JPH06168449A - High-density optical disk - Google Patents

Abstract

PURPOSE:To provide the high-density optical disk which is formed with pits at a higher density than the density of a CD and can prevent the malfunction of the CD reproducing device even when erroneously mounted on the CD reproducing device by providing interchangeability with a CD reproducing device. CONSTITUTION:The pits of the same size as the size of the pits of the CD are formed within a region of 23 to 25mm radius among the recording regions of the high-density optical disk and lead-in and lead-out information meeting the requirements specified for the CD are recorded as data pit arrays. As a result, the CD reproducing device can make the operation from the start of reproduction to the end of the reproduction based on the normal reproduction operation in the region of 23mm to 25mm region even when the high-density disk is erroneously mounted on the CD reproducing device. Consequently, the various faults which can be generated by the malfunction of the system controller in the CD reproducing device are prevented.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high density optical disk having pits formed at a density higher than that of a so-called compact disk (hereinafter abbreviated as CD) among optical disks having phase pits formed according to signals. In particular, by providing compatibility with the CD reproducing device, especially when the disc has an outer dimension substantially equal to that of the CD and is accidentally attached to the optical disc device for CD reproduction (hereinafter abbreviated as the CD reproducing device) that may occur for this reason. The present invention relates to a high density optical disc capable of preventing malfunction.

[0002]

2. Description of the Related Art In an optical disk device such as a CD reproducing device,
The digital signal is reproduced by narrowing the laser light emitted from the laser diode to its wavelength limit, irradiating a narrowed light spot on the pit train on the optical disc, and detecting the change in the reflected light amount. In recent years, with the shortening of the wavelength of laser diodes, it has become possible to reduce the diameter of the light spot, and as a result, it is possible to reproduce high-density optical discs with a smaller pit size and track pitch than CDs. Is coming. In such a high density optical disc, as a matter of course, for example, audio signal reproduction at the same time as a CD can be performed with a disc having a smaller size, and conversely, when the disc size is about the same as the CD, It is possible to reproduce the audio signal for a longer time. Further, due to the progress of video signal compression technology, it may be possible to reproduce a video signal for a long time even with a disc size similar to that of a CD.

On the other hand, if such a high density optical disc is the same size as a CD, it is necessary to construct the system configuration and the disc format of the optical disc device so that the high density optical disc and the CD can be discriminated. Conventionally, when there are discs having the same disc shape or the same disc cartridge shape but different disc signal formats, for example, the following method is used to determine the disc type. Has been.

That is, the disc is provided with a pit row in which the pits of adjacent tracks are equal to each other in a predetermined area of the innermost periphery of the disc. On the disk device side, only focus control is performed in this area, and reproduction is performed with tracking control off. At this time, the light spot crosses the track diagonally depending on the amount of eccentricity of the disc. However, since the pits of adjacent tracks are equal as described above, there is some variation in the signal amplitude, but the signal reproduction Will be possible. Therefore, by forming information on various disc formats as pits in the area, it is possible to determine the type of the disc. Regarding the discs mentioned above, IS
O Standard Document ISO / IEC JTC 1 / SC 23N (Final tex
t of DIS9171-2).

[0005]

The above-mentioned prior art is to provide a pit in which information regarding the type of the disc is recorded in a predetermined area on the innermost circumference of the optical disc, and the above-mentioned technique is adopted when the optical disc device side mounts or reproduces the disc. A prerequisite is that the system is configured to operate. However, the CD and the CD reproducing device are not currently configured as described above. Therefore, when a high density optical disc is mounted in the CD reproducing device, even if a pit row for providing disc type discrimination information is provided in a predetermined area on the high density optical disc side, the system configuration of the CD reproducing device side is not changed. As far as it goes, the following problems occur.

[0006] In general, a CD reproducing apparatus, at the start of reproduction, has focus control pull-in, tracking control pull-in, pit signal reproduction, and disc rotation control by a sync signal included in a reproduction signal at the lead-in area of the innermost disc. It operates in the order of pulling in. Assuming that a high-density optical disc is mounted on such a CD reproducing apparatus and a reproducing operation is started, the focus control pull-in operation may be performed, but the subsequent tracking control pull-in operation may not be performed. is there. For example, if the track pitch of the high density optical disc is narrower than the track pitch of the CD, the modulation degree of the tracking error signal decreases, and the tracking control becomes unstable or impossible. If the track pitch is about the same as the CD and the pit length in the track tangential direction is smaller than the CD, tracking control can be performed, but the reproduction signal modulation degree of the pit decreases, so that the signal can be reproduced stably. The disk rotation control operation becomes unstable or impossible. As a result, the system control operation of the CD player becomes unstable, and there is a risk of causing various failures.

On the other hand, it may be possible to discriminate between a high-density optical disc and a CD by changing the system configuration of the CD reproducing apparatus, but C which has already been widely spread for consumer use.
Making changes to all D playback devices is virtually difficult.

In view of the above circumstances, an object of the present invention is to allow a CD reproducing device, which has been widely spread for consumer use, to be mounted with a high density optical disk by mistake without changing the CD reproducing device. It is to provide a high-density optical disc that can prevent malfunctions by making it compatible with.

[0009]

In order to achieve the above object, the high density optical disc of the present invention has a CD signal format lead-in area and a lead-in area at least in the same area as the CD lead-in area (radius 23 mm to 25 mm). The out information is formed by pits having the same pit depth and width and the track pitch of the CD. Also, radius of 23mm
In areas other than ~ 25 mm, CD pit depth and width,
Alternatively, a pit smaller than the track pitch is formed.

[0010]

In a general CD reproducing apparatus, at the start of reproduction, first, a focus control pull-in operation is performed with a target of a disk radius of 23 mm to 25 mm, and then the series of operations described above is started. Here, in the high density optical disc according to the present invention, in the range of the radius of 23 mm to 25 mm,
Since the pits having the same depth and width as the pits of the CD and the track pitch are formed, the CD reproducing device can operate the focus control, the tracking control, and the disc rotation control at the start of the reproduction in exactly the same manner as the CD reproduction. It will be possible.

Further, the subcode value of the lead-in information formed in the above range is, for example, the number of songs 1, the absolute start time of the first song ≈ the lead-out track start absolute time, and the lead-out is immediately after the absolute start time of the first song. By providing the above, it is possible to end the reproducing operation immediately after reproducing the lead-in.

With the above configuration and operation, the high density optical disc can be made compatible with the CD reproducing device. Therefore, even if the high density optical disc is mistakenly attached to the CD reproducing device, the malfunction of the CD reproducing device can be prevented. It becomes possible to prevent it.

[0013]

EXAMPLES A high density optical disk according to each example of the present invention will be described below. FIG. 1A shows the first embodiment of the present invention.
FIG. 1B is a cross-sectional view of a high density optical disc according to an example, and FIG. 1B is an enlarged view of an area A and an area B in FIG. In FIG. 1, 1 is a high density optical disc,
Reference numeral 2 is a transparent substrate having pits formed therein, and 3 is a reflective film layer formed of a material such as aluminum. Note that FIG.
(B) shows the case of a cross section in which each track has pits. Further, the protective film layer is omitted for simplification of the drawing. FIG. 2 is a diagram showing pits in the A area and the B area formed on the high density optical disc.

The inner radius r ₁ and the outer radius r ₅ of the high density optical disc 1 are, for example, r ₁ = the same as the size of a CD.
7.5 mm and r ₅ = 60 mm. The information recording area in which the pits are formed has a radius r ₂ in this embodiment.
And the area A - radius r _3, is divided into two regions in the region B of the radius r ₃ ~ radius r _4. Phase A pits having a track pitch p ₁ and a depth d ₁ are formed in the area A, and pits having a track pitch p ₂ and a depth d ₂ are formed in the area B.

Here, the radius r ₂ and the radius r ₃ are set so that the position of the area A coincides with the position of the lead-in area of the CD.
And r ₂ = 23 mm and r ₃ = 25 mm, respectively.
Further, in the area A, the track pitch p _{1 is set} so that various signals can be detected by the light spot of the CD reproducing device.
And the phase pit depth d ₁ are p ₁ = 1.6 ± 0.1 μm and d ₁ <0.13 μm, which are the standard values of CD. Incidentally, at least in the area A, the reflection film layer 3
The reflectance is 70% or more. In addition, the data bit string recorded as a pit string in the area A conforms to the signal format of the CD standard including the data modulation method, and the lead-in and the lead-out are in order from the inner peripheral side.

FIG. 3 shows an example of a lead-in subcode signal recorded in the area A. Here, when the start absolute time T ₁ of the first song is, for example, 0 minutes 0 seconds 0 frame, the final track absolute time is T ₂ and the lead-out track start absolute time is T ₃ , T ₁ = T ₂ = T ₃ Formula or T ₁ + several frames (or several seconds) = T ₂ Formula T ₂ + several frames (or several seconds) = T ₃ Formula Further, the start position of the absolute time is set within the area A having the radius r ₂ to the radius r ₃ , and further the lead-out is provided within the area A according to the equation or the equation.

By providing the pit string having the data bit string as described above, when the high-density optical disc 1 is mounted in a general CD reproducing apparatus, the reproduction is started.
The following operation can be expected as the operation of the CD reproducing device. That is, 1) Focusing operation, tracking control, and disk rotation control pull-in operation are performed on the area A. 2) Read the lead-in subcode data. 3) The reproduction operation is started from the absolute time 0 minutes 0 seconds 0 frame. 4) The lead-out is read immediately after the start of reproduction. 5) Focus control, tracking control, and disk rotation control are all turned off, and the reproducing operation is completed.

The data string in the area A is not limited to the above example, and may be any data string in which the reproducing operation of the CD reproducing device is completed in the area A.

On the other hand, in the region B, for example, the outer radius r ₅ is r ₅
= 60 mm, the radius r ₃ and the radius r ₄ are r
₃ = 25 mm and r ₄ <58 mm. In the region B, the track pitch p ₂ and the pit depth d ₂ are set to C so as to be suitable for reproduction by a small-diameter light spot.
The value is smaller than p ₁ and d ₁ which are the standard values of D. For example, values suitable for reproduction on an optical disk device having an optical head in which the wavelength of the light source is λ = 530 nm and the numerical aperture of the objective lens is NA = 0.55 are p ₂ = 0.9 μm and d ₂ <0.
It becomes 088 μm. In this case, the recording density in the area B includes the increase in the recording density in the track tangential direction,
It is about 3 times the recording density of the area A, that is, the CD.

Incidentally, the pit row formed in the B region is shown here by taking concrete numerical values as the track pitch p ₂ and the pit depth d ₂ by way of example.
_There is no particular limitation on the values of ₂ and d ₂ . Further, even if the values of p ₂ and d ₂ are the same as those of the CD, for example, since the data modulation method of the data bit string, the pit shape, etc. are different from those of the CD, a normal reproducing operation is performed in the CD reproducing device. It also includes pit rows that are not performed.

By constructing the high density optical disk as described above, the high density optical disk 1 is mistakenly used in the CD reproducing device.
Even if the CD player is mounted and the playback operation is started, the CD player can normally perform focus, tracking, and disk rotation control, and the runaway of the system control of the CD player can be prevented.

FIGS. 4 and 5 are diagrams showing tracks of a pit train near the boundary between the A area and the B area of the high density optical discs according to the second and third embodiments of the present invention. The third embodiment is an example in the case where the relationship of the track pitch of each area is p ₁ > p ₂ . In the second embodiment of FIG. 4, the tracks of the A area and the B area are discontinuous,
A pit-free portion (mirror portion) having a width p ₃ is provided at the boundary of each area. In the third embodiment of FIG. 5, the tracks of the A region and the B region are continuous, and a transition region of width p ₄ is provided which gradually reduces the track pitch from p ₁ to p ₂ over several turns. In FIG. 5, p ₁ > p ₄ > p ₂
Is. Further, the area B starts from the inner circumference side for at least one turn from the position where the track pitch starts to be reduced.

FIG. 6 is a diagram showing tracks of a pit string near the boundary between the A area and the B area of the high density optical disk according to the fourth embodiment of the present invention. In particular, the track pitch ratio of the A area and the B area is p. _This is an example suitable for the case where ₁ : p ₂ = 2: 1 ... In this embodiment, the first pits 4 are formed at the track pitch p ₁ over the entire recording area of the high density optical disc 1, and in the area B, the second pit row is formed at the center of the track pitch of the pit row 4. 5 is formed. As a result, the track pitch in the B area becomes 1/2 of p ₁ .

In each of the above-mentioned examples, a preferred example is shown in which the external dimensions of the high density optical disc 1 are substantially equal to those of the CD. However, in order to protect the CD reproducing device, the high density optical disc is naturally used. It may be arranged so that it cannot be physically mounted on the CD player. For example, the outer radius r in FIG.
₅ , at least _one of the inner radius r ₁ is expressed as r ₅ > 60 mm Formula r ₁ ≠ 15 mm Formula Alternatively, the external dimensions of the high density optical disc 1 are C
Even if it is substantially equal to D, by making the disc a cartridge built-in type, it is physically impossible to mount it on the disc turntable of the CD reproducing device. The object of the present invention can of course be achieved by the above method.

[0025]

As described above, according to the present invention, in a high density optical disc in which pits whose pit depth, track pitch, etc. are different from the CD value are formed, a radius of 23 mm to
In the area of 25 mm, pits of the same size as the CD are formed, and a CD standard lead-in as a data bit string,
By recording the lead-out information, even if the high-density optical disc is mistakenly attached to the CD reproducing device, the CD reproducing device is allowed to perform the operation from the reproduction start to the reproduction end based on the normal reproduction operation in the area. It becomes possible. As a result, it is possible to prevent various troubles that may occur due to the unstable system control operation in the CD reproducing device.

[Brief description of drawings]

FIG. 1 is a sectional view of a high density optical disc according to a first embodiment of the present invention.

FIG. 2 is an explanatory diagram showing pits formed on the high density optical disc according to the first embodiment of the present invention.

FIG. 3 is an explanatory diagram showing an example of contents of a subcode signal recorded in an area A in each embodiment of the present invention.

FIG. 4 is an explanatory diagram showing tracks at a boundary portion between an A area and a B area of a high density optical disc according to a second embodiment of the present invention.

FIG. 5 is an explanatory diagram showing tracks at a boundary portion between an A area and an B area of a high density optical disc according to a third embodiment of the present invention.

FIG. 6 is an explanatory diagram showing tracks at a boundary portion between an area A and an area B of a high density optical disc according to a fourth example of the present invention.

[Explanation of symbols]

 1 high density optical disc 2 transparent substrate 3 reflective film layer

Claims (6)

[Claims] 1. An optical disc in which phase pits are formed according to a signal, wherein a signal recording surface is divided in a radial direction into two or more regions including a first region and a second region, A high density characterized by forming phase pits having different phase pit depths, phase pit row intervals, phase pit shapes, or signal modulation methods in the first region and the second region, respectively. optical disk. 2. The phase pit formed in the first region according to claim 1, wherein the pit depth is 0.13 μm or less, and the phase pit row interval is 1.6 ± 0.
A high-density optical disc, which is formed to 1 μm. 3. The method according to claim 1, wherein the first region has a radius of at least 23 mm to 25 mm.
High-density optical disk characterized by including the range of. 4. The high density optical disc according to claim 1, wherein a mirror portion region having no phase pit is provided at a boundary portion between the first region and the second region. 5. The method according to claim 1, wherein a phase pit row interval between the first region and the second region is different, a boundary portion between the first region and the second region is A high-density optical disc, characterized in that a transition region for gradually changing the pit row interval is provided over one or more turns. 6. The disk recording according to claim 1, wherein when the ratio of the first area and the second phase pit row interval is 2: 1, the phase pit row interval of the first area is recorded. A high-density optical disc, wherein a first phase pit row is formed over the entire area, and a second phase pit row is formed in the center of the first area between the first phase pit rows in the second area.