JPS62137744A - optical disc - Google Patents

Abstract

PURPOSE:To obtain an optical disk which has a RAM part and ROM part and excels in reliability and mass productivity by forming the same information recording medium to the RAM part and ROM part and putting only the ROM part recorded with fixed information in the recording state. CONSTITUTION:Rugged parts 20 are provided on a PMMA substrate 10 and the fixed information by pits is preliminarily formed in the rugged parts 20 in the ROM part. Guide grooves for making tracking in the recording state and address pits which are address information are preliminarily formed in the rugged parts 20 in the RAM part. A mask 21 imposed on the optical disk 24 and a xenon lamp 19 is made to emit light. The information recording layer in the ROM part of the disk 24 is put into the recording state by the irradiation rays 20 thereof. The optical disk in which the RAM part and ROM part co-exist is thus easily obtd. and an expansion in the system for applying the optical disk is made possible.

Description

[Detailed Description of the Invention] [Field of Application of the Invention] The present invention provides an R
The present invention relates to an optical disc including an OM section within one disc.

[Background of the invention]

Optical discs have entered the practical stage as media for recording large amounts of information.

Optical discs are broadly divided into read-only type optical discs (ROM discs) in which information is recorded in advance and only played back, and optical discs (RAM discs) in which information can be recorded and played back on its own (RAM discs). can.

Furthermore, when the above two types exist in an optical disk, the respective areas are referred to as a ROM section and a RAM section.

A ROM disk has information recorded on a transparent disk substrate as a row of uneven pits 7. To reproduce the recorded information, a laser beam spot is applied to the bit surface, and the reflected light from the pits and the This method utilizes the fact that the amount of detected light changes due to interference between light reflected from the surrounding area of the bit. This will be explained in detail in Fig. 5. Fig. 5 is a schematic diagram for explaining the reproduction method of an RJ QM disk, in which 1 is an optical disk (ROM disk), 2 is an information pit surface, and 6 is a semiconductor laser. , 4 is a magnifying lens, 5 is a half mirror, 96 is an objective lens, 7 is a condensing lens, and 8 is a detection confectionery (for example, a photodiode).

In the figure, the laser beam from the semiconductor laser 5 is magnified by a lens 4. ROM through half mirror 5 and objective lens 6
The light is focused on the information bit surface 2 of the disk 1. The reflected light from the information bit surface enters the photodiode 8 through the objective lens 6, half mirror 5, and condensing lens 7, and optical information based on the scanning information recorded on the information bit surface 2 is converted into an electrical signal. Convert and read. Tracking and focusing of a bit string are controlled by inputting a spot of reflected light from a bit surface to, for example, a four-division light receiving element.

A RAM disk records information on a transparent disk substrate using changes in reflectance due to heat mode, and reproduces information by detecting changes in reflectance. From this point on, the recording/reproducing method for this RAM disk will be explained.

FIG. 6 is a schematic diagram illustrating a method for recording and reproducing a RAM disk. Reference numeral 6 denotes an objective lens, which constitutes an optical system similar to that shown in FIG.

10 is a transparent substrate of the RAM disk, 11 is an information recording layer,
12 is a protective adhesive layer.

In the figure, information is recorded on the information recording layer 11 in a heat mode by laser light passing through an objective lens 6. The information recording layer 11 is made of, for example, a chalcogenide-based material, and utilizes the fact that the reflectance changes due to a phase change of the information recording layer caused by laser beam irradiation. When reading out information recorded in this way, the information recording layer is irradiated with a laser beam weaker than that used during recording, and the reflected light is extracted by an optical system similar to that shown in Figure 5, and is then used as a photodiode or other device. The detection element converts it into an electrical signal. The RAM disk shown in FIG. 6 is a double-sided optical disk made by bonding two disks together, and the protective adhesive layer 12 is shown as a single layer. 0 Optical disks have the advantage of having a large storage capacity compared to other information recording devices, and ROM disks allow large amounts of fixed information to be duplicated through resurification processes such as injection molding. .

Examples of detailed descriptions of the above-mentioned ROM disks and RAM disks include pages 108 to 110 of "Introduction to Video Discs and DAD" (January 10, 1988, published by Corona Publishing) and 128 to 129, or the one titled "Optical disk memory beginning to be used for image files" described in Nikkei Electronics, published January 4, 1982, pages 86 to 112.

By combining the features of the ROM disk and RAM disk as described above, the fields of application of the optical disk system can be expanded.

Specifically, it is sufficient to consider a case in which a ROM part and a RAM part are mixed on one original disk.

In order to obtain such a RA IVI-ROM mixed disk, the following problems were encountered.

(1) Usually, a ROM disk is equipped with an Al reflective layer, and its reflectance is about 80 inches, whereas a RAM disk is equipped with an information recording layer made of a chalcogenide-based material, and its reflectance is about 10 inches. It is about 20%. Therefore, if these are formed in one disk area, the reflectances of the two will be too different, making it extremely difficult for systems such as focusing and tracking control to handle them.

(2) In order to equalize the reflectance of both, it is possible to make the reflective layer of the ROM part the same as the information recording layer of the R11M part, but in this case, the ROM part may be irradiated with the recording laser beam by mistake. If so, there is a risk that the information in the ROM section may be destroyed.

(3) It is possible to make the RAM part and the R0M part using different materials, but this would make the optical disk manufacturing process very complicated.

[Purpose of the invention]

The object of the present invention is to eliminate the drawbacks of the above-mentioned prior art, and to
The objective of the present invention is to provide an optical disc that is equipped with a ROM section and a ROM section, and is highly reliable and mass-producible.

[Summary of the invention]

To achieve this objective, the present invention provides a RAM section and an RO section.
The feature is that the same information recording medium is formed in the M section, and only the ROM section in which fixed information is recorded is in a recording state.

Putting the information recording medium in the ROM section into the recording state means that the ROM section of the information recording medium as a RAM disk formed on the entire surface of the optical disk is in the recorded state in the RAM section, that is, the reflectance changes by irradiation with a recording laser beam. This is equivalent to the state of rubbing. Note that a state equivalent to when the information recording medium is not irradiated with a recording laser beam is referred to as an unrecorded state.

To put the ROM section into a recording state, an information recording medium as a RAM disk is formed across the ROM section and RAM section of the optical disk, and a mask is used so that only the ROM section is irradiated with light. Light is irradiated from a light source that includes a wavelength that is absorbed by the recording medium.

Since the difference in reflectance between the recorded state and the unrecorded state of the information recording medium is at most 2 to 3 times, system control such as focusing control 9 and tracking control is relatively easy. Then, RoMg+ko, R in the recording state
Even if the light beam (laser light) for recording the AM section is irradiated by mistake, the reflectance will hardly change and the ROM information will be saved since it is already in the recording state. Since the state is obtained by irradiating light using a mask as described above, the manufacturing process of the original disk according to the present invention becomes very simple.

[Embodiments of the invention]

Embodiments of the present invention will be described below with reference to the drawings. ○ FIG. 1 is a cross-sectional structural diagram showing an embodiment of an optical disc according to the present invention, and numeral 10 is an optically transparent PMMA (acrylic resin) substrate. , 15 is a 5bzSes layer, 14 is Bi
The layer 15 is a protective film made of an ultraviolet curing resin, 16 is an adhesive, and 20 is an uneven portion.

In the same figure, a two-layer recording film consisting of 5bzSe3415 and a Bi layer 14 is formed by vapor deposition to constitute an information recording layer, a protective film 15 made of an ultraviolet curing resin is formed on this, and two sheets are bonded together with an adhesive 16. A double-sided optical disc is obtained by pasting together two discs.

The thickness of each layer is 5bzSes layer 15 is 600 people, Bi
The layer 14 has a thickness of 250X, and the protective film 15 has a thickness of 30 μm.

An uneven portion 20 is provided on the PMMA group 8i10,
'In the ROM section, fixed information in the form of bits is formed in the uneven portion 20, and in the RAM section, a guide groove for tracking during recording and address pits that are address information are formed in the uneven portion 20. I'll keep it.

Next, a method of putting the information recording layer of the ROM section of the disk into a recording state will be explained.

FIG. 72 is a conceptual diagram showing an example of the method for forming an optical disk according to the present invention, in which 19 is a xenon lamp, 20 is an irradiation light beam, 21 is a mask, 22 is a mask substrate, 23 is a light shielding member, and 24 is an optical disk. .

In the figure, the information recording layer is designed to have a film thickness that utilizes the coherence of light so as to obtain large energy absorption in the wavelength range of the semiconductor laser used during recording. Therefore, in order to bring the information recording layer into a recording state by light irradiation, it is necessary to select a light emitting source that generates light having a wavelength near the semiconductor laser wavelength range. In the illustrated example, a xenon lamp is used as the light source. Xenon lamps are used for photography or for lighting squares, and their spectral energy distribution is not only close to natural daylight, but also extends to wavelengths around 800nrn, which is the wavelength range of semiconductor lasers. ing.

Therefore, a xenon lamp is a preferred light source for practicing the present invention.

The mask 21 irradiates the RAM portion of the optical disk 24 with the light beam 2.
A member for blocking light (light blocking member) 23 is provided on an optically transparent substrate 22, for example, glass.

The light blocking member 23 can be formed of a thin film of Cr, A1, etc., a paint containing an opaque dye or pigment, an opaque adhesive tape, or the like.

In this example, a light shielding layer of about 1000X Cr thin film was provided on a glass substrate.

The mask 21 thus formed is placed on the optical disk 24 again, the xenon lamp 19 is turned on, and the irradiation light 20
The information recording layer of the ROM portion of the optical disc 24 is put into a recording state.

FIG. 6 is a top view showing an embodiment of the optical disk according to the present invention, in which 24' is a ROM-RAM mixed type optical disk, 25a and 25b are RAM sections, and 26 is a ROM section. Reference numeral 26 indicates a portion where light is not blocked by the mask 21 in the ratio forming method shown in FIG. 2, and corresponds to a portion where the information recording layer is in a recording state.

FIG. 4 is a circuit diagram showing an example of a xenon lamp light emitting circuit for putting the ROM section of the optical disk into a recording state according to the present invention, in which 19 is a xenon lamp, and E is a power source r Tr.
is step-up transformer + CI + C2 is capacitor + R
+ + R2+ R3 is a resistor + y1+ SW2 is a switch, and G is a trigger electrode.

In the figure, by closing the switch SWI, the capacitor C is charged by the power supply E. After that, S
When W2 is closed, capacitors CI and C2 are connected to the transformer Tr.
A current flows due to the discharge ζ, and a high voltage of several thousand to a half voltage is applied to the trigger electrode G of the xenon lamp 19 due to the boosting action of the Tr. This allows xenon lamp 1
The gas in the xenon lamp 9 is ionized, the internal resistance is reduced, and a discharge is instantaneously generated between the two poles of the xenon lamp 19 to emit light. This light emission time is 2 mS to 0.5 mS.

In the above embodiments, a xenon lamp was used as the light emitting source, but the present invention is not limited to this, and various gas lasers may be used since the information recording medium absorbs energy widely, mainly in the semiconductor laser wavelength range. be able to. Furthermore, using a semiconductor laser, the RO of the optical disk is
It is also possible to expose the M portion one track at a time to bring it into a recording state.

In addition, although a two-layer recording film of 5b2S6s and Bi was used as the information recording medium, other chalcogenes were also used.

It goes without saying that the present invention can also be applied to compound compounds or information recording media that utilize diffusion.

Furthermore, in the above embodiments, the ROM section in the recorded state was formed by light irradiation, but conversely, the RAM section in the unrecorded state may be formed by light irradiation.

In the above embodiment, the entire ROM section of the optical disk is in the recording state, but the present invention is not limited to this. For example, the ROM section may be partially in the recording state, or the RA
A part of the M portion may be in a recording state.

〔Effect of the invention〕

As explained above, according to the present invention, by a simple method,
It is possible to easily obtain an optical disk in which a RAM section and a ROM section are mixed, it is possible to expand the application system of the optical disk, and it is possible to provide an optical disk with excellent functions by eliminating the drawbacks of the above-mentioned prior art.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional structural diagram showing an embodiment of an optical disc according to the present invention, FIG. 2 is a conceptual diagram showing an example of a method for forming an optical disc according to the present invention, and FIG. 3 is a diagram showing an embodiment of an optical disc according to the present invention. 4 is a circuit diagram showing an example of a xenon lamp light emitting circuit for putting the ROM portion of an optical disc into a recording state according to the present invention; FIG. 5 is a configuration diagram for explaining a method for reproducing a ROM disc; FIG. 6 is a schematic diagram illustrating a method for recording and reproducing a RAM disk. 10-PMMA substrate 13-8bzSe3 layer 14・B
i-layer 15...protective film 16...adhesive layer 19...
Xenon lamp 20... Uneven part 21... Mask 22... Mask substrate 25... Light blocking member 24
．． 24'...Optical disc patent attorney Masaru Ogawa
Man, Pa31 Figure 2゜Atsushi 20 Fu 3 Mouth

Claims (1)

[Claims] A RAM area where information can be stored and played back, and an RO area where information is formed in advance as a pit string and only played back.
In an optical disc having an M area, the optical disc has an information recording layer spanning a RAM area and a ROM area, and the RAM area of the information recording layer is in an unrecorded state,
An optical disc characterized in that the RAM area and the ROM area have substantially the same reflectance by setting the ROM area in a recording state.