit position 3, 4 or 3, 7.
Or, if the playback signal is determined to be 1' at channel bit positions 3 and 4, the position information code of track (n+7) or (n+o) is 11.
A different location information I~ will be detected,
I can't get the correct location code. As a result, the seek operation becomes unstable, the target location cannot be reached, and the target information cannot be reproduced from the optical disk. Therefore, it is preferable not to use the pattern shown in FIG. 14, but since the relationship between the position information codes of two adjacent tracks is as described above, the degree of freedom in pattern selection is reduced. There is a problem in that even patterns that are likely to cause detection errors as shown in the figure must be used.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical disc that can improve the above-mentioned drawbacks, solve the problems caused by the small number of types of patterns of position information knees 1 to 1, and make it possible to correctly detect position information codes.

[Means to solve the problem]

In order to achieve the above object, the present invention provides a method for each track.
or a plurality of location information codes, each location information code has a predetermined number (N) of marks in a predetermined channel bit length range, and each location information code has a predetermined number (N) of marks in a predetermined channel bit length range, and In an optical disc arranged such that the information codes are aligned in the radial direction of the optical disc, the relationship between the mark positions of two position information knees 1' adjacent in the radial direction of the optical disc is (1) the same. (2) A relationship in which the position of only one mark among the N marks differs by one channel bit, and (3) One long mark each consisting of two or more consecutive marks. and (4) two of the long marks consisting of three or more consecutive marks. The arrangement is such that at least one of two relationships holds true: the positions of two or more consecutive marks differ by one channel bit in the same direction.

[For production]

During the seek, the light spot moves on the optical disk and the position information code is detected.

〔Example〕

In the present invention, each track has one or more position information codes, and each position information code has a predetermined number (N) of marks within a predetermined channel bit length (M). In an optical disc that has a positional information code on each track and is arranged so that the positional information codes on each track are aligned in the radial direction of the optical disc, the relationship between the mark positions of two positional information codes that are adjacent to each other in the radial direction of the optical disc is , (1) They are the same; (2) the positions of only one of the N marks differ by a coach yarn bit; and (3) they consist of two or more consecutive marks. (4) Long marks consisting of three or more consecutive marks, in which the position of only one long mark differs from each other by one channel bit. The positions of two or more consecutive marks differ by one channel bit in the same direction.In FIG. 6, M=6. An example of position information codes having the relationship (3) above on two adjacent tracks in the case of N=3 is shown below. These two position information codes are provided at the center 15''2 of two adjacent tracks j, i-+-1, and 3
Two consecutive marks A.

The positions of the long marks B and C differ from each other by one channel bit.

When the light spot passes through the center of track 1 as shown in Figure 6 (■), the reproduced signal becomes as shown in Figure 7 (■), and the reproduced signal is determined to be 1' at channel bit position 4°5.6. The position information code of track 1 is detected.

When the light spot passes through the center of track l+1 as shown in Figure 6 (■), the reproduced signal becomes as shown in Figure 7 (■), and the reproduced signal is determined to be 1' at channel bit positions 3, 4.5. The position information code of track j+1 is detected.

When the light spot passes between 1 and rack j, 1+1 as shown in Figure 6 (■), the reproduced signal reaches its maximum at channel bit positions 4 and 5 and reaches channel pit position 3 or 1 as shown in Figure 8. 6 has the next largest amplitude. Therefore, the reproduced signal is determined to be 1' at channel bit position 3, 4.5 or 4, 5.6, and the position information code of track 5 or 1~rack]+1 is detected.

As is clear from Fig. 6, when the light spot passes closer to track i than ■, the position information code of track i is detected from the reproduced signal, and when the light spot passes closer to track i+1 than ■ The position information code of track i+1 is detected from the reproduced signal. The light spot is a track].

When passing between i+1, no other location information codes are detected. Therefore, although the position information code having the relationship (3) has not been used in the past, it is suitable as a position information code.

FIG. 9 shows M=6. An example of position information codes having the relationship (4) above on two adjacent tracks in the case of N=3 is shown below. These two location information codes are track j
Three consecutive marks A above.

Marks B and C at channel bit positions 5 and 6 in the long mark consisting of B and C change to channel bit positions 6 and 7, respectively, on track j+1.

When the light spot passes through the center of the track j as shown in Figure 9 ■, the reproduced signal becomes as shown in Figure 10 ■, and the reproduced signal is determined to be 1' at the channel pit position 4° 5.6. Then, the position information code of track j is detected.

When the light spot passes through the center of track J+1 as shown in FIG. 9 (■), the reproduced signal becomes as shown in FIG. 10 (■), and the reproduced signal reaches channel bit position 4. ．． At 6.7]
', and the position information code of track j+1 is detected.

11 When the light spot passes between tracks JrJ+1 as shown in Figure 9 ■, the reproduced signal reaches its maximum amplitude at channel pit position 6 and reaches the next largest amplitude at channel pit position 4, as shown in Figure 11. , the next largest amplitude is obtained at channel pitch 1 to position 5 or 7. However, in this example, the reproduced signal is influenced more by the long mark of length 3 on track j, and the channel pit position 5 is slightly larger than the channel pit position 7. therefore,
The reproduced signal is at channel bit position 4. ．． 5.6, it is determined to be 1', and the position information code of rack J is detected at 1.

When the light spot passes closer to track j+1 than ■, the playback signal will be slightly larger at channel pit position 7 than at channel pit position 5, and at track j+1.
location information code is detected. If the light spot passes between tracks J + J + 1 then track J +
No location information code other than the J+1 location information code is detected.

Therefore, the position information code having the relationship (4) is suitable as a position information code, although it has not been used conventionally.

FIG. 1 shows a portion of an embodiment of the present invention.

The optical disc of this embodiment has concentric or spiral tracks, and a servo area (
Approximately 1,000 to 2,000 pieces are provided per round of the rack. In each servo area, a position information code, a wobble mark, and a clock mark are provided on the center 15 of the track or slightly shifted from the center 15, and each position information code is set in advance at the center 15 of the track. It has a predetermined number (N) of marks in the range of channel bit length (M), where M=6. N=2.

Further, in this embodiment, the position information codes on each track are arranged so as to be aligned in the radial direction of the optical disc, and the N marks A and B of two position information codes adjacent to each other in the radial direction of the optical disc are arranged so as to be aligned in the radial direction of the optical disc. (2) the position of only one mark out of N marks differs by one channel bit, and (3) a long mark consisting of two or more consecutive marks is or more, and the position of only one of the long marks differs from each other by one channel bit.

In the conventional example shown in FIG. 18, only 12 patterns out of C2=1.5 patterns could be used, but in this embodiment, patterns having the relationship (3) above can be used, so 15 patterns can be used. You can use everything. In this embodiment, the position information code changes every track (one round of tracks) and has the same pattern for every 15 tracks of two radially adjacent track numbers (N+O) to (N+14). Track numbers (N+2) and (N+3),
(N+3) and (N+4), (N+5) and (N+6), (
N+6) and (N+7), (N+7) and (N+8), (N
+8) and (N+9), (N+9) and (N +10), (
N+10) and (N+11), (N+11) and (N+
12), (N +12) and (N+13), (N+13)
, (N+]4), (N+]4), and (N+O), N marks A and B have the relationship (2) with each other, and each two radially adjacent Track numbers (N+O) and (N+1), (N+1) and (N+2)
), (N+4), and (N+5), N marks A, B, and C have a relationship of (3) with each other.

This optical disk is loaded into a live device, and the optical disk drive device rotates the optical disk and uses an optical pickup to read information from the optical disk. Furthermore, when the optical disk drive device seeks the optical pickup in the radial direction of the optical disk, it uses the optical pickup to detect the position information code and counts the number of tracks that the optical pickup has traversed, and this count value corresponds to the target track. Terminate the seek when the value is reached.

In this case, the optical disk drive device detects the amplitude (amount of decrease from the mirror level) of the reproduced signal from the optical pickup with respect to the position information code, and selects N bits (in the two-leg embodiment) for each channel bit position in descending order of magnitude. 2) is determined to be 1', and the others are determined to be O', and the number of transverse lines crossed by the optical pickup is counted.

FIG. 2 shows a portion of another embodiment of the invention.

This embodiment differs from the above embodiment in that the location information code is M=6.0 as shown in FIG. The configuration is such that N=2. This location information code is 12 as in the conventional example shown in FIG.
Although regular pattern combinations are used, combinations of patterns that are likely to cause detection errors as shown in FIG. 5 are prohibited and not used. In the conventional example, the degree of freedom in pattern combinations is low, so if you try to use 12 pattern combinations, you have no choice but to use two of the pattern combinations that are prone to detection errors as shown in Figure 5. I don't get it,
In the conventional example shown in Fig. 18, tracks (n+5) and (n+6)
, (n + 7) as each position information code shown in FIG.

■ is used. In this example, patterns having the relationship (3) above are used, so pattern combinations that are likely to cause detection errors as shown in FIG. 5 are not used.
Two patterns are obtained, and the degree of freedom in selecting a position information code pattern is large, making it possible to correctly detect the position information code.

In this embodiment, the position information code specifically changes every track (one round of the track), and every 12 tracks from 1 to rack number (N10) to (N+11), which are two radially adjacent tracks. It will be the same pattern. Also, track number (
N+1) and (N+2), (N+2) and (N+3), (N
+3) and (N+4), (N + 4) and (N+5),
(N+5) and (N+6), (N+6) and (N+7), (
N+7) and (N+8), (N+8) and (N+9), (N
+9) and (N+10) position information codes have N marks A and B in the relationship (2) with each other, and the track number (
N+O) and (N+1), (N+10) and (N+11),
The positional information knees I (N+11) and (N+O), or the N marks A and B, have a relationship of (3) with each other.

FIG. 3 shows a portion of another embodiment of the invention.

This embodiment differs from the above embodiment in that the location information code is M=6.0 as shown in FIG. The configuration is such that N=3. This location information code is the track number (N+O) and (N
+1), (N+2) and (N+3), (N+3) and (N+
4), (N+4) and (N+5), (N+5) and (N
+6), (N++3) and (N+7), (N-1-7) and (N+8), (N+8) and (N+9), (N+9) and (
N + 10), (N + 10) and (N+11), (
N +11) and (N+12), (N+12) and (N+1
3), (N+14) and (N+15), (N+15) and (
Each location information code (N+O) has N marks A, B, C.
have the relationship (2) with each other, and the track number (N+1.
), (N+2), (N+13), and (N+14) are N marks A and B.

C have the relationship (3) with each other.

FIG. 4 shows a portion of another embodiment of the invention.

This embodiment differs from the above embodiment in that the position information code is set to M=6 as shown in FIG. The configuration is such that N=3. In this position information knee 1-, track numbers (N+2) and (N+3), (N+3) and (N+4.), (N+4) and (N+5), (N+5) and (N+6), (N+6) and (
N+7), (N+7) and (N+8), (N+8) and (N
+9), (N+9) and (N +10), (N+], O)
and (N+11), (N+11) and (N+12), (N
+12) and (N+13) position information codes are N marks A and B.

C have the relationship (2) with each other, and the track number (N+O
) and (N-1-1), (N + 14) and (N+], 5
), (N+15), and (N+O) are N marks A.

B and C have the relationship (3) with each other, and l-rank number (
N + 1- ) and (N+2), (N+13) and (N+
14) Each location information code has N marks A, , B, C.
are in the relationship (4) with each other.

Note that the position information code has the relationship (1) when the pattern is changed every two tracks.

〔Effect of the invention〕

As described above, according to the present invention, each track has one or more position information codes, and each position information code has a predetermined number (()) within a predetermined channel bit length range. In an optical disc having a mark N) and arranged so that the position information code on each one square is aligned in the radial direction of the optical disc,
The relationship between the mark positions of two position information codes adjacent in the radial direction of the optical disc is (1) the same relationship, and (2) only one mark position 9 of the N marks is 1. (3) They each have at least one long mark consisting of two or more consecutive marks, and only one of these long marks has a position that is different from each other by one channel bit. (4) A relationship in which the positions of two or more consecutive marks among long marks consisting of three or more consecutive marks differ by one channel bit in the same direction. Since it is configured to have at least one of two relationships, it is possible to increase the types of patterns for the position information knee 1 and solve problems such as slowing down of the seek operation. Moreover, it becomes possible to correctly detect the position information code without using patterns that are likely to cause detection errors.

[Brief explanation of drawings]

1 to 4 are diagrams showing a part of each embodiment of the present invention,
FIG. 5 is a diagram showing prohibited patterns of the location information code in the same embodiment, and FIGS. 9 to 11 are diagrams showing the state of the reproduced signal obtained from the optical pickup when the light spot passes through a part of another example of the present invention, and FIG. FIG. 13 is a diagram showing a part of an example of the optical disc; FIG. 13 is a diagram showing a part of the same optical disc;
4 to 17 are diagrams showing reproduction signals obtained from an optical pickup when a light spot passes over the same optical disk, and FIG. 18 is a diagram showing a part of a conventional example. 15...Center of track, A, B, C...marks. 1 ＠ ■ Koshu Taku υdai most 橡片ml smell 3do) Heishu Kishu Mudoshin

Claims (1)

[Claims] 1. Each track has one or more position information codes, each of which has a predetermined number (N) of position information codes within a predetermined channel bit length range. In an optical disc that has marks and is arranged so that the position information codes on each track are aligned in the radial direction of the optical disc, the relationship between the mark positions of two position information codes that are adjacent to each other in the radial direction of the optical disc. but,
(1) They are the same; (2) the position of only one mark among N marks differs by one channel bit; and (3) a length consisting of two or more consecutive marks. (4) Among long marks consisting of three or more consecutive marks, the position of only one long mark differs from each other by one channel bit. An optical disc characterized in that the positions of two or more consecutive marks are different from each other by one channel bit in the same direction.