JPS63298836A - Optical recording medium and its production - Google Patents

Abstract

PURPOSE:To eliminate the influence of grooves for tracking servo at the time of reproduction and to enable reproduction with a CD player by providing the grooves on the face on the side opposite to a recording layer. CONSTITUTION:After a transparent layer 3 and the recording layer 1 are formed on a transparent substrate 2, signals are written from an external information source to the prescribed place of the recording layer 1 through the substrate 2 to form pit arrays 11 thereon by using a laser pickup 21 for recording while the tracking servo is applied thereto by a laser pickup 22 for tracking servo utilizing the grooves 15 for tracking servo. A reflecting layer 5 is formed on the recording layer 1 after the information is recorded on the recording layer. The entire part of the recording layer 1 is thereafter faded, by which the recording layer is changed to the transparent layer 1' which has no specific absorption. In addition, only the deformations corresponding to the written information exist on the transparent layer and there are no grooves for tracking servo which increase the amplitude of a tracking error signal. The reproduction with the commercially marketed CD player is thereby enabled.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a writable optical recording medium and a method for manufacturing the same.

2. Description of the Related Art Optical recording media, especially optical disks, have been making remarkable progress in recent years, and as the market expands, it is expected that they will be used for a wide variety of purposes and applications. Generally, optical discs are broadly classified into two types: read-only discs and writable discs. The former uses a stamper on which information has been recorded, and by vapor-depositing aluminum onto a transparent substrate onto which the information on the stamper has been transferred by molding, tens of thousands of discs with the same information are manufactured. compact disc (hereinafter referred to as CD)
is a representative example.

By the way, CDs are relatively inexpensive because they are mass-produced by manufacturers, but small-scale production, especially application to personal music discs, has not been possible in terms of cost performance. Writable optical discs are suitable for purposes such as personal music discs and personal information files, but on the other hand, they are expensive to manufacture, are more than twice as thick as CDs, and are reflective. The current C
The D player could not reproduce the written signal.

Conventionally, in order to solve these problems, a recording layer made of an organic dye was formed on a transparent substrate, a semiconductor laser was focused on the recording layer to write a signal as a pit string, and then the recording layer was bleached and reflected. A method of forming layers was devised, which made it possible to create writable optical discs at low cost and to play them on commercially available CD players.

This method will be explained using figures. As shown in FIG. 4, a groove 41 for performing tracking servo in advance.
A fading recording layer 31 is formed on the transparent substrate 32 on which a recording layer 31 is formed, and then a signal is written as a pit train on this recording layer using a focused laser beam while applying a tracking servo, and then the recording layer 31 is faded. By further forming a reflective layer 33 on the recording layer having recorded pit rows, an optical recording medium having a structure as shown in FIG. 5 can be obtained.

Problems to be Solved by the Invention The optical recording medium obtained by the above method for manufacturing an optical recording medium is writable and has a high reflectance. However, when this medium is placed on an evaluation deck and the tracking error signal amplitude is observed with an oscilloscope with the tracking servo removed, the problem is that it is approximately twice the tracking error signal amplitude of a commercially available CD. There is. Therefore, some commercially available CD players cannot reproduce optical recording media obtained by this manufacturing method.

Means to solve the problem: Use a transparent substrate with grooves for tracking servo formed on one side and flat on the other side. and a step of forming a transparent layer that reflects the tracking servo laser beam, and a step of forming a recording layer on a flat surface of the transparent substrate that is perforated by the recording laser beam and can be used for recording. , While applying tracking servo using the groove, by irradiating the recording layer with the recording laser through the transparent substrate using a recording laser pink-up that is linked to the movement of the laser big amplifier for tracking servo, external A process of writing a signal from an information source to form a focused line on the recording layer, a process of forming a reflective layer on the recording layer where the focused line has been formed, a process of discoloring the entire recording layer, and the above steps. The optical recording medium obtained by the manufacturing method described above solves the above problems.

A tracking servo groove necessary for recording information is provided on the surface of the working transparent substrate opposite to the flat surface on which the recording layer is provided, and pickups are provided for tracking servo and recording, respectively. By interlocking the tracking servo, it is possible to record information on a predetermined flat location while applying tracking servo. Furthermore, by providing a reflective layer, the reflectance can be increased, and by discoloring the recording layer, it becomes a transparent layer that does not have any unique absorption, and the transparent layer also corresponds to the information written on it. Since only the deformation is present and there is no tracking servo groove that would increase the tracking error signal amplitude, it can be played on a commercially available CD player.

EXAMPLE Hereinafter, an example of the present invention will be described in detail with reference to the drawings.

1 to 3 are diagrams showing an outline of the optical recording medium in the main manufacturing steps according to the present invention. A groove 15 for tracking servo is formed on one side of the transparent substrate 2, and the other side 16 is flat. This transparent substrate 2 is preferably made of a material that does not absorb in the wavelength range of the semiconductor laser, and specifically,
Optical glass, methacrylic resin, polycarbonate resin, and other transparent resins are used. Further, to form the groove 15 for the tracking servo, a conventional method such as a method using a photocurable resin or injection molding using a stamper can be used.

A transparent layer 3 is formed on the surface of the transparent substrate 2 where the grooves 15 are located, which is transparent to the recording laser beam and reflective to the tracking servo laser beam having a wavelength different from that of the recording laser beam. Form. On the other hand, holes are formed on the flat surface 16 in response to the recording laser beam so that recording can be made.
Form 3 layers 1. The recording layer 1 used here has spectral absorption characteristics in the wavelength range of the semiconductor laser, a row of perforated pits is formed by the focused semiconductor laser, and the entire recording layer is easily discolored, and the spectral absorption characteristics described above are It is necessary to use a material whose absorption disappears, and organic dyes or dyes dispersed in transparent resins, particularly cyanine dyes, are suitable.

In addition, the transparent layer 3. The most suitable method for forming the recording layer 1 on the transparent substrate 2 is the spin code method, but dipping,
It can also be produced by methods such as roll coating. In addition,
It is also possible to form a thin protective layer in order to improve the solvent resistance of the transparent substrate 2 before applying the transmission layer or the recording layer.

After forming the transparent layer 3 and the recording layer N1 on the transparent substrate 2, as shown in FIG. A signal from an external information source is written to a predetermined location of the recording layer 1 through the transparent substrate 2 using the pickup 21 to form a pit array 11 (FIG. 2). Here, a tracking servo laser pickup 22 and a recording laser are used. The pickup 21 has a structure that can be interlocked with a mechanical mechanism or other mechanism. Further, the recording laser pink-up 21 performs focus servo control in the depth direction. In FIG. 1, the tracking servo laser pickup 22 and the recording laser pickup 21 are on the same side of the transparent substrate 2, but the tracking servo laser pickup 22 may be provided on the opposite side. Of course, this is possible as long as it is transparent to light. In this case, the tracking servo laser beam is focused on the transmitted JWs through the transparent substrate 2.

After recording information in the recording N1, a high reflectance can be easily obtained by vapor depositing aluminum as a method for forming the zero reflection layer forming the reflection N5. Then the recording layer!
By discoloring the entire recording layer, the recording layer becomes a 1° transparent layer and no longer has any unique absorption. An excellent method for this fading process is to irradiate specific light to oxidize and decompose the functional groups of the dye molecules that form the recording layer 1, and this method allows the recorded pits to fade without changing their shape. However, other generally known thermal fading or chemical fading methods can also be used. Note that the method for forming the reflective layer 5 and the fading process may be performed before or after the other. Furthermore, in order to protect the reflective layer 5, it is of course possible to apply a protective layer on this layer.

FIG. 3 shows the state during reproduction of the optical recording medium according to the present invention, in which the reproduction laser pickup 21' is inserted through the transparent substrate 2 into the transparent if' corresponding to the written information.
The focus is on the deformations (pits) on the upper surface. The wavelength of the reproducing laser is the same as the wavelength of the recording laser.

Since the structure of the optical recording medium shown in FIG. 3 has an information recording section essentially the same as that of a CD, it can be played back on a CD player.

Specific examples will be described below.

(Example 1) Thickness: 1.21-, depth: 0.08 μm, width: 0.8 μm on one side
A polycarbonate resin molded substrate 2 on which a μ city tracking servo groove 15 is formed in a spiral shape with a 1.6 μm pinch is prepared, and Victoria Blue ethanol having the spectral characteristics shown in FIG. 1 solution
The i3 overlayer 3 was formed by spin coding at 1000 rpm. On the other hand, a protective layer of 100 SiO□ was sputtered on the other flat surface, and then a methylene chloride solution of a polymethine dye having the spectral characteristics shown in Fig. 6 was spin-coded at 1100 Qrp to form the recording layer l. did. After that, using a deck equipped with a He-Ne laser as a tracking servo laser and a semiconductor laser with a wavelength of 830 nm as a recording laser, while applying tracking servo with the He-Ne laser pickup,
Information was written to the recording jilt at a linear velocity of S, and the written signal is a TTL level output signal from the CD encoder.Next, aluminum was deposited to a thickness of 800 mm on the recording layer l, and further It was exposed to light using a xenon arc lamp to fade and become transparent. When the completed optical disc was played on a CD player 5L-P3 (manufactured by Matsushita Electric Industrial ■), music could be played in the same way as a commercially available CD. The tracking error signal amplitude was almost equal to that of a commercially available CD.

(Example 2) An optical disc was obtained by the same method and steps as in Example 1, except that a dye represented by the following structural formula was used as the recording layer. When the completed optical disc was played back on a CD player as in Example 1, music could be played, and the tracking error signal amplitude was almost the same as that of a commercially available CD.

(Margins below) Effects of the Invention According to the present invention, it is possible to inexpensively manufacture a small-scale optical recording medium capable of recording and reproducing a wide variety of types, and furthermore, the tracking servo groove that increases the amplitude of the tracking error signal can be recorded. By providing it on the surface opposite to the layer, there is an effect that reproduction can be performed on an LCD player without being affected by the groove during reproduction. Furthermore, since optical discs such as optical video discs and CD-ROMs on which video information is recorded basically have the same disc structure, the optical recording medium according to the present invention can be played on these discs as well. There is a certain effect.

[Brief explanation of drawings]

Figures 1 to 3 are cross-sectional views showing the outline of the optical recording medium in the main manufacturing process according to the present invention, and Figures 4 and 5 show the state of the optical recording medium in the manufacturing process according to the conventional technology. A cross-sectional diagram representing
FIG. 6 is a graph showing the spectral transmittance of polymethine dyes, and FIG. 7 is a graph showing the spectral transmittance of Victoria Blue. 1...Recording layer, 1°...Transparent layer, 2.
...Transparent substrate, 3... Transmissive layer, 5...
...Reflection layer, 11...Pit row, 15...
... Tracking servo groove, 16 ... Flat surface, 21 ... Recording big amplifier, 21゛ ...
... Pickup for reproduction, 22 ... Pink up for tracking servo, 31 ... Discoloration recording layer, 32 ... Transparent substrate, 33 ...
Reflective layer, 41... Tracking servo groove. Name of agent: Patent attorney Toshio Nakao, Haka 1, Zoi Gohei

Claims (3)

[Claims] (1) A transparent substrate with a groove for tracking servo on one side and a flat surface on the other side has a groove that is transparent to the recording laser beam and different from the recording laser beam. A transparent layer is provided on the other flat surface of the transparent substrate, and a signal is transmitted as a surface deformation on the transparent layer. An optical recording medium comprising a reflective layer on a surface which is recorded and has a deformation. (2) The transparent layer absorbs the recording laser beam before information is recorded, and when reproducing the information after recording, it absorbs the reproduction laser beam of the same wavelength as the recording laser beam. The optical recording medium according to claim (1), which is transparent. (3) Using a transparent substrate with grooves for tracking servo formed on one side and flat on the other side, the surface with the grooves is transparent to the recording laser beam and the recording laser A step of forming a transparent layer that reflects a tracking servo laser beam having a wavelength different from that of light, and a recording capable of perforating and recording on the flat surface of the transparent substrate in response to the recording laser. In the step of forming a layer, while applying tracking servo using the groove with a tracking servo laser pickup, a recording laser is emitted through the transparent substrate using a recording laser pickup that is linked with the movement of the tracking servo laser pickup. A step of writing a signal from an external information source by irradiating the recording layer to form a pit string on the recording layer, a step of forming a reflective layer on the recording layer on which the pit string is formed, and a step of forming a reflective layer on the recording layer in which the pit string is formed. A method for producing an optical recording medium, which comprises the step of discoloring the entirety.