JPH1173686A - Optical storage medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the width of grooves adequate for stabilizing signal quality, the adequate ratio of the width of lands and the width of prepits and the adequate depths of the prepits and grooves in the case the prepits are formed on the lands between the adjacent grooves. SOLUTION: The grooves 2 for recording desired information are concentrically or spirally formed on a substrate 1 and the lands 3 are formed in contact with both sides in the width direction of the grooves 2. The prepits 4, 4,... recording the address information of the optical disk are formed on continuation with the grooves 2 on the lands 3. The width of the grooves 2 is 1/3 to 1/2 the diameter of the spot 6 of a laser scanning beam for irradiating the surfaces of the grooves 2. The ratio of the width of the prepits 4 to the width of the lands 3 is specified to 0.3 to 0.6. The depths of both of the prepits 4 and the grooves 2 are specified to 40 to 65 nm.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an optical storage medium for optically recording and reproducing information.

[0002]

2. Description of the Related Art A conventional write-once optical disc is disclosed, for example, in Japanese Patent Laid-Open No. 4-368629.

As shown in FIG. 5, in a conventional write-once optical disc on which a groove (a guide groove functioning as a laser irradiation guide) is recorded, a groove 102 is formed concentrically or spirally on a substrate 101. Also, the groove 102
On the both sides in the width direction, lands 103, 103 are formed in contact with the groove 102, and the lands 103 are also formed concentrically or spirally.

[0004] Desired information is recorded in the groove 102. In the concentric or spiral locus of the groove 102, a preformat portion 104 is also formed instead of the groove 102. This preformat unit 1
.. Are formed in advance, and address information of the optical disk is recorded on the pre-pits 04.

To write desired information on the optical disk, the light spot 106 of the laser beam is
02, and scans in the direction of arrow 107. In the pre-format section 104, pre-pits 105, 105,.
This is performed by reading the address information formed in step (1) and writing information to be recorded in the groove 102.

The reading of information recorded on the optical disc is also performed by the pre-pit 10 of the pre-format section 104.
Read the address information of 5, 105,...
02 by reading the recorded information.

[0007]

However, in the prior art, since the groove 102 and the preformat portion 104 are formed on the same concentric or spiral track, the optical disk is formed by the amount of the preformat portion 104. There is a problem that the storage capacity of the device becomes small.

In order to solve this problem, a groove is also formed in a portion where a preformat portion is formed in the conventional technique, and prepits for receiving address information of the optical disk are in contact with both sides in the width direction of the groove. Formed in a part of the land, and this pre-pit is
It is conceivable to form the groove continuously from the groove so as to contact the side of the groove.

In this case, when reading and scanning are performed along the trajectory of the concentric or spiral groove, the laser beam is recorded while scanning over the groove in an area where the groove and the prepit coexist. The read information is read by a track sum signal of the amount of light detected by the photodetector divided in the tangential direction of the track on the optical disk. Further, the address information based on the pre-pits is read by a track difference signal of a push-pull signal for land tracking.

However, in this technique, in an area where a groove and a prepit coexist, the laser beam is focused while reading two pieces of information: information recorded on the groove and address information recorded on an adjacent land. Since the beam always scans over the groove, the pre-pit address information must be obtained as crosstalk to the recorded information of the groove, so appropriately select values such as groove width, pre-pit width, depth, etc. Otherwise, there is a problem that the signal quality becomes unstable.

An object of the present invention is to provide an appropriate groove width capable of stabilizing signal quality when prepits recording address information are formed on lands between adjacent grooves.

Another object of the present invention is to form an appropriate land width and prepit width which can stabilize signal quality when prepits recording address information are formed on lands between adjacent grooves. Is to provide a ratio.

Another object of the present invention is to provide an appropriate prepit or groove depth capable of stabilizing signal quality when prepits recording address information are formed on lands between adjacent grooves. Is to do.

[0014]

According to a first aspect of the present invention, a groove is formed concentrically or spirally on a substrate, and lands are formed in contact with both sides in the width direction of the groove. An optical storage medium for recording information in a groove, wherein prepits for recording address information of the optical storage medium are formed adjacent to the groove on the land, and the width of the groove is Is 〜 to の of the spot diameter of the scanning beam for irradiating.

Therefore, as for the size of the groove width of the groove, the smaller the groove, the larger the address signal can be obtained. However, when the width of the groove is too small, the amplitude itself of the address signal becomes small. Since the radial contrast is also reduced, the preferred groove width is １ ／ to の of the spot diameter of the scanning beam in consideration of both.

According to a second aspect of the present invention, a groove is formed concentrically or spirally on a substrate, and lands are formed in contact with both sides in the width direction of the groove, and information is recorded in the groove. An optical storage medium, wherein the ratio of the width of the prepit to the width of the land is 0.3 to 0.6.

Therefore, if the ratio of the width of the pre-pit to the width of the land is too small or too large, a sufficiently large address signal cannot be obtained. If the ratio is too large, the influence on the adjacent track appears. In order to obtain a signal sufficient to obtain the address information, the ratio is set to 0.
It is preferable to set it to 3 to 0.6.

According to a third aspect of the present invention, a groove is formed concentrically or spirally on a substrate, and lands are formed in contact with both sides in the width direction of the groove, and information is recorded in the groove. An optical storage medium, wherein each of the pre-pits and the grooves has a depth of 40 to 65 nm.

Therefore, if the depth of the groove and the prepit is 40 nm to 65 nm, a good address signal can be obtained when reading the prepit, and the formation of the groove becomes relatively easy.

[0020]

FIG. 1 is a partially enlarged plan view of an optical disk according to an embodiment of the present invention.

This optical disc employs a groove recording system, and a groove 2 is formed concentrically or spirally on a substrate 1. Desired information is recorded in the groove 2. On both sides in the width direction of the groove 2, lands 3, 3 are formed in contact with the groove 2, and the lands 3 are also formed concentrically or spirally.

The pre-pits 4, 4,... For recording the address information of the optical disk are formed continuously with the groove 2 on the land 3 adjacent to one side 5 of the groove 2.

In this optical disk, the light spot 6 of the laser condensed beam is scanned on the groove 2 in the direction of arrow 7 while the pre-pits 4, 4,.
It is necessary to obtain the address information.

FIG. 2 shows a reproduced signal obtained by the presence of the pre-pits 4, 4,... When the laser focused beam scans along the groove 2. This is obtained by a track difference signal (hereinafter simply referred to as a difference signal) of the push-pull signal for tracking the land 3. The address information of the optical disk by the pre-pits 4, 4,... Is read from the difference signal. That is, FIG.
5 is a graph in which a horizontal axis indicates a scanning position when scanning along the vertical axis and a vertical axis indicates a signal voltage of the difference signal. The region 10 in this signal voltage waveform is a waveform when scanning the region where the groove 2 and the pre-pits 4, 4,... Are adjacent to each other, and the other region is when the region where only the groove 2 is scanned. It is a waveform.

FIG. 3 shows the light spot 6 of the laser focused beam.
Are located at the center of the groove 2 in the width direction as shown in FIG. 1, the difference signal (vertical axis) obtained by the presence of the pre-pits 4, 4,. 4 is a graph showing measurement results when the ratio of the width Pw (horizontal axis) of the groove No. 4 is changed for a groove having a small groove width and a groove having a large groove width. here,
The laser focused beam used for scanning had a spot diameter of 0.9 μm and a wavelength of 635 nm.

From FIG. 3, it can be seen that the smaller the groove width of the groove 2, the larger the address signal (difference signal) by the larger pre-pits 4, 4,. However, if the width of the groove 2 becomes too small, the amplitude of the difference signal itself becomes small, and the radial contrast also becomes small. Therefore, from the balance between the two, the preferred width of the groove 2 is 0.30 in this example.
０．４0.45 μm, that is, １ ／ to よ い of the spot diameter of the laser scanning beam.

Further, as the ratio (Pw / Lw) of the width Pw of the prepit 4 to the width Lw of the land 3 increases as shown in FIGS. 3 and 4, the difference signal also has a larger value. However, when (Pw / Lw) is 0.6 or more, the influence on the adjacent track increases, and a large difference signal is obtained by the pre-pits during scanning of the adjacent track. Therefore, the condition of 0.3 ≦ (Pw / Lw) ≦ 0.6 is optimal for obtaining a difference signal sufficient to obtain address information and not affecting adjacent tracks. I understood

FIG. 4 shows the light spot 6 of the laser focused beam.
Are centered in the width direction of the groove 2 as shown in FIG. 1, the difference signal (vertical axis) obtained by the presence of the pre-pits 4, 4,... Of the change in the ratio of the width Pw (horizontal axis) of the groove 2 and the depth of the prepit 4 to 40 n
It is the graph shown about the case where it was set to m, 60 nm, and 80 nm.

As can be seen from the figure, the difference signal can be made relatively large when the depth of the groove 2 and the pre-pit 4 is 40 nm, and becomes even larger when the depth is 60 nm. Assuming 80 nm, the depth is 4
The difference signal is much lower than in the case of 0 nm. Therefore, the depth of the groove 2 and the pre-pit 4 is set to 40 nm or more.
It was found that a good push-pull signal can be obtained when reading the pre-pits 4, 4,..., And that the formation of the groove is relatively easy if the thickness is 65 nm.

As described above, when the pre-pits 4, 4,... Are formed on the lands 3 between the adjacent grooves 2, 2, the appropriate width of the grooves 2 and the appropriate lands 3 can stabilize the signal quality. And the width of the pre-pits 4 and the appropriate depth of the pre-pits 4 and grooves 2 can be obtained.

[0031]

According to the first aspect of the present invention, a groove is formed concentrically or spirally on a substrate, and lands are formed in contact with both sides in the width direction of the groove. An optical storage medium for recording, wherein pre-pits for recording address information of the optical storage medium are formed adjacent to the grooves on the lands, and the width of the grooves is determined by irradiating the grooves with light. Since the beam spot diameter is 1/3 to 1/2 of the beam spot diameter, the groove width of the groove should not be too large or too small to obtain a sufficiently large address signal. Thus, it is possible to provide an appropriate groove width that can stabilize signal quality.

According to a second aspect of the present invention, a groove is formed concentrically or spirally on a substrate, and lands are formed in contact with both sides in the width direction of the groove to record information on the groove. Since the optical storage medium is characterized in that the ratio of the width of the prepit to the width of the land is 0.3 to 0.6, the ratio of the width of the prepit to the width of the land must be a sufficiently large address. An appropriate land width to prepit width ratio that can stabilize signal quality can be provided by not being too large or too small to obtain an information signal.

According to a third aspect of the present invention, a groove is formed concentrically or spirally on a substrate, and lands are formed in contact with both sides in the width direction of the groove, and information is recorded in the groove. Since the optical storage medium is characterized in that the depth of each of the prepits and the grooves is 40 to 65 nm, the depths of the grooves and the prepits are sufficient to obtain a sufficiently large signal of address information. Proper groove and pre-pit depths that can stabilize signal quality can be provided without being too large or too small.

[Brief description of the drawings]

FIG. 1 is a partially enlarged plan view of an optical disc according to an embodiment of the present invention.

FIG. 2 is a graph showing a relationship between an address signal and a scanning position by the optical disc.

FIG. 3 is a graph showing a relationship between an address signal and a prepit width / land width by the optical disc.

FIG. 4 is a graph showing a relationship between an address signal and a prepit width / land width by the optical disc.

FIG. 5 is a partially enlarged plan view of a conventional optical disk.

[Explanation of symbols]

 1 substrate 2 groove 3 land 4 pre-pit

Claims (3)

[Claims] 1. An optical storage medium for recording information in a groove, wherein a groove is formed concentrically or spirally on a substrate, and a land is formed in contact with both sides in the width direction of the groove. Prepits for recording address information of the optical storage medium are formed on the lands adjacent to the grooves, and the width of the grooves is 1/3 to 1/3 of the spot diameter of a scanning beam applied to the grooves. An optical storage medium characterized by being 1/2. 2. An optical storage medium for recording information in a groove, wherein a groove is formed concentrically or spirally on a substrate, and lands are formed in contact with both sides in the width direction of the groove. The ratio of the width of the pre-pit to the width of the land is 0.3-0.
6. An optical storage medium according to claim 6, wherein 3. An optical storage medium for recording information on said groove, wherein a groove is formed concentrically or spirally on the substrate, and lands are formed in contact with both sides in the width direction of the groove. Prepits and grooves have a depth of 40 to 6
An optical storage medium having a thickness of 5 nm.